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Theme 1
Molecules, Cells and the Basis
for Disease
2018/2019
2 | 6 9
Molecules, Cells and the Basis for Disease
This theme brings together stem cells and regenerative medicine (inc. cellular
therapies), immunology, genetics, cellular biology (particularly relating to
cancer), and biophysics. These areas – and particularly the interfaces between
them – are current strengths and priorities for King’s.
Lead: Professor Rebecca Oakey
When choosing a project from this catalogue in the funding section & research proposal
section of the online application form please enter MRCDTP2018_Theme1
Deadline for application: Sunday 26th
November 2017
Shortlisted candidates will be contacted in early January.
Interviews: 31st January & 1
st February 2018
The 2018/19 studentships will commence in September 2018.
For further Information or queries relating to the application process please contact
mrc-dtp@kcl.ac.uk
Projects listed in this catalogue are subject to amendments,
candidates invited to interview will have the opportunity to discuss
projects in further detail.
3 | 6 9
Contents 1.1 Targeting Wnt signaling for therapy in human prostate cancer (PCa) stem like cells .................. 5
2.1 Using exosomal delivery to gene-edit pancreatic cancer cells for therapy .................................. 6
3.1 Autoimmune pain ......................................................................................................................... 8
4.1 Manipulating the pituitary stem cell compartment during development and disease ................ 9
5.1 Exploring the impact of defects in DNA repair and DNA tolerance pathways on DNA damage
and mutations induced by human carcinogens using next generation sequencing ........................ 10
6.1 Investigation into novel immunotherapeutics which target the development of tumour
associated macrophages in cancer ................................................................................................... 12
7.1 Exploring epigenetic alterations to elucidate the role of smoking in inflammatory bowel
disease: implications for therapy ...................................................................................................... 13
8.1 A characterisation of IL-36 signalling as a therapeutic target in psoriasis .................................. 15
9.1 Investigating developmental and epigenetic mechanisms of adipose tissue homeostasis. ...... 17
10.1 Defining cellular and molecular mechanisms underlying cancer immunotherapy-induced
auto-inflammatory syndromes ......................................................................................................... 18
11.1 Allergic Disease: To Nip in the Bud ........................................................................................... 19
12.1 Integrative analysis of multi-omics datasets for the identification and validation of immune
biomarkers in psoriasis ..................................................................................................................... 20
13.1 Broadly neutralizing antibody responses in HIV infection ........................................................ 22
14.1 Cell Death for Regeneration: Mesenchymal Stromal Cells and Myocardial Repair .................. 23
15.1 Identification of novel immunomodulatory target checkpoints for Prostate Cancer
therapeutics ...................................................................................................................................... 25
16.1 The effect of lipid composition on the mechanostransduction of individual live cells ............ 27
17.1 The CXCL8-producing T cell in infants: function in health and HIV........................................... 28
18.1 Mechanisms of action of a novel marine natural product for the management of
osteoporosis and metabolic bone disease........................................................................................ 29
19.1 A Wnt-based Bioengineering Approach To Polarise Osteosarcoma and limit their tumorigenic
potential ............................................................................................................................................ 30
20.1 The role of the Larp6 RNA binding protein in vertebrate oogenesis, development and fertility
.......................................................................................................................................................... 31
21.1 The role of the pro-FLG Ca2+-binding domain in the formation of the skin barrier and
pathogenesis of atopic dermatitis .................................................................................................... 33
22.1 The role of glycosylation in the biological functions of tumour antigen-specific IgE class
antibodies ......................................................................................................................................... 35
23.1 Dissecting the influence of chromatin modifications on muscle stem programming by a
quantitative live cell imaging approach ............................................................................................ 36
24.1 Investigate a novel, unexplored link between WNT signalling and regulators of cell migration
in cancer progression. ....................................................................................................................... 38
25.1 Novel functions of long noncoding RNAs in cancer .................................................................. 40
4 | 6 9
26.1 HIV-1 mediated reprogramming of T cell gene expression networks ...................................... 41
27.1 Role of intrahepatic Tregs in the modulation of liver inflammation and the promotion of
tissue regeneration ........................................................................................................................... 42
28.1 Identification of host factors that promote assembly of Ebola virus ....................................... 43
29.1 Identification of type 1 diabetes-associated non-canonical spliced epitopes and their
immunological role in the autoimmune response ............................................................................ 44
30.1 Explaining the sexual dimorphism in Lupus through genetics .................................................. 45
31.1 Role of c-Fos in mucosal infections, immunity and microbiome interactions .......................... 46
32.1 Type 1 interferon resistance in the HIV-1 envelope glycoprotein ............................................ 47
33.1 Inhibition of Salmonella and Shigella intracellular replication by interferon-stimulated genes.
.......................................................................................................................................................... 49
34.1 Understanding regulation of cellular energy metabolism ........................................................ 51
35.1 Long range interactions of regulatory elements influencing gene expression in bronchial
epithelial cells ................................................................................................................................... 53
36.1 Determining how a novel complex promotes tumour growth, by protecting an iron-sulphur
cluster from cancer-associated oxidative stress. .............................................................................. 54
37.1 Exploring novel molecular mechanisms driving skin fibrosis.................................................... 55
38.1 Modulation of host immunity to prevent bacterial infection ................................................... 57
39.1 The molecular basis of erythrocyte cation transport abnormalities in sickle cell disease ....... 58
40.1 Monocytes and monocyte-derived cells as therapeutic targets in kidney disease .................. 59
41.1 Nutritional genomics as an emerging tool for the prevention of cardiovascular disease ........ 60
42.1 Modeling diabetes using induced Pluripotent Stem Cells (iPSCs): investigating the regulation
of Ngn3 in iPSCs to beta cell differentiation. .................................................................................... 61
43.1 Role of fat tissue gene expression in Type 2 Diabetes and Obesity ......................................... 63
44.1 Structural and functional determinants of kinesin-1-dependent cellular transport in
neurodegeneration and aging .......................................................................................................... 64
45.1 Investigating human regulatory T cell subsets in autoimmunity and transplantation ............. 65
46.1 Dissecting the heterogeneity of tumour-infiltrating phagocytes: implications for tissue
remodelling and immunotherapy. .................................................................................................... 67
47.1 Therapeutic target discovery in severe inflammatory skin disease.......................................... 69
48.1 Improving skeletal muscle function in the muscle wasting disease FSHD................................ 70
49.1 Tackling hearing loss: development, regeneration and reconstruction of the ear .................. 72
5 | 6 9
1.1 Targeting Wnt signaling for therapy in human prostate cancer (PCa) stem like cells
Co-supervisor 1A: Aamir Ahmed
Research Division or CAG: School of Basic and Medical Biosciences/ Division of Genetics and
Molecular Medicine
E-mail: aamir.ahmed@kcl.ac.uk
Website: https://www.kcl.ac.uk/lsm/research/divisions/gmm/departments/stemcells/people/Dr-
Aamir-Ahmed.aspx
Co-supervisor 1B: Prokar Dasgupta
Research Division or CAG: DTIMB
Email: prokar.dasgupta@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/prokar.dasgupta.html
Project Description:
PCa is the most frequently diagnosed cancer in men and in the UK kills about 10,000 men every year.
It has been proposed that cells in aggressive PCa acquire properties and expression profile resembling
embryonic stem cells (ESC). Self-renewal, a key property of stem cells, is regulated by the Wnt
signaling cascade for which Ca2+ and ß-catenin transcription factor co-activators are intracellular
transducers. We have shown that Wnt signaling is important in PCa but its role in PCa stem like cells
has not been characterized. Targeting Wnt signalling in PCa stem cells with our novel membrane
potential regulating compound (MPRC) inhibitors (International Patent Application
PCT/GB2014/053138) could provide an effective treatment for this disease. The key objective will
be to investigate the role of Wnt signaling and potential for MPRC to inhibit Wnt signaling regulated
self renewal in human PCa stem like cells using the following techniques:
1. Quantitative multilabel immunochemistry for stem cell, Wnt, PCa and ESC signature markers
to identify stem cells in situ using confocal and super resolution microscopy (Year 1)
2. Magnetic and fluorescence activated cell sorting, using markers such as Trop2 and CD49f to
isolate human PCa stem like cells (Year 1)
3. Cell culture characterization and knockdown for Wnt signaling genes in PCa derived cells
using CRISPR/Cas9 (Years 1/2)
4. Patch clamp, live calcium imaging and immunocytochemistry for ß-catenin ± MPRCs to
investigate functional activity of Wnt signaling (Years 2/3)
5. Serial transplantation of PCa stem like cells in in vivo mouse models (Year 3)
One representative publication from each co-supervisor:
Petrou T, Olsen HL, Thrasivoulou C, Masters JR, Ashmore JF, Ahmed A: Intracellular Calcium
Mobilization in Response to Ion Channel Regulators via a Calcium-Induced Calcium Release
Mechanism. J Pharmacol Exp Ther 2017;360:378-387
Yamamoto H, Masters JR, Dasgupta P, Chandra A, Popert R, Freeman A, Ahmed A: CD49f is an
efficient marker of monolayer- and spheroid colony-forming cells of the benign and malignant human
prostate. PLoS One 2012;7:e46979.
6 | 6 9
2.1 Using exosomal delivery to gene-edit pancreatic cancer cells for therapy
Co-supervisor 1A: Prof Khuloud T Al-Jamal
Research Division or CAG: IPS
E-mail: Khuloud.al-jamal@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/khuloud.al-jamal.html
Co-supervisor 1B: Claire Wells
Research Division or CAG: Cancer
Email: claire.wells@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/claire.wells.html
Collaborating Clinician: Dr. Debashis Sarker
Research Division or CAG: Cancer Studies
Email: debashis.sarker@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/debashis.sarker.html
Project Description:
Pancreatic cancer (PC) currently has no effective treatment. The development of exosomes as
delivery systems for biologics is an emerging topic in the field of cancer therapy. An attractive target
is the PAK family kinases (PAK1-6) many of which are overexpressed in pancreatic cancer and have
previously been shown to drive both proliferation and cell invasion.
This 3+1-year project aims to validate the role of PAK family in PC progression using a combination
of gene-editing approach and exosomal delivery (nanomedicines).
In the rotation project, the candidate will learn techniques such as culturing PC cells, isolation and
characterisation of exosomes: size and surface markers (CD81/CD9) by nanoparticle tracking analysis
and flow cytometry, respectively. Exosomes will be fluorescently labelled and uptake in cancer cells
will be studied by flow cytometry.
Plans for Years 1-3 are as follows:
Year 1: Target validation and engineering of exosomes
Initially, the role of PAK family genes will be studied by siRNA technology using commercial
transfecting reagents. The two most effective genes will be picked up for subsequent CRISPR-gene-
editing studies. Exosomes (as carriers) will be engineered to carry Cas9/gRNA complex (therapeutic
cargo).
Year 2: In vitro efficacy studies
The ability of exosomes to deliver Cas9/gRNA complexes into pancreatic cancer cells will be studied
by flow cytometry. Gene-editing and effect on cell proliferation will be studied by molecular biology
techniques (PCR, Western Blotting, T7 assay) and cell proliferation assay, respectively.
Year 3: In vivo biodistribution and therapy studies
Quantitative uptake of exosomes will be assessed in orthotopic pancreatic cancer mouse model by ex
vivo gamma counting. Therapeutic effect will be monitored by measuring tumour size by live animal
bioluminescence imaging.
Year 3: In vivo biodistribution and therapy studies
7 | 6 9
Quantitative uptake of exosomes will be assessed in orthotopic pancreatic cancer mouse model by ex
vivo gamma counting. Therapeutic effect will be monitored by measuring tumour size by live animal
bioluminescence imaging.
One representative publication from each co-supervisor:
Bai J, Wang J T-W, Rubio N, Protti A, Heidari H, Elgogary RI, Southern P, Al-Jamal WT,
Sosabowski JK, Shah AM, Bals S, Pankhurst QA and Al-Jamal KT. (2016) Triple-modal imaging of
magnetically-targeted nanocapsules in solid tumors in vivo, Theranostics. 6(3): 342–356.
Helen King, Kiruthikah Thillai, Andrew Whale, Prabhu Arumugam, Hesham Eldaly, Hemant M
Kocher and Claire M Wells (2017). PAK4 interacts with p85 alpha:implications for pancreatic cancer
cell migration. Nature Scientific Reports 7:42575
8 | 6 9
3.1 Autoimmune pain
Co-supervisor 1A: David Andersson
Research Division or CAG: Wolfson CARD, IOPPN
E-mail: david.andersson@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/david.andersson.html
Co-supervisor 1B: Stuart Bevan
Research Division or CAG: Wolfson CARD, IOPPN
Email: stuart.bevan@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/stuart.bevan.html
Project Description:
About 10% of adults in the UK suffer from chronic pain, with about half of this group experiencing
depression and 25% losing their jobs because of pain (Chief Medical Officer). The available therapies
are ineffective in many patients and for several important disorders the cause of pain is unknown.
We have discovered that Complex Regional Pain Syndrome (CRPS) is an autoimmune condition,
where autoantibodies cause pain by stimulating pain-sensing nerves. CRPS can be studied in a
“passive transfer” model, where antibodies purified from patients produce a CRPS-like condition in
mice. The identification of CRPS as an autoimmune condition will lead to new opportunities for
development of treatments and diagnostic tools.
Very recently we have discovered that a second, far more common, musculoskeletal pain disorder can
be transferred from patients to mice using passive transfer. During this studentship, the student will
have an opportunity to identify the cause of this common chronic pain disorder.
In the first 12-18 months, the PhD student will determine the effects of patient antibodies on the
function of mouse sensory nerves using electrophysiology (skin-nerve preparations).
During the remainder of years 2-3, the effect of patient antibodies on neurons isolated from mice will
be studied to identify the mechanisms responsible for pain.
Throughout the project, the student will use histochemical, biochemical and proteomic approaches to
identify molecules targeted by autoantibodies.
Year 4 will be spent completing experiments, writing manuscripts, thesis and fellowship applications.
The student will be encouraged to present findings at national and international meeting.
One representative publication from each co-supervisor:
Andersson DA, Gentry C, Alenmyr L, Killander D, Lewis SE, Andersson A, Bucher B, Galzi JL,
Sterner O, Bevan S, Hogestatt ED, Zygmunt PM (2011) TRPA1 mediates spinal antinociception
induced by acetaminophen and the cannabinoid Delta(9)-tetrahydrocannabiorcol. Nat Commun
2:551.
Quallo T, Vastani N, Horridge E, Gentry C, Parra A, Moss S, Viana F, Belmonte C, Andersson DA,
Bevan S (2015) TRPM8 is a neuronal osmosensor that regulates eye blinking in mice. Nat Commun
6:7150.
9 | 6 9
4.1 Manipulating the pituitary stem cell compartment during development and
disease Co-supervisor 1A: Cynthia Andoniadou
Research Division or CAG: Dental Institute
E-mail: cynthia.andoniadou@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/cynthia.andoniadou.html
Twitter: @PituitaryLab
Co-supervisor 1B: Corinne Houart
Research Division or CAG: IOPPN
Email: corinne.houart@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/corinne.houart.html
Project Description:
Background
This project will study the function of novel determinants that regulate stem cell potential during
development and disease. The Hippo kinase cascade is a signaling pathway regulating organ size,
proliferation and apoptosis and we have found this to be active in pituitary stem cells (Lodge et al
2016). We have recently established that deregulation of this cascade in the pituitary leads to
neoplasia, where stem cells undergo uncontrollable rounds of symmetric divisions. This project will
explore the molecular mechanisms underlying this process and aim to restore normal stem cell
behaviour through pharmacological targeting of the Hippo pathway. This research ultimately aims to
open new avenues for safer and better treatments for human conditions and the findings will
additionally be of relevance to regenerative medicine approaches.
Objectives for 3mo rotation
The student will use in vitro approaches on stem cell cultures and ex vivo on whole pituitaries, to
assess the effects of pharmacological manipulation of the Hippo pathway on pituitary stem cell
behaviour and potential.
Objectives for 3y PhD
1. To test the action of pharmacological manipulation of the Hippo pathway in vivo, on genetic models
of pituitary tumours and in zebrafish xenograft models.
2. To understand the molecular mechanisms regulating cell fate decisions via Hippo signalling,
through mouse genetics and molecular biology approaches.
Laboratory skills training provided
Mouse genetics, zebrafish injections, developmental biology, dissection, immunofluorescence, ex
vivo/in vitro culture, microscopy, molecular biology, RNAscope in situ hybridisation.
One representative publication from each co-supervisor:
Andoniadou CL et al, (2013) Sox2+ stem/progenitor cells in the adult mouse pituitary support organ
homeostasis and have tumor-inducing potential. Cell Stem Cell, Oct;13(4):433-45.
Thomas-Jinu S, […], and Houart C. Non-nuclear Pool of Splicing Factor SFPQ Regulates Axonal
Transcripts Required for Normal Motor Development. Neuron. 2017 May 17;94(4):931
10 | 6 9
5.1 Exploring the impact of defects in DNA repair and DNA tolerance pathways on
DNA damage and mutations induced by human carcinogens using next generation
sequencing
Co-supervisor 1A: Dr. Volker M. Arlt
Research Division or CAG: Analytical and Environmental Sciences Division/MRC-PHE Centre for
Environment & Health/ NIHR Health Protection Research Unit in Health Impact of Environmental
Hazards
E-mail: volker.arlt@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/volker.arlt.html
Co-supervisor 1B: Prof. David H. Phillips
Research Division or CAG: Analytical and Environmental Sciences Division/MRC-PHE Centre for
Environment & Health/ NIHR Health Protection Research Unit in Health Impact of Environmental
Hazards
Email: david.phillips@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/david.phillips.html
Project Description:
Modern life involves unavoidable exposure to environmental carcinogens. These can damage cellular
DNA and cause mutations that make key contributions to various human diseases including cancer.
To ensure genome integrity, DNA damage response (DDR), DNA repair and DNA damage tolerance
pathways act as fail-safe mechanisms. Mutations in DNA repair genes have been linked to tumour
development but the underlying role of DNA repair defects in mutagenesis is less well characterised.
In addition, certain types of DNA damage are substrates for DNA damage tolerance pathways.
Translesion synthesis (TLS) polymerases can bypass the damage to enable replication to continue.
However, error-prone TLS can lead to mutations.
The project aims to determine the mutational patterns induced by DNA damaging agents (i.e.
environmental carcinogens or chemotherapeutic drugs) in human induced pluripotent stem cells by
next generating sequencing.
Objectives are:
• to investigate cellular responses in normal and DNA repair- or TLS polymerase-defective
cells (YEAR 1+2).
• to use whole genome sequencing to gain insights into how DNA repair or DNA damage
tolerance pathways prevent or promote mutagenesis (YEAR 3+4).
Correlation between mutagenesis linked to gene-environmental interactions and reduced cellular
viability, activation of DDR pathways and induced DNA damage will be sought. Mutation patterns
obtained by whole genome sequencing will be compared with mutational signatures in human cancer
genomes in the COSMIC database (Catalogue Of Somatic Mutations In Cancer;
http://cancer.sanger.ac.uk/cosmic) database. Bioinformatics analysis will reveal conserved mutation
patterns and illuminate how deficiencies in DNA repair or DNA tolerance pathway prevent or
promote mutagenesis induced in human cells.
One representative publication from each co-supervisor:
Kucab JE, Zwart EP, van Steeg H, Luijten M, Schmeiser HH, Phillips DH, Arlt VM (2016) TP53
and lacZ mutagenesis induced by 3-nitrobenzanthrone in Xpa-deficient human TP53 knock-in
mouse embryo fibroblasts. In: DNA Repair, 39, 21-33.
11 | 6 9
Alexandrov LB, Ju YS, Haase K, Van Loo P, Martincorena I, Nik-Zainal S, Totoki Y, Fujimoto A,
Nakagawa H, Shibata T, Campbell PJ, Vineis P, Phillips DH, Stratton MR (2016) Mutational
signatures associated with tobacco smoking in human cancer. In: Science, 354, 618-622.
12 | 6 9
6.1 Investigation into novel immunotherapeutics which target the development of
tumour associated macrophages in cancer
Co-supervisor 1A: Dr James Arnold
Research Division or CAG: Cancer Sciences
E-mail: james.n.arnold@kcl.ac.uk
Website: https://www.kcl.ac.uk/lsm/research/divisions/cancer/research/groups/tig.aspx
Co-supervisor 1B: Professor Joy Burchell
Research Division or CAG: Cancer Science
Email: joy.burchell@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/joy.burchell.html
Project Description:
the tumour microenvironment and facilitate cancer progression. Macrophages get hijacked by the
tumour to help support angiogenesis, immune and chemotherapeutic suppression, and tumour cell
migration which results in metastasis. Our laboratory has characterised a subpopulation of TAMs
which have potent immune suppressive functions in the tumour microenvironment. However, little is
currently known about the environmental signals which these cells receive to direct their generation
within the tumour. Macrophages are a highly plastic cell type and their phenotype is acutely defined
by the microenvironment in which they differentiate. By understanding the key environmental cues
that these cells are responding to will allow for us to further understand the response pathways being
utilised by these cells. Also, this investigation will allow for us to identify novel targets for therapeutic
intervention, and even potentially uncover the key to preventing these cells from adopting the
phenotype altogether.
The proposed project will utilise spontaneous in vivo models of breast cancer and a novel transgenic
model that has been developed by the laboratory, alongside transcriptomic microarray analyses and
gene knockdown studies to try to gain insight into the key signals directing the TAM’s pro-tumoural
phenotype. Once the targets of interest have been identified they will be investigated in detail for their
role in macrophage differentiation. The findings will be validated in human breast cancer, utilising in
vitro macrophage culture, tumour sections and online patient survival and expression databases.
This project will utilise the following techniques: Transcriptomic microarray and associated software
analysis, flow cytometry, confocal microscopy, quantitative reverse transcriptase PCR, Western blot,
In vivo and ex vivo models, cell culture (primary and cell line), co-culture, and therapeutic
interventions (small molecule inhibitors, neutralising antibodies).
Objectives
Year 1 Target identification/establishment of assays
Year 2 In vivo and in vitro characterisation of targets in TAM development
Year 3 Identification and validation of a strategy to therapeutically exploit the target using in vivo
models
One representative publication from each co-supervisor:
Arnold JN, Magiera L, Kraman M, Fearon DT. Tumoral immune suppression by macrophages
expressing fibroblast activation protein-α and heme oxygenase-1. Cancer Immunol Res. 2014
Feb;2(2):121-6.
13 | 6 9
Beatson R, Tajadura-Ortega V, Achkova D, Picco G, Tsourouktsoglou TD, Klausing S, Hillier M,
Maher J, Noll T, Crocker PR, Taylor-Papadimitriou J, Burchell JM. The mucin MUC1 modulates
the tumor immunological microenvironment through engagement of the lectin Siglec-9. Nat
Immunol. 2016 Nov;17(11):1273-1281.
7.1 Exploring epigenetic alterations to elucidate the role of smoking in inflammatory
bowel disease: implications for therapy
Co-supervisor 1: Jordana Bell
Research Division or CAG: Department of Twin Research and Genetic Epidemiology
E-mail: jordana.bell@kcl.ac.uk
Website:
http://www.kcl.ac.uk/lsm/research/divisions/gmm/departments/twin/research/bell/index.aspx Twitter: @jordanatbell
Co-supervisor 2: Natalie Prescott
Research Division or CAG: Department of Medical and Molecular Genetics
Email: natalie.prescott@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/natalie.prescott.html
Project Description:
Inflammatory bowel disease (IBD) represents a group of autoimmune diseases that affect the
gastrointestinal tract, with two primary disease subtypes - Crohn’s Disease (CD) and Ulcerative
Colitis (UC). It is well established that smoking has a strong influence on IBD, but with striking
divergent risk effects between CD and UC: while smoking is a risk factor in CD with detrimental
effects on its clinical course, smoking has protective effects in UC with a beneficial influence on
progression. Much research has explored the differential smoking effects in IBD subtypes, but the
molecular mechanisms involved are poorly understood.
Epigenetic mechanisms, including DNA methylation, are key regulators of gene expression and can
mediate environmental disease risk. Many studies have identified a strong influence of smoking on
methylation, with distinct methylome signatures at many genomic loci, which can persist for decades
after quitting smoking.
Our hypothesis is that epigenetic alterations mediate the differential effects of smoking on CD and
UC. The project will investigate this in a cohort of IBD patients and healthy controls (TwinsUK)
using genome-wide DNA methylation profiles in multiple tissues including intestinal biopsies from
smokers and non-smokers.
Aim 1. Identify epigenetic changes in the gut and blood that mediate the contrasting risk effects of
smoking on CD and UC.
Aim 2. Explore gene expression profiles in biopsies from patients and controls to identify functional
impacts of these epigenetic changes.
Aim 3. Harness combined smoking, metabolomic, epigenetic and expression data to dissect how
components of tobacco smoke affect IBD risk and progression.
One representative publication from each co-supervisor:
Castillo-Fernandez JE, Loke YJ, Bass-Stringer S, Gao F, Xia Y, Wu H, Lu H, Liu Y, Wang J, Spector
TD, Saffery R, Craig JM*, Bell JT*. 2017. DNA methylation changes at infertility genes in newborn
twins conceived by in vitro fertilisation. Genome Medicine, 9:28. doi:10.1186/s13073-017-0413-5.
14 | 6 9
Genome-wide association study implicates immune activation of multiple integrin genes in
inflammatory bowel disease. de Lange, K. M. , Moutsianas, L. , Lee, J. C. , Lamb, C. A. , Luo, Y. ,
Kennedy, N. A. , Jostins, L. , Rice, D. L. , Gutierrez-Achury, J. , Ji, S-G. , Heap, G. , Nimmo, E. R.
, Edwards, C. , Henderson, P. , Mowat, C. , Sanderson, J. , Satsangi, J. , Simmons, A. , Wilson, D. C.
, Tremelling, M. Hart, A., Mathew, C. G., Newman, W. G., Parkes, M., Lees, C. W., Uhlig, H.,
Hawkey, C., Prescott, N. J., Ahmad, T., Mansfield, J. C., Anderson, C. A. & Barrett, J. C. 9 Jan 2017
In : Nature Genetics.
15 | 6 9
8.1 A characterisation of IL-36 signalling as a therapeutic target in psoriasis
Co-supervisor 1: Francesca Capon
Research Division or CAG: School of Basic and Medical Biosciences
E-mail: francesca.capon@kcl.ac.uk
Website:
https://www.kcl.ac.uk/lsm/research/divisions/gmm/departments/mmg/researchgroups/CaponLab/index.aspx Twitter: @FranciCapon
Co-supervisor 2: jonathan.barker@kcl.ac.uk
Research Division or CAG: School of Basic and Medical Biosciences
Email: jonathan.barker@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/jonathan.barker.html
Project Description:
Psoriasis is a chronic inflammatory skin disorder that affects more than a million people in the UK
alone. In recent years our group has carried out gene identification and transcriptional profiling
studies, which have demonstrated a pathogenic role for the de-regulation of IL-36 signalling. While
these findings point to IL-36 blockade as an attractive therapeutic strategy, the physiological function
of IL-36 is not fully understood so that cytokine inhibition may have unexpected adverse
consequences.
The aim of this project is to characterise the systemic effects of IL-36 and the consequences of IL-36
blockade on immune function.
During their rotation project, the student will carry out IL-36 stimulations in purified immune
populations, with a view to identifying the leukocyte subsets that respond to IL-36 and the
consequences of IL-36 treatment on their activation status.
In subsequent years, the student will:
- Identify IL-36 driven transcriptional networks by carrying out RNA sequencing in the cell
populations identified during the rotation project (Year-1).
- Experimentally validate the newly identified networks through in-vitro studies (e.g. by
CRISPR-mediated gene silencing of key transcriptional regulators) (Year-2)
- Investigate the consequences of IL-36 blockade on the newly identified networks through ex-
vivo studies of purified cell populations obtained from patients and controls (Year-3)
The student will be monitored by two experienced supervisors with complementary expertise in
functional genomics (FC) and clinical dermatology (JNB). Training will be provided in the use of
computational tools (differential expression and network analysis) and experimental techniques
(isolation, culture and manipulation of primary cells).
One representative publication from each co-supervisor:
Mahil SK, Catapano M, Di Meglio P, Dand N, Ahlfors H, Carr IM, Smith CH, Trembath RC,
Peakman M, Wright J, Ciccarelli F, Barker JN, Capon F. An analysis of IL-36 signature genes and
individuals with IL1RL2 knockout mutations validates IL-36 as a psoriasis therapeutic target.
Science Translational Medicine, in press
16 | 6 9
Aterido A, Julià A, Ferrándiz C, Puig L, Fonseca E, Fernández-López E, Dauden E, Sánchez-
Carazo JL, López-Estebaranz JL, Moreno-Ramírez D, Vanaclocha F, Herrera E, de la Cueva P,
Dand N, Palau N, Alonso A, López-Lasanta M, Tortosa R, García-Montero A, Codó L, Gelpí JL,
Bertranpetit J, Absher D, Capon F, Myers RM, Barker JN, Marsal S. Genome-wide pathway
analysis identifies genetic pathway associated with psoriasis. J Invest Dermatol 2016 136:593-602
17 | 6 9
9.1 Investigating developmental and epigenetic mechanisms of adipose tissue
homeostasis.
Co-supervisor 1: Dr Marika Charalambous
Research Division or CAG: Genetics and Molecular Medicine
E-mail: marika.charalambous@kcl.ac.uk
Co-supervisor 2: Dr Michelle Holland
Research Division or CAG: Genetics and Molecular Medicine
Email: michelle.holland@kcl.ac.uk
Website:
https://www.kcl.ac.uk/lsm/research/divisions/gmm/departments/mmg/researchgroups/HollandGr
oup/Epigenetics-and-post-transcriptional-gene-regulation-group.aspx
Project Description:
Obesity involves the expansion of white adipose tissue (WAT). This occurs through increased lipid
filling within existing adipocytes to increase adipocyte size (hypertrophy), OR increased
differentiation of adipocyte precursor cells (APCs) to increase adipocyte number (hyperplasia). The
size of adipocytes is important –large cells are pro-inflammatory and associated with insulin resistance,
especially if this occurs in the visceral compared to the subcutaneous WAT depot. Therefore, the
availability of APCs, which is determined in early development, is a critical factor in how WAT
behaves.
In this project, we will use a mouse model to determine how perinatal nutrition, a risk factor for later
life metabolic disease, influences the APC store. This will involve assessing the number, distribution
and differentiation capacity of APCs both in vivo and ex vivo. Additionally, we will examine gene
expression and the role of the mRNA epitranscriptomic modification, N-6-methyladenosine (m6A).
A role for m6A in obesity is suggested by genome-wide association studies in humans and this will
provide an exciting opportunity to examine its function in a disease relevant cell type.
Aim 1 (Years 1-2): To determine if maternal protein restriction changes APC numbers and
differentiation capacity in neonatal mice (animal models, microdissection, FACS, cell culture).
Aim 2 (Years 1-2): To examine if maternal protein restriction alters m6A levels, distribution and the
transcriptome of APCs (molecular biology, high throughput sequencing, bioinformatics).
Aim 3: (Years 2-3): To examine how maternal protein restriction influences the WAT response to a
high fat diet in adulthood (microscopy).
One representative publication from each co-supervisor:
Cleaton MAM, Corish JA, Howard M, Gutteridge I, Takahashi N, Bauer SR, Powell TL,
Ferguson-Smith AC, Charalambous M. (2016). Conceptus-derived Delta-like homologue-1
(DLK1) is required for maternal metabolic adaptations to pregnancy and predicts birthweight. Nat
Genet 48(12):1473-1480.
Holland ML*, Lowe R, Caton PW, Gemma C, Carbajosa G, Danson AF, Carpenter AAM, Loche
E, Ozanne SE, Rakyan VK. Early life nutrition modulates the epigenetic state of specific rDNA
genetic variants in mice. Science 2016; 353: 495-8.
18 | 6 9
10.1 Defining cellular and molecular mechanisms underlying cancer immunotherapy-
induced auto-inflammatory syndromes
1Co-supervisor 1A: Andrew P. Cope
Research Division or CAG:
E-mail: Centre for Inflammation Biology and Cancer Immunology, School of Immunology and
Microbial Sciences
Website:
https://www.kcl.ac.uk/lsm/research/divisions/diiid/departments/rheumatology/index.aspx
Co-supervisor 1B: Sophie Papa
Research Division or CAG: School of Cancer and Pharmaceutical Sciences
Email: sophie.papa@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/en/persons/sophie-papa(7c2a3d52-07a2-4193-80de-
6efe118c092a).html
Project Description:
Cancer therapy with immune checkpoint inhibitors is transforming the treatment of solid tumours
such as melanoma. The rationale is based on breaking immune tolerance to tumour antigens,
unleashing effector T cells to kill tumour antigen expressing cells. This is accomplished by inhibiting
the function of the immune system’s own immunosuppressive “checkpoint” molecules, the best
characterised being CTLA4 and PD-1. In spite of these breakthroughs, response rates to cancer
immunotherapy are well below 50% across indication, highlighting a need to better understand
responders and non-responder states. These therapies, at the same time, break tolerance to self
antigens leading to an emerging group of auto-inflammatory syndromes comprising rapid onset (6-8
weeks), and often severe inflammatory disease targeting skin, gut, joint or endocrine organs. Being
one of the largest cancer immunotherapy centres in the UK offers an unparalleled opportunity to
understand the delicate balance between tumour immunity and autoimmunity in cancer patients, with
the explicit intention of preventing adverse immune reactions on the one hand, and uncovering new
insights into the pathogenesis of autoimmunity on the other. In this project the student will undertake
deep immune phenotyping of peripheral blood and tissues from cancer patients before and after
receiving checkpoint inhibitor therapy (Year 1), exploiting high-end flow and mass cytometry to map
the very earliest events associated with the onset of immune mediated inflammatory syndromes. This
will be complemented by analysis of blood transcriptomes (Year 2), seeking to understand the
relationship between cellular and molecular signatures and specific disease phenotype (Years 1-3).
One representative publication from each co-supervisor:
Papa S, van Schalkwyk M, Maher J. Clinical Evaluation of ErbB-Targeted CAR T-Cells, Following
Intracavity Delivery in Patients with ErbB-Expressing Solid Tumors. Methods Mol Biol.
2015;1317:365-82.
Burn GL, Cornish GH, Potrzebowska K, Samuelsson M, Griffié J, Minoughan S, Yates M, Ashdown
G, Pernodet N, Morrison VL, Sanchez-Blanco C, Purvis H, Clarke F, Brownlie RJ, Vyse TJ,
Zamoyska R, Owen DM, Svensson LM, Cope AP. Superresolution imaging of the cytoplasmic
phosphatase PTPN22 links integrin-mediated T cell adhesion with autoimmunity. Sci Signal. 2016
Oct 4;9(448):ra99.
19 | 6 9
11.1 Allergic Disease: To Nip in the Bud
Co-supervisor 1: Dr. Susan Cox
Research Division or CAG: Randall Division
E-mail: Susan.cox@kcl.ac.uk
Website:
http://www.kcl.ac.uk/lsm/research/divisions/randall/research/sections/cell/cox/coxsusan.aspx
Co-supervisor 2: Prof. Hannah Gould
Research Division or CAG: Randall Division
Email: Hannah.gould@kcl.ac.uk
Website:
http://www.kcl.ac.uk/lsm/research/divisions/randall/research/sections/allergy/gould/gouldhanna
h.aspx
Clinical Supervisor: Dr Stephen Till
Research School/Division or CAG: Asthma, allergy and lung biology, School of Immunology &
Microbial Sciences
Email: Stephen.Till@kcl.ac.uk
Project Description:
IgE antibodies play a key role in allergic disease by sensitizing mast cells for allergen triggering.
Allergen-specific IgE antibodies are produced by the interaction between allergen and the B cell
receptor (BCR) on cells that have switched to the expression of membrane IgE (mIgE). While studies
of antigen recognition by the IgM- and IgG-BCRs have elucidated aspects of antigen uptake and
signaling, it is now clear that the outcomes for the IgE-BCR are fundamentally different. This means
there the IgE-BCR signalling pathway could be a unique target for intervention in allergic disease. As
demonstrated in studies of the IgM and IgG-BCR, high-resolution imaging is a powerful approach to
elucidate the pathways of BCR signaling. The Cox group develops super-resolution localisation
microscopy techniques, specialising in live cell measurements.
This project uses an innovative method which allows simultaneous imaging of a single fluorophore in
two colour channels to track both single molecules and global structures of various proteins, including
the IgE-BCRs, membrane proteins, cytoskeleton components and signalling molecules. The
dynamics of these proteins will be followed through the processes of allergen uptake, endocytosis and
the subsequent fate of the cell. The student will image live human B cells transformed to express
allergen-specific recombinant mIgEs, derived from allergy patients. In year 1 the student will be
introduced to imaging and will construct vectors for expression of the different antibody classes, with
the imaging technique being adapted to the specific problem in year 2 and acquisition of data in years
2 and 3.
One representative publication from each co-supervisor:
Fox-Roberts P, Marsh R, Pfisterer K, Jayo A, Parsons M, Cox S. Local dimensionality determines
imaging speed in localisation microscopy Nature Communications, 8 13358 2017
Ramadani F, Bowen H, Upton N, Hobson PS, Chan YC, Chen YC, Chang TW, McDonnell JM,
Sutton BJ, Fear DF, Gould HJ. Ontogeny of human IgE-expressing B cells and plasma cells. Allergy,
72 66-76 2017
20 | 6 9
12.1 Integrative analysis of multi-omics datasets for the identification and validation
of immune biomarkers in psoriasis
Co-supervisor 1: Paola Di Meglio
Research Division or CAG: School of Basic and Medical Bioscience
E-mail: paola.dimeglio@kcl.ac.uk
Website:
https://www.kcl.ac.uk/lsm/research/divisions/gmm/departments/dermatology/Groups/DiMeglio/
index.aspx
Co-supervisor 2: Sophia Tsoka
Research Division or CAG: Department of Informatics
Email: Sophia.tsoka@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/sophia.tsoka.html
Collaborating Clinician: Catherine Smith
Research School/Division or CAG: School of Basic and Medical Bioscience
Email: Catherine.smith@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/en/persons/catherine-smith(efc3a4a6-07c1-4180-add6-
29789ffe399d).html
Project Description:
Psoriasis is a chronic inflammatory skin disease affecting at least 1 million people in the UK, with a
severe impact on patient quality of life. Monoclonal antibodies targeting key pro-inflammatory
molecules (“biologics”), are effective, but not in every patient, and there is an unmet need to identify
biomarkers that predicts patient response to therapy. As part of the MRC-funded PSORT (Psoriasis
Stratification to Optimise Relevant Therapy) Consortium, we are employing high-throughput ‘omics’
platforms to interrogate relevant immune pathways in patients treated with biologics, and identify
predictive immune biomarkers.
Using phospho-flow cytometry, we have measured the phosphorylation status of key transcription
factors in peripheral blood mononuclear cells of patient receiving biologics. Independent cohorts for
replication studies, as well as additional datasets for multi-omics data integration are also available.
The objectives of this project are: rotation & Year1) to develop Exploratory Data Analysis (EDA)
strategies, underpinned by principles of immunology, bioinformatics and system biology, for the
selection of putative phospho-biomarkers in existing datasets; Year2) to experimentally replicate
putative biomarkers in an independent patient cohort; Year3) to develop innovative analysis strategies
for the bioinformatic integration of multi-omics datasets and the identification of predictive immune
biomarkers in psoriasis .
The student will benefit from the co-supervision model of the DTP Studentship being fully integrated
in an immunology and a bioinformatics group, with clinical inputs from an academic dermatologist.
He/she will receive extensive training in both disciplines, ultimately developing a highly distinctive
skillset, spanning from the generation to the analysis of high-dimension complex biomedical data.
One representative publication from each co-supervisor:
Roederer M, Quaye L, Mangino M, Beddall MH, Mahnke Y, Chattopadhyay P, Tosi I, Napolitano
L, Terranova Barberio M, Menni C, Villanova F, Di Meglio P, Spector TD, Nestle FO.
The genetic architecture of the human immune system: a bioresource for autoimmunity and disease
pathogenesis. Cell. 161:387-403. 2015.
21 | 6 9
C. Ainali, N. Valeyev, G. Perera, A. Williams, J.E. Gudjonsson, C.A. Ouzounis, F.O Nestle, S.
Tsoka, “Transcriptome Classification Reveals Molecular Subtypes in Psoriasis”, BMC Genomics,
13(1), 472, 2012.
22 | 6 9
13.1 Broadly neutralizing antibody responses in HIV infection
Co-supervisor 1A: Dr Katie Doores
Research Division or CAG: SIMS/Infectious Diseases
E-mail: katie.doores@kcl.ac.uk
Website:
https://www.kcl.ac.uk/lsm/research/divisions/diiid/departments/infectious/research/doores/index
.aspx
Co-supervisor 1B: Dr Julie Fox
Research Division or CAG: SIMS/Infectious Diseases
Email: julie.fox@kcl.ac.uk
Website:
https://www.kcl.ac.uk/lsm/research/divisions/diiid/departments/infectious/research/juliefox.aspx
Project Description:
An HIV vaccine is desperately needed to prevent new HIV infections worldwide. Approximately 10-
30% of HIV infected individuals generate antibodies that are capable of neutralizing a broad range of
HIV isolates and these antibodies have been shown to protect against SHIV challenge in Macaque
models. Isolation and characterisation of these antibodies has revealed regions of the HIV envelope
glycoprotein, gp120/gp41, that are susceptible to antibody binding and re-eliciting these antibodies
may be a key step for a successful HIV vaccine. Gp120 is heavily glycosylated with host-derived N-
linked glycans and it was previously thought that these glycans shield conserved protein regions from
the immune system. However, we have recently shown that many of the most broad and potent HIV
neutralizing antibodies bind directly to these glycans highlighting them as potential targets for HIV
vaccine design.
Using unique longitudinal patient samples from acutely HIV infected individuals in the SPARTAC
study (N Engl J Med 2013;368:207-17) we will investigate the development of HIV broadly
neutralizing antibodies (bnAbs) in vivo using in vitro neutralization assays, antigen-specific B cell
sorting and antibody cloning, next generation sequencing of antibody genes and viral Envelope single
genome amplification. We will determine how the viral Envelope evolution guides and directs bnAb
development in these HIV-infected individuals. Ultimately these studies will be used to design
immunogens and immunization strategies aimed at re-eliciting these bnAbs through vaccination
One representative publication from each co-supervisor:
L. M. Walker,* M. Huber,* K. J. Doores,* E. Falkowska, R. Pejchal, J.-P. Julien, S.-K. Wang, A.
Ramos, P. Y. Chan-Hui, M. Moyle, J. L. Mitcham, P. W. Hammond, O. A. Olsen, P. Phung, S. Fling,
C.-H. Wong, S. Phogat, T. Wrin, M. D. Simek, Protocol G Principal Investigators, W. C. Koff, I. A.
Wilson, D. R. Burton, P. Poignard, Broad neutralization coverage of HIV by multiple highly potent
antibodies, Nature, 2011, 477, 466-470.
J. Tiraboschi , S. Ray, K. Patel, A. Teague, M. Pace, P. Phalora, N. Robinson, E. Hopkins, J.
Meyerowitz, Y. Wang, J. Cason, S. Kaye, J. Sanderson, P. Klenerman, S. Fidler, J. Frater, J. Fox,
The impact of immunoglobulin in acute HIV infection on the HIV reservoir: a randomized controlled
trial, HIV Med, 2017, doi: 10.1111/hiv.12524.
23 | 6 9
14.1 Cell Death for Regeneration: Mesenchymal Stromal Cells and Myocardial Repair
Co-supervisor 1: Dr. Georgina M. Ellison-Hughes
Research Division or CAG: School of Basic and Medical Biosciences
E-mail: georgina.ellison@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/georgina.ellison.html
Twitter: @SuperGME
Co-supervisor 2: Prof. Francesco Dazzi
Research Division or CAG: School of Cancer & Pharmaceutical Sciences
Email: francesco.dazzi@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/francesco.dazzi.html
Twitter: @Dazzi_Lab
Project Description:
Myocardial infarction (MI) is damage/death to the heart muscle. Immediately after MI, cardiac
wound repair is initiated, starting with a strong infiltration of immune cells and inflammatory response.
Recent data shows that mesenchymal stromal cells (MSCs) can facilitate myocardial tissue repair.
However, the therapeutic activity is dependent on exposure of MSC to the correct setting of
microenvironment, also known as MSC ‘licensing’. A better understanding of the licensing
mechanisms will shed light on key signals that stimulate endogenous tissue repair mechanisms and
provide crucial steps for clinical development.
The Dazzi lab has recently shown that injected MSCs are induced to undergo apoptosis by the
recipient cytotoxic T cells and natural killer (NK) cells. Apoptotic MSCs are then engulfed by host
phagocytes that become immunosuppressive (Galleu et al. 2017). This activity could prove
fundamental also for stimulating spontaneous myocardial tissue repair and facilitate engraftment, self-
renewal and/or differentiation of resident cardiac stem/progenitor cells (CPCs).
This project will elucidate the mechanisms by which the post-MI environment licenses indirect
tissue repair, promoting immunomodulatory properties of transplanted MSCs and the direct
regenerative activity of cardiac stem/progenitor cells, resulting in improved cardiac repair and
regeneration. The Ellison lab has extensive experience and knowledge of CPCs resident in the adult
heart and stimulating the heart’s regenerative capacity post-injury.
Over-arching Objectives:
1: Characterising the immunomodulatory and pro-regenerative properties of MSCs and CPCs in vitro
and in vivo
2: Elucidating the mechanisms underlying the stimulation of cardiac repair mechanisms by MSC and
CPC immunomodulation
One representative publication from each co-supervisor:
Ellison GM, Vicinanza C, Smith AJ, Aquila I, Leone A, Waring CD, Henning BJ, Stirparo GG,
Papait R, Scarfo M, Agosti V, Viglietto G, Condorelli G, Indolfi C, Ottolenghi S, Torella D &
Nadal-Ginard B (2013). Adult c-kitpos Cardiac Stem Cells Are Necessary and Sufficient for
Functional Cardiac Regeneration and Repair. Cell, 154: 827-842. doi: 10.1016/j.cell.2013.07.039.
Galleu A, Riffo-Vasquez Y, Trento C, Lomas C, Dolcetti L, Cheung TS, von Bonin M, Barbieri L,
Halai K, Ward S, Weng L, Chakraverty R, Lombardi G, Watt F, Orchard K, Marks DI, Apperley
J, Bornhauser M, Walczak H, Bennett C, and Dazzi F. (2017). Perforin-dependent apoptosis in
24 | 6 9
mesenchymal stromal cells is required to initiate host-mediated in vivo immunomodulation in graft-
versus-host disease. Science Translational Medicine, In press.
25 | 6 9
15.1 Identification of novel immunomodulatory target checkpoints for Prostate
Cancer therapeutics
Co-supervisor 1: Christine Galustian
Research Division or CAG: Immunology and Microbial Sciences/MRC Centre for transplantation
E-mail: christine.galustian@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/christine.galustian.html
Co-supervisor 2: Richard A Smith
Research Division or CAG: Immunology and Microbial Sciences/MRC Centre for transplantation
Email: richard.a.smith@kcl.ac.uk
Website:
Collaborating Clinician: Professor Prokar Dasgupta
Research School/Division or CAG: Immunology and Microbial Sciences/MRC Centre for
transplantation
Email: prokar.dasgupta@kcl.ac.uk
Website: prokar.co.uk
Project Description:
Prostate cancer is the most common cancer among men. Immunotherapies such as Provenge™ have
improved end-stage prostate cancer survival1. However, although immune-cells such as CD8 T-cells
can infiltrate the prostate, this microenvironment renders these cells suppressive2. The cause of this
immunosuppression is not clear, although many immune-checkpoint proteins have been recently
discovered3.
The project aims to use a novel syngeneic human prostate tumour/immune-cell model to identify
immunomodulatory molecules in the cancerous prostate. Using syngeneic PBMCs and cells from
patient tumours (of varying stagings), mechanisms of immune-tolerance and molecules differentiating
indolent/aggressive disease can be determined. Moreover, potent immunotherapeutic agents
modifiable to localise to cell-membranes can be assessed using this model (see below). The supervisors
provide training in Immunology and Molecular Biology (Genomics/Proteomics), Protein Chemistry,
and Clinical Cancer diagnostics.
Objectives/methodologies:
Years 1-2: Studying immune-effector function of cells from patients with different stagings: This
will involve training including flow-cytometry, ELISA, and isolation/culture of primary-tumour cells.
Years 2-3: Immunome profiling from patient effector/tumour cells to determine markers of disease
progression. Training will be provided in technologies such as genomic/proteomic microarrays.
Antibodies will be raised/obtained to selected inhibitory markers.
Years 3-4: Assessing novel immunotherapeutic agents in the above model. Richard Smith has
developed a cytotopic-tailing technology to localise therapeutic proteins/peptides to tissues/organs to
reduce systemic-toxicity and increase agent avidity4. Training will be provided in protein chemistry
to prepare agents modified with cytotopic “tails” (e.g antibodies from years 2-3) and will assay
efficacy of these agents on immune-cell function using assays described in year 1.
References for project
26 | 6 9
1. Dawson N. Immunotherapeutic approaches in prostate cancer: PROVENGE. Clin Adv Hematol
Oncol 2010;8:419-421.
2. Shafer-Weaver KA, Anderson MJ, Stagliano K, Malyguine A, Greenberg NM, Hurwitz AA.
Cutting Edge: Tumor-Specific CD8+ T Cells Infiltrating Prostatic Tumors Are Induced to Become
Suppressor Cells. The Journal of Immunology 2009;183:4848-4852.
3. Galustian C, Vyakarnam A, Elhage O, Hickman O, Dasgupta P, Smith RA. Immunotherapy of
prostate cancer: identification of new treatments and targets for therapy, and role of WAP domain-
containing proteins. Biochem Soc Trans 2011;39:1433-1436.
4. Smith GP, Smith RAG. Membrane-targeted complement inhibitors. Molecular Immunology
2001;38:249-255.
One representative publication from each co-supervisor:
Galustian C, Vyakarnam A, Elhage O, Hickman O, Dasgupta P, Smith RA. Immunotherapy of
prostate cancer: identification of new treatments and targets for therapy, and role of WAP domain-
containing proteins. Biochem Soc Trans 2011;39:1433-1436.
Smith GP, Smith RAG. Membrane-targeted complement inhibitors. Molecular Immunology
2001;38:249-255.
27 | 6 9
16.1 The effect of lipid composition on the mechanostransduction of individual live
cells
Co-supervisor 1: Professor Sergi Garcia-Manyes
Research Division or CAG: Physics/Randall Division
E-mail: sergi.garcia-manyes@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/sergi.garcia-manyes.html
Co-supervisor 2: Professor Ulrike Eggert
Research Division or CAG: Randall Division/Chemistry
Email: ulrike.eggert@kcl.ac.uk
Website:
http://www.kcl.ac.uk/biohealth/research/divisions/randall/research/sections/motility/eggert/inde
x.aspx
Project Description:
Are the lipids forming the plasma membrane and nuclear envelope (NE) dynamically modified under
mechanical stress? Lipids and proteins are key components of membranes, yet most of the effort to
understand mechanotransduction has focused on proteins alone. We will explore whether the
lipidome changes in the plasma membranes and NE of cells exposed to mechanical stress. We will
subject cultured cells to substrates of different stiffness, and extract their nuclei. Plasma membrane
and nuclear lipids will be extracted and analysed by MS to determine their lipidomic profiles. In
parallel, we will use Atomic Force Microscopy (AFM) in combination with magnetic tweezers cell
stretching experiments to probe the mechanical properties of plasma and nuclear membranes.
We will investigate the effect of mechanical forces on the lipid composition of cells and isolated nuclei.
The student will gain expertise in single cell AFM and magnetic tweezers characterisation, combined
with cell and molecular biology techniques. S/he will also gain deep knowledge in mass spectrometry.
In Year 1, cell biology experiments will be performed at UE lab and the student will learn how to
prepare substrates of different stiffness in SGM lab. Year 2 will be devoted to conduct single cell
mechanical experiments using AFM and Magnetic Tweezers (SGM). During Year 3 the student will
concentrate on lidiomics (UE). Experiments, analysis and paper writing will continue in Year 3-4.
This is a unique opportunity to explore fundamental biophysical questions of lipids during
mechanotransduction at the single cell level, combining cutting-edge nanomechanical biophysical
techniques (Garcia-Manyes) and modern cell biology and mass spectrometry (Eggert).
One representative publication from each co-supervisor:
Atilla-Gokcumen, Muro, E.; Relat-Goberna, J.; Sasse, S.; Bedigian, S.; Coughlin, M.L.; Garcia-
Manyes, S.; Eggert, U.S.; «Dividing cells regulate their lipid composition and localization» Cell
(2014), 156 (3), 428
Beedle, A. E., Mora, M., Lynham, S., Stirnemann, G., Garcia-Manyes, S. «Tailoring protein
nanomechanics with chemical reactivity» Nature Communications (2017).
28 | 6 9
17.1 The CXCL8-producing T cell in infants: function in health and HIV
Co-supervisor 1: Deena Gibbons
Research Division or CAG: SIMS
E-mail: Deena.gibbons@kcl.ac.uk
Website:
http://www.kcl.ac.uk/lsm/research/divisions/diiid/departments/immunobiology/research/gibbons
/index.aspx
Co-supervisor 2: Susan John
Research Division or CAG: SIMS
Email: susan.john@kcl.ac.uk
Website:
http://www.kcl.ac.uk/lsm/research/divisions/diiid/departments/immunobiology/research/SusanJo
hn/index.aspx
Project Description:
The human neonatal immune system is not just an immature version of that of the adult but is
qualitatively and quantitatively different. Our research focuses on understanding immune cell
development and function in the human neonate and how this impacts on disease. We identified that
neonates possess robust effector potential in the form of CXCL8 (aka interleukin-8, IL8) and thus
dispelled the long held view that the infant immune system was anti-inflammatory. CXCL8
production is imprinted in the thymus during T cell development and the expression of CXCL8
appears to be selected for upon thymic egress suggestive of an important function. CXCL8 producing
T cells do not remain as such but these cells represent an intermediate cell en route to classic adaptive
immune cell functions such as IFN production. This raises a number of important questions that form
the basis of this PhD project:
1. There is an efflux of recent thymic emigrants upon initiation of HIV treatment-this suggests an
efflux of CXCL8-producing cells-what is the effect of CXCL8 and these cells upon HIV
pathogenesis?
2. Are CXCL8-producing cells protective or pathogenic in infant infections such as sepsis?
3. What are the signals and signalling pathways that allow conversion of CXCL8-producing T cells
to IFN -producing cells and other T cell lineages?
Methods will involve multiple cellular and molecular techniques (eg flow cytometry and RNA
sequencing) as well as work both in vitro and in vivo mouse models.
One representative publication from each co-supervisor:
Deena Gibbons, Paul Fleming, Alex Virasami, Marie-Laure Michel, Neil Sebire, Kate Costeloe,
Robert Carr, Nigel Klein, Adrian Hayday. Interleukin-8 (CXCL8) Production is the signatory T
cell effector function of human newborn infants. Nature Medicine 20, 1206-10 (2014)
Rani A, Afzali B, Kelly A, Tewolde-Berhan L, Hackett M, Kanhere A.S, Pedroza-Pacheco I,
Bowen H, Jurcevic S, Jenner R.G., Cousins, D., Ragheb J.A., Lavender Pand John S. IL-2 regulates
expression of c-maf in human CD4 T cells. 2011. J. Immunol. 187(7): 3721-9.
29 | 6 9
18.1 Mechanisms of action of a novel marine natural product for the management of
osteoporosis and metabolic bone disease.
Co-supervisor 1: Prof Agi E. Grigoriadis
Research Division or CAG: Centre for Craniofacial and Regenerative Medicine, Dental Institute
E-mail: agi.grigoriadis@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/agi.grigoriadis.html
Co-supervisor 2: Professor Paul F. Long
Research Division or CAG: School of Cancer & Pharmaceutical Sciences
Email: paul.long@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/paul.long.html
Collaborating Clinician: Dr Geeta Hampson
Research School/Division or CAG: GRIIDA
Email: Geeta.Hampson@gstt.nhs.uk
Website: http://www.guysandstthomasbrc.nihr.ac.uk/staff/geeta-hampson/
Project Description:
Bone diseases characterised by bone loss, such as osteoporosis and cancers that metastasise to bone,
are debilitating diseases that affect millions of people worldwide. There are no cures and current
treatments have many side effects. Natural products are chemicals from nature that can be used as
the basis for new medicines. Natural products from marine sponges show exceptional promise as
potential pharmaceuticals and could offer effective strategies for the treatment of metabolic bone
diseases. We are working on a family of natural products from a Great Barrier Reef sponge that shows
potent activity on cells that both form and degrade bone. The prospects of using these compounds
as tools to manipulate bone cell activity with a view to provide mechanistic data that underpin
development of a new medicine is completely novel and represents the aim of the project. The
project provides training for the student in multidisciplinary yet complementary skills of
biochemical/molecular bone cell biology (Prof Grigoriadis) and pharmacology/pharmaceuticals (Prof
Long), to achieve the following project goals:
Year 1: Dose- and time-dependent effects of natural compounds on bone cell differentiation and gene
expression in vitro.
Years 2 & 3: Consolidation of in vitro experiments, progressing to translational aspects of the project
using in vivo mouse models of bone disease, and investigating new mechanisms of action. Candidate
target genes are already established.
Year 4: Finalising experimental work and writing-up.
This studentship offers a mobility component with our project partners at the Australian Institute of
Marine Science.
One representative publication from each co-supervisor:
Grigoriadis AE, Kennedy M, Bozec A, Brunton F, Stenbeck G, Park IH, Wagner EF, Keller GM.
(2010) Directed differentiation of hematopoietic precursors and functional osteoclasts from human
ES and iPS cells. Blood 115:2769-76.
Gacesa R, Barlow DJ, Long PF. (2016) Machine learning can differentiate venom toxins from other
proteins having non-toxic physiological functions. PeerJ Comp. Sci. 2:e90.
30 | 6 9
19.1 A Wnt-based Bioengineering Approach To Polarise Osteosarcoma and limit their
tumorigenic potential
Co-supervisor 1: Shukry James Habib
Research Division or CAG: Centre for Stem Cells and Regenerative Medicine
E-mail: https://kclpure.kcl.ac.uk/portal/shukry.habib.html Website: www.habiblab.org
Co-supervisor 2: Eileen Gentleman
Research Division or CAG: Centre for Craniofacial and Regenerative Biology
Email: eileen.gentleman@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/eileen.gentleman.html
Project Description:
The bone cancer Osteosarcoma is the second leading cause of cancer-related deaths in paediatric
patients. Despite surgery and chemotherapy, long-term survival rates for patients diagnosed with
osteosarcoma have not improved over the last 30 years. Osteosarcoma stem cells (OSCS) derive the
growth of tumour. The levels of Lrp5, the receptor of Wnt ligands, are statistically correlated with
poor prognosis and Wnt signalling is a therapeutic target for blocking tumorogensis.
This project will investigate the cell division of OSCS, and engineer strategies to polarise them in
order to direct them to divide asymmetrically, limit their proliferation potential and control cellular
fate. We hypothesise that the Wnt signalling pathway could be employed for controlling the cellular
polarity and division.
The Habib lab has engineered localised Wnt niches that can induce asymmetric cell division of
embryonic and bone stem cells. The combination of our bioengineering approaches with advanced
materials that mimic the bone niche (Gentelman lab) provide grounds to explore the mechanistic
regulation of the OSSC division and opportunities to limit their tumorigenic potential.
1st -2nd year: Culturing and characterising OSCS. Employing 3D microscopy to study the division
OSCS by establishing a molecular segregation map for cell polarity proteins, Wnt pathway
components and cell fate markers. Purification of Wnt proteins will also be done.
3nd- 4th year: Engineering localised Wnt niches in 3D biomaterials and testing their effect on OSCS
proliferation and invasion. Flow cytometery to separate between the daughter cells of OSCSs and
investigating their tumorigenic potential in in vitro and in vivo transplantation assays.
One representative publication from each co-supervisor:
Habib S.J., B. Chen, F. Tsai, K. Anastassiadis, T. Meyer, E. Betzig and R. Nusse (2013) A
Localized Wnt signal orients asymmetric stem cell division in vitro. Science 339(6126):14451448.
Ferreira SA, Motwani MS, Faull P, Seymour A, Yu TTL, Enayati M, Taheem DK, Kania EM,
Oommen OP, Ahmed T, Loaiza S, Parzych K, Dazzi F, Auner HW, Varghese OP, Festy F,
Grigoriadis AE, Snijders AP, Bozec L, Gentleman E (2017) “Bi-directional cell-pericellular matrix
interactions direct stem cell fate.” Nature Materials (in press)
31 | 6 9
20.1 The role of the Larp6 RNA binding protein in vertebrate oogenesis, development
and fertility
Co-supervisor 1: Prof Simon M Hughes
Research Division or CAG: Randall Division
E-mail: simon.hughes@kcl.ac.uk
Website:
http://www.kcl.ac.uk/lsm/research/divisions/randall/research/sections/signalling/hughes/index.as
px
Co-supervisor 2: Prof. Maria R (Sasi) Conte
Research Division or CAG: Randall Division
Email: sasi.conte@kcl.ac.uk
Website:
https://www.kcl.ac.uk/lsm/research/divisions/randall/research/sections/structural/conte/contesasi
.aspx
Project Description:
Much human infertility is unexplained. We have found that mutation of the larp6a gene leads to
defective oogenesis and reduced female fertility.
LARP6 is a recently discovered RNA-binding protein involved in regulation of gene expression at
the translational level. Its functions are still largely unknown although it has been reported to control
collagen production. Furthermore, LARP6’s ability to recognise specific mRNA targets and its
molecular mechanisms are still unclear.
Evidence for a role for LARP6 in infertility is growing: drosophila Larp mutants are characterised by
female infertility and show defective early embryo development. We mutated the two Larp6 genes in
zebrafish (larp6a and larp6b) using CRISPR/Cas9 genome editing and discovered an exciting
maternal effect mutation in larp6a: larp6a mutant females have fragile oocytes, small chorion (egg
shell) and cytological defects including mis-localisation of other mRNAs leading to reduced fertility.
The PhD project therefore aims to explore:
a) the function of LARP6a, and its mechanism in female infertility
b) the identification of LARP6a mRNA targets, using CLIPseq technology
c) the structural biology of LARP6a mRNA binding and its role in mRNA localisation
d) the function of LARP6b and possible cooperation with LARP6a
e) the involvement of human LARP6 in infertility
This work will contribute towards identifying whether LARP6 plays a role in fertility and
degenerative muscle disorders and how it functions.
For more information on the laboratories, see:
http://www.kcl.ac.uk/lsm/research/divisions/randall/research/sections/signalling/hughes/hughessi
mon.aspx
https://www.kcl.ac.uk/lsm/research/divisions/randall/research/sections/structural/conte/contesasi
.aspx
Key techniques / transferable skills:
Molecular biology, protein biochemistry, zebrafish genetics, embryonic development,
immunohistochemistry, imaging, biophysical measurements.
One representative publication from each co-supervisor:
32 | 6 9
Pipalia, T.G., *Koth, J., Roy, S.D., Hammond, C.L.. Kawakami, K. and S.M. Hughes (2016) Cellular
dynamics of regeneration reveals role of two distinct Pax7 stem cell populations in larval zebrafish
muscle repair. Disease Mod. Mech. 9: 671-684. doi: 10.1242/dmm.022251 PMID: 27149989
Martino. L., Pennell, S., Kelly, G., Busi, B., Brown, P., Atkinson, R.A., Salisbury, N.J.H., Ooi, Z-
H., See, K-W., Smerdon, S.J., Alfano, C., Bui, T.T., Conte, M.R.* (2015) Synergic interplay of the
La motif, RRM1, and the interdomain linker of LARP6 in the recognition of collagen mRNA expands
the RNA binding repertoire of the La module. Nucleic Acids Res, 43, 645-60.
33 | 6 9
21.1 The role of the pro-FLG Ca2+-binding domain in the formation of the skin barrier
and pathogenesis of atopic dermatitis
Co-supervisor 1: Dusko Ilic
Research Division or CAG: Women’s Health
E-mail: dusko.ilic@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/dusko.ilic.html
Co-supervisor 2: Carsten Flohr
Research Division or CAG: GMM
Email: carsten.flohr@kcl.ac.uk
Website:
http://www.kcl.ac.uk/lsm/research/divisions/gmm/departments/dermatology/Groups/flohr/index.
aspx
Collaborating Clinician: Catherine Smith
Research School/Division or CAG: GMM
Email: catherine.smith@kcl.ac.uk
Website:
http://www.kcl.ac.uk/lsm/research/divisions/gmm/departments/dermatology/Research/stru/abou
t/people/smith-catherine.aspx
Project Description:
Atopic dermatitis (AD) affects 20% of children and 5% of adults in the UK and has a profound effect
of patients’ quality of life. A genetic predisposition for skin barrier dysfunction, together with
environmental factors, such as exposure to hard water (high CaCO3 levels) and the use of protease
containing detergents, results in the typical immunological phenotype of AD.
Normal epidermis displays a marked Ca2+ gradient, which controls the expression of filaggrin (FLG)
and differentiation of the epidermis. Recent genetic studies have found that loss-of-function mutations
in the FLG gene are present in up to 50% of AD patients. Pro-FLG has a Ca2+-binding domain of
unknown function, which is cleaved off when pro-FLG is proteolytically processed into functional
FLG during the biogenesis of the stratum corneum.
We will use CRISPR/Cas9 gene-editing technology to delete the FLG Ca2+-binding domain in
healthy human embryonic stem cell (hESC) lines. We will then use these isogenic normal and mutated
hESC to differentiate various skin cell types and build 3D in vitro models of full thickness skin. The
developed model will be used to assess processes related to keratinocyte differentiation and skin
barrier integrity to determine the role of the pro-FLG Ca2+-binding domain in the formation of a
functional skin barrier and the pathogenesis of AD. We will also expose the outer surface our 3D in
vitro model to varying CaCO3 levels to assess the effect on skin barrier integrity. The project will
inform novel methods of treatment and disease prevention.
One representative publication from each co-supervisor:
Petrova A, Celli A, Jacquet L, Dafou D, Crumrine D, Hupe M, Arno M, Hobbs C, Cvoro A,
Karagiannis P, Devito L, Sun R, Adame LC, Vaughan R, McGrath JA, Mauro TM, Ilic D. 3D In
vitro model of a functional epidermal permeability barrier from human embryonic stem cells and
induced pluripotent stem cells. Stem Cell Reports 2014;2:675-689.
Perkin MR, Craven J, Logan K, Strachan D, Marrs T, Radulovic S, Campbell LE, MacCallum SF,
McLean WH, Lack G, Flohr C. Association between domestic water hardness, chlorine, and atopic
34 | 6 9
dermatitis risk in early life: A population-based cross-sectional study. J Allergy Clin Immunol
2016;138(2):509-516.
35 | 6 9
22.1 The role of glycosylation in the biological functions of tumour antigen-specific IgE
class antibodies
Co-supervisor 1: Dr Sophia Karagiannis
Research Division or CAG: St John’s Institute of Dermatology, School of Basic & Medical
Biosciences
E-mail: sophia.karagiannis@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/sophia.karagiannis.html
Co-supervisor 2: Prof James Spicer
Research Division or CAG: School of Cancer & Pharmaceutical Sciences
Email: james.spicer@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/james.spicer.html
Project Description:
IgE antibodies are mediators of allergic and anti-parasitic immune responses. These activities have
been harnessed for the development of IgE-based antibodies specific for cancer-associated antigens as
a novel cancer immunotherapy strategy. Our findings to-date suggest that IgE-based
immunotherapeutics effectively restrict tumour growth. Our first-in-class IgE antibody recognising a
tumour-associated antigen is undergoing a Phase I clinical trial at Guy’s Hospital headed by co-
supervisor Spicer. IgEs are highly glycosylated antibodies, yet the precise effects of IgE glycan
moieties on the potency and immune cell-activating mechanisms of IgE against cancer remain unclear.
We aim to understand and exploit the role of glycosylation on the biological and anti-tumour functions
of IgE class antibodies. The goal is to identify optimised antibodies for immuno-oncology. Firstly, we
will generate defined IgE glycoforms by administering inhibitors of glycan biosynthesis (e.g. mannose,
fucose, galactose). Year 1 will focus on antibody generation and pharmacological evaluation. Year 2
will entail study of biological functions of IgE glycoforms compared with IgE expressed under native
conditions. These include antigen and receptor binding properties (e.g. ELISA, Biacore, flow
cytometry), IgE-mediated signalling, phagocytosis/cytotoxicity, apoptosis, proliferation, viability of
cancer cells and mast cell degranulation. In Year 3, the most promising antibodies will undergo further
selection to confirm potency and early ex vivo safety evaluations in patient blood and serum. These
studies will establish IgE structure/function relationships and aid the identification of IgE glycoforms
with defined anti-tumour functions. The project has considerable potential to deliver optimized
antibodies and expedite translation to benefit patients with solid tumours.
One representative publication from each co-supervisor:
Josephs DH et al., Anti-Folate Receptor-α IgE but not IgG Recruits Macrophages to Attack
Tumors via TNFα/MCP-1 Signaling. Cancer Research. (2017) 77(5):1127-1141. doi:
10.1158/0008-5472.CAN-16-1829.
Rudman S et al., A phase 1 study of AS1409, a novel antibody-cytokine fusion protein, in patients
with malignant melanoma or renal cell carcinoma. Clin Cancer Res (2011) 17: 1998-2005.
36 | 6 9
23.1 Dissecting the influence of chromatin modifications on muscle stem
programming by a quantitative live cell imaging approach
Co-supervisor 1: Robert Knight
Research Division or CAG: Dental Institute/ Centre for Craniofacial and Regenerative Biology
E-mail: robert.knight@kcl.ac.uk
Website:
https://www.kcl.ac.uk/dentistry/research/divisions/craniofac/ResearchGroups/KnightLab/Knight
Lab.aspx
Co-supervisor 2: Alessandra Vigilante
Research Division or CAG: FoLSM/ Centre for Stem Cells and Regenerative Medicine
Email: alessandra.vigilante@kcl.ac.uk
Website: https://www.kcl.ac.uk/lsm/research/divisions/gmm/departments/stemcells/people/Dr-
Alessandra-Vigilante.aspx
Project Description:
Stem cells hold great promise for regenerative biology, but current barriers to their application in a
clinical setting include our very limited understanding of how they behave in vivo. Although we know
stem cells are very motile and are highly sensitive to environmental cues, how these are interpreted
has proven challenging. Further, epigenetic changes, due to diet or exposure to chemicals, likewise
can affect stem cell responses.
In this project we propose to use laser microscopy to visualise how muscle stem cells (muSCs) respond
to an injury signal and use advanced statistical and computational techniques to reveal the influence
of epigenetic signals on these behaviours. Bioinformatics approaches will be implemented to process
the data and to identify candidate novel regulators, which may be of value in a therapeutic context to
treat patients with muscle wasting disorders such as muscle dystrophies.
Skills Training
This project will provide opportunities to acquire extensive expertise in cell biology and master
general approaches of learning from 'big data' that are applicable across many disciplines. Students
will learn both experimental and computational skills on how to perform live cell imaging both in vitro
and in vivo (zebrafish and mouse models) using confocal, multiphoton and light sheet microscopy. 4D
time-lapsed movies will be analysed by using and writing computational tools. Cell culture, molecular
biology and use of animal models will also be taught.
Objectives
Year 1-2: analyse cell behaviour to identify candidate regulators of muSC behaviour
Year 3: functionally test candidate regulatory genes
Year 4: perform a pharmacological screen for novel muSC regulators using predictive computational
tools
One representative publication from each co-supervisor:
Moyle, L. M., Blanc, E., Jaka, O., Prueller, J., Banerji, C. R. S., Tedesco, F.S., Harridge, S. D. R.,
*Knight, R. D., *Zammit, P. S. 'Ret function in muscle stem cell function points to tyrosine kinase
inhibitor therapy for fascioscapulohumeral muscle dystrophy'. eLife (2016) 14(5) e11405.
37 | 6 9
Sugimoto Y, Vigilante A, Darbo E, et al. hiCLIP reveals the in vivo atlas of mRNA secondary
structures recognized by Staufen 1. Nature. 2015;519(7544):491-494.
38 | 6 9
24.1 Investigate a novel, unexplored link between WNT signalling and regulators of
cell migration in cancer progression.
Co-supervisor 1: Matthias Krause
Research Division or CAG: Randall Division of Cell and Molecular Biophysics
E-mail: matthias.krause@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/matthias.krause.html
Co-supervisor 2: Claudia Linker
Research Division or CAG: Randall Division of Cell and Molecular Biophysics
Email: claudia.linker@kcl.ac.uk
Website:
https://www.kcl.ac.uk/lsm/research/divisions/randall/research/sections/motility/linker/index.aspx
Project Description:
Cancer is a devastating disease: more than one in three people in the UK will develop cancer in their
lifetime. WNT signalling is a key pathway controlling morphogenesis in embryos and it has been
shown that perturbations of this pathway promote cancer progression. Regulators of the actin
cytoskeleton control cell migration and their dysregulation has been implicated in cancer metastasis.
In this project, you will investigate a novel, unexplored link between WNT signalling and regulators
of the actin cytoskeleton using biochemistry, molecular
biology, and advanced live cell imaging in vivo. We have
unpublished data showing a novel interaction between a
component of the canonical WNT signalling pathway and
regulators of the actin cytoskeleton. During your rotation,
you will map this interaction by site directed mutagenesis.
Thereafter, you will test the functional significance of this
interaction in cancer cell proliferation and migration. You
will then use CRISPR to genome edit cancer cell lines and
employ advanced live cell imaging techniques in cell lines
and zebrafish embryos to define the role of this signalling
regulation. Taken together, your PhD work will unravel a
novel and general mechanism of WNT signalling and how it
contributes to embryogenesis and cancer progression.
You will join laboratories studying the regulation of cell migration (Krause laboratory – cancer cell
migration and proliferation, regulation of actin cytoskeleton; Linker laboratory – in vivo cell
migration, WNT signalling) and will be trained in techniques including protein biochemistry,
molecular biology (CRISPR, etc), zebrafish embryology and advanced imaging.
One representative publication from each co-supervisor:
Carmona, G., Perera U., Gillett C., Naba A., Law A., Sharma V.P., Wang J., Wyckoff J., Balsamo
M., Mosis F., De Piano, M., Monypenny, J., Woodman, N., McConnell, R.E., Mouneimne, G.,
Van Hemelrijck, M., Cao, Y., Condeelis, J., Hynes, R.O., Gertler, F.B., and Krause M. (2016)
Lamellipodin promotes invasive 3D cancer cell migration via regulated interactions with Ena/VASP
and SCAR/WAVE, Oncogene, 35(39), 5155-69.
Logan and Nusse, 2004
39 | 6 9
Richardson J, Gauert A, Briones Montecinos L, Fanlo L, Alhashem ZM, Assar R, Marti E, Kabla A,
Härtel S, and Linker C. (2016) Leader Cells Define Directionality of Trunk, but Not Cranial,
Neural Crest Cell Migration. Cell Rep.;15(9):2076-88.
40 | 6 9
25.1 Novel functions of long noncoding RNAs in cancer
Co-supervisor 1: Eugene Makeyev
Research Division or CAG: IoPPN, Centre for Developmental Neurobiology
E-mail: eugene.makeyev@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/eugene.makeyev.html
Co-supervisor 2: Victoria Sanz Moreno
Research Division or CAG: Faculty of Life Sciences and Medicine/Randall Division of Cell and
Molecular Biolphysics
Email: victoria.sanz_moreno@kcl.ac.uk
Website:
https://www.kcl.ac.uk/lsm/research/divisions/randall/research/sections/motility/sanzmoreno/rese
arch.aspx
Project Description:
Metastasis is the spread of cancer cells around the body and is the cause of ~90% of cancer-related
deaths. We have recently identified a new long noncoding RNA (lncRNA), PNCTR, and shown that
it can modulate gene expression in metastatic cancer cells by sequestering multiple copies of an
important RNA-binding protein, PTBP1. Student joining our team will develop this exciting line of
research by focusing on the following questions.
Rotation-Year 1: What types and stages of human cancers are characterized by elevated expression
of PNCTR? The student will analyse next-generation RNA-sequencing (RNA-seq) data (Makeyev
lab) and measure PNCTR expression in a representative panel of cancer samples including metastatic
lesions (Sanz-Moreno lab).
Year 2: How does PNCTR contribute to cancer progression? This will be addressed by altering
PNCTR expression using appropriate over-expression and knockdown approaches (Makeyev) and
examining the effects of these treatments on cell proliferation and metastasis by appropriate in vitro
and in vivo assays (Sanz-Moreno).
Year(s) 3-4: What molecular mechanisms underlie increased expression of PNCTR in cancer cells?
This will involve analyses of possible genome rearrangements or/and expression levels of relevant
transcription and RNA processing factors in cancer cells (Makeyev/Sanz-Moreno).
In addition to its strong potential for biomedically important discoveries leading to new cancer
biomarkers and therapeutic approaches, this research program will allow the student to acquire
multidisciplinary skills in bioinformatics (RNA-seq data analysis), RNA biology (RT-(q)PCR,
Northern blotting, RNA-FISH) and various cell and cancer biology approaches (high-end
microscopy, in-vitro assays for invasion/metastasis, xenografts/allografts in mice).
One representative publication from each co-supervisor:
Dai W, Li W, Hoque M, Li Z, Tian B and Makeyev EV (2015) A post-transcriptional mechanism
pacing expression of neural genes with precursor cell differentiation status. Nat. Commun. 6, 7576.
Cantelli G, Orgaz JL, Rodriguez-Hernandez I, Karagiannis P, Maiques O, Matias-Guiu X, Nestle
FO, Marti RM , Karagiannis SN and Sanz-Moreno V (2015) TGFbeta-induced transcription
sustains amoeboid melanoma migration and dissemination. Curr Biol, 16;25(22):2899-914. doi:
10.1016/j.cub.2015.09.054.
41 | 6 9
26.1 HIV-1 mediated reprogramming of T cell gene expression networks
Co-supervisor 1: Michael Malim
Research Division or CAG: School of Immunology & Microbial Sciences
E-mail: michael.malim@kcl.ac.uk
Website: http://www.kcl.ac.uk/malim
Twitter: @michael_malim
Co-supervisor 2: Rebecca Oakey
Research Division or CAG: School of Basic & Medical Biosciences
Email: rebecca.oakey@kcl.ac.uk
Website:
http://www.kcl.ac.uk/lsm/research/divisions/gmm/departments/mmg/researchgroups/OakeyLab/
index.aspx
Twitter: @rjoakey2012
Project Description:
Virus infection triggers two fundamental types of cellular response: those that inhibit infection
(broadly termed immune responses) and those that promote virus production, persistence and/or
dissemination (here called reprogramming). The balance between these opposing forms of response
dictates the overall outcome of infection and, ultimately, contributes to the pathogenic consequences
for the infected host. To date, little is understood regarding the capacity of the pathogenic retrovirus,
HIV-1, to reprogramme infected T lymphocytes, or the consequences of such changes for altering cell
function. This project will build upon a substantial body of data where we have demonstrated that
HIV-1 reorganises the transcriptional landscape of T lymphocytes within the first few hours of
infection. We will employ a multi-disciplinary approach including virology, molecular genetics,
chromatin-biochemistry, high-throughput nucleic acid sequencing, single-cell analytics and
bioinformatics to tackle the following key questions. One, what are the virus determinants that drive
these RNA expression changes and through which signalling pathways do they function? Two, what
genome-wide alterations in chromatin and epigenetic marks underpin changes in RNA levels, and
which steps of RNA biogenesis are regulated? Three, do all cells respond to infection equivalently or
is there cell-to-cell variation; and if the latter, what cell-specific signatures underpin the differences?
Four, how does reprogramming impact the fate of HIV-1 infection, perhaps by altering virus
production, persistence/latency, or sites of provirus integration? Together, insight in these areas will
yield new information on the dynamic interplay between HIV-1 and its human host.
One representative publication from each co-supervisor:
Goujon, C., Moncorgé, O., Bauby, H., Doyle, T., Ward, C.C., Schaller, T., Hué, S., Barclay, W.S.,
Schulz, R. and Malim, M.H. (2013). Human MX2 is an interferon-induced post-entry inhibitor of
HIV-1 infection. Nature 502, 559-562. This paper employed comparative transcriptomics to
identify candidate innate immune inhibitors of HIV infection, that were subsequently functionally
screened and validated.
Prickett, A.R., Barkas, N., McCole, R.B., Hughes, S., Amante, S.M., Schulz, R., and Oakey, R.J.
Genome wide and parental allele specific analysis of CTCF and Cohesin binding sites in mouse
brain reveals a tissue-specific binding pattern and an association with differentially methylated
regions. Genome Research 2013. 23(10):1624-1635. This paper illustrates the use of genome wide
sequencing techniques in understanding gene regulation.
42 | 6 9
27.1 Role of intrahepatic Tregs in the modulation of liver inflammation and the
promotion of tissue regeneration
Co-supervisor 1: Dr Marc Martinez-Llordella
Research Division or CAG: School of Immunology & Microbial Sciences / Department of Liver
Science / MRC Centre for Transplantation
E-mail: marc.martinez-llordella@kcl.ac.uk
Website: http://www.kcl.ac.uk/lsm/research/divisions/timb/research/liver.aspx
Co-supervisor 2: Prof Alberto Sanchez-Fueyo
Research Division or CAG: School of Immunology & Microbial Sciences / Department of Liver
Science / MRC Centre for Transplantation / King’s College Hospital, Institute of Liver Studies
Email: sanchez_fueyo@kcl.ac.uk
Website: http://www.kcl.ac.uk/lsm/research/divisions/timb/research/liver.aspx
Project Description:
Hepatic inflammation of any aetiology is characterized by lymphocyte infiltration. If the inflammation
is not controlled it could lead to fibrosis, resulting in cirrhosis or liver failure. The balance of effector
and regulatory T cells (Tregs) generally determines the outcome of hepatitis. Tregs are a
heterogeneous population with specific properties depending on the homing tissue, including
immunoregulation and tissue repair. However, the factors that modulate Treg homeostasis and
function in the liver remain unclear. Our previous studies have demonstrated that IL-2 administration
preferentially expand Tregs in the liver and increases their suppressive functions. Therefore, we
believe that IL-2 therapy can modulate Treg immunoregulation during hepatic inflammation and
enhance tissue regeneration.
The objectives of this study are: i) to characterise the phenotype and features of intrahepatic Tregs in
humans and mice; ii) to determine the Treg homeostasis and cell-to-cell interactions during chronic
liver inflammation; iii) to assess the role of Tregs in the tissue regeneration after hepatic injury; and
iv) to evaluate the benefits of combining IL-2 therapy with hepatocyte transplantation to improve
regeneration of end-stage liver damage.
In order to achieve our aims, we will employ animal models of acute hepatitis and liver fibrosis (wild-
type and Treg-depleted mice), and 3D microfluidic cell cultures (liver-on-chip) to mimic the human
hepatic physiology. Single-cell RNAseq and CyTOF analysis will be integrated to characterize new
Treg subsets. In addition, we will perform isolation and cell culture techniques from human and mouse
(MLR, Treg suppression assays…), cell biology assays (flow cytometry, ELISA…) and molecular
analysis (qPCR, DNA sequencing…).
One representative publication from each co-supervisor:
Whitehouse, G., Gray, E., Mastoridis, S., Merritt, E., Kodela, E., Yang, J. H. M., Danger, R.,
Mairal, M., Christakoudi, S., Lozano, J. J., Macdougall, I. C., Tree, T., Sanchez-Fueyo, A. &
Martinez-Llordella, M. IL-2 therapy restores regulatory T-cell dysfunction induced by calcineurin
inhibitors PNAS. 2017; 114(27):7083-7088
Bohne F, Martínez-Llordella M, Lozano JJ, Miquel R, Benítez C, Londoño MC, Manzia TM,
Angelico R, Swinkels DW, Tjalsma H, López M, Abraldes JG, Bonaccorsi-Riani E, Jaeckel E,
Taubert R, Pirenne J, Rimola A, Tisone G, Sánchez-Fueyo A. Intra-graft expression of genes
involved in iron homeostasis predicts the development of operational tolerance in human liver
transplantation. J Clin Invest. 2012 Jan;122(1):368-82.
43 | 6 9
28.1 Identification of host factors that promote assembly of Ebola virus
Co-supervisor 1: Prof Juan Martin-Serrano
Research Division or CAG: School of Immunology & Microbial Sciences, Infectious Diseases
Department
E-mail: juan.martin_serrano@kcl.ac.uk
Website:
https://www.kcl.ac.uk/lsm/research/divisions/diiid/departments/infectious/research/Martin-
Serrano/indexJD.aspx
Co-supervisor 2: Dr Monica Agromayor
Research Division or CAG: School of Immunology & Microbial Sciences, Infectious Diseases
Department
Email: monica.agromayor@kcl.ac.uk
Website:
https://www.kcl.ac.uk/lsm/research/divisions/diiid/departments/infectious/research/agromayor/i
ndex.aspx
Project Description:
Ebola virus (EBOV) is a filovirus that causes severe haemorrhagic fever. The major EBOV structural
component is VP40, the matrix protein that plays a central role in the assembly of infectious viral
particles. VP40 expression is sufficient to form viral-like particles that share the filamentous
morphology with infectious Ebola virions. Therefore, VP40 is the minimal unit required for assembly
that recruits the host factors required for this process, as shown by our observations that VP40 recruits
the Endosomal Sorting Required for Transport (ESCRT) machinery to promote viral egress.
VP40 promotes assembly by adopting multiple conformations. VP40 dimers change membrane
curvature and subsequently assemble into hexamers that form the filaments that shape EBOV virions.
The octameric ring conformation of VP40 binds RNA and plays a poorly defined role in EBOV
replication.
The aim of this project is the identification of VP40-binding host proteins that are involved in EBOV
replication. We have performed a genome-wide screen to identify human proteins that bind either
WT or the octamer-locked form of VP40. The student will determine the role of the candidate hits in
EBOV replication. The selected open reading frames will be cloned into yeast two-hybrid and co-
precipitation plasmids to further validate the interaction with VP40. Co-localization by super-
resolution and live-cell microscopy will further confirm the interaction of candidate host proteins with
VP40. Expression of the short-listed genes will be disrupted by siRNA and CRISPR-based gene
editing to assess their contribution to EBOV assembly and replication, taking advantage of a
transcription/replication-competent virus-like particle (trVLP) system.
One representative publication from each co-supervisor:
HECT ubiquitin ligases link viral and cellular PPXY motifs to the vacuolar protein-sorting pathway.
Martin-Serrano J, Eastman SW, Chung W, Bieniasz PD. J Cell Biol. 2005 Jan 3;168(1):89-101.
The UBAP1 subunit of ESCRT-I interacts with ubiquitin via a SOUBA domain. Agromayor M,
Soler N, Caballe A, Kueck T, Freund SM, Allen MD, Bycroft M, Perisic O, Ye Y, McDonald B,
Scheel H, Hofmann K, Neil SJ, Martin-Serrano J, Williams RL. Structure. 2012 Mar 7;20(3):414-
28.
44 | 6 9
29.1 Identification of type 1 diabetes-associated non-canonical spliced epitopes and
their immunological role in the autoimmune response
Co-supervisor 1: Michele Mishto
Research Division or CAG: School of Immunology & Microbial Sciences| Peter Gorer Department
of Immunobiology, Centre for Inflammation Biology and Cancer Immunology (CIBCI)
E-mail: Michele.mishto@kcl.ac.uk
Website:
https://www.kcl.ac.uk/lsm/research/divisions/diiid/departments/immunobiology/research/mishto
/Michel e-Mishto.aspx
Co-supervisor 2: Mark Peakman
Research Division or CAG: DIIID
Email: mark.peakman@kcl.ac.uk
Website: www.kcl.ac.uk/lsm/research/divisions/diiid/.../peakman/index.aspx
Project Description:
The project aims to identify MHC class I (MHC-I)-restricted epitopes associated with Type 1
diabetes (T1D) and produced by proteasome-catalysed peptide splicing.
We recently showed that the latter activity of proteasome produces around 30 % of the self antigenic
epitopes in human cells (Liepe et al., Science 2016). Spliced epitopes can trigger a CD8+ T cell
response against cancer and infection (Mishto and Liepe, Trends Imm. 2017). An autoimmune
cytotoxic T cell (CTL) response is responsible for the killing of cells, which is the cause of the T1D.
The identification and elimination of autoreactive CTLs specific for T1D-associated epitopes is one
of the promising therapies to defeat T1DM (Harbige et al., J. Autoimm. 2017).
The ground-breaking discovery of the unexpected frequency of spliced self antigenic peptides opened
a window to a large, and so far unforeseen, pool of epitopes and their potential importance in
autoimmune CTL responses. The systematic identification of MHC-I-restricted spliced peptides is
now feasible (Liepe et al., Science 2016). That methodology, which relies on a combination of cellular
biology, mass spectrometry and bioinformatics approaches, will be applied to carry out the project.
The PhD student will work in tight collaboration with the two co-supervisors and a selected group of
international collaborators. Upon the identification of the T1D-associated spliced antigenic peptides,
the PhD student will test patient-specific recognition by CTLs of the epitope candidates using
peptide-HLA tetramer reagents and deep immunophenotyping by flow cytometry and will further
characterise the cellular processing and presentation pathways involved by applying biochemical and
molecular biology methods, which are well established in the groups of the two co-supervisors.
One representative publication from each co-supervisor:
Liepe J, Marino F, Sidney J, Jeko A, Bunting DE, Sette A, Kloetzel PM, Stumpf MP, Heck AJ,
Mishto M. A large fraction of HLA class I ligands are proteasome-generated spliced peptides.
Science 2016 Oct; 354(6310): 354-358. DOI: 10.1126/science.aaf4384. Epub 2016 Oct 20.
PubMed PMID: 27846572.
Alhadj Ali M, Liu YF, Arif S, Tatovic D, Shariff H, Gibson VB, and Peakman M, Dayan CM.
Metabolic and immune effects of immunotherapy with proinsulin peptide in human new-onset type
1
diabetes. Sci Transl Med. 2017 Aug 9;9(402). PMID: 28794283
45 | 6 9
30.1 Explaining the sexual dimorphism in Lupus through genetics
Co-supervisor 1: Dr David Morris
Research Division or CAG: School of Medicine
E-mail: david.l.morris@kcl.ac.uk
Website:
https://www.kcl.ac.uk/lsm/research/divisions/gmm/departments/mmg/researchgroups/VyseLab/
dmorris.aspx
Twitter: @daweimo
Co-supervisor 2: Professor Timothy Vyse
Research Division or CAG: School of Medicine
Email: timothy.vyse@kcl.ac.uk
Website:
https://www.kcl.ac.uk/lsm/research/divisions/gmm/departments/mmg/researchgroups/VyseLab/i
ndex.aspx
Project Description:
Systemic Lupus Erythematosus (SLE) is an autoimmune disease that affects millions of people
worldwide. Strikingly 9/10 SLE cases are women, yet little is understood as to why. Hormonal and
environmental factors are believed to be partly responsible, and while there is strong evidence for a
genetic basis for this dimorphism there is still a gulf in our understating. There are many avenues ripe
for investigation and, with the advent of new technologies and a large amount of data available, a
thorough study of the differences in genetics between the sexes is warranted. Current interests include
the overlap between SLE associated genetic loci and genes showing sex differences in expression,
genetic associations on the X chromosome and the cellular origins of effects.
This PhD will investigate all forms of genetic variation between the sexes that are informative of the
sexual dimorphism of SLE. The student will learn and apply cutting edge statistical techniques on the
richest data on SLE in the world. A background in statistics is not required but an interest in analyses
will be important. The PhD will cover the use of statistical methodology including linear and logistic
regression, multivariate analysis, Bayesian analysis, model choice and prediction. The student will
learn the statistical language R to a high standard making them very competitive in the current
research environment. The student will also learn and run modern genetic analyses software. The
study will use the largest collection of SLE genetic data in the world together with gene expression
data.
One representative publication from each co-supervisor:
Morris DL, Sheng Y, Zhang Y, Wang Y-F, Zhu Z, Tombleson P, Chen L, Graham D S-C,
Bentham J, Chen R, Zuo X, Wang T, Wen L, Yang C, Liu L, Yang L, Li F, Huang Y, Yin X, Yang
S, Rönnblom L, Fürnrohr BG, Voll RE, Schett G, Costedoat–Chalumeau N, Gaffney PM, Lau YL,
Zhang X, Yang W, Cui Y, Vyse TJ. (2016). Genome-wide association meta-analysis in Chinese and
European individuals identifies ten new loci associated with systemic lupus erythematosus. Nature
Genetics. doi: 10.1038/ng.3603. Aug; 48(8): 940-946
Bentham J, Morris DL, Graham DSC, Pinder CL, Tombleson P, Behrens TW, Martín J, Fairfax
BP, Knight JC, Chen L, Replogle J, Syvänen A-C, Rönnblom L, Graham RR, Wither JE, Rioux JD,
Alarcón-Riquelme ME & Vyse TJ. (2015). Genetic association analyses implicate aberrant
regulation of innate and adaptive immunity genes genes in the pathogenesis of systemic lupus
erythematosus Nature Genetics. doi:10.1038/ng.3434 Dec; 47(12) 1457-64
46 | 6 9
31.1 Role of c-Fos in mucosal infections, immunity and microbiome interactions
Co-supervisor 1: Julian Naglik
Research Division or CAG: Mucosal & Salivary Biology Division
E-mail: julian.naglik@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/julian.naglik.html
Co-supervisor 2: David Moyes
Research Division or CAG: Mucosal & Salivary Biology Division
Email: david.moyes@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/david.moyes.html
Project Description:
Mucosal infections are a global medical problem that devastate the lives of millions of individuals each
year. Using model fungal and bacterial pathogens, we have identified c-Fos as a key transcription
factor within epithelial cells that is activated during infection and a critical mediator of mucosal innate
immune responses. We hypothesise that c-Fos is a master regulator of host innate responses against
mucosal pathogens. With our collaborators, we have generated a mouse that is c-Fos deficient only in
oral and vaginal tissues. We will utilise this conditional c-Fos knockout mouse to assess the role of this
transcription factor in microbial homeostasis and during mucosal fungal and bacterial infections.
Given the potential role of c-Fos in mucosal immune homeostasis, in Year One, the oral, vaginal and
gut microbiome (bacteriome and mycobiome) of the conditional c-Fos knockout mice will be
determined to identify alterations in microbial composition. The gut microbiome will also be included
in this analysis, as alterations in the oral microbiome may be reflected in the gut. In Years 2 and 3, the
conditional c-Fos knockout mice will be infected with different fungal and bacterial pathogens to
determine (i) their susceptibility to infection, and (ii) the role of c-Fos in mediating innate immune
responses (e.g. cytokines/chemokines, antimicrobial peptides, neutrophil recruitment). This cutting-
edge, multidisciplinary project will combine infection, immunity, imaging and cellular analyses to
reveal the role of c-Fos during mucosal infection and immune protection, and may identify c-Fos as a
new target for novel antimicrobial therapies against mucosal infections.
One representative publication from each co-supervisor:
Moyes DL, Wilson D, Richardson JP, Tang SX, Wernecke J, Höfs S, Gratacap RL, Mogavero S,
Robbins J, Runglall M, Murciano C, Blagojevic M, Thavaraj S, Förster TM, Hebecker B, Kasper L,
Vizcay G, Iancu SI, Kichik N, Häder A, Kurzai O, Cota E, Bader O, Wheeler RT, Gutsmann T,
Hube B and Naglik JR (2016). Candidalysin: A fungal peptide toxin critical for mucosal infection.
Nature 532, 64-68.
Conti HR, Bruno VM, Childs EE, Daugherty S, Hunter JP, Mengesha BG, Saevig DL, Hendricks
MR, Coleman BM, Brane L, Solis N, Cruz JA, Verma AH, Garg AV, Hise AG, Richardson JP, Naglik
JR, Filler SG, Kolls JK, Sinha S and Gaffen SL (2016). IL-17RA signaling in oral epithelium is
necessary and sufficient for protection against oropharyngeal candidiasis. Cell Host & Microbe 20,
606–617.
47 | 6 9
32.1 Type 1 interferon resistance in the HIV-1 envelope glycoprotein
Co-supervisor 1: Prof Stuart Neil
Research Division or CAG: SIMS
E-mail: stuart.neil@kcl.ac.uk
Website:
https://www.kcl.ac.uk/lsm/research/divisions/diiid/departments/infectious/research/neil/index.as
px
Twitter: @stuartjdneil
Co-supervisor 2: Dylan Owen
Research Division or CAG: FNMS
Email: dylan.owen@kcl.ac.uk
Website: https://www.kcl.ac.uk/nms/depts/physics/people/academicstaff/owen.aspx
Collaborating Clinician: Dr Julie Fox
Research School/Division or CAG: SIMS
Email: julie.fox@kcl.ac.uk
Website:
https://www.kcl.ac.uk/lsm/research/divisions/diiid/departments/infectious/research/juliefox.aspx
Project Description:
A key attribute for the transmission of HIV-1 between individuals is the virus’s intrinsic resistance to
the antiviral activities of type-1 interferons (IFN-I). Transmitted viruses have a higher resistance to
IFN-I than those isolated from the recipient partner 6 months later. The effects of IFN-I on HIV-1
replication are mediated by interferon-induced genes (ISGs), several of which directly inhibit stages
of the virus lifecycle. The Interferon-Induced Transmembrane Proteins (IFITMs) are broadly-acting
ISGs that target the cell entry process that is mediated by its envelope glycoprotein (Env). We have
found that transmitted HIV-1 strains are IFITM resistant but sensitivity increases over time as Env
adapts to escape host antibody responses. Insensitivity to IFITMs contributes substantially to the
IFN-I resistance of the transmitted virus. Preliminary data suggests that IFITM/IFN resistance of Env
correlates with the structural rearrangements it must undergo when it binds to its receptor CD4. The
more stable the Env, the more IFITM resistant. Thus the transmitted Env is structurally constrained
by the need to be IFN-resistant. Since this is the structure that an effective vaccine needs to protect
against, understanding the molecular basis of these constraints is essential. In this project the student
will:
• use molecular and cellular virology, FRET-based assays and super-resolution microscopy to
study how the clustering and dynamics of Env/receptor interactions contribute to
IFN/IFITM resistance (Yrs 1-2).
• using patient samples from well characterized cohorts, clone and characterize Envs from
patients longitudinally and determine how neutralizing antibody escape leads to loss of IFN
resistance in Env (Yrs 2-3).
One representative publication from each co-supervisor:
Resistance of Transmitted Founder HIV-1 to IFITM-Mediated Restriction. Foster TL, Wilson H,
Iyer SS, Coss K, Doores K, Smith S, Kellam P, Finzi A, Borrow P, Hahn BH, Neil SJ. Cell Host
Microbe. 2016 Oct 12;20(4):429-442. doi: 10.1016/j.chom.2016.08.006. Epub 2016 Sep 15.
PMID: 27640936
48 | 6 9
Bayesian cluster identification in single-molecule localization microscopy data. Rubin-Delanchy, P.,
Burn, G. L., Griffié, J., Williamson, D. J., Heard, N. A., Cope, A. P. & Owen, D. M. 5 Oct 2015 In
: NATURE METHODS. 12, 11, p. 1072-1076
49 | 6 9
33.1 Inhibition of Salmonella and Shigella intracellular replication by interferon-
stimulated genes.
Co-supervisor 1: Charlotte Odendall
Research Division or CAG: School of Immunology and Microbial Sciences
E-mail: charlotte.odendall@kcl.ac.uk
Website:
https://www.kcl.ac.uk/lsm/research/divisions/diiid/departments/infectious/research/Odendall/ind
ex.aspx
Co-supervisor 2: Chad Swanson
Research Division or CAG: School of Immunology and Microbial Sciences
Email: chad.swanson@kcl.ac.uk
Website:
http://www.kcl.ac.uk/lsm/research/divisions/diiid/departments/infectious/research/swanson/inde
x.aspx
Project Description:
Type I and III interferons (IFNs) are produced in response to non-self by the innate immune system
and are better described as inhibitors of viral infections. We found that IFNs block the growth of
Salmonella within host cells. IFNs function by inducing a large family of 300 proteins termed
Interferon stimulated genes (ISGs), with a wide range of different functions. This project seeks to
determine which ISG(s) are responsible for IFN-mediated inhibition of bacterial growth, using
Salmonella Typhimurium and Shigella sonnei as models. These pathogenic bacteria cause disease
using type III secretion systems (T3SS), molecular needles that enable the transport of virulence
proteins into host cells. Both pathogens replicate intracellularly but Salmonella replicates within
specialised phagosomes while Shigella escapes the phagosome and replicates in the cytosol. We expect
different sets of ISGs will affect the intracellular replication of these bacteria.
We will first perform an expression screen using an ISG library. Individual ISGs will be expressed and
their ability to block intracellular bacterial replication will be assessed. Bacterial replication in infected
cells will be assessed via plating of live bacteria or flow cytometry. In parallel we will perform an
siRNA screen of known ISGs. ISGs will be knocked down and infection assays will be carried out in
the presence of IFNs. Positive hits will be cells that no longer control bacterial infection in the presence
of IFN (Year 1 and 2). Identified ISGs will be further studied to determine which step of the bacterial
intracellular lifecycle they affect (Year 3). Finally, the roles of ISGs in inhibition of bacterial virulence
will then potentially be studied in well-established in vivo models (Year 3).
This project will investigate both aspects of host pathogen interactions, as well as bridge the fields of
virology and bacteriology as IFNs and ISGs are normally considered as antiviral factors.
Techniques involved will be :
- Molecular Biology
- Tissue culture
- Flow cytometry
- Microbiology
- Infection assays with different bacterial pathogens
- Biochemistry (western immunoblotting, immunoprecipitation)
- Microscopy
- In vivo infection models
50 | 6 9
One representative publication from each co-supervisor:
Odendall, C. et al. Diverse intracellular pathogens activate type III interferon expression from
peroxisomes. Nat. Immunol. 15, 717–726 (2014).
HIV-1 and M-PMV RNA Nuclear Export Elements Program Viral Genomes for Distinct
Cytoplasmic Trafficking Behaviors. Pocock GM, Becker JT, Swanson CM, Ahlquist P, Sherer NM.
PLoS Pathog. 2016 12:e1005565.
51 | 6 9
34.1 Understanding regulation of cellular energy metabolism
Co-supervisor 1: Snezhana Oliferenko
Research Division or CAG: School of Basic and Medical Biosciences / Randall Division of Cell and
Molecular Biophysics
E-mail: snezhana.oliferenko@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/snezhana.oliferenko.html
Co-supervisor 2: Simon Ameer-Beg
Research Division or CAG: School of Basic and Medical Biosciences / Randall Division of Cell and
Molecular Biophysics
Email: simon.ameer-beg@kcl.ac.uk
Website: http://www.kcl.ac.uk/lsm/research/divisions/randall/research/sections/cell/ameer-
beg/index.aspx
Project Description:
Cellular energy metabolism occurs through oxidative phosphorylation in mitochondria and glycolysis
in the cytoplasm. In humans, differentiated cells tend to rely on oxidative phosphorylation but
dividing cells or abnormally proliferating cancers often adopt aerobic glycolysis that favours increased
macromolecular synthesis, a phenomenon known as Warburg effect. How is energy production
regulated? How do cells choose a particular energy generation route, and how do they switch between
alternative strategies? How do these metabolic choices affect the rates of cellular growth? We want
to answer these fundamental, yet surprisingly poorly understood questions by combining precise
spatiotemporal imaging of cellular energy metabolic pathways with the awesome power of genetic
engineering. We will visualize energy metabolites such as glucose, ATP, glutamate and others in real
time using Förster Resonance Energy Transfer (FRET)-based sensors and probe how fluctuations in
nutrient availability, cellular differentiation, chronological aging and genetic perturbations of
metabolic regulation affect their intracellular flux. To speed up our research by straightforward
genome editing, we will initially use two yeast species that exhibit divergent energy production
pathways. We will eventually translate our research to human cells with a view of understanding how
altered energy metabolism contributes to disease.
Year 1. Development of genetically encoded FRET-based biosensors to report metabolic activity (SO
and SAB).
Year 2. Understanding spatiotemporal regulation of metabolic sensors at a single-cell level in response
to environmental and genetic perturbations (SO and SAB).
Years 3-4. Studying the mechanisms underlying regulation of energy metabolism and preparing
experimental results for publication (SO and SAB).
One representative publication from each co-supervisor:
Makarova, M., Gu, Y., Chen, J-S., Beckley, J., Gould, K. and S. Oliferenko. 2016. Temporal
regulation of Lipin activity diverged to account for differences in mitotic programs. Current Biology.
26: 237-243.
*Highlighted in Prasad, R. and Y. Barral. 2016. Posttranslational Regulation: A Way to Evolve.
Current Biology. 26: R102-124, and Editor’s Choice in Science: 351:828-829
A high speed multifocal multiphoton fluorescence lifetime imaging microscope for live-cell FRET
imaging. Poland, S. P., Krstajić, N., Monypenny, J., Coelho, S., Tyndall, D., Walker, R. J.,
52 | 6 9
Devauges, V., Richardson, J., Dutton, N., Barber, P., Day-Uei Li, D., Suhling, K., Ng, T.,
Henderson, R. K. & Ameer-Beg, S. M. 2015. Biomedical optics express. 6: 277-296
53 | 6 9
35.1 Long range interactions of regulatory elements influencing gene expression in
bronchial epithelial cells
Co-supervisor 1: Cameron Osborne
Research Division or CAG: Basic and Medical Biosciences
E-mail: cameron.osborne@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/cameron.osborne.html
Twitter: @camosbornelab
Co-supervisor 2: Paul Lavender
Research Division or CAG: Immunology and Microbial Sciences
Email: paul.lavender@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/paul.lavender.html
Project Description:
Asthma is a complex disease involving multiple cell types which affects over 5 million people and costs
over £1 billion per year. In asthmatic subjects, gene expression in the primary barrier, bronchial
epithelial cells, is perturbed through poorly understood mechanisms. A key abnormality, which may
be amenable to therapeutic intervention, is altered signalling through long-range regulatory elements,
such as enhancers. To fully understand the transcriptional defect, it is crucial to have comprehensive
knowledge of regulatory elements that influence transcription. This task is not trivial; regulatory
elements can be positioned at great distances (megabase range) from the genes they control.
We have developed a method called Capture Hi-C (CHI-C) to identify regulatory interactions of
gene promoters on a genome-wide scale (Mifsud et al. 2015 Nature Genetics). We find that different
cell types form distinct regulatory contacts. By applying this technique in leukaemia patient samples,
we have identified disease specific interactions, which may be determinants of malignant phenotypes
and could potentially reveal critical prognostic information.
In this project, we will apply these methodologies to asthma samples, to better understand the
regulatory defects. The student will generate and bioinformatically analyse CHi-C libraries from
asthmatic and control samples. These datasets will be integrated with existing NGS datasets
(ChIPseq, RNAseq) to provide novel insights into disease pathogenesis, identifying biomarkers and
therapeutic targets with translational potential.
In months 1-18, the student will generate and sequence CHi-C libraries. In years 2-3, he/she will
validate targets and develop strong computational skills to carry out extensive bioinformatics analyses.
One representative publication from each co-supervisor:
Mifsud B et al. 2015. Mapping long-range promoter contacts in human cells with high-resolution
capture Hi-C. Nature Genetics. DOI: 10.1038/ng.3286.
Hertweck A, et al 2016. T-bet recruits P-TEFb to super-enhancers to regulate T helper cell
differentiation. Cell Reports. 15(12):2756-70.
54 | 6 9
36.1 Determining how a novel complex promotes tumour growth, by protecting an
iron-sulphur cluster from cancer-associated oxidative stress.
Co-supervisor 1: Dr. Barry Panaretou
Research Division or CAG: Institute of Pharmaceutical Science
E-mail: barry.panaretou@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/barry.panaretou.html
Co-supervisor 2: Professor Annalisa Pastore
Research Division or CAG: Clinical Neurosciences (IoPPN)
Email: annalisa.1.pastore@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/annalisa.1.pastore.html
Project Description:
Solid tumours generate elevated levels of reactive oxygen species (ROS), that compromise their
ability to grow. Iron-sulphur (Fe-S) clusters, essential cofactors for numerous proteins, are particularly
ROS-labile. Strategies cancer cells evolve to limit damage to Fe-S clusters remain uncharacterised.
We have identified a heterodimeric complex, composed of the proteins Lto1 and Yae1, that protect
the Fe-S cluster located at the N terminus of ABCE1, an enzyme crucial for ribosome biogenesis and
function. Not surprisingly, one of the members of this complex is overexpressed in many solid tumours.
To exploit this complex as a drug target, we aim to understand how the complex protects Fe-S
clusters.
Year 1:
ABCE1 will be cloned into an E.coli expression vector. Following purification, the Fe-S clusters will
be re-constituted under anaerobic conditions in the presence of the IscU Fe-S cluster re-assembly
enzyme using techniques established in Pastore’s lab. UV absorbance spectra will be used to assess
holo-protein stability.
Year 2:
Yae1/Lto1 will be expressed in E.coli. Purification of the heterodimer will be followed by assembly
of the ABCE1/Yae1/Lto1 complex, and determination of its structure via a combination of NMR
and SAXS studies.
Year 3:
A series of mutants will be expressed in vivo which should compromise the function of the
heterotrimer. This will be carried out by exploiting the tractable molecular genetics of the baker’s
yeast model system, and will be used to assess the physiological relevance of the biophysical data
generated during the project.
Training: Protein purification/biophysical techniques (Pastore). Gene cloning/molecular genetic
analysis (Panaretou).
One representative publication from each co-supervisor:
Zhai C, Li Y, Mascarenhas C, Lin Q, Li K, Vyrides I, Grant CM, Panaretou B. (2014) The function
of ORAOV1/LTO1, a gene that is overexpressed frequently in cancer: essential roles in the function
and biogenesis of the ribosome. Oncogene 33: 484
55 | 6 9
Popovic M, Sanfelice D, Pastore C, Prischi F, Temussi PA and Pastore A (2015) Selective
observation of the disordered import signal of a globular protein by in-cell NMR: the example of
frataxins. Protein Science 24: 996
37.1 Exploring novel molecular mechanisms driving skin fibrosis
Co-supervisor 1: Prof Maddy Parsons
Research Division or CAG: Randall Division
E-mail: maddy.parsons@kcl.ac.uk
Website:
http://www.kcl.ac.uk/lsm/research/divisions/randall/research/sections/motility/parsons/parsonsm
addy.aspx
Co-supervisor 2: Professor John McGrath
Research Division or CAG: St John’s Institute of Dermatology/Genetics/GRIIDA
Email: john.mcgrath@kcl.ac.uk
Website:
http://www.kcl.ac.uk/medicine/research/divisions/gmm/departments/dermatology/Groups/McGr
athLab/index.aspx
Project Description:
Keloids are abnormal fibro-proliferative scars that often occur after burns or other skin injuries and
continue to extend beyond the original wound boundaries. They are refractory to treatment, have a
tendency to recur even after surgical excision, and can continue to increase in size, leading to
significant deleterious impacts on tissue function. Keloids may also occur spontaneously or through
inherited traits and whilst a number of genes or loci have been implicated in susceptibility to
developing keloids, the underlying molecular mechanisms remain unclear. Using whole exome data
from multiple pedigrees with autosomal dominant transmission of keloid susceptibility, we have
identified a novel mutation in the gene encoding for the secreted protein TSG6 (also known as
TNFAIP6) that segregates with individuals prone to keloid scars. TSG6 is known to have anti-
inflammatory properties and it has also been suggested to be involved in fibrosis. The goal of this
project is to define the molecular mechanisms by which TSG6 regulates fibrosis with a view to
understanding the potential for modulating TSG6 as a potential therapy for keloid scars. The aims of
the project are:
• Use CRISPR/Cas9 to generate TSG6 knockout and mutant knockin fibroblasts and
characterise the effects of WT and mutant TSG6 expression and secretion on fibroblast
proliferation, differentiation and collagen production using 3D dermal-equivalent models.
Validate in cells from patients (Years1/2)
• Define the signalling changes in TSG6-deficient/mutant fibroblasts using total and phospho-
proteomic analysis and follow-up with specific inhibitors to define roles in phenotypic changes
(Years2/3)
• Analyse the interplay between TSG6-deficient/mutant fibroblasts and keratinocytes using
co-culture organotypic models (Years 3/4)
• Determine the capacity for exogenous TSG6 addition to reduce fibrosis in dermal models
(Year 4)
Data arising from this study will shed light on the mechanisms driving dermal fibrosis and inform on
potential novel therapeutics for future use in the clinic.
One representative publication from each co-supervisor:
56 | 6 9
McGrath JA, Stone KL, Begum R, Simpson MJ, Dopping-Hepenstal PJ, Liu L, McMillan JR, South
AP, Pourreyron P, McLean I, Martinez A, Mellerio JE, Parsons M. Germline mutation in the EXPH5
gene implicates the Rab27B effector protein Slac2-b (exophilin- 5) in inherited skin fragility. Am J
Hum Gen. 2012. 91(6); 1115-21
Zhang G, Begum R, Gu Y, Chen H, Gao X, McGrath JA, Song B* Parsons M*. Kindlin-1 regulates
keratinocyte electrotaxis. J Invest Dermatol. 2016. pii: S0022-202X(16)32105-4. doi:
10.1016/j.jid.2016.05.129
57 | 6 9
38.1 Modulation of host immunity to prevent bacterial infection
Co-supervisor 1: Dr Khondaker Miraz Rahman
Research Division or CAG: Institute of Pharmaceutical Science
E-mail: k.miraz.rahman@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/k.miraz.rahman.html
Co-supervisor 2: Dr Simon Pitchford
Research Division or CAG: Institute of Pharmaceutical Science
Email: simon.pitchford@kcl.ac.uk
Website:
http://www.kcl.ac.uk/biohealth/research/divisions/ips/research/pharmathera/Staff/Pitchford.aspx
Project Description:
Antimicrobial resistance is a major global concern. To develop new strategies to tackle antimicrobial
resistance, an understanding of the cascade of events leading to colonisation, persistence and
ultimately the pathogenesis of an invading microorganism in response to the host environment is
essential. The immune system present in host provides the key protection against invading
microorganisms and can prevent events leading to infection. The overwhelming evidence indicates
that ATP and ADP are important endogenous signalling molecules in immunity and inflammation.
We hypothesise that activating purinergic receptors P2Y1 and P2Y14 would strengthen the host
immune system against infection by a resistant pathogenic microorganism, and protect the host from
the bacterial challenge, because we have reported that these receptors are responsible for inflammatory
responses in murine models of lung inflammation. The PhD project would test this hypothesis by
developing selective P2Y1 and P2Y14 agonists using a combination of advanced in silico and
medicinal chemistry techniques. The developed agonists will be tested initially in vitro and
subsequently in vivo in mice to assess their ability to modulate the immune system, involving,
haematological, cell activation, chemotaxis, bacteria killing assays, The student will learn specialised
in vivo skills, advanced microscopy, flow cytometry, and various haematological laboratory
techniques. This will be followed by the bacterial challenge of agonists treated mice to evaluate the
relationship between immune system mediated protections from bacterial infection.
Specific deliverables and work plan of the project includes -
Year1 and 2: In silico deign and synthesis of P2Y1 and P2Y14 receptor agonists
Year 3: Use the synthesised compounds as chemical tools to study immune modulation using
biochemical and cellular assays.
Year 4: In vivo evaluation of P2Y1 and P2Y14 agonists for their ability to protect hosts from the
bacterial challenge.
One representative publication from each co-supervisor:
Picconi, P.; Hind, C.; Jamshidi, S.; Nahar, K.; Clifford, M.; Wand, M. E.; Sutton, J. M.; Rahman,
K. M., Triaryl benzimidazoles as a new class of antibacterial agents against resistant pathogenic
microorganisms. Journal of Medicinal Chemistry 2017, 60 (14), 6045-6059.
Amison, R.; Arnold, S.; O'Shaughnessy, B.; Cleary, S.; Ofoedu, J.; Idzko, M.; Page, C.; Pitchford,
S., Lipopolysaccharide (LPS) induced pulmonary neutrophil recruitment and platelet activation is
mediated via the P2Y 1 and P2Y 14 receptors in mice. Pulmonary Pharmacology & Therapeutics
2017, 45, 62-68.
58 | 6 9
39.1 The molecular basis of erythrocyte cation transport abnormalities in sickle cell
disease
Co-supervisor 1: David Rees
Research Division or CAG: Cancer Studies
E-mail: david.rees@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/david.rees.html
Co-supervisor 2: Stephan Menzel
Research Division or CAG: Cancer Studies
Email: Stephan.menzel@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/stephan.menzel.html
Project Description:
Sickle cell disease (SCD) is the most common serious inherited disease in the world. It is characterised
by haemoglobin polymerisation, which increases red cell rigidity leading to vaso-occlusion. Increased
erythrocyte cation loss is central to red cell pathology, causing cellular dehydration. Three pathways
are implicated in increased cation loss: K-Cl cotransport, the Gardos channel and Psickle. The exact
molecular identity and control of these pathways is poorly understood. This project involves
characterising the cation transport properties of established immortalized human erythroid progenitor
cell lines, using patch clamping and ion flux measurements, performed in conjunction with Dr John
Gibson (Cambridge University). Gene editing techniques, including CRISPR-Cas9, will be used to
inactivate and modify genes known to be involved in cation transport in the erythroid cultures, and
cation measurements repeated to identify any effects on red cell phenotype. This will potentially
identify genes central to the pathology of erythrocyte dehydration in SCD and novel therapeutic
targets. The candidate will develop skills in red cell physiology, erythroid culture techniques, cation
transport, CRISPR-Cas9 and other gene editing technology, flow cytometry and clinical
haematology.
Objectives:
Year 1: learn basic techniques of erythoid culture, cation transport measurements and gene editing.
Review literature on genetics of erythroid cation transport. Measure cation transport on erythroid
cultures.
Year 2: Edit selected cation transport genes and measure physiological changes in red cells.
Year 3: Complete experiments and write-up thesis.
One representative publication from each co-supervisor:
Piel FB, Steinberg MH, Rees DC. Sickle Cell Disease. N Engl J Med. 2017;376(16):1561-1573.
Menzel S, Garner C, Gut I, Matsuda F, Yamaguchi M, Heath S, Foglio M, Zelenika D, Boland A,
Rooks H, Best S, Spector TD, Farrall M, Lathrop M, Thein SL. A QTL influencing F cell
production maps to a gene encoding a zinc-finger protein on chromosome 2p15. Nat Genet.
2007;39(10):1197-9.
59 | 6 9
40.1 Monocytes and monocyte-derived cells as therapeutic targets in kidney disease
Co-supervisor 1: Michael Robson
Research Division or CAG: Immunology and Microbial Sciences
E-mail: Michael.Robson@kcl.ac.uk
Website: https://www.kcl.ac.uk/lsm/research/divisions/timb/about/people/profiles/michaelrobson.aspx
Co-supervisor 2: Anthony Dorling
Research Division or CAG: Life Sciences and Medicine
Email: anthony.dorling@kcl.ac.uk
Website:
https://www.kcl.ac.uk/lsm/research/divisions/timb/about/people/profiles/anthonydorling.aspx
Project Description:
Introduction: Glomerulonephritis is a leading cause of kidney failure resulting in a need for dialysis
and transplantation. Monocyte and monocyte-derived cells play an important role in kidney disease.
They can affect both the inflammatory component of the disease and the resolution. Resolution may
occur with scarring or fibrosis which results in an irreversible decline in function of the kidney. There
is good evidence that monocyte-derived cells can contribute to kidney fibrosis.
Aims: The overall aim of this project is to understand how monocytes and monocyte-derived cells
cause inflammation and fibrosis in glomerulonephritis and to develop therapies to improve outcomes.
Project plan: Year 1: The student will use pre-clinical models of immune-mediated kidney disease
(glomerulonephritis) established in the laboratory of supervisor A. They will examine in detail the
phenotype of cells present in the circulation and kidney during the development of disease.
Year 2: Pro-fibrotic cells are mobilised from the bone marrow during vascular injury in a model
established in the laboratory of supervisor B. These cells will be isolated and transferred in to mice
with glomerulonephritis in order to examine their effect on disease.
Year 3: We are developing therapeutic strategies that target monocytes and monocyte-derived cells.
They will be tested in these models of glomerulonephritis.
Skills and training: The students will learn to conduction experiments in these pre-clinical models.
They will be proficient in many techniques including flow cytometry, protein purification, histological
methods.
One representative publication from each co-supervisor:
Chen D, Ma L, Tham EL, Maresh S, Lechler RI, McVey JH, Dorling A: Fibrocytes mediate
intimal hyperplasia post-vascular injury and are regulated by two tissue factor-dependent
mechanisms. J Thromb Haemost 2013, 11(5):963-974.
Popat RJ, Hakki S, Thakker A, Coughlan AM, Watson J, Little MA, Spickett CM, Lavender P,
Afzali B, Kemper C and Robson MG: Anti-myeloperoxidase antibodies attenuate the monocyte
response to LPS and shape macrophage development,. JCI Insight 2016, in press.
60 | 6 9
41.1 Nutritional genomics as an emerging tool for the prevention of cardiovascular
disease
Co-supervisor 1: Ana Rodriguez-Mateos
Research Division or CAG: Department of Nutritional Sciences
E-mail: ana.rodriguez-mateos@kcl.ac.uk
Website: http://www.kcl.ac.uk/lsm/research/divisions/dns/about/people/Profiles/Ana-Rodriguez-
Mateos.aspx
Twitter: @anarmateos
Co-supervisor 2: Reiner Schulz
Research Division or CAG: Genetics and Molecular Medicine
Email: reiner.schulz@kcl.ac.uk
Website: http://atlas.genetics.kcl.ac.uk/~rschulz/
Project Description:
Nutritional genomics is an emerging science which combines the study of nutrition and genetics to
investigate how genes and nutrients interact, and how people respond to food differently based on
their genetic makeup. As diet is one of the most important modifiable risk factors for cardiovascular
disease (CVD), nutrigenomics represents a very promising approach for the prevention of CVD,
potentially enabling better outcomes through optimisation of individuals’ diets. The aim of this project
is to investigate this two-way relationship between food and genes: can the food we eat affect the way
our genes are expressed, and can our genes influence how our bodies respond to food? More
specifically, this work will focus on the nutrigenomic effects of certain natural compounds from fruits
and vegetables called polyphenols, which are believed to be cardioprotective. Specific objectives:
1) To analyse gene expression profiles of individuals participating in nutritional intervention
studies with CVD outcomes to elucidate genes and cell signalling pathways affected by
polyphenol consumption, and whether intervention decreases CVD risk (Year 1)
2) To analyse genetic polymorphisms associated with CVD to understand whether they mediate
differential gene expression in response to polyphenol intake (Year 2)
3) To merge other omics and clinical data obtained from the same studies to investigate how
transcriptomics correlate with, for example, metabolomics and metagenomics (Year 3)
The student has opportunity to tailor above project according to their areas of interest, e.g., genomics,
bioinformatics and big data management.
One representative publication from each co-supervisor:
Rodriguez-Mateos A, Rendeiro C, Bergillos-Meca T, Tabatabaee S, George TW, Heiss C, Spencer
JP. Intake and time dependence of blueberry flavonoid-induced improvements in vascular function:
a randomized, controlled, double-blind, crossover intervention study with mechanistic insights into
biological activity.Am J Clin Nutr. 2013 Nov;98(5):1179-91.
Prickett A, Ishida M, Böhm S, Frost JM, Puszyk W, Abu-Amero S, Stanier P, Moore GE, Oakey RJ,
and Schulz R. Genome-wide methylation analysis in Silver-Russell syndrome patients. Human
Genetics. 2015;134(3):317-332. doi:10.1007/s00439-014-1526-1.
61 | 6 9
42.1 Modeling diabetes using induced Pluripotent Stem Cells (iPSCs): investigating the
regulation of Ngn3 in iPSCs to beta cell differentiation.
Co-supervisor 1: Rocio Sancho
Research Division or CAG: School of Basic & Medical Biosciences / King’s Centre for Stem Cells
and Regenerative Medicine
E-mail: rocio.sancho@kcl.ac.uk
Website: https://www.kcl.ac.uk/lsm/research/divisions/gmm/departments/stemcells/people/Dr-
Rocio-Sancho.aspx
Co-supervisor 2: Ivo Lieberam
Research Division or CAG: School of Basic & Medical Biosciences / King’s Centre for Stem Cells
and Regenerative Medicine
Email: ivo.lieberam@kcl.ac.uk
Website: https://www.kcl.ac.uk/lsm/research/divisions/gmm/departments/stemcells/people/Dr-
Ivo-Lieberam.aspx
Project Description:
Diabetes is caused by the irreversible loss of insulin-producing beta cells in the pancreas. Insulin
injections is used in patients to control glucose levels however the risk of complications is high. In the
last decade, stem cell research has shed new light on novel therapies for diabetes. Efficient protocols
have been described to induce differentiation of skin-derived induced pluripotent stem cell (iPSCs)
into insulin-producing beta like cells. However, the process is still inefficient and the beta cells
generated as often not fully functional. One of the key embryonic transcription factors crucial to
initiate a beta cell fate program in iPSCs is Neurogenin3 (Ngn3). Ngn3 is a very unstable protein and
its molecular regulation during iPSCs to Beta-like cell differentiation has never been explored.
The goal of the proposed PhD project is to understand how the pro-endocrine factor Ngn3 is regulated during
iPSCs to beta cell differentiation, to enable us to optimise the regulating pathways to improve the efficiency
of beta cell generation and achieve fully functional beta cells.
• During the rotation project the PhD student will set up pilot screens for novel regulators and
interactors of Ngn3 in human iPSCs. 0+4 students will also familiarise with all the techniques
required for screen validation by characterising a protein already identified as a regulator of
Ngn3.
• The goal of year 1/2 is to perform Crispr/Cas9 screening for Ngn3 -regulators using flow
cytometry, and identify Ngn3 interacting proteins using immunoprecipitation and mass
spectrometry using human iPSCs (from HiPSCi).
• In year 2/3 biochemical and functional validation of the top 3 screen hits will be performed.
• In the final year functional (insulin release, calcium measuring, in vivo mouse kidney
transplantation, ex vivo engraftment on decellularised pancreas, alginate encapsulation-
transplantation) will be performed in collaboration with Dr. Aileen King and Professor Peter
Jones to assess the physiological function of the newly generated beta cells.
During this project, the PhD student will acquire exceptional technical skills in the CSCRM
(Bioinformatics, iPSCs culturing and differentiation, fluorescence microscopy, flow cytometry,
molecular Biology, gene editing – Crispr/Cas9 and In vivo models of diabetes). In addition, the
62 | 6 9
student will be immersed in all the activities organized by the CSCRM at KCL, and will benefit from
the iPSCs expertise in CSCRM.
One representative publication from each co-supervisor:
Sancho R, Gruber R, Gu G, Behrens A. Loss of Fbw7 reprograms adult pancreatic ductal cells into
α, δ, and β cells. Cell Stem Cell. 2014 Aug 7;15(2):139-53.
Bryson JB, Machado CB, Crossley M, Stevenson D, Bros-Facer V, Burrone J, Greensmith L,
Lieberam I. Optical control of muscle function by transplantation of stem cell-derived motor
neurons in mice. Science. 2014 Apr 4;344(6179):94-7.
63 | 6 9
43.1 Role of fat tissue gene expression in Type 2 Diabetes and Obesity
Co-supervisor 1: Kerrin Small
Research Division or CAG: Lifecourse Science
E-mail: Kerrin.small@kcl.ac.uk
Website:
http://www.kcl.ac.uk/lsm/research/divisions/gmm/departments/twin/research/small/index.aspx
Twitter: @kerrin_small
Co-supervisor 2: Alan Hodgkinson
Research Division or CAG: Basic and Medical Biosciences
Email: alan.hodgkinson@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/alan.hodgkinson.html Twitter: @alanjhodgkinson
Project Description:
Type 2 Diabetes and obesity-related traits are global epidemics. In the UK alone, ~4 million people
are living with diabetes and 10% of the NHS budget is spent on diabetes. Understanding the
molecular mechanisms underlying genetic risk of diabetes will help direct novel treatments and
prevention. We have previously shown that gene expression in adipose (fat) tissue mediates a subset
of Type 2 Diabetes associated GWAS loci, including a master trans-regulator at the KLF14 locus
which regulates 400 genes. This project will seek to identify novel regulatory variants that influence
gene expression and use them to interpret disease associations, with a particular focus on Type 2
Diabetes and obesity-related traits. In particular this project will focus on two under-explored classes
of regulatory variants, rare variants and trans-eQTLs. The student will utilize a unique multi-tissue
RNAseq data set from deeply-phenotyped twins from the TwinsUK cohort, and integrate this newly
generated matched whole genome sequence data. The student will be taught how to analyze high-
throughput sequencing data to answer important biological questions. More broadly the student will
undergo training in genomic analysis, bioinformatics (including programming) and scientific writing.
Objectives:
Year 1: Identify regulatory variants (eQTLs, rare variants and splicing) utilizing RNAseq data from
multiple tissues and matched whole genome sequence.
Year 2: Identify trans-eQTLs in adipose tissue in a large multi-centre dataset.
Year 3: Integrate identified regulatory variants with Type 2 Diabetes and obesity-related traits to
elucidate underlying regulatory mechanisms mediating disease risk and response.
One representative publication from each co-supervisor:
Glastonbury C, Vinuela A, Buil A, Halldorsson, G, Thorleifsson, G, Helgason. H, Thorsteinsdottir
U, Stefansson K, Dermitzakis ET, Spector TD, Small KS Adiposity-dependent regulatory effects on
multi-tissue transcriptomes. Am J Hum Genet. 2016 Sept 1;99(5):567-79. doi:
10.1016/j.ajhg.2016.07.001
Hodgkinson, A., Idaghdour, Y., Gbeha, E., Grenier, J.C., Hip-Ki, E., Bruat, V., Goulet, J.P., de
Malliard, T. and Awadalla, P. 2014. High-Resolution Genomic Analysis of Human Mitochondrial
RNA Sequence Variation. Science 344: 413-415.
64 | 6 9
44.1 Structural and functional determinants of kinesin-1-dependent cellular transport
in neurodegeneration and aging
Co-supervisor 1: Roberto A Steiner
Research Division or CAG: Randall Division
E-mail: roberto.steiner@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/roberto.steiner.html
Co-supervisor 2: Alessio Vagnoni
Research Division or CAG: IoPPN - Basic and Clinical Neuroscience
Email: alessio.vagnoni@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/alessio.vagnoni.html
Twitter: @alessio_vagnoni
Project Description:
Misregulation or disruption of these cellular transport processes can contribute to many human
diseases ranging from neurodegenerative conditions such as Alzheimer's disease to cancer and even
contribute to viral infections by HIV-1 or bacterial
1 infections. Molecular motor proteins are used for the
cellular transport of cargoes. Kinesin-1 is a tetrameric
motor that moves its cargos unidirectionally along
microtubules in an ATP-dependent manner. How
specific molecules are recognised as cargos is a very
important question and we have recently made a
critical step towards the structural elucidation of the
mechanism for cargo recognition by kinesin-1 (1). We
are now looking for a highly motivated graduate with
an interest in structural biology to study other exciting
aspects of this critically important transport system. In
particular, we will focus on the protein complex
between kinesin-1, JIP1, and JIP3 for which we have
exciting preliminary data. The student will gain
experience in molecular biology as well as in the
overexpression and purification techniques for macromolecular complexes. The student will also
develop a strong foundation in advanced structural biology techniques (for example X-ray
crystallography, cryo-EM, SAXS), complementary biophysical methods (ITC, fluorescence
polarization), and cellular/functional assays. The project will develop in Year1 with the molecular
biology/biochemistry component while carrying out already some structural biology/biophysical
experiments. In the following years emphasis will be given to the structural biology/functional
components of the work. Functional studies will be carried out taking advantage of a novel in vivo
assay (2) to study the biology of ageing Drosophila neurons.
One representative publication from each co-supervisor:
Pernigo et al. (2013) Structural basis for kinesin-1:cargo recognition. Science, 340, 356-359.
(Vagnoni et al. (2016) A simple method for imaging axonal transport in aging neurons using the adult
Drosophila wing. Nat. Protoc. 11, 1711-1723.
65 | 6 9
45.1 Investigating human regulatory T cell subsets in autoimmunity and
transplantation
Co-Supervisor 1A: Dr Timothy Tree
Research School/Division or CAG: School of Immunology & Microbial Sciences, Division of
Immunology, Infection & Inflammatory Disease
E-mail: timothy.tree@kcl.ac.uk
Website:
http://www.kcl.ac.uk/lsm/research/divisions/diiid/departments/immunobiology/research/Tree/in
dex.aspx
Co-Supervisor 1B: Professor Sir Robert Lechler
Research School/Division or CAG: Immunoregulation & Immune Intervention, MRC Centre for
Transplantation
Email: Robert.lechler@kcl.ac.uk
Website:
https://www.kcl.ac.uk/lsm/research/divisions/timb/about/people/profiles/robertlechler.aspx
Collaborating Clinician: Dr Pratik Chowdry
Research School/Division or CAG: School of Life Course Sciences, Division of Diabetes &
Nutritional Sciences.
Email: pratik.choudhary@kcl.ac.uk
Website:
https://www.kcl.ac.uk/lsm/research/divisions/dns/about/people/Profiles/pratikchoudhary.aspx
Project Description
Regulatory T cells (Tregs) form a key part of immune regulation. A reduction in Treg frequency or
function has been implicated in the pathogenesis of a variety of autoimmune diseases and transplant
rejection. Such observations have fuelled interest in developing therapies that invigorate Tregs for
use in these conditions, some of which are being tested at KCL. However, work from our and other
laboratories has revealed that Tregs are not a simple single homogenous group of cells but are in fact
a heterogeneous mixture of cellular sub-phenotypes with distinct developmental states, capacities
and targets of suppression. This project will use cutting edge technologies to investigate the
functional properties of different Treg subsets, defining their cellular and molecular characteristics.
Work will particularly focus on identifying Treg subsets capable of suppressing key immune effectors
known to play a key role in tissue destruction in type 1 diabetes (T1D) and transplant rejection. We
will then measure the frequency and stability of relevant Treg subsets in clinical samples from patients
with T1D, those undergoing organ transplantation and relevant controls.
This project will include comprehensive training in modern cellular and molecular immunology and
lead to the acquisition of a wide range of skills including cell culture, FACS and cell sorting,
recombinant DNA technology and the performance of a wide range of analysis of immune cell
function.
66 | 6 9
Yearly objectives:
Y1 Isolation and basic functional assessment of Treg subsets
Y2 Detailed cellular and molecular characterization of key Treg subsets
Y3 Investigate Treg sub-populations in patient cohorts
One representative publication from each co-supervisor:
Hull, C. M., M. Peakman and T. I. M. Tree (2017). "Regulatory T cell dysfunction in type 1
diabetes: what's broken and how can we fix it?" Diabetologia. 60 (10): 1839-1850
Mason, G. M., K. Lowe, R. Melchiotti, R. Ellis, E. de Rinaldis, M. Peakman, S. Heck, G.
Lombardi and T. I. Tree (2015). "Phenotypic Complexity of the Human Regulatory T Cell
Compartment Revealed by Mass Cytometry." J Immunol 195(5): 2030-2037.
67 | 6 9
46.1 Dissecting the heterogeneity of tumour-infiltrating phagocytes: implications for
tissue remodelling and immunotherapy.
Co-supervisor 1: Pierre Guermonprez
Research Division or CAG: School of Immunology and Microbial Sciences
E-mail: pierre.guermonprez@kcl.ac.uk
Website:
http://www.kcl.ac.uk/lsm/research/divisions/diiid/departments/immunobiology/research/guermo
nprez/index.aspx
Co-supervisor 2: Tanya Shaw
Research Division or CAG: School of Immunology and Microbial Sciences
Email: tanya.shaw@kcl.ac.uk
Website:
https://www.kcl.ac.uk/lsm/research/divisions/diiid/centres/cibci/research/shaw/DrTanyaShaw.as
px
Project Description:
BACKGROUND:
Tumour-infiltrating phagocytes (TIPs) are important components of the tumour microenvironment.
TIPs release a variety of immuno-suppressive factors, thus dampening the adaptive immune response
of Th1 and CD8+ cytotoxic lymphocytes to tumours.
Most TIPs derive from infiltrating monocytes and accumulate either inside or at the invasive margin
of tumours, and participate in tissue remodelling by multiple mechanisms.
Tumours secrete factors actively instructing monocyte recruitment and differentiation into TIPs. For
example, oncogenic variants of Kras driving lung cancer induce GMCSF secretion that promotes
recruitment and differentiation. However, how tumour-derived factors shape TIP phenotype and pro-
tumorigenic function remains ill-defined.
AIMS:
Overall, this project intends to characterize TIP diversity and function in relation with tumour-
derived instructive factors. This investigation will be performed in the context of lung
adenocarcinoma. Using a combination of mouse models of inducible oncogenes as well as transplanted
human tumour lines in immune-deficient mice, we aim to:
1- define and characterize the heterogeneity of TIPs in relationship with tumour-derived
hematopoietic growth factors using unbiased high dimensional flow cytometry and single cell
transcriptome analysis.
2- decipher the molecular mechanisms by which diverse TIPs influence tissue remodelling and
neoplastic growth.
3- design and evaluate TIP reprogramming immunotherapeutic interventions for efficient re-
purposing of TIPs into anti-tumoural effectors (e.g. by blocking tumour-derived factors influencing
TIP recruitment or activation).
The student will be trained in the area of cancer immunology, will use in vitro and in vivo models,
and will learn the techniques associated with transcriptional profiling and bioinformatics, flow
cytometry, and histology and microscopy.
68 | 6 9
One representative publication from each co-supervisor:
The Heterogeneity of Ly6Chi Monocytes Controls Their Differentiation into iNOS+ Macrophages
or Monocyte-Derived Dendritic Cells. Menezes S, Melandri D, Anselmi G, Perchet T, Loschko J,
Dubrot J, Patel R, Gautier EL, Hugues S, Longhi MP, Henry JY, Quezada SA, Lauvau G, Lennon
Duménil AM, Gutiérrez-Martínez E, Bessis A, Gomez-Perdiguero E, Jacome-Galarza CE, Garner
H, Geissmann F, Golub R, Nussenzweig MC, Guermonprez P. Immunity. 2016 Dec
20;45(6):1205-1218.
Acute knockdown of inflammation-induced osteopontin leads to rapid repair and reduced scarring
at the wound site. R Mori, TJ Shaw, P Martin. Journal of Experimental Medicine 2008, 205(1):43-
51.
69 | 6 9
47.1 Therapeutic target discovery in severe inflammatory skin disease
Co-supervisor 1: Michael Simpson
Research Division or CAG: School of Basic & Translational Sciences
E-mail: Michael.simpson@kcl.ac.uk
Website: https://kclpure.kcl.ac.uk/portal/en/persons/michael-simpson(e8b68dcb-3f9f-4a97-9dcd-
0a81e8f4ee23).html
Co-supervisor 2: Catherine Smith
Research Division or CAG: School of Basic & Translational Sciences
Email: catherine.smith@kcl.ac.uk
Website:
https://www.kcl.ac.uk/lsm/research/divisions/gmm/departments/dermatology/Research/stru/abo
ut/people/smith-catherine.aspx
Project Description:
Human genetics is a valuable tool to prioritise molecular targets for therapeutic drug development.
This project aims to utilise large-scale genomics data across many thousands of individuals (already
collected) to both characterise the genetic contributants to inflammatory skin diseases and identify
molecular targets for therapeutic intervention.
Our group has been at the forefront of research seeking to identify genomic loci contributing to the
genetic basis of psoriasis and acne, including recent large-scale genome-wide investigations. We are
currently in the process generating genomewide genotyping data on in excess of 6,500 individuals
with severe acne and 10,000 individuals with psoriasis. The proposed project will utilize these data to
identify further risk loci and fine mapping of these signals. The project will employ cutting edge
analytical approaches aimed at integrating these data with large publicly available genomic data and
transcriptomic experiments relating to skin biology. The approach will identify putative therapeutic
targets whose activity is disrupted by genetic variation that predisposes these common inflammatory
disorders, highlighting critical points in the disease-causing pathway can be evaluated for therapeutic
manipulation.
The supervisors will provide a world-class training in contemporary genome science, statistics,
bioinformatics and provide the opportunity for interaction with research groups in academia and
industry. The work will be undertaken in a multidisciplinary environment supported by core facilities
and underpinned by a longstanding collaboration between geneticists and dermatologists.
One representative publication from each co-supervisor:
Genome-wide association study identifies three novel susceptibility loci for severe Acne vulgaris.
Navarini AA, Simpson MA, Weale M, Knight J, Carlavan I, Reiniche P, Burden DA, Layton A,
Bataille V, Allen M, Pleass R, Pink A, Creamer D, English J, Munn S, Walton S; Acne Genetic
Study Group, Willis C, Déret S, Voegel JJ, Spector T, Smith CH, Trembath RC, Barker JN. Nat
Commun. 2014 13;5:4020
Mutations in IL36RN/IL1F5 are associated with the severe episodic inflammatory skin disease
known as generalized pustular psoriasis. Onoufriadis A1, Simpson MA, Pink AE, Di Meglio P,
Smith CH, Pullabhatla V, Knight J, Spain SL, Nestle FO, Burden AD, Capon F, Trembath RC,
Barker JN. Am J Hum Genet. 2011 9;89(3):432-7
70 | 6 9
48.1 Improving skeletal muscle function in the muscle wasting disease FSHD
Co-supervisor 1: Professor Peter Steven Zammit
Research Division or CAG: Randall Division of Cell and Molecular Biophysics
E-mail: peter.zammit@kcl.ac.uk
Website:
http://www.kcl.ac.uk/lsm/research/divisions/randall/research/sections/signalling/zammit/index.as
px
Co-supervisor 2: Professor Malcolm P.O. Logan
Research Division or CAG: Randall Division of Cell and Molecular Biophysics
Email: Malcolm.logan@kcl.ac.uk
Website:
http://www.kcl.ac.uk/lsm/research/divisions/randall/research/sections/signalling/logan/index.asp
x
Project Description:
Facioscapulohumeral muscular dystrophy (FSHD) is characterised by muscle weakness, where
muscle wastes and connective tissue becomes deregulated, so scar tissue forms. FSHD is caused by
ectopic expression of a transcription factor called DUX4. FSHD muscle cells are sensitive to oxidative
stress, and treatment of FSHD patients with anti-oxidants vitamin E, vitamin C, zinc, and
selenomethionine improves some muscle function measurements (clinicaltrials.gov:NCT01596803)
(doi:10.1016/j.freeradbiomed.2014.09.014). Analysis of our FSHD gene expression (RNA-Seq) data
has also implicated mediators of oxidative stress and mitochondrial generation, indicating activation
of mitochondrial biogenesis as a therapeutic strategy. We have good preliminary data that several
nutritional supplements target this pathway, improving muscle formation.
Hypothesis
Improving protection against oxidative stress and enhancing mitochondrial biogenesis will improve
muscle function in FSHD.
Objectives
Year 1: Screen nutritional supplements that can affect mitochondrial biosynthesis/protect against
oxidative stress on FSHD myoblasts/fibroblasts. Characterise connective tissue perturbation by
analysing gene expression data from FSHD muscle biopsies.
Year 2: Test selected nutritional supplements on a range of FSHD patient cells lines.
Year 3: Measure effects of nutritional supplements on muscle and connective tissue expressing DUX4
both in vitro and in animal models.
Year 4: Investigate interaction of nutritional supplements with known/novel signalling pathways to
identify mechanism.
Skills training
Molecular Biology (e.g. cloning), Cell Biology (mouse/human cell culture, retroviral-transduction,
siRNA-mediated gene-knockdown), Animal Models, Gene Expression/Protein Analysis (RT-qPCR,
Western blotting, immunolabeling), Imaging/Time-Lapse using state-of-the-art
confocal/multiphoton microscopy and Bioinformatics.
Expertise
Zammit: muscle stem cell function in health and disease.
Logan: muscle associated connective tissue and its disease associations.
71 | 6 9
One representative publication from each co-supervisor:
Moyle L.A., Blanc E., Jaka O., Prueller J., Banerji C.R.S, Tedesco F.S., Harridge S.D.R., Knight,
R.D. and Zammit P.S. (2016). Ret function in muscle stem cells points to tyrosine kinase inhibitor
therapy for facioscapulohumeral muscular dystrophy. eLIFE 5:e11405. (doi: 10.7554/eLife.11405).
Tbx4 and Tbx5 acting in connective tissue are required for limb muscle and tendon patterning. Hasson, P;
DeLaurier, A; Bennett, M; Grigorieva, E; Naiche, LA; Papaioannou, VE; Mohun, TJ and Logan,
MPO (2010) Developmental Cell 18, 148-156
72 | 6 9
49.1 Tackling hearing loss: development, regeneration and reconstruction of the ear
Co-supervisor 1: Prof Abigail Tucker
Research Division or CAG: Craniofacial Development & Stem Cell Biology
E-mail: Abigail.tucker@kcl.ac.uk
Website:
http://www.kcl.ac.uk/dentistry/research/divisions/craniofac/ResearchGroups/TuckerLab/Tucker
Lab.aspx
Co-supervisor 2: Mr Dan Jiang
Research Division or CAG: Otolaryngology, Head & Neck Surgery, Guys and St Thomas’s Hospital
Honorary Prof: Craniofacial Development & Stem Cell Biology
Email: dan.jiang@kcl.ac.uk
Website: http://www.guysandstthomas.nhs.uk/our-services/consultant-profiles/audiology/dan-
jiang.aspx
Project Description:
Birth defects associated with the middle and external ear lead to conductive hearing loss where sound
fails to pass to the inner ear. Our knowledge of how these birth defects arise is limited, hampering our
ability to correct defects. We aim to study the development of the ear taking advantage of mouse
mutants with aberrant ear development and data from patients attending the Ear Clinic at St Thomas’
Hospital. The project is a collaboration between an expert in ear development in mice (Prof Tucker)
and a clinician specialising in ear surgery (Prof Jiang). Overall we aim to understand how the ear
forms and integrates so that ear defects can be more successfully repaired and the ear reconstructed
during surgery.
Aim 1 (year 1): To investigate the normal process of external ear formation during mouse embryonic
development.
Aim 2 (year 1 & 2): To understand the mechanisms behind ear defects using mouse models of human
syndromes associated with external ear defects. These will include 22q11.2 deletion syndrome (Tbx1
mice), Branchio-oto-renal syndrome (Eya1 mice), LADD syndrome (Fgf10 mice), and
holoprosencephaly (Gas1 mice).
Aim 3 (year 2 & 3): To analyse CT scans from patients with ear defects to correlate the findings from
the mouse with humans, and to assess the success of reconstructive surgery.
Skills training: The student will be trained in a range of molecular biology techniques, anatomy and
regenerative biology, while having access to clinical data. In addition critical thinking, presentation
and writing skills will be taught.
One representative publication from each co-supervisor:
Thompson, H. Tucker , A.S. (2013). Dual origin of the epithelium of the middle ear. Science 339,
1453-1456.
Eze N, Jiang D, O'Connor AF. (2014) The atretic plate – a conduit for drill vibration to the inner
ear. Acta Otolaryngol. 134(1):14-8.
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