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EECS 730Introduction to Bioinformatics
Introduction to Proteomics
Luke HuanElectrical Engineering and Computer Science
http://people.eecs.ku.edu/~jhuan/
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Proteome: Protein complement of a genome
Time- and cell- specific protein complement of the genome.
Encompasses all proteins expressed in a cell at one time, including isoforms and post-translational modifications.
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Proteome Contrast to genome
The genome is constant for one cell and identical for all cells of an organism, and does not change very much within a species
The proteome is very dynamic with time and in response to external factors, and differs substantially between cell types.
Variable In different cell and tissue types in same organism In different growth and developmental stages of organism
Dynamic Depends on response of genome to environmental factors
Disease state Drug challenge Growth conditions Stress
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Introduction to proteomics
Proteomics is the study of total protein complements, proteomes, e.g. from a given tissue or cell type. Don’t forget that the proteome is dynamic, changing to reflect the
environment that the cell is in Definitions
Classical - restricted to large scale analysis of gene products involving only proteins
Inclusive - combination of protein studies with analyses that have genetic components such as mRNA, genomics, and yeast two-hybrid
Examples of important proteomic questions:1) What proteins are present?2) What other proteins does a particular protein interact with (networks)?3) What does a particular protein look like (structure)?
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Genomics vs. proteomics
Genomics has provided spectacular amounts of data, but most of it remains uninterpretable at our current level of understanding.
In some ways, genomics raises more questions than it answers.
The emerging field of proteomics promises to answer some of those questions by systematically studying all of the proteins encoded by the genome.
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1 gene is no longer equal to one protein In fact, the definition of a gene is debatable. (ORF, promoter,
pseudogene, gene product, etc) 1 gene = how many proteins?
There are only 30,000 genes in the human genome, yet there are more than 100,000 proteins in the human proteome.
Actually, cataloguing the human proteome requires much more than just 100K proteins.
30,000 genes x myriad of modifications >> 100K protein forms! Modifications include: alternate RNA splicing, chemical modifications,
cleavage Chemical modifications include: phosphorylation, acetylation,
glycosylation, and many more.
1 gene = 1 protein?
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Why proteomics?
Annotation of genomes, i.e. functional annotation Genome + proteome = annotation
Protein Function Protein Post-Translational Modification Protein Localization and Compartmentalization Protein-Protein Interactions Protein Expression Studies
Differential gene expression is not the answer
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Microarray data doesn’t correlate perfectly with protein expression levels
Analysis of mRNA transcripts with microarray has provided dynamic information regarding which genes are expressed in cells under a given set of experimental conditions, yielding clues as to which proteins are involved in certain pathways and disease states.
However, differences in the half-lives of RNA and proteins, as well as post-translational modifications important to protein function prevent mRNA profiles from being perfectly correlated to the cells’ actual protein profiles.
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Introduction to proteomics
Composition of the proteome depends on cell type, developmental phase and conditions
Proteome analyses are still struggling to solve the ”basic proteome” of different cells and tissues or limited changes under changing conditions or during processes
Current methods can only ”see” the most abundant proteins
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Types of proteomics
Protein Expression Quantitative study of protein expression between samples
that differ by some variable
Structural Proteomics Goal is to map out the 3-D structure of proteins and protein
complexes
Functional Proteomics To study protein-protein interaction, 3-D structures, cellular
localization and PTMS in order to understand the physiological function of the whole set of proteome.
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Large-scale protein analysis
2D protein gels Yeast two-hybrid Rosetta Stone approach Pathways
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2D protein electrophoresis and mass spectrometry
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Two-dimensional protein gels
First dimension: isoelectric focusing
Electrophorese ampholytes to establisha pH gradient
Can use a pre-made strip
Proteins migrate to their isoelectric point(pI) then stop (net charge is zero)
Range of pI typically 4-9 (5-8 most common)
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Two-dimensional protein gels
Second dimension: SDS-PAGE
Electrophorese proteins through an acrylamidematrix
Proteins are charged and migrate through an electric field v = Eq / d6r
Conditions are denaturing
Can resolve hundreds to thousands of proteins
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Proteins identified on 2D gels (IEF/SDS-PAGE)
Protein mass analysis by MALDI-TOF
-- done at core facilities-- often detect posttranslational modifications-- matrix assisted laser desorption/ionization time-of-flight spectroscopy
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Evaluation of 2D gels (IEF/SDS-PAGE)
Advantages:Visualize hundreds to thousands of proteinsImproved identification of protein spots
Disadvantages:Limited number of samples can be processedMostly abundant proteins visualizedTechnically difficultLabor-intensive, not really ”high-throughput” methods
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Yeast-Two-hybrid (Y2H)
Aim: Identify pairs of physical interactions among
proteins.
Solution: Use the transcription mechanism of the cell
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Yeast-two-hybrid: Principles
Recap of biology: Protein vs. domain
A protein is composed of modules or domains
Domains are individually folded units within the same protein chain.
The presence of multiple domains in a protein allow the protein to perform different functions.
The central dogma of biology
d1d2 d3p1
d4d5p2
TRANSCRIPTION
DNA
RNA
TRANSLATION
PROTEIN
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Yeast-two-hybrid: Principles
Normal transcription requires both the DNA-binding domain (BD) and the activation domain (AD) of a transcriptional activator (TA).
Transcriptional activator (TA) Protein that is required to activate transcription A DNA-binding domain (BD): binding to DNA, An activation domain (AD): activating transcription of the DNA
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Yeast-two-hybrid: Principles
The binding domain and the activation domain do not necessarily have to be on the same protein.
In fact, a protein with a DNA binding domain can activate transcription when simply bound to another protein containing an activation domain
this principle forms the basis for the yeast two-hybrid technique
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Major components of a Yeast-two-hybrid experiment: Bait protein – the protein of interest (X): with a DNA binding
domain attached to its N-terminus
Prey protein – its potential binding partner (Y): fused to an activation domain
A reporter gene (R): a gene whose protein product can be easily detected and measured
Yeast-two-hybrid: Principles
Protein X interacts with protein Y
X and Y form a functional transcriptional activator
the reporter gene is transcribed
Use the reporter produced as a measure of interaction between X and Y
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Yeast two-hybrid transcription
The yeast two-hybrid technique measures protein-protein interactions by measuring transcription of a reporter gene. If protein X and protein Y interact, then their DNA-binding domain and activation domain will combine to form a functional transcriptional activator (TA). The TA will then proceed to transcribe the reporter gene that is paired with its promoter.
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Yeast two-hybrid screens Screen a library of proteins for
potential binding partner Identifying interacting proteins in a
pairwise fashion Feasible at a large scale (genome
scale)X Y
Z
A
bait prey
Reporter Gene
BaitProtein
BindingDomain
Prey Protein
ActivationDomain
Bait-prey model
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http://depts.washington.edu/sfields/
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red = cellular role & subcellular localization of interacting proteins are identical; blue = localiations are identical; green = cellular roles are identical
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Y2H Identify proteins that are physically associated in vivo. Use yeast S. cerevisiae as a host
Disadvantage The fused proteins must be able to fold correctly and exist as a
stable protein inside the yeast cells Advantage
Yeast is closer to higher eukaryotics than in vitro experiments or those systems based on bacterial hosts
Weak and transient interactions Often the most interesting in signaling cascades Are more readily detected in two-hybrid since the reporter gene
strategy results in a significant amplification. Always a trade-off between the identification of weak
interactions and the number of false positives
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<4%
Low overlap among independent experiments
482 2422855
Uetz et al.
1337
Ito et al.
3277
proteins
<23%
1244 4274201
Uetz et al.
1445
Ito et al.
4475
interactions
High false positives and false negatives in yeast-two hybrid data
Two sets of independent experiments Ito et al PNAS 1999 Uetz et al Nature 2000
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False positives
Proteins with transcription activation activity (bait works by itself)
Proteins that normally never see each other (e.g. due to the time/space constraints) are expressed together and may be sticky
Proteins are expressed at high levels and this promotes promiscuous interaction
Another protein bridges the two interacting partners
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False negatives
Proteins become toxic upon expression in yeast Proteins are toxic when expressed and targeted into the
yeast nucleus. Proteins proteolyse essential yeast proteins or proteins
essential for the system like the DNA binding domain or the activation domain.
Proteins don’t get into the nucleus (membrane protein esp.)
Proteins are not modified correctly in heterologous environment
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Final Remark on Y2H
Although the outcome of a screening often results in many new hypotheses, they still need to be validated by other techniques.
There is enough reason to remain sceptic about two-hybrid screenings but the most convincing argument in favor of the two-hybrid is the number and speed
Referred to as functional screens Interacting proteins might give a functional hint if at least
one of the partners has a known functional commitment in a well understood signaling pathway.
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Analysis of protein complexes
Aim: Identification of complexes and their sub units.
Solution: a two step method Isolation of only relevant complexes Identification of complex units.
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Affinity chromatography/mass spec
Major methods High throughput mass spectrometric protein
complex identification (HMSPCI) Tandem affinity purification (TAP)
Again, bait – prey model Very sensitive method Identify multi-protein complexes
Not really possible in yeast two-hybrid
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Methods
1. Attach tags to bait proteins Introduce DNA encoding
these into cells Cells express modified
proteins Proteins form complexes
with other proteins in vivo Cells have to express
modified protein properly Tag can interfere with
protein folding and function Overexpressed protein
may be toxic to cell
1
2
3
4 5
6-9
Kumar and Snyder, 2002
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Methods2. Bait proteins and associated
proteins are precipitated on an affinity column
• Tag sticks to column along with protein complex
• Elute other proteins
• Elute tagged protein
3. Resolve proteins on an SDS-PAGE gel
• Separate by charge & weight
4. Cut out protein bands
• Proteins of same size will be in same band
5. Digest protein bands with trypsin Results in segments of proteins
1
2
3
4 5
6-9
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Methods
Mass spectrometry to analyze protein composition:
6. Samples are vaporized and ionized7. Ions enter mass analyzer and are separated by mass to charge
ratio 8. Ions are detected and a signal generated9. Compare signal to database to identify proteins in complex
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Methods
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Affinity chromatography/mass spec
Data on complexes deposited in databases
http://yeast.cellzome.comhttp://www.bind.ca
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Affinity chromatography/mass spec
False positives:• sticky proteins
Bait proteinGST
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Affinity chromatography/mass spec
False negatives:• Bait must be properly localized and in its native condition• Affinity tag may interfere with function• Transient protein interactions may be missed• Highly specific physiological conditions may be required• Bias against hydrophobic, and small proteins
Bait proteinGST
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The Rosetta Stone approach
Marcotte et al. (1999) and other groups hypothesized that some pairs of interacting proteins are encoded by two genes in many genomes, but occasionally theyare fused into a single gene.
By scanning many genomes for examples of “fusedgenes,” several thousand protein-protein predictionshave been made.
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Yeast topoisomerase II
E. coligyrase B
E. coligyrase A
Fig. 8.23Page 256
The Rosetta Stone approach
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Function Prediction from Interaction
It is possible to deduct functions of a protein through the functions of its interaction partners.
A difficult task: Within-class, cross-class interactions
Available methods based on protein interaction Neighboring counting method Methods based on χ2-statistics Markov Random Fields Simulated annealing