defects in gene regulation can alter the development of an organism regulation of gene expression
TRANSCRIPT
Defects in gene regulation can alter the development of an organism
Regulation of Gene Expression
Seven processes that affect the steady-state concentration of a protein in a cell
Regulation of Gene Expression
• Principles of gene regulation
• Regulation of gene expression in prokaryotes
• Regulation of gene expression in eukaryotes
Principles of Gene Regulation
constitutive vs. regulated gene expression
housekeeping genes, gene products that are required at all times at a more or less constant level.e.g., in citric acid cycle
Principles of Gene Regulation
1) RNA polymerase binds to DNA at promoters
Principles of Gene Regulation (cont’d)
2) Transcription initiation is regulated by proteins that bind to or near promoters.
Repression of a repressible gene:(i.e., negative regulation) repressors (vs. activators) bind to operators of DNA.Repressor is regulated by an effector, usually a small molecule or a protein, that binds and causes a conformational change.Activator binds to DNA sites called enhancer to enhance the RNA polymerase activity. (i.e., positive regulation)Induction of an inducible gene, e.g., heat-shock genes.
Heat-shock promoters
Principles of Gene Regulation (cont’d)
3) Most prokaryotic genes are regulated in units called operons.
Francois Jacob & Jacques Monod, 1960
Lactose metabolism in E. coli
4) The lac operon is subject to negative regulation: repressor
tetramericrepressor
uninduced
IPTG induced
5) Regulatory proteins have discrete DNA-binding domains
Functional groups (pink) in DNA available for protein binding
5) Regulatory proteins have discrete DNA-binding domains
e.g., specific amino acid-base pair interactions in DNA-protein interaction
e.g., a DNA-binding domain (3) interacts directly with DNA at major groove
AATTGT…ACAATTTTAACA…TGTTAA
The DNA binding sites for regulatory proteins are often inverted repeats of a short DNA sequence (a palindrome) at which multiple subunits (usually two) of a regulatory protein bind cooperatively.
e.g., Lac repressor vs. operatorinverted repeats
Examples of DNA-binding motifs/domains:
• helix-turn-helix: e.g., Lac repressor• zinc finger: e.g., Zif 268• homeodomain: e.g., Ultrabithorax (Ubx)
Helix-turn-helix
DNA-binding domains
Lac repressor,a tetramer
allolactose-bindingdomains
hydrogen-bonding (red)hydrophobic interactions (yellow)
• zinc finger:
Zn2+
(2 Cys, 2 His)
~30 a.a.
In many eukaryotic (few prokaryotic) DNA-binding proteins
e.g., Zif 268
• homeodomain:
homeobox: DNA sequence encoding homeodomain
a helix (red) protruding into the major groove
e.g., Ultrabithorax (Ubx)
6) Regulatory proteins also have protein-protein interaction domains
Leucine zippers
• Leucine zippers• basic helix-loop-helix
interacting Leu (red)
basic helix-loop-helixe.g., transcription factor Max (dimeric)
DNA-binding segment (pink)
helix-loop-helix
(red & purple)
A pair of interacting Leu
Regulation of Gene Expression
• Principles of gene regulation
• Regulation of gene expression in prokaryotes
• Regulation of gene expression in eukaryotes
The Lac Operon
The lac Operon Is Subject to Positive Regulation:Activation by CRP (cAMP receptor protein)
CRP homodimer
cAMP (pink)
DNA is bended
Region interacting with RNA polymerase (yellow)
The effect of glucose on CRP is mediated by cAMP.Transcription occurs only at low glucose and high lactose.
cAMP & CRP are involved in the coordinated regulation of many operons. A net of operons with a common regulatoris called regulon.
The ara operonundergoes both positive & negative regulationby a single regulatory protein AraC.
Th end product of the arabinose metabolic pathway,D-xylulose 5-phosphate, is an intermediate in thepentose phosphate pathway.
When the AraC repressor is depleted, The araC gene is transcribed from its own promoter.
At high glucose and low arabinose, AraC binds andbrings araO2 and araI sites together to form aDNA loop, repressing araBAD.
At low glucose, but arabinose is present, AraC repressor binds arabinose and changes conformation to become an activator.DNA loop is opened, and AraC binds to each half-site of araI and araO1. The proteins interact with each other, and act in concert with CRP-cAMP to facilitate transcription of the araBAD genes.
Many Genes for Amino Acid Biosynthesis Are Regulated by Transcription Attenuatione.g., the trp operon
At high tryptophen, 1) the repressor binds its operator, 2) transcription of trp mRNA is attenuated.
Trp repressordimeric,helix-turn-helix
bound tryptophen (red)
The trp mRNA leader (trpL):Sequence 1 encodes a small peptide, leader peptide,containing two Trp residues.
Transcription attenuation in the trp operon
Transcription attenuation in the trp operonattenuator
At high trp
At low trp
The Trp Operon
Induction of the SOS Response in E. coli Requires Destruction of Repressor Protein LexA:
Coprotease RecA is activated by DNA damage (single stranded DNA)LexA is cleaved and inactivated by RecA
Operon-like regulation
mRNAs of some ribosomal proteins (r-protein):
r-protein acts as a translational repressor
Synthesis of Ribosomal Proteins Is Coordinated with rRNA Synthesis
yellow: RNA pol subunitsblue: EFs
Synthesis of Ribosomal Proteins Is Coordinated with rRNA Synthesis
e.g., stringent response in E. coli, response to amino acid starvation
uncharged tRNA binding > stingent factor (RelA) binding >catalysing ppGpp synthesis > binding to -subunit of pol >rRNA synthesis reduced
Some Genes Are Regulated by Genetic Recombination
e.g., regulation of flagellingenes in Salmonella: phase variation allows evasion of host immune response.
repressor
Regulation of Gene Expression
• Principles of gene regulation
• Regulation of gene expression in prokaryotes
• Regulation of gene expression in eukaryotes
Extraordinary complexity of gene regulation in eukaryotes
• Transcriptional Active Chromatin is Structurally Different from Inactive Chromatin: hypersensitive sites (100 ~ 200 bp), DNaseI sensitive sequences whithin the 1000 bp flanking the 5’ end of transcribed genes.• Modifications Increase the Accessibility of DNA: e.g., 5’-methylation of cytosine of CpG sequences is common in eukaryotic DNA, active genes tend to be undermethylated.• ……
Extraordinary complexity of gene regulation in eukaryotes
• Chromatin Is Remodeled by Acetylation and Nucleosome Displacements chromatin remodeling: the detailed mechanisms for transcription-associated structure changes in chromatin.
Extraordinary complexity of gene regulation in eukaryotes
• Many Eukaryotic Promoters Are Positively Regulated• DNA-Binding Transactivators and Coactivators Facilitate Assembly of the General Transcription Factors enhancer in higher eukaryotes, upstream activator sequences (UASs) in yeast.
Three Classes of Proteins Are Involved in Transcriptional Activation
basal transcription factors, DNA-binding transactivators, and coactivators.
A wide variety of repressors function by a range of mechanisms
The Genes Required for Galactose Metabolism in Yeast Are Subject to Both Positive and Negative Regulation
regulated 6 genes (table 28-3)regulatory proteins:Gal4p, Gal80p & Gal3p
Binding of galactose to Gal3p and its interaction with Gal80p produce a conformation change in Gal80p that allows Gal4p to function in transcription activation.
Unlike bacteria, there is no operons in yeast. Each of the GAL genes is transcribed separately.
The GAL system is shown to illustrate the transcription activation of a group of related eukaryotic genes.
The initiation complexes assemble stepwise:1) DNA-binding transactivators2) Basal transcription factors/pol II3) Additional protein complexes needed to remodel the chromatin
e.g., SWI/SNF: histone remodeling SAGA: histone acetylation
Typical DNA-binding transactivators have a DNA-binding domain and an activation domain.e.g., Gal4p, acidic activation domain function in activation CTF1(CCAAT-binding transcription factor 1), proline-rich activation domain Sp1, glutamine-rich activation domain
“Domain-swapping” experiment: A chimeric protein containing the DNA-binding domain of Sp1 and the activation domain of CTF1 activates transcriptionif a GC box is present.
Eukaryotic Gene Expression Can Be Regulated by Intercellular and Intracellular Signalse.g., steroid hormone (estrogen) receptors
Regulation Can Occur through Phosphorylation of Nuclear Transcription Factors
e.g., The catalytic subunit of protein kinase A, released when cAMP levels rise, enters the nucleus and phosphorylates a nuclear protein, the CRE-binding protein (CREB), >> binding to CREs near certain genes and acting as a transcription factor.
Many Eukaryotic mRNAs Are Subject to Translational Repression
e.g., translational repressors (RNA-binding proteins) interact with initiation factors or with the ribosome to prevent or slow translation
Development Is Controlled by Cascades of Regulatory Proteins
Maternal Genes
Christiane Nusslein-Volhard (p.1112)bicoid (bcd) gene product gradient
Two posteriors
Segmentation genese.g., ftz gene product (Ftz) Early embryo
Late embryo
Homeotic genes:
Antennapaedia (~ mouse HOX 1.1)
bithorax mutation
The discovry of structural determinants with identifiable molecular functionsis the first step in understanding the molecular events underlying development.