Regulation of Gene Expression PDF

Summary

This document provides an overview of the regulation of gene expression. It discusses various aspects of gene control, including different types of transcription factors and mechanisms of chromatin remodeling and modification. The document also covers important concepts such as DNA methylation, alternative splicing, translational control and protein degradation.

Full Transcript

Regulation
of Gene
Expression
Part 2
 Learning Outcomes
1.List the processes that are controlled by 8.Describe how chromatin structure can be
differential regulation of gene expression in modified by the chromatin remodeling
multicellular eukaryotes complex and how chromatin remodeling
2.Describe the structure of a transcription factor, affects gene expression
and be able to identify three major classes of
transcription factor DNA-binding domains 9.Describe how DNA methylation by DNA
methyltransferases regulate gene expression
3.Define combinatorial control of gene
expression and explain its role in regulation of gene
expression 10.Explain how alternative splicing can lead
to alternative mRNAs, and predict possible
4.Characterize and name the transcription factor splicing products from a eukaryotic gene
DNA binding sites based on their distance from
the transcription start site
11. Contrast global and specific translational
5.Describe the role of coactivators and control, and give describe examples of each
corepressors in mediating the effect of transcription
factors on gene expression, and list examples of 12. Describe the mechanisms of protein
each modification and selective degradation by
6.Explain the role of the mediator protein complex proteasome and explain how these processes
in regulating transcription regulate gene expression at the post-
7.Characterize the mechanism by which histone translational level.
acetyltransferases (HATs) and histone deacetylases
(HDACs) regulate gene expression 13. Predict at which level a gene is regulated
 Mechanism of Gene Regulation
in Prokaryotes and Eukaryotes

In prokaryotes the primary control point is the
process of transcription initiation
In eukaryotes expression of gene into proteins
can be controlled at various locations.

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Check Points for Gene Expression in Eukaryotes

o Synthesis of proteins is controlled
right from the chromatin stage.
o Expression of gene is controlled at
many steps during the process of
transcription and translation.
o Description of the control points is
dealt in detail in the subsequent
slides.

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 Zinc finger motif
TF III A, a positive regulator of 5S RNA gene transcription requires
Zinc for activity.
It contains nine Zinc ions in a repeating coordination complex
closely spaced to the cysteine-cysteine residues followed by 12-
13 amino acids and later by a histidine- histidine pair.
Zinc is coordinated by two cysteine and two histidine residues.
The protein containing zinc fingers lie on the face of DNA helix.
Zinc finger motif
Chromatin Structure
Two forms of chromatin
o Euchromatin – A lesser coiled transcriptionally active region
which can be easily accessed by the RNA polymerases.

o Heterochromatin – A highly condensed transcriptionally inactive
region. The genes in this region cannot be accessed by the RNA
polymerases for active transcription.

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 Chromatin Structure

Mechanisms which affect the chromatin structure and
hence the expression of gene are:

1. Histone modifications – These modifications make a
region of gene either transcriptionally active or
inactive.
a)Acetylation
↑Acetylation ----↓ Condensation of DNA ----- ↑ Transcription
of genes in that region

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