DMD5025/CHS5042 Regulation of Gene Expression PDF

Summary

This document provides an overview of gene expression regulation, including constitutive and regulated genes. It covers topics such as epigenetic regulation, chromatin modifications, genome imprinting, RNA processing, and its impact on gene expression, along with translational regulation, control, and different pathways required for tooth development.

Full Transcript

DMD5025/CHS5042
Regulation of Gene Expression
Q. Quinn Li, PhD
Office: DOC108
Office phone: 469-8523
[email protected]
Objectives
Define constitutive vs inducible gene expression patterns
Describe major steps of gene expression regulation
Define epigenetic regulation of gene expression
Describe chromatin modifications associated with hetero- and
euchromatin
Relate the importance of genome imprinting in genetics
Recognize major structural classes and functions of transcription factors
Relate the impact of RNA processing in gene expression
Describe mechanisms to regulate mRNA stability and rate of translation
including lncRNA and miRNA, and RNA binding proteins
Relate processes of gene regulation to cell signaling pathways required
for tooth development
Flow of genetic information -- CENTRAL DOGMA

MORPHOLOGY
DNA RNA PROTEIN PHYSIOLOGY
DEVELOPMENT
Non-coding RNA

DNA: deoxyribonucleic acid
RNA: ribonucleic acid
Messenger RNA - mRNA
Transfer RNA - tRNA
Ribosomal RNA - rRNA
Small non-coding RNA
Long non-coding RNA
 Gene Expression Regulation
Expression of almost all genes are regulated at different
levels, but in relative terms, there are differences.
Constitutively expressed genes:
Genes that are generally continuously expressed (housekeeping
genes), e.g. genes for ribosomal proteins
Regulated expressed genes:
Expression is controlled by the needs of the cell, e.g. responding
to the environment.
More dramatically up or down regulated than constitutive genes.
Example of controlled gene expression:
Comparison of synthesis of different globin chains at given stages of human development
 Multi level gene expression controls in eukaryotes

1

2 Nucleus
The Big Picture

Cytoplasm
3

5 4

6 Protein modifications
7
Not all steps applicable to
all genes/proteins
 Most Eukaryotic Genes are “Silenced”

Eukaryotic RNA polymerases have very low affinity for promoters
without help from DNA binding proteins

Usually several different proteins must bind before a gene is
activated

Positive regulation makes more sense in highly differentiated cell
systems (most genes are “off” unless needed); allows fine control
for huge genomes like ours
 Transcriptional control in Eukaryotes
The key is to control RNA polymerase activities: similar to prokaryote in
this sense

1. Accessibility to DNA: Epigenetics
Histone modifications
Chromatin remodeling
DNA methylation
2. Promoters, enhancers, and transcriptional factors
Trans-acting factors: protein transcriptional factors
Cis-elements: DNA sequences recognized by transcriptional factors and other
proteins
 Two Types of Chromatin
Heterochromatin is not transcribed
(silent)
DNA is hypermethylated at CpG
dinucleotides
Histones are deacetylated
Euchromatin is transcribed (active)
DNA is hypomethylated
Histones are acetylated
Chromatin relaxes, resulting in
hypersensitivity to DNase treatment
 What Is Epigenetics?

Epi: over or above;
Epigenetics: inheritance of variation above and beyond
differences in DNA sequences.

Epi-genetics: Phenotypes and and processes that are transmitted
through cell division and sometimes to future generations, but
are not the results of differences in DNA sequence.

Changes in chromatin structure, or DNA methylation
Changes in patterns of DNA methylation
Chemical modification of histone proteins
RNA molecules that affect chromatin structure and gene
expression
Epigenetic regulation:

Chromosome Changes
Histones are general repressors of transcription
Histone modifications:
Addition or removal of phosphate groups, methyl groups, or acetyl groups
etc.
Histone code, patterns of histone modification that may encode
information affecting how genes are expressed.
Chromatin remodeling: Some proteins alter chromatin structure
through protein interactions, without modifying histone proteins.
 Epigenetic Modifications Histone 3, #9
amino acid Lys

Activating Marks Silencing Marks
Histone methylation Histone methylation
H3: K4, K36, K79 H3: K27, K9
H4: K20
Histone acetylation Histone deacetylation
H3 and H4 H3 and H4
Most prominent

Histone phosphorylation
H3S10
Histone ubiquitylation Histone ubiquitylation
H2BK123 H2BK119
Unmethylated CpG Methylated CpG
Epigenetic regulation:

Histone modifications
Acetylation generally stimulates transcription

Acetyl group (CH3CO-) added

Histone acetyltransferases
(HATs)

Histone deacetylase

Closed form Open form
 DNA modification
DNA methylation: addition of methyl groups to nucleotide bases; mostly 5-
methylcytosine
Methylated DNA generally become transcriptionally inactive
Heterochromatin are normally highly methylated
Chromosome maintain certain patterns of methylation, particularly CpG
islands (C-p-G sequence).
 Parent DNA

Maintenance of DNA methylation
through replication

Methylated DNA may be transmitted to
next generations
Methyltranferase emzyme recognizes and Replicated DNA
makes the new strand methylated
May be de-methylated or de novo
methylated according to epigenetic
regulations

One daughter DNA
Methylcytosines attract “repressor” proteins
Co-repressors
MeC
Binding
Protein

Chromatin Modifiers

MBP: methyl binding protein
Trends in Biochem Sci 31:89-97, 2006.
TF: transcription factor
 Epigenetic Processes Produce a Diverse Set of Effects

Behavioral epigenetics: life experiences, especially early in life, have
long-lasting effects on behavior: stresses, food tastes
Epigenetic changes induced by maternal behavior: transgenerational
effects
Epigenetic effects by environment
Folate deficiency during development increases risk for neural tube
defects
Hyperhomocysteinuria increases risk for cardiovascular disease
Cigarette smoke causes global epigenetic changes in multiple tissues
hypomethylation of oncogenes
hypermethylation of tumor suppressor genes
 Genomic Imprinting
Gene Silencing as Dosage Compensation

Genome Imprinting: differential expression of
maternal and paternal genes in offspring
Mostly DNA methylation differences for purposes of dosage
compensation/gene silencing
Affects the expression of certain disease phenotypes
Examples:
Many embryogenesis related genes
X-chromosome inactivation
May be maintained by siRNA
 X Chromosome inactivation

PRC2: polycomb repressive complex 2
lncRNA: long non-coding RNA
Genomic Imprinting
Prader-Willi Syndrome vs
Angelman Syndrome
1st identified as deletion in region 15q11-13
That region contains genes that are differentially silenced in
male vs female gametes
 if mutant chromosome 15 is inherited from father, only
maternal genes from that region are expressed and vice versa
 only paternal genes expressed = Angelman (mutant maternal
chromosome 15)
 only maternal genes expressed = Prader-Willi (mutant
paternal chromosome 15)
Genomic Imprinting
Chromosome 15q11-13 has imprinted regions:
a hypothetical example

Maternal Paternal Maternal Paternal

1 1 1 1
Deleted in 2 2 2 2 Deleted in
Angelman’s 3 3 3 3 Prader Wili
4 4 4 4
5 5 5 5
Prader-Willi vs Angelman Syndrome

Prader-Willi Angelman
mental retardation mental retardation
obesity hypotonia
hypogonadism absence of speech
small hands & feet large mandible
itchy skin tongue thrusting
voracious appetite epilepsy

No gender differences
 Expression of only maternal
genes (mutant region of
paternal chromosome 15)
causes Prader-Willi

Expression of only paternal
genes (mutant region of
maternal chromosome 15)
causes Angelman Syndrome
Changes in DNA
methylation and chromatin
structure affect
development

E.g. In vitro cell culture
studies from induced
pluripotent stem cells
(iPSCs)
Q
u
e
s
t
i
o
n
s
 Transcriptional Initiation:
Two basic classes of genes
1. Constitutive: essential for cell survival
relatively “unregulated” gene expression
simple promoters
E.g.: genes that encode enzymes of glycolysis, the TCA cycle, and
respiratory chain and many structural proteins (actin, tubulin)

2. Inducible/repressible: highly regulated
respond to cell signals
complex promoters
E.g.: genes that encode hormone responsive proteins, inflammatory
proteins, etc.
Transcriptional control:

Typical Eukaryotic Promoters for Pol II
Upstream elements, bound by activators:
vary, or combination of common motifs;
control specificity and/or efficiency
Coordinating Transcription Regulation in Eukaryotes

Few operon structures (lower organisms).
Coordinately regulated genes usually are dispersed.
Cis-acting sequences (or cis-elements)
core promoter and promoter-proximal elements
enhancers
Silencers
Insolator: a DNA cis-element that blocks the action of a promoter
and/or enhancer.
Trans-acting control
numerous transcription factors
Some are DNA biding proteins
 Classes of Transcription Factors
Basal Factors: position RNA polymerase on the core promoter: TFIID,A,B,E,F & H
Activators: bind to enhancer elements; recruit chromatin modifiers and increase rate
of assembly of transcriptional machinery
Co-Activators or mediator: adapter molecules that connect activators (& repressors) to
basal factors
Repressors: bind to silencer elements; interfere with activators to slow transcription or
induce heterochromatin formation
Chromatin modifiers: HATs, HDACs, HMG proteins; promotes and stabilizes
euchromatin formation to allow core binding proteins access to promoter

Combination of a few different transcriptional factors may control different arrays of
gene expression
 Structural Motifs of
DNA Binding Proteins homeodomain
(include TFs) proteins (Hox,
Msx-1, Barx-1)

steroid involved in
hormone protein/protein
receptors (ER, interactions e.g.
PR, AR, GCR) AP-1, Nrf2
Eukaryotic Transcriptional Activation

CTD: C-terminal domain of RNA Pol II
HMG: High-mobility group (HMG) proteins
Inr: initiator element
UAS: upstream activation sequence
TBP: TATA binding protein
Transcriptional Repression
RNA processing control of gene expression

Alternative splicing:
Splice introns differently in different tissues or response to different
signals
Produce different mature mRNA >> proteins
Alternative polyadenylation:
Use of different poly(A) sites of a pre-mRNA molecule, produce
different mature mRNA>> proteins
Affect the stability of mRNA
Could suppress translation
Increase transcriptome and proteome diversity
One gene generates many version of mature mRNA
More mRNA diversity >> proteome diversity
Example: Alternative splicing and alternative polyadenylation of human
calcitonin gene

AAA

Selective outcome
of exons 4 and 5
result in different
proteins produced
RNA processing control
Alternative polyadenylation regulates oncogene expressions

Poly(A) site 1 Poly(A) site 1

Use of different poly(A) sites leads to inclusion or exclusion of
cis-elements (miRNAs)
These cis-elements are targets of other regulations e.g.
microRNA (miR-15), stability factor (ARE: AU-repeat element)
Poly(A) site in introns or exons are also found. Impact?
Cyclin D1 regulates cell cycle

Mayr and Bartel, 2009, Cell 138, 673–684
RNA stability control

mRNA Degradation Control
mRNA turnover very quickly once in cytoplasm
The rate of turnover is a gene expression control point
Cis-elements reside in 3’-UTR, like UUUUUAU
Other factors affect this process
Two pathways in yeast:
De-adenylation dependent: poly(A) degradation first
De-adenylation independent: no relying on poly(A) degradation
Endonuclease mediated decay
RNA stability control

mRNA Stability

Stability time span: From minutes to days, differ in genes and conditions.
RNA stability control

RNA Interference:
a post-transcriptional gene expression regulation

RNAi: Gene expression regulation mechanism by small RNA molecules.
AKA: Gene silencing, or post-transcriptional gene silencing
Nobel prize: Andrew Fire and Craig Mello, 2006
Small interfering RNAs and microRNAs (20-30 nts) regulate gene expression
through at least four distinct mechanisms:
(1) cleavage of mRNA,
(2) inhibition of translation
(3) transcriptional silencing
(4) degradation of mRNA.
Micro RNA and small silencing RNA
(Chpt 14)
RNAi: originated as a
defense mechanism

General cellular RNA are single
stranded
Origin
Viral RNA some time are
double stranded
Originally found in plants
or
RISC: RNA-induced silencing complex
 Processing

Cellular origin: Internal External
 Action
function

Or RNA
degradation
 RNA induced
transcriptional
silencing
 lncRNA: long non-coding RNA
Long (>200 bases) RNA that is transcribed but not translated into a
protein product
Most are transcribed by RNA polymerase II
Most have 5’ cap and 3’ polyA tails
Introns are spliced but not as efficiently as in mRNA
Some remain in nucleus; some transported to cytoplasm
Functions:
Modulate chromatin function
Alter stability and translation of cytoplasmic mRNAs
Interfere with signaling pathways
Translational control

Example immune response

Enhancement of translation
Translational control
(conti.)

Cell proliferation
 Protein Control - Degradation
Protein degradation rate determines its level
A short-lived mRNA may make a very stable protein
A long-lived mRNA may make a unstable protein
Protein stability varies
Lens proteins, lift-time
Steroid receptors, minutes
Through co-factor ubiquitin and degradesome
Protein Control - activation and inactivation

Protein amount may not change, but activity changes
Phosphorylation of protein mostly activates a protein
Dephosphorylation mostly inactivates a protein
Co-factor protein binding to activate a protein
Other modifications (e.g. acetylation, glycosylation)
Application: Tooth Development
BMP BMP BMP BMP
Dental lamina = band of epithelial tissue
FGF FGF FGF FGF Dental papilla = condensation of
PDGF PDGF
SHH
SHH SHH
SHH ectomesenchymal cells that lie below enamel
WNT WNT organ
TGF TGF
WNT WNT

ACTIVIN BMP BMP
BMP FGF FGF
Barx 1 Barx 1 WNT
Gli1-3 Cbfa1 Barx 1
Msx1 Gli1-3 Cbfa1
Msx2 Msx1 Gli1-3
Pax9 Pax9 Msx1
Pax9
Transcriptional regulation of tooth development

Inhibition, no
expression

p19ink4d Activation,
expression

Transcriptional factor Msx1 functions as an inhibitor of the expression of gene
p19ink4d (a cell cycle regulator act on cyclin D-dependent kinase (CDK) )
 Transcriptional regulation of tooth development
p19ink4d Promoter

p19ink4d gene

Two Msx1 binding sites on the promoter of p19ink4d. It works with many other
transcriptional factors to reach final goal of regulating p19ink4d expression.
 Cell Signaling & Incisor/Molar Determination in mice

noggin
BMP-4

Molar

Growth factor FGF-8: Barx-1 >>>>> molars
Growth factor BMP-4: Msx-1 & Barx-1 >>>>> incisors
If block BMP-4 with an inhibitor protein (noggin), influence of Barx-1 extends medially; can
convert future incisors into molars.