2024 Gene Expression Notes PDF

Summary

These notes cover gene expression in eukaryotic organisms, comparing and contrasting prokaryotic and eukaryotic gene expression, and the role of cis-acting elements, promoter-proximal elements, and enhancers in tissue-specific transcription. It also outlines the different categories of transcription factors and epigenetic regulation.

Full Transcript

Burman University, BIOL 374, Gene Expression, p.1

Learning Objectives: After completing this module, you will be able to
1. Compare and contrast gene expression in prokaryotic and eukaryotic organisms.
2. Compare the eukaryotic RNA polymerases and the genes they transcribe.
3. Describe RNA pol II promoters and the general transcription factors associated with
them.
4. Define the role of cis-acting elements, promoter-proximal elements and enhancers, in
tissue-specific transcription.
5. Describe the different categories of transcription factors that act at the cis-acting
elements.
6. Describe the epigenetic regulation of genes by DNA methylation and lncRNA
inactivation of the X chromosome.
7. Define the terms activation, repression, cis-element, trans factors, enhancesome, hyper-
and hypo-acetylation, condensation and decondensation of chromosomes, mediator
complex, gene silencing, epigenetics, lncRNA, DNase 1 footprinting, EMSA, CpG
islands, CTD domain of RNA pol II and more.
8. Compare transcription initiation in RNA Pol I and III with Pol II.

Text: Lodish et al. (2021), Ch. 8

Verse: But God gives it a body as he has determined, and to each kind of seed he gives its own
body. Not all flesh is the same: People have one kind of flesh, animals have another, birds
another and fish another. 1 Cor 15:38-39 (NIV)

The accepted molecular biological basis of speciation is genome changes that facilitate
the natural selection of species members that are more adapted to the prevailing environment.
While this understanding is reasonable, there are some problems, specifically, 1) it would take a
long time to accumulate significant mutations to allow the genetic program, or blue print, to be
different enough to account for those adaptations, and 2) the inability to explain high similarities
and identities in the genomes of divergent species. So rapid adaptations (in terms of a few
decades) is not possible with those subtle base pair changes.

However, a natural disaster could trigger the Darwinian concept of adaptive radiation
(where organisms diversify rapidly from an ancestral species into a multitude of new forms due
to a sudden change/environmental challenge). The “Darwin's finches” are often used as an
example of adaptive radiation. These are a group of about 18 species of passerine birds that are
well known for their remarkable diversity in beak form and function. The finches’ beaks and
bodies changed allowing them to eat certain types of foods such as nuts, fruits, and insects.

Recent work showed that changes in epigenetics is a better explanation to how Darwin’s
finches respond to rapid environmental changes. In one study, very little genetic variations were
detected in rural and urban populations of two species of Darwin’s finches but substantial
epigenetic differences were seen that could be related to environmental differences resulting
from urbanization (McNew et al., 2017). Likewise, in another study, epigenetic alterations in

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DNA methylation patterns (also referred to as epimutations in this study) were more common in
five different species than polymorphic genome variations (Skinner, et al., 2014). Furthermore,
the number of epimutations increased with phylogenetic distance compared to those from genetic
mutations (the number of genetic mutations did not consistently increase with phylogenetic
distance). As environmental factors are known to result in heritable changes in the epigenome, it
is possible that epigenetic changes (DNA methylation, histone modifications, chromatin
remodeling, and lncRNA regulation and all those great concepts we are learning) contribute to
the molecular basis of the evolution of Darwin’s finches.

While the Bible text from last week describes God’s gift of this “seed” or genomic design
for all creatures. Considerable physical variations can be obtained by epigenetic control of this
genome. It also could explain the high degree of genomic sequence similarities between species
because it may not be the DNA sequence which defines a species but its epigenome (epigenome
is usually defined as the complete description of the chemical modifications to DNA and histone
proteins that regulate the expression of genes within the genome).

References:

McNew, S.M., Beck, D., Sadler-Riggleman, I. et al. Epigenetic variation between urban and rural
populations of Darwin’s finches. BMC Evol Biol 17, 183 (2017). https://doi.org/10.1186/s12862-017-
1025-9

Michael K. Skinner, Carlos Gurerrero-Bosagna, M. Muksitul Haque, Eric E. Nilsson, Jennifer A.H. Koop,
Sarah A. Knutie, Dale H. Clayton, Epigenetics and the Evolution of Darwin’s Finches, Genome Biology
and Evolution, Volume 6, Issue 8, August 2014, Pages 1972–1989, https://doi.org/10.1093/gbe/evu158

Introduction (Topic 7)
§ Gene Expression
– Entire process whereby the information encoded in a particular gene is decoded
into a particular protein.
– Includes:
1. Transcription initiation [F8-3]
2. RNA Polymerization/Elongation
3. Transcription termination

§ Constitutive vs. Inducible
1. Constitutive or housekeeping genes are always active in growing cells, during all
stages of the cell cycle, e.g., ribosomes, cytochrome B, b-actin and others.
2. The synthesis of inducible or regulated genes is controlled in response to the
needs of a cell or organism.
Results in differential gene expression, e.g., in developmental proteins.

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7.1 Overview of Eukaryotic Gene Control and RNA Polymerases
§ In bacterial cells and most single cell eukaryotes, gene control serves mainly to allow
these cells to adjust to changes in its environment so that growth and division can be
optimized.
§ However, gene control in multicellular organisms is important for development and
differentiation, and is generally not reversible. With exception, relatively few
eukaryotic genes are reversibly regulated by environmental conditions.
§ The primary purpose of gene control in multicellular organisms is the precise execution
of developmental decisions, i.e., proper genes are expressed in the proper cells/time
during development and cellular differentiation.
§ Transcriptional control is the primary means of regulating eukaryotic gene
expression.
§ Protein-binding regulatory DNA sequences, or cis-control elements, are associated with
genes.
§ Some of these cis-elements may be kilobases away from the transcription start site (e.g.,
Pax6 genes; F8-4).
§ Specific proteins, or trans factors, that bind to
a gene’s regulatory sequences (i.e., cis
elements) determine where transcription will
start, and either activate or repress its
transcription.
§ Some trans factors that position Pol II at
transcription initiation start sites and help
separate the DNA strands, thus required by all
Pol II-promoters, are called general
transcription factors.
§ Inactive genes are assembled into condensed
chromatin, which inhibits the binding of RNA
polymerases and general transcription factors
required for transcription initiation.
§ Activator proteins bind to control elements
close to transcription start sites, as well as
kilobases away, to promote chromatin
decondensation and RNA polymerase binding.
§ Repressor proteins bind control elements,
causing condensation of chromatin and
inhibition of polymerase binding [F8-3].

§ Three eukaryotic polymerases catalyze formation of different RNAs [T8-1, T9-2 (old
text)].
– Purified RNA Polymerases are eluted at different salt concentrations during ion-
exchange chromatography [F8-6].
– Also differ in their sensitivity to a-amanitin (poisonous cyclic octapeptide
produced by some mushrooms). Pol I is insensitive, Pol II is very sensitive, and Pol

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III has intermediate sensitivity.
1. RNA Pol I: pre-rRNA (ribosome components, protein synthesis)
2. RNA Pol II: mRNA, snRNA (small nuclear RNAs required for splicing) siRNA
(chromatin-mediated repression, translation control) and miRNA (translation
control)
3. RNA Pol III: tRNAs, 5S rRNA, small stable RNAs (protein synthesis, ribosome
components, etc)

§ Subunit structure of yeast and E. coli RNA
polymerases [F8-7].
– All three yeast polymerases have 5 core
subunits homologous to the b’, b, two
a and w subunits of E. coli RNA
polymerase.
– The largest subunit of RNA Pol II also
contains an essential C-terminal domain (CTD) [F8-8].
The CTD has a repeated heptapeptide (Tyr-Ser-
Pro-Thr-Ser-Pro-Ser; in vertebrates there are 52
repeats) in the C-terminal domain (CTD).
The Ser (and some Tyr) residues of the CTD
become phosphorylated right after transcription
initiation and remains phosphorylated during
active transcription.
– Both RNA Pol I & III have the same two nonidentical
a-like subunits, whereas RNA Pol II have more
distantly related nonidentical a-subunits.
– All three share the same w-like subunit and 4 other
common subunits.
– In addition, each yeast RNA polymerase contains 3 to
7 unique subunits.
– In the transcribing complex, a common clamp domain

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closes on the template and the newly formed DNA-RNA hybrid, enabling RNA Pol
II to transcribe long stretches of DNA [F8-9]. This domain is part of the b’, or
RPB1, subunit.
Together the factor DSIF (F8-3), a transcription elongation factor, the clamp
converts the polymerase to be a processive enzyme, polymerizing ribonucleotides
rapidly until transcription is terminated.

7.2 RNA Pol II Promoters and General Transcription Factors
§ Protein-coding genes are transcribed by RNA pol II.
§ Expression of these genes is regulated by multiple protein-
binding DNA sequences, generically referred to as
transcriptional control regions.
§ These control regions are cis-acting elements which only
affecting expression of genes on the same DNA molecule.
§ Transcription is initiated at a specific base pair, +1 (that
corresponds to the 5’-cap in mRNA) and is controlled by
the binding of trans-acting proteins (transcription
factors) to cis-acting regulatory DNA sequences.
§ Eukaryotic cis-acting elements are often much further from
the promoter they regulate (many kilobases from start
sites), and transcription from a single promoter may be
regulated by binding of multiple transcription factors to
alternative control elements.
§ Transcription control sequences can be identified by
analysis of a 5¢-deletion series [F7-13; old text].

§ Most eukaryotic genes are regulated by multiple cis-acting control regions:
1. Promoters determine the site of transcription initiation and direct binding of RNA
pol II.
2. Promoter-proximal elements, close to the start site, help regulate eukaryotic genes
(discussed later in 7.3).
3. Enhancers, distant from the transcriptional start site, can stimulate transcription by
RNA pol II (discussed later in 7.3).

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A. Promoters
1. TATA box
– Most common in rapidly transcribed
genes.
– Similar to E.coli Pribnow box.
– The TATA box is a highly conserved
promoter in eukaryotic DNA [F9-16].
~ 26 to 31 bases upstream from the +1 start site.
Deletion of the spacing between the TATA box and +1 site result in
transcription initiation at a new site ~ 25 bp downstream from the TATA box.
2. Initiators
– Less common than TATA box.
– Most have a cytosine (C) at –1 and an adenine (A) at +1 transcription start site.
– Degenerate initiator consensus sequence:
5’-YYA+1N(T/A)YYY-3’ where Y = C or T, N = any base, A at +1, and A or T at
+3.
3. CpG islands
– Generally, for genes that are transcribed at low rates, e.g., “house-keeping”
genes.
– Tend to have ill-defined initiation site, anywhere over a 100-1000 bp region. As a
result, mRNAs tend to have several alternative 5’-ends.
– Contain a CG-rich stretch of 20-50 bases within ~ 100 bp upstream of the
initiation site.
– CG-rich regions/clusters, or CpG islands, are rare in mammalian genomes.
– Cs in CpG islands are unmethylated (most Cs followed by Gs in the genome are
methylated; 5-methyl C).
– CpG islands coincide with nucleosome-free regions of DNA.
– CpG island promoters are divergently transcribed, however, RNA molecules
transcribed in the wrong direction, i.e., resulting in (-) standed RNA, are
terminated at ~1-3 kb from the +1 site.

B. General Transcription Factors at the Promoters
– Initiation by Pol II requires general transcription factors (TFIIs, e.g., TFIIB), which
position Pol II at initiation sites and are required for transcription of most genes
transcribed by this polymerase.
– Most general transcription factors are multimeric and highly conserved.
– TFIIs together with Pol II, called the preinitiation complex (or PIC), assemble in a
specific order in vitro but most of the proteins may combine to form a holoenzyme
complex in vivo.
– Stepwise assembly of Pol II transcription-initiation complex in vitro [F9-19]
1. Locating the start site
– Involves the binding of TFIID, which binds to the TATA-box through its
TATA-binding protein subunit, TBP.

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– TFIID is ~ 750 kDa; single TBP (38 kDa) and 13 TAFs
(TBP-associated factors).
– TBP
The conserved C-terminal domain (180 aa) of TBP binds
to TATA-box DNA.
TBP is saddle-shaped monomer with dyad symmetry.
TBP interacts with the minor groove in DNA, bending
the helix (F5-5).
Only TBP (but not TAFs of
TFIID) is required for in vitro
RNA Pol II initiation.

2. TFIIA and TFIIB join TBP
– TFIIA associates with TBP and DNA
on the upstream side of the
TBP-TATA box complex.
– C-terminal of TFIIB contacts both
DNA (on either side of TATA-box)
and TBP.
– Additionally, TFIIB binds to the
TFIIB recognition element BRE
upstream of the TATA-box in
“strong” promoters [F9-16].
– N-terminal of TFIIB assists Pol II
in melting the DNA at the
transcription start site.
– TAF subunits also contact the DPE
element (downstream promoter
element; ~30 bp downstream from
the transcription start site) present in
TATA-less genes like the initiator
element.
– These additional interaction increases
TFIID binding.
3. Formation of core preinitiation complex
(PIC)
– Preformed complex of TFIIF and
Pol II binds, positioning the Pol II
over the start site.

4. Closed PIC
– TFIIE tetramer joins preformed
complex; contains the docking site
for TFIIH.
– TFIIH joins to form closed PIC.

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5. Open PIC
– TFIIH has 10 subunits.
– Helicase activity of one
of the TFIIH subunits unwind DNA (using ATP) at start site, allowing Pol
II to form the open PIC complex.

6. Pol II starts transcribing mRNA.
– The kinase subunits of TFIIH phosphorylate the Pol II CTD at multiple
sites (phosphorylated CTD is a docking site for other entities needed later).
– All of initiation TFs but TBP dissociate and are replaced by elongation
factors.

7.3 Regulatory Sequences in Protein-Coding Genes and
Activators/Repressors that Modulate Them.
§ Transcription factors, often cell-type specific, (i.e., functioning only in differentiated
cell types; as opposed to the general TFs that bind to promoter sequences in S9.3B) can
stimulate or repress transcription.
§ They do so by binding to promoter-proximal elements and enhancers in eukaryotic
DNA.
§ The human genome codes for ~ 2000 different transcription factors, however, their
concentrations very low in the cell (often 20 bp) may decrease transcription.
– Cell-type specific.

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– Transcription-control elements can be identified
with linker scanning mutants [F9-22]. Linkers,
used to introduce mutations, are inserted in the
control regions in an overlapping fashion, hence
linker scanning mutation.

B. Enhancers
– Multiple ~6- to 10-bp control elements, each a
protein-binding site and contributing to the
overall activity of the enhancer, within a region of
~200 bp.
– Located 200 to 50,000 bp upstream or
downstream from a promoter, within an intron,
or downstream from the final exon of a gene, and in either orientations (i.e., on + or
– strand of DNA) [F9-23a].
– Again cell-type specific.
– SV40 enhancer element (~100 bp) stimulates transcription of all mammalian
promoters that have been tested.

C. Yeast transcription control regions
§ In yeast, upstream activating sequences (UASs) function similarly to promoter-
proximal and enhancer elements in higher eukaryotes [F9-23c].

D. Trans-acting elements
– Repressors and activators that bind to these cis-
elements (i.e., transcriptional control regions) are
trans-acting.
– Trans-acting elements affect expression of
regulated genes no matter on which DNA molecule
in the cell these are located, i.e., on the same or
different DNA molecule.
– Trans-acting elements, or transcription factors,
are diffusible proteins.
– Protein-DNA interactions can be detected by
footprinting and gel-shift assays.
1. In DNase I footprinting, a region of DNA is
protected from digestion by the nuclease DNase
I when it is bound by a protein [F9-24a; middle
fig]. Fig 9-24b (right fig) illustrate a DNase I
experiment of a promoter with general
transcription factors.

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2. In the gel-shift assay, or electrophoretic mobility
shift (EMSA, or band-shift), the electrophoretic
mobility of a DNA fragment is retarded when it is
complexed to protein, causing a shift in the location of
the fragment band [F9-25; top left].
– Once a transcription factor is isolated and purified, its
partial amino acid sequence can be determined and used
to clone a gene or cDNA encoding it. The isolated gene
can then be used to test the ability to activate or repress
transcription in an in vivo transfection assay [F9-26].

E. Activators are modular
§ Transcriptional activators are modular proteins composed of
at least 2 distinct functional domains [F9-28]:
1. DNA-binding domain bind to specific DNA sequences.
2. Activation domain interact with other proteins to
stimulate transcription from a nearby promoter.
– Modular domains are connected by flexible regions in the
protein chain that allow activation domains in different
activators to interact even when their DNA-binding domains
are bound to sites separated by
tens/hundreds of bp.
– Roles of modular domains, i.e., DNA-
binding or activation, can be demonstrated
by using deletion constructs, e.g., Gal4
deletion mutants demonstrating functional
domains [F9-27].

F. Repressors
– Repressors are functional converse of
activators, i.e., they inhibit gene
transcription.
– Repressors are also modular, with DNA-
binding domains and repression
domains.
– Many eukaryotic genes are subject to
simultaneous activation and repression.

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The outcome is determined by which one wins – the activator or repressor.
– Repression domains can also function by interacting with other protein domains
located far away.
– Some repressors interfere with the binding of an activator to its cognate site.
– Others allow activators to bind to their cognate cis-elements, however, by binding
next to the activators inhibit the activator via its repression domain so that the
gene is repressed.

G. DNA-binding domains
§ DNA-binding domains contain a variety of structural motifs that bind specific cis-
sequences.
§ The binding usually occurs by noncovalent interactions between amino acid side
chains one or more a-helices in the DNA-binding domain and the bases within a
major grove in its cognate site.
§ e.g., Bacteriophage 434 repressor and DNA [F9-29]
Binds as a dimer, where each monomer of the repressor
binds to a half-site (half-sites are located at adjacent
major grooves).
The a-helix is called the recognition helix or sequence-
reading helix.
The DNA-binding domain of the bacteriophage 434
repressor has a helix-turn-helix motif.

– DNA-binding domains in eukaryotic transcription
factors can be classified into numerous structural types/motifs:
1. Homeodomain proteins
2. Zinc-finger proteins
3. Leucine-zipper proteins
4. Basic helix-loop-helix (bHLH) proteins

– Homeodomain proteins
60-residue DNA-binding motif, called the homeodomain (or “homeobox” motif)
1st found in the homeotic genes (e.g., antennapedia and ultrabithorax) in
Drosophila.
Conserved regions were diagrammed in a box when sequences were compared.
DNA-binding domain has a helix-turn-helix motif similar to bacteriophage
repressor (F9-29).

– Zinc-finger proteins
The zinc-finger motif has a polypeptide chain folded
around a central Zn2+ ion, to resemble a finger.
Several types including the C2H2 type, which has Zn2+ ion
bound by 2 Cys and 2 His residues (most common DNA-
binding motif in mammals; F9-30a).
C2H2 zinc-finger proteins

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§ Most transcription factors contain multiple C2H2 zinc fingers that bind as a
monomer wrapping around the DNA double helix (F9-30a; bottom left).
§ Each C2H2 finger has an a-helix that is inserted in the major groove of
DNA.

C4 zinc-
finger proteins
§ The Zn2+ ion is bound by 4 Cys.
§ This includes the steroid receptor superfamily, which has 2-finger units that
bind as hetero- or homo-dimers [F9-30b; top right].

– Leucine-Zipper Protein
Fig F9-30c shows the interaction of a homodimeric
leucine-zipper protein and DNA.
Hydrophobic Leu stripe, called the Leucine-Zipper,
along one side of the a helix is required for
dimerization.
The coiled-coil dimerization is stabilized by
hydrophobic interactions.
Two extended a helices grip the DNA like a pair of scissors at 2 adjacent
major grooves.
Belong to the general basic zipper (bZip) proteins because any hydrophobic aa
can be used in the zipper region. Most bZips are heterodimeric.

– Basic helix-loop-helix (bHLH) proteins [F9-30d]
The DNA-binding domain of basic helix-loop-helix
(bHLH) proteins is very similar to the Leucine
Zipper proteins.
Basic amino acids interact with the DNA, hence
basic Helix-Loop-Helix (bHLH).
A nonhelical region (loop) separates two a helices.
One pair of the a helices form “bZip” coiled-coils.

H. Activation/repression domains
– Activation and repression domains in transcription factors exhibit considerable
structural diversity, i.e., a variety of amino acid sequences and 3-dimensional
structures.
– Some have acidic activation domains, rich in acidic amino acids.

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– Ligand binding induces conformational change that
allow activation domain to interact with other proteins
[F9-31].
Some exist as unstructured, random-coiled
regions until they interact with a co-
activator/ligand, e.g., CREB with cAMP (F9-31a).
Binding of ligand (estrogen) creates a domain that
can bind a co-activator (F9-31b).
The antagonistic ligand (tamoxifen) block the
interaction with the coactivator by stabilizing an
alternate, non-activating structure (F9-31c).

I. Multiple transcription factor binding sites.
§ The transcription-control regions of most genes
contain binding sites for multiple transcription factors.
§ Transcription of such genes varies depending on the repertoire of transcription
factors that are expressed and activated in a particular cell at a particular time.

J. Heterodimeric transcription factors
– Transcription factors bZip and bHLH can form
heterodimers, i.e., of two different monomers to form
a functioning heterodimer.
– Heterodimeric transcriptional factors increase gene-
control options (F9-32).
– Combinatorial activation/repression domains can be
formed with homo- [F9-32a] & hetero-dimers.
– In heterodimeric transcriptional factors, each composite
binding site is divided into two half-sites, each one
bound by a monomer in the heterodimeric
transcription factor [F9-32bc].
– The alternative combinations of these monomers
bring together many different combinations of
activation domains and DNA sites recognized.
– Combinatorial complexity can also result from
cooperative binding of two unrelated transcription
factors on neighboring sites [F9-33].

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K. In vivo Polymerase II Initiation
– Enhancesome
Enhancers generally contain multiple clustered
binding sites for transcription factors [F9-34].
Cooperative binding of multiple activators to
nearby sites in an enhancer forms a large
nucleoprotein/multiprotein complex called an
enhancesome.
Assembly of enhancesome requires small
proteins (called architectural proteins, e.g.
HMG1) that bind to the DNA minor groove
and bend the DNA sharply, allowing proteins to bind on
either side of the bend to interact more readily [F7-30; old
text].
– In vivo assembly of Pol II initiation complex requires the
Mediator complex.
The multiprotein Mediator complex is large, with ~ 30 proteins and as large as a
ribosome [F9-39].
~ 20 mediator subunits, comprising of the “head
and middle” portions, may be involved in the
binding to Pol II.
The rest bind to activation domains in various
activator proteins.
The mediator complex forms a bridge between
activators bound to its cognate site on the DNA
and Pol II on the promoter.
Multiple weak interactions are enhanced because
the transcription factors are bound to neighboring
DNA sites indirectly.
The mediator is a co-activator; forms a molecular bridge between activation
domains of transcription factors and RNA Pol II.
By binding several activators simultaneously, the mediator help integrate the
effects of multiple activators on a single promoter [F9-40].
Activators bound to a distant enhancer
can interact with transcription factors
bound to a promoter because DNA is
flexible and the intervening DNA can
form a large loop.
– Cell-type Specificity in Transcription
Initiation.
The highly cooperative assembly of
preinitiation complexes in vivo
generally requires several activators
[Fig; old text].

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A cell must produce the specific
set of activators required for
transcription of a particular gene
in order to express that gene.
Therefore, tissue-specific
proteins are expressed because
of the presence of tissue-
specific transcription factors, or
a combination of a specific set of
activators.

L. Elongation and Termination of
Transcription
§ Different mechanisms of
transcription termination are
employed by each of the eukaryotic nuclear RNA polymerases.
§ Once RNA pol II transcribes protein-coding genes beyond ~200 bases, further
elongation is highly processive and does not terminate until the cleavage and
polyadenylation site is transcribed.
§ Termination then occurs 0.5 -2 kb beyond the poly A site.

7.4 Molecular Mechanisms of Transcription Activation & Repression
§ Occurs at 3 levels:
1. Changes in chromatin structure directed by activators and repressors
2. Modulation of the levels and/or activities of activators and repressors (see 9.6)
3. Direct influence of activators and repressors on assembly of transcription-initiation
complexes (see S7.3K)

§ Heterochromatin
§ Heterochromatin are condensed regions of chromatin.
§ In these regions, DNA is relatively inaccessible to
transcription factors and other proteins.
§ Formation of heterochromatin “silences” (or
represses) gene expression at telomeres, near
centromeres and other regions.

§ In the life cycle of S. cerevisiae, mating-type control in
yeast is controlled by gene silencing [F9-35].
– When the a or a sequences are present in the MAT
(mating-type) locus, they can be transcribed into
mRNAs whose encoded proteins specify the mating-
type phenotype of the cell.

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– The amino acid residues (~20-60) at the N-terminus of each histone extend from the
surface of the nucleosome [F8-26a].
– These amino acids are rich in Lysine residues, which can be reversibly modified by
acetylation.
– Heterochromatin is hypoacetylated.

– Schematic model of silencing at yeast telomeres
[F9-36d]
– The interactions of several proteins with each
other and the hypoacetylated N-termini of
histones H3 and H4 are responsible for the
repressing chromatin structure in these regions.
– RAP1 – binds directly to telomeres (HML &
HMR), and to each other.
– SIR 2, 3 & 4 (silent information regulators) –
bind to hypoacetylated histones H3 & H4, and
to each other.
– Assembly of multiprotein repressing complex
result in the formation of heterochromatin.

§ Repressors/Activators & Acetylation
– Some repressors interact with histone deacetylase complexes, resulting in the
deacetylation of histones in nucleosomes near the repressor-binding site [F9-37a].
– Deacetylated histones lead to condensed chromatin, inhibiting the interaction of
general transcription factors and promoter DNA, thereby
repressing transcription initiation.
– Conversely, activators result in hyperacetylation by
stimulating histone acetylase complexes, thereby
stimulating transcription initiation [F9-37b].

§ Chromatin-remodeling complexes
– In addition to histone acetylase complexes, chromatin-
remodeling complexes are also required for activation at
many promoters.
– Homologous to helicases, these multisubunit
complexes can transiently dissociate DNA from
histone cores in an ATP-dependent reaction, or decondense chromatin.
– Thus, promotes the binding of DNA-proteins needed for initiation to occur.

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7.5 Regulation of Transcription-Factors Activity
§ Transcription factors can be in an active or inactive conformation.
§ Conformational change that modify their interactions with other proteins can be achieved
by:
1. Noncovalent binding of a ligand, e.g., lipid-soluble hormone binding, or
2. Covalent modification, e.g., via phosphorylation.

§ Lipid-soluble hormones control the activities of nuclear receptors [F9-42].
§ Secreted from one cell type and travel through
extracellular fluids to affect the function of cells
at a different location.
§ Can diffuse through plasma and nuclear
membranes.
§ Bind to and regulate members of the nuclear-
receptor superfamily.
All nuclear receptors share a common domain structure [F9-43]
Unique N-terminal domain that
can function as the activation
domains.
Conserved DNA-binding
domain that bind to nuclear-
receptor response elements on
DNA control regions.
The hormone-binding (or ligand-
binding) domain, at the C-
terminal, contains a hormone-
dependent activation domain.

§ Response elements are DNA sites that major nuclear
receptors bind to [F9-44].
– Estrogen receptor response element (ERE)
– 6-bp inverted repeats
– Receptors bind as homodimers.
– Thyroid hormone receptor response element (TRE)
– 6-bp direct repeats of ERE separated by 4 bp
– Receptors bind as heterodimers with a common
nuclear-receptor monomer called RXR, e.g.,
RXR-TR.

§ Mechanism of hormonal control of nuclear-receptor
activity
– For heterodimeric nuclear receptors, e.g., RXR-TR,
when bound to their response elements, act as
repressors or activators of transcription depending

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on whether hormone occupies the ligand-
binding site.
- hormone à represses à histone
deacetylation
+ hormone à activates à histone
hyperacetylation
– For homodimeric nuclear receptors, e.g., ER,
their activity is regulated by controlling their
transport from the cytoplasm to the nucleus
in a hormone-dependent nuclear translocation
[F9-45a, d].

§ Polypeptide hormone binding results in phosphorylation of some transcription
factors.
– Peptide or protein hormones cannot diffuse through the lipid bilayers.
– Instead they bind to cell surface receptors, which pass the signal to proteins in the
cytoplasm (process called signal transduction; Chapters 15 & 16).
– Usually leads to transcription-factor
phosphorylation, which could either
activate or deactivate the
transcription factor, e.g., JAK-STAT
Pathway [F16-12a].

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7.6 Epigenetic Regulation of Transcription
§ Epigenetic control of transcription refers to repression or activation that is maintained
after cells replicate as the result of DNA methylation or post-translational
modification of histones, especially histone methylation.
§ Methylation of CpG sequences in CpG island promoters in mammals generates
binding sites for a family of methyl-binding proteins (MBDs) that associate with
histone deacetylases, inducing hypoacetylation of the promoter regions and
transcriptional repression.

§

Lysine 9 on histone H3 when di- and
trimethylation creates binding sites for the
heterochromatin-associated protein HP1, which
results in the condensation of chromatin and
transcriptional repression.
– These post-translational modifications are
perpetuated following chromosome replication
because the methylated histones are randomly
associated with the daughter DNA molecules
and associate with H3K9 HMT that methylate
H3 lys 9 on newly synthesized histone
octamers assembled on the daughter DNA [F9-47].
– Post-translational modification (methylations, phosphorylations, and unbiquinations)
of histone tails are associated with active and repressed genes [T9-3].

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§ lncRNA and X-chromosome
– Long noncoding RNA (lncRNA) direct
epigenetic repression in metazoans.
– X-chromosome inactivation in female mammals
requires XIST lncRNA from the Xist gene that is
transcribed from the X-inactivation center of one
X chromosome and then spreads by a poorly
understood mechanism along the length of the
same chromosome [F9-50c].
– The active X chromosome produces another
lncRNA called TSIX that represses the
inhibitory effect of XIST [F9-50a].
– In differentiated female cells, the inactive X
chromosome (Xi) is associated with XIST
lncRNA.
– The XIST lncRNA only acts in cis, i.e.,
remaining with the inactive X and does not
interact with the active X, or other chromosomes.
– During very early embryogenesis, TSIX
lncRNA is expressed in both the X
chromosomes, thus preventing the expression
of XIST lncRNA (present on the complementary
strand of the DNA). As cells differentiate, the
Tsix gene (gene for TSIX lncRNA) is repressed
in one of the X chromosomes, allowing the
transcription of the XIST lncRNA.
– Accumulation of XIST lncRNA leads to X inactivation of that X chromosome (the
process of choosing which X chromosome is inactivated is random, i.e., Xp from
sperm or Xm from egg).
– XIST lncRNA interacts with a co-repressor that binds a histone deacetylase and
repression complexes (e.g., PRC2; F9-50d] at an early stage of embryogenesis,
initiating X inactivation.
– X inactivation is maintained throughout the remainder of embryogenesis and
adult life by continued association with repression complexes and DNA methylation
of CpG island promoters on the inactive X.

§ Some lncRNAs have been discovered that lead to repression of other genes in trans (i.e.,
on another chromosome), as opposed to the cis inactivation imposed by XIST.
– e.g., HOTAIR, a lncRNA in the HOXC locus of the Hox genes, can repress the
HOXD locus on another chromosome.
– Repression is initiated by their interaction with repression complexes.

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7.7 Other Transcription Systems
§ Transcription initiation by Pol I and Pol III is analogous to that by Pol II.
§ All RNA polymerases use some promoter sequences and TBP.
§ Differences:
1. Different general transcription factors.
2. RNA Pol I & III do not require ATP
hydrolysis during transcription initiation.
3. No defined enhancers or promoter-proximal
elements.

A. RNA Pol I [F9-51]
– General multimeric transcription factors, UBF
and Pol I/TBP/TAFs, bind to upstream
control element (UCE; -155 to -60) and core
element (-40 to +5), respectively.

B. RNA Pol III [F9-52]
– Internal promoter elements (A-, B- and C-
boxes) located downstream from the transcription
start site.
– Also, in snRNA promoters with TATA and
upstream promoter element (PSE).

C. Mitochondrial/Chloroplast DNAs
– Mitochondrial DNA is transcribed by a nuclear-
encoded RNA pol composed of 2 subunits - one
homologous to the bacteriophage T7 RNA pol and
the other resembles bacterial s factors.
– Chloroplast DNA is transcribed by a chloroplast-
encoded RNA pol homologous to bacterial RNA
pol, except that it lacks a s factor.

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