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Title: Welcome Each of You to My Molecular Biology Class


1
Welcome Each of You to My Molecular Biology Class
2
Molecular Biology of the Gene, 5/E --- Watson et
al. (2004)
Part I Chemistry and Genetics Part II
Maintenance of the Genome Part III Expression
of the Genome Part IV Regulation Part V Methods
2005-5-10
3
Part IV Regulation
Ch 16 Transcriptional regulation in
prokaryotes Ch 17 Transcriptional regulation in
eukaryotes Ch18 Regulatory RNAs Ch 19 Gene
regulation in development and evolution Ch 20
Genome Analysis and Systems Biology
4
Surfing the contents of Part IV --The heart of
the frontier biological disciplines
5
  • Molecular Biology Course
  • Chapter 17
  • Gene Regulation
  • in Eukaryotes

6
  • TOPIC 1 Conserved Mechanisms of Transcriptional
    Regulation from Yeast to Human (2 techniques).
  • TOPIC 2 Recruitment of Protein Complexes to Genes
    by Eukaryotic Activators. (2 techniques)
  • TOPIC 3 Transcriptional Repressors
  • TOPIC 4 Signal Integration and Combinatorial
    Control.
  • TOPIC 5 Signal Transduction and the Control of
    Transcriptional Regulators.
  • TOPIC 6 Gene Silencing by Modification of
    Histones and DNA.
  • TOPIC 7 Epigenetic Gene Regulation.

7
1. Gene Expression is Controlled by Regulatory
Proteins (????)
Principles of Transcription Regulation
  • Gene expression is very often controlled by
    Extracellular Signals, which are communicated to
    genes by regulatory proteins
  • Positive regulators or activators
    INCREASE the transcription
  • Negative regulators or repressors
  • DECREASE or ELIMINATE the transcription

8
  • Similarity of regulation between eukaryotes
    and prokaryote
  • 1.Principles are the same
  • signals (??),
  • activators and repressors (?????????)
  • recruitment and allostery, cooperative binding
    (??,???????)
  • 2. The gene expression steps subjected to
    regulation are similar, and the initiation of
    transcription is the most pervasively regulated
    step.

9
  • Difference in regulation between eukaryotes and
    prokaryote
  • Pre-mRNA splicing adds an important step for
    regulation. (mRNA?????)
  • The eukaryotic transcriptional machinery is more
    elaborate than its bacterial counterpart.
    (?????????)
  • Nucleosomes and their modifiers influence access
    to genes. (????????)
  • Many eukaryotic genes have more regulatory
    binding sites and are controlled by more
    regulatory proteins than are bacterial genes.
    (???????????)

10
  • A lot more regulator bindings sites in
    multicellular organisms reflects the more
    extensive signal integration

Bacteria
Yeast
Human
Fig. 17-1
11
  • Enhancer (????) a given site binds regulator
    responsible for activating the gene. Alternative
    enhancer binds different groups of regulators and
    control expression of the same gene at different
    times and places in responsible to different
    signals. Activation at a distance is much more
    common in eukaryotes.
  • Insulators (???) or boundary elements (????) are
    regulatory sequences between enhancers and
    promoters. They block activation of a linked
    promoter by activator bound at the enhancer, and
    therefore ensure activators work discriminately.

12
CHAPTER 17 Gene Regulation in eukaryotes
???????????????? The structure features of the
eukaryotic transcription activators
Topic 1 Conserved Mechanisms of Transcriptional
Regulation from Yeast (??) to Mammals (????)
13
  • The basic features of gene regulation are the
    same in all eukaryotes, because of the similarity
    in their transcription and nucleosome structure.
  • Yeast is the most amenable to both genetic and
    biochemical dissection, and produces much of
    knowledge of the action of the eukaryotic
    repressor and activator.
  • The typical eukaryotic activators works in a
    manner similar to the simplest bacterial case.
  • Repressors work in a variety of ways.

14
  • 1. Eukaryotic activators (??????) have separate
    DNA binding and activating functions, which are
    very often on separate domains of the
    protein.

Fig. 17-2 Gal4 bound to its site on DNA
15
  • Eukaryotic activators---Example 1 Gal4
  • Gal4 is the most studied eukaryotic activator
  • Gal4 activates transcription of the galactose
    genes in the yeast S. cerevisae.
  • Gal4 binds to four sites (UASG) upstream of GAL1,
    and activates transcription 1,000-fold in the
    presence of galactose

Fig. 17-3 The regulatory sequences of the Yeast
GAL1 gene.
16
  • Experimental evidences showing that Gal4 contains
    separate DNA binding and activating domains.
  • Expression of the N-terminal region (DNA-binding
    domain) of the activator produces a protein bound
    to the DNA normally but did not activate
    transcription.
  • Fusion of the C-terminal region (activation
    domain) of the activator to the DNA binding
    domain of a bacterial repressor, LexA activates
    the transcription of the reporter gene. Domain
    swap experiment

17
  • Domain swap experiment
  • Moving domains among proteins, proving that
    domains can be dissected into separate parts of
    the proteins.
  • Many similar experiments shows that DNA binding
    domains and activating regions are separable.

??????1
18
Box1 The two hybrid Assay (?????) to study
protein-protein interaction and identify proteins
interacting with a known protein in cells
??????2
Fuse protein A and protein B genes to the DNA
binding domain and activating region of Gal4,
respectively.
Produce fusion proteins
19
  • 2. Eukaryotic regulators use a range of DNA
    binding domains, but DNA recognition involves the
    same principles as found in bacteria.
  • Homeodomain proteins (HTH)
  • Zinc containing DNA-binding domain zinc finger
    and zinc cluster
  • Leucine zipper motif
  • Helix-Loop-Helix proteins basic zipper and HLH
    proteins

20
  • Bacterial regulatory proteins
  • Most use the helix-turn-helix motif to bind DNA
    target
  • Most bind as dimers to DNA sequence each monomer
    inserts an a helix into the major groove.
  • Eukaryotic regulatory proteins
  • Recognize the DNA using the similar principles,
    with some variations in detail.
  • In addition to form homodimers (?????), some form
    heterodimers (?????) to recognize DNA, extending
    the range of DNA-binding specificity.

21
  • Homeodomain proteins The homeodomain (?????) is
    a class of helix-turn-helix DNA-binding domain
    and recognizes DNA in essentially the same way as
    those bacterial proteins.

What is the same?
Figure 17-5
22
Zinc containing DNA-binding domains (?????) Zinc
finger proteins (TFIIIA) and Zinc cluster domain
(Gal4)
Figure 17-6
23
Leucine Zipper Motif (???????) The Motif
combines dimerization and DNA-binding surfaces
within a single structural unit.
Figure 17-7
24
Dimerization (???) is mediated by hydrophobic
interactions between the appropriately-spaced
leucine (???) to form a coiled coil structure
25
(No Transcript)
26
Helix-Loop-Helix motif similar as in leucine
zipper motif.
Figure 17-8
27
myogenic factor??????????????
28
Because the region of the a-helix that binds DNA
contains baisc amino acids residues, Leucine
zipper and HLH proteins are often called basic
zipper and basic HLH proteins. Both of these
proteins use hydrophobic amino acid residues for
dimerization.
29
  • 3. Activating regions (????) are not well-defined
    structures
  • The activating regions are grouped on the basis
    of amino acids content.
  • Acidic activation region (??????) contain both
    critical acidic amino acids and hydrophobic aa.
    yeast Gal4
  • Glutamine-rich region (???????) mammalian
    activator SP1
  • Proline-rich region (??????) mammalian
    activator CTF1

30
CHAPTER 17 Gene Regulation in eukaryotes
???????????????????????? Activation of the
eukaryotic transcription by recruitment
Activation at a distance
Topic 2 Recruitment of Protein Complexes to
Genes by Eukaryotic Activators
31
  • Eukaryotic activators (??????) also work by
    recruiting (??) as in bacteria, but recruit
    polymerase indirectly in two ways
  • 1. Interacting with parts of the
  • transcription machinery.
  • 2. Recruiting nucleosome modifiers that alter
    chromatin in the vicinity of a gene.

32
1. Activators recruit the transcription machinery
to the gene.
33
  • The eukaryotic transcriptional machinery contains
    polymerase and numerous proteins being organized
    to several complexes, such as the Mediator and
    the TF?D complex. Activators interact with one or
    more of these complexes and recruit them to the
    gene.

Figure 17-9
34
  • Box 2 Chromatin Immuno-precipitation (ChIP)
    (????????) to visualize where a given protein
    (activator) is bound in the genome of a living
    cell.)

??????3
35
  • Activator Bypass Experiment (???????)-Activation
    of transcription through direct tethering of
    mediator to DNA.

??????4
Directly fuse the bacterial DNA-binding protein
LexA protein to Gal11, a component of the
mediator complex to activate GAL1 expression.
Figure 17-10
36
At most genes, the transcription machinery is not
prebound, and appear at the promoter only upon
activation. Thus, no allosteric activation of the
prebound polymerase has been evident in
eukaryotic regulation?
37
2. Activators also recruit modifiers that help
the transcription machinery bind at the promoter
  • Two types of Nucleosome modifiers
  • Those add chemical groups to the tails of
    histones (???????????), such as histone acetyl
    transferases (HATs)
  • Those remodel the nucleosomes (?????), such as
    the ATP-dependent activity of SWI/SNF.

38
  • How the nucleosome modification help activate a
    gene?
  • Loosen the chromatin structure by chromosome
    remodeling (Fig. 17-11b) and histone modification
    such as acetylation (Fig. 17-11a), which uncover
    DNA-binding sites that would otherwise remain
    inaccessible within the nucleosome.

39
(???????)
uncover DNA-binding sites
  • Fig 17-11 Local alterations in chromatin directed
    by activators

40
  • 2. Adding acetyl groups to histones helps the
    binding of the transcriptional machinery. One
    component of TFIID complex bears bromodomains
    that specifically bind to the acetyl groups.
    Therefore, a gene bearing acetylated nucleosomes
    at its promoter have a higher affinity for the
    transcriptional machinery than the one with
    unacetylated nucleosomes.

41
???????
One component of TFIID complex bears bromodomains.
Figure 7-39 Effect of histone tail modification
42
3. Action at a distance loops and insulators
  • Many enkaryotic activators-particularly
  • in higher eukaryotes-work from a distance.
  • How?
  • Some proteins help, for example Chip protein in
    Drosophila.
  • The compacted chromosome structure help. DNA is
    wrapped in nucleosomes in eukaryotes. So sites
    separated by many base pairs may not be as far
    apart in the cell as thought.

43
Specific cis-acting elements called insulators
(???) control the actions of activators,
preventing the activating the non-specific genes
44
  • Insulators
  • block
  • activation
  • by
  • enhancers

Figure 17-12
45
  • Transcriptional Silencing (????)
  • Transcriptional Silencing is a specialized form
    of repression that can spread along chromatin,
    switching off multiple genes without the need for
    each to bear binding sites for specific
    repressor.
  • Insulator elements (?????) can block this
    spreading, so insulators protect genes from both
    indiscriminate activation and repression.????????
    ?????
  • ApplicationA gene inserted at random into the
    mammalian genome is often silenced, and placing
    insulators upstream and downstream of that gene
    can protect the gene from silencing.

46
  • 4 Appropriate regulation of some groups of genes
    requires locus control region (LCR).
  1. Human and mouse globin genes are clustered in
    genome and differently expressed at different
    stages of development
  2. A group of regulatory elements collectively
    called the locus control region (LCR), is found
    30-50 kb upstream of the cluster of globin genes.
    It binds regulatory proteins that cause the
    chromatin structure to open up, allowing access
    to the array of regulators that control
    expression of the individual genes in a defined
    order.

47
Figure 17-13
Please compare LCR with the Lac operon controlled
gene expression in bacteria
48
  • Another group of mouse genes whose expression
    is regulated in a temporarily and spatially
    ordered sequence are called HoxD genes. They are
    controlled by an element called the GCR (global
    control region) in a manner very like that of LCR.

49
CHAPTER 17 Gene Regulation in eukaryotes
??????????(?????)????
Topic 3 Transcriptional Repressor its
regulation
In eukaryotes, most repressors do not repress
transcription by binding to sites that overlap
with the promoter and thus block binding of
polymerase. (Bacteria often do so)
50
  • Commonly, eukaryotic repressors recruit
    nucleosome modifiers that compact the nucleosome
    or remove the groups recognized by the
    transcriptional machinery contrast to the
    activator recruited nucleosome modifers, histone
    deacetylases (????????) removing the acetyl
    groups. Some modifier adds methyl groups to the
    histone tails, which frequently repress the
    transcription.
  • This modification causes transcriptional
    silencing.

51
  • Three other ways in which an eukaryotic repressor
    works include
  • Competes with the activator for an overlapped
    binding site.
  • Binds to a site different from that of the
    activator, but physically interacts with an
    activator and thus block its activating region.
  • Binds to a site upstream of the promoter,
    physically interacts with the transcription
    machinery at the promoter to inhibit
    transcription initiation.

52
Competes for the activator binding
Inhibits the function of the activator.
Figure 17-19 Ways in which eukaryotic repressor
work
53
Binds to the transcription machinery
Recruits nucleosome modifiers (most common)
54
  • A specific example Repression of the GAL1 gene
    in yeast

In the presence of glucose, Mig1 binds to a site
between the USAG and the GAL1 promoter, and
recruits the Tup1 repressing complex. Tup1
recruits histone deacetylases, and also directly
interacts with the transcription machinery to
repress transcription.
55
CHAPTER 17 Gene Regulation in eukaryotes
???????????????????? Features of the eukaryotic
transcriptional regulation signal integration
and combinatorial control
Topic 4 Signal Integration and Combinatorial
Control
56
1. Activators work together synergistically (???)
to integrate signals.
???????????????
57
Review the Lac operon control in bacteria. Two
signals are integrated to control Lac expression
Glucose
Lactose
Figure 16-6
58
  • In multicellular organisms, signal integration
    (????) is used extensively. In some cases,
    numerous signals are required to switch a gene
    on. However, each signal is transmitted to the
    gene by a separate regulator, and therefore,
    multiple activators often work together, and they
    do so synergistically (two activators working
    together is greater than the sum of each of them
    working alone.)

59
Three strategies of the synergy (???????) S1
Multiple activators recruit a single component of
the transcriptional machinery. For example, by
touching the different part of the mediator
complex (??????). The combined binding energy has
an exponential effect on recruitment. S2
Multiple activators each recruit a different
component of the transcriptional machinery. These
components binds to the promoter DNA
inefficiently without help.
60
S3 Multiple activators help each other bind to
their sites upstream of the gene they control.
(Figure 17-14)
61
  • a.Classical cooperative binding.
  • b. Both proteins interacting with a third
    protein.
  • c. The first protein recruit a nucleosome
    remodeller whose action reveal a binding site for
    the second protein.
  • d. Binding a protein unwinds the DNA from
    nucleosome a little, revealing the binding site
    for another protein.

Figure 17-14 Cooperative binding of activators
62
2. Signal integration the HO gene is controlled
by two regulators one recruits nucleosome
modifiers and the other recruits mediator.
S3???example
The HO gene is only expressed in mother cells and
only a certain point in the cell cycle, resulting
in the budding division feature of yeast S.
cerevisiae (????). The mother cell and cell cycle
conditions (signals) are communicated to the HO
gene (target) by two activators SWI5 and SBF
(communicators).
63
  • SWI5 acts only in the mother cell and binds to
    multiple sites some distance from the gene
    unaided, which recruit enzymes to open the SBF
    binding sites.
  • SBF only active at the correct stages of the
    cell cycle, and cannot bind the sites unaided.

(??? ????)
Alter the nucleosome
Figure 17-15
64
Figure 17-14 Cooperative binding of activators.
(c) The first protein recruit a nucleosome
remodeller whose action reveal a binding site for
the second protein.
65
3. Signal integration Cooperative binding of
activators at the human b-interferon gene.
S3???example
The human b-interferon gene (target gene) is
activated in cells upon viral infection (signal).
Infection triggers three activators
(communicator) NFkB, IRF, and Jun/ATF.
Activators bind cooperatively to sites adjacent
to one another within an enhancer located about 1
kb upstream of the promoter, which forms a
structure called enhanceosome.
66
(??b?????)
  1. Activators interact with each other
  2. HMG-I binds within the enhancer and aids the
    binding of the activators (bends the DNA to
    promote the activator interaction)

Figure 17-16
67
HMG-I is constitutively active in the cells, and
play an architectural role in the INF-b gene
activation process.
68
Figure 17-14 Cooperative binding of activators.
(a)Classical cooperative binding through direct
interaction between the two proteins.
69
4. Combinatory control (????) lies at the heart
of the complexity and diversity of eukaryotes, in
which Both activators and repressors work
together.
?????????????????????????????????????????,????????
???????
70
  • In bacteria
  • A regulator (CAP) works together with different
    repressors at different genes, this is an example
    of Combinatorial Control.
  • In fact, CAP acts at more than 100 genes in
    E.coli, working with an array of partners.

71
There is extensive combinatorial control in
eukaryotes.---A generic picture
Four signals
Figure 17-18
Three signals
In complex multicellular organisms, combinatorial
control involves many more regulators and genes
than shown above. Both activators and repressors
can be involved.
72
5. An example combinatory control of the
mating-type genes from S. cerevisiae
(?????????????)
73
  • The yeast S. cerevisiae exists in three forms
  • ---two haploid cells (???) of different mating
    types- a and a.
  • ---the diploid cells (???) (a/a) formed when an a
    and an a cell mate
  • and fuse.
  • Cells of the two mating types (a and a) differ
    because they express different sets of genes a
    specific genes and a specific genes.

74
  • a cells make the regulatory protein a1,
  • a cells make the protein a1 and a2.
  • Both cell types express the fourth regulator
    protein Mcm1 that is also involved in regulatory
    the mating-type specific genes.
  • How do these regulators work together to keep a
    cell in its own type? Figure 17-19

75
Figure 17-19 Control of cell-type specific genes
in yeast
76
CHAPTER 17 Gene Regulation in eukaryotes
??????????????????? Signal transduction---A life
science frontier centered on the eukaryotic
transcriptional regulation.
Topic 5 Signal Transduction (????) and the
Control of Transcriptional Regulators
77
Topic 4 Signal Transduction and the Control of
Transcriptional Regulators
1. Signals are often communicated to
transcriptional regulators through signal
transduction pathway
??????????????????????
78
  • Environmental Signals/Information (??)
  • 1. Small molecules such as sugar, histamine
    (??).
  • 2. Proteins released by one cell and received by
    another.
  • In eukaryotic cells, most signals are
    communicated to genes through signal transduction
    pathway (indirect), in which the initiating
    ligand is detected by a specific cell surface
    receptor.
  • What about in bacteria?

79
Signal transduction pathway
1. The initial ligand (signal) binds to an
extracellular domain of a specific cell surface
receptor
2. The signal is thus communicated to the
intracellular domain of receptor (via an
allosteric change or dimerization )
  • 3. The signal is then relayed (????) to the
    relevant transcriptional regulator.

4. The transcriptional regulator control the
target gene expression (topic 2-4).
80
  • a. The STAT pathway

b. The MAP kinase pathway
Figure 17-22Signal transduction pathway
81
Topic 4 Signal Transduction and the Control of
Transcriptional Regulators
2. Signals control the activities of eukaryotic
transcriptional regulators in a variety of ways.
???????????????????
82
  • Mechanism 1 unmasking an activating region
    (Topic 2 3)
  • A conformational change to reveal the previously
    buried activating region.
  • Releasing of the previously bound masking
    protein. Example the activator Gal4 is
    controlled by the masking Gal80) (Fig.17-23).
  • Some masking proteins not only block the
    activating region of an activator but also
    recruit a deacetylase enzyme to repress the
    target genes. Example Rb represses the function
    of the mammalian transcription activator E2F in
    this way. Phosphorylation of Rb releases E2F to
    activate the target gene expression.

83
  • Activator Gal4 is regulated by a masking protein
    Gal80

Gal4
Figure 17-23
84
  • Mechanism 2 Transport into and out of the
    nucleus (Fig.17-21)
  • When not active, many activators and repressors
    are held in the cytoplasm. The signaling ligand
    causes them to move into the nucleus where they
    activate transcription (Fig.19-4b).

85
  • Other Mechanisms 1 A cascade of kinases that
    ultimately cause the phosphorylation of regulator
    in nucleus (new) (Fig.19-4a).

86
  • Other Mechanisms 2 The activated receptor is
    cleaved by cellular proteases (???), and the
    c-terminal portion of the receptor enters the
    nuclease and activates the regulator
    (new)(Fig.19-4c).

87
CHAPTER 17 Gene Regulation in eukaryotes
Topic 6 Gene Silencing by Modification of
Histones and DNA
88
  • Transcriptional silencing is a position effect.
    (1) A gene is silenced because of where it is
    located, not in response to a specific
    environmental signal. (2) Silencing can spread
    over large stretches of DNA, switching off
    multiple genes, even those quite distant from the
    initiating event.

89
  • The most common form of silencing is associated
    with a dense form of chromatin called
    heterochromatin.
  • Heterochromatin is frequently associated with
    particular regions of the chromosome, notably the
    telomeres, and the centromeres.
  • In mammalian cells, about 50 of the genome is
    estimated to be in some form of heterochromatin.

90
  • Transcriptional silencing is associated with
    Modification of nucleosomes that alters the
    accessibility of a gene to the transcriptional
    machinery and other regulatory proteins.
  • The modification enzymes for silencing include
    deacetylases, DNA methylases.

91
Topic 6 Gene Silencing by Modification of
Histones and DNA
6-1. Silencing in yeast is mediated by
deacetylation and methylation of the histones
??????????????????????????
92
  • The telomeres, the silent mating-type locus, and
    the rDNA genes are all silent regions in S.
    cerevisiae.
  • Three genes encoding regulators of silencing,
    SIR2, 3, and 4 have been found (SIR stands for
    Silent Information Regulator).

Rap1 recruits Sir complex to the temomere. Sir2
deacetylates nearby nucleosome.
Fig. 17-24. Silencing at the yeast telomere
93
Silencing specificity is determined by Rap1, the
telomere DNA-binding protein. It can also be
determined by RNA molecules using RNAi machinery
(Chapter 18). The spreading of silencing is
restricted/controlled by insulators and other
kind of histone modifications that block binding
of the Sir2 proteins.
94
  • Transcription can also be silenced by methylation
    of DNA by histone methyltransferase (H3 and H4,
    Chapter 7).
  • This enzyme have been recently found in yeast,
    but is common in mammalian cells. Its function is
    better understood in higher eukaryotes.
  • In higher eukaryotes, silencing is typically
    associated with chromatin containing histones
    that both deacetylated and methylated.

95
Topic 6 Gene Silencing by Modification of
Histones and DNA
6-2. In Drosophila, HP1 recognizes Methylated
Histones and Condense Chromatin.
????,HP1???????????????????
96
  • HP1 protein is a component of heterochromatin in
    Drosophila that binds to methylated residue in
    histone H3.
  • Such a histone modification is produced by
    Su(Var)3-9.
  • Different types of modification at the histones
    can be involved in distinct gene regulation. What
    will happen when multiple forms of modification
    occur? ---A Histone Code hypothesis.

97
  • Box 17-4 Is there a histone code?
  • According to this idea, different patterns of
    modification on histone tails can be read to
    mean different things. The meaning would be the
    result of the direct effects of these
    modifications on chromatin density and form.
  • But in addition, the particular pattern of
    modifications at any given location would recruit
    specific proteins.

98
Topic 6 Gene Silencing by Modification of
Histones and DNA
6-3. DNA Methylation Is Associated with Silenced
Genes in Mammlian cells.
DNA?????????????????????DNA????????????
Some mammalian genes are kept silent by
methylation of nearby DNA sequences.
99
  • Large regions of mammalian genome are marked by
    methylation of DNA sequences, which is often seen
    in heterochromatic regions. Why?
  • The methylated DNA sequences are often
  • recognized by DNA-binding proteins (such as
    MeCP2) that recruit histone decetylases and
    histone methylases, which then modify nearby
    chromatin.
  • Thus, methylation of DNA can mark sites where
    heterochromatin subsequently forms (Fig. 17-25).

100
Fig. 17-25 Switching a gene off through DNA
methylation and the subsequent histone
modification
101
  • DNA methylation lies at the heart of Imprinting
  • Imprinting- in a diploid cell, one copy of a gene
    from the father or mother is expressed while the
    other copy is silenced.
  • Two well-studied examples human H19 and
    insulin-like growth factor 2 (Igf2) genes

102
Enhancer activate both gene transcription ICR
an insulator binds CTCF protein and blocks the
activity of the enhancer on Igf2.Methylation of
ICR allows the enhancer to activate Igf2. H19
repression is mediated by DNA methylation and the
subsequent MeCP2 binding to the methylated ICR
Figure 17-26 Imprinting
103
CHAPTER 17 Gene Regulation in eukaryotes
Topic 7 Epigenetic Regulation
104
  • Patterns of gene expression must
  • sometimes be inherited.
  • After the expression of specific genes in a set
    of cells are switched on by a signal, these
    genes may have to remain switched on for many
    cell generations, even if the signal that induced
    them is present only fleetingly (???).
  • The inheritance of gene expression patterns, in
    the absence of both mutation and the initiating
    signal, is called epigenetic regulation.

105
Topic 7 Epigenetic Regulation
Some States of Gene Expression Are Inherited
through Cell Division Even When the Initiating
Signal Is No Longer Present
????????????????????????????
106
  • DNA methylation provides a mechanism of
    epigenetic regulation. DNA methylation is
    reliably inherited throughout cell division Fig.
    17-28 .
  • Certain DNA methylases can methylate, at low
    frequency, previously unmodified DNA but far
    more efficiently, the so-called maintenance
    methylases modify hemimethylated DNA-the very
    substrate provided by replication of fully
    methylated DNA.
  • A link with reprogramming of somatic cells into
    Embryonic Stem-like cells. Box 17-6

107
  • Figure 17-28 Patterns of DNA methylation can be
    maintained through cell division

108
Key points of the chapter
  • TOPIC 1 Conserved structures of eukaryotic
    transcription activators (2 separable domains and
    2 techniques).
  • TOPIC 2 Recruitment of Protein Complexes to Genes
    by Eukaryotic Activators. (two classes of
    complexes ) (2 techniques)
  • TOPIC 3 Transcriptional Repressors (4 ways of
    repression)
  • TOPIC 4 two examples of signal integration and
    one example of combinatorial control.

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  • TOPIC 5 Common pathway of signal transduction
    and 4 different ways to Control transcriptional
    Regulators. Two examples (STAT, MAPK)
  • TOPIC 6 Gene Silencing by Modification of
    Histones and DNA (Yeast telomere, YP1 in
    Drosaphila, DNA methylation in mammalian,
    imprinting example HP19-Igf2).
  • TOPIC 7 Epigenetic Gene Regulation concept, the
    inheritance of DNA methylation.
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