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Eukaryotic Gene Regulation

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Small fraction of genes are used in each cell but they all have the same genes ... put adult nuclei in an egg cell and can get tadpole development. clone ... – PowerPoint PPT presentation

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Title: Eukaryotic Gene Regulation


1
Chapter 23
  • Eukaryotic Gene Regulation

2
Levels of Regulation
  • 5 main levels
  • genome level
  • transcription level
  • RNA processing and export
  • translation level
  • post-translational events
  • Last 3 are also categorized as post-transcriptiona
    l controls

3
Genome Control
  • Small fraction of genes are used in each cell but
    they all have the same genes
  • except sperm and egg cells haploid
  • Nucleus is totipotent
  • put adult nuclei in an egg cell and can get
    tadpole development
  • clone
  • Can do in plants by isolating a single cell and
    grow in a dish without transplanting nucleus into
    a new cell

4
Gene Amplification
  • Selective amplification of certain genes
  • Genomic control as regulates the change in the
    make of the structural organization of genome
  • rRNA genes in Xenopus usually number 500 copies
    for each gene but during oogenesis they increase
    4000x
  • needed for the amount of ribosomes that are
    needed to make the proteins

5
rRNA Genes
  • Present as circles in the nucleoli
  • Use RNA rather than protein as to get abundant
    protein we can use the mRNA over and over to get
    enough protein

6
Additional Genome Modification
  • Some organisms will delete genes they no longer
    need
  • RBCs remove all DNA once they have enough mRNA
    for hemoglobin for their lifespan
  • Copopods get rid of heterochromatin in all cells
    with the exception of cells destined to become
    gamates

7
DNA Rearrangement
  • Alter the genome
  • See in yeast that control mating and vertebrates
    that make antibodies

8
Yeast Mating Type
  • 2 haploid cells meet and fuse
  • both a and ? genes are present in the HML? and
    HMRa locus but mating type is dependent on which
    gene is in the MAT locus
  • can get DNA rearrangement to change the mating
    type cassette movement
  • SIR gene products keep the extra copies of the
    genes from being expressed to keep from altering
    the phenotype
  • ? and a encode secretory proteins and surface
    receptors

9
Ab Formation
  • Ab made of 2 heavy chains and 2 light chains
  • Proteins are made from selecting gene segments
    from a small number of segments that will yield
    numerous Ab
  • millions of combinations
  • Heavy chain use a V, J, D and C segment
  • Light chain use only the V, J and C segments

10
Recombination Aides Transcription
  • Enhancer region is near the C segments but the
    promoter is upstream of the V region
  • Need enhancer to activate transcription of Ab
    genes into mRNA and prior to rearrangement, the
    enhancer and promoter are too far apart to work
    together

11
Genome Decondensation
  • Need some degree of chromatin infolding to get
    the necessary transcription machinery access to
    the DNA
  • Saw first in fruit fly salivary glands
  • cell becomes larger and daughter strands are not
    separated into new cells but rather, remain
    attached to form polytene chromosomes

12
Polytene Chromosomes
  • See areas of highly condensed inactive DNA and
    areas that are open and not so condensed
  • Green areas are areas of transcription
    fluorescent Ab to RNA polymerase

13
Chromosomal Puffs
  • Puffs are large areas of decondensed DNA that is
    being actively transcribed
  • Under the influence of ecdysone insect steroid
    hormone that triggers transcription

14
DNase 1 Sensitivity
  • DNase I is an endonuclease that degrades dsDNA
    that is not protected by proteins (histones)
  • Active genes will be degraded and others left
    untouched
  • tissue specific in terms of DNA being degraded

15
Chromatin Changes
  • Chromatin uncoiling is prerequisite for DNA
    transcription
  • DNase 1 hypersensitivity is common upstream of
    transcription start sites and are 10x more
    susceptible to DNase 1 that other DNA
  • usually no chromatin present to protect the DNA
  • area of hypersensitivity


16
DNA Methylation
  • Methylation of various Cytosine residues in DNA
  • most vertebrates contain small amount -CH3 in the
    non-coding regions _at_ 5 end of genes
  • -CH3 of the parent strand will dictate the -CH3
    of new daughter strand
  • Epigenetic changes change the gene expression
    without altering the DNA sequence

17
X Chromosome
  • Most recognized -CH3 DNA sequence
  • 2nd X-chromosome is heavily -CH3 and this causes
    the chromosome to become a tight mass of
    heterochromatin called a Barr Body
  • same X remains inactive for the all descendents
    of that cell following Barr Body formation in
    embryogenesis

18
Methylation
  • Can use restriction enzymes to determine -CH3
    patterns as on the same gene in different tissues
    they are specific
  • Usually inactive genes are -CH3 and active are
    not
  • -CH3 prevents transcription
  • not always true, some active genes are -CH3 while
    some un-CH3 genes are inactive
  • Methylation is one of many factors regulating
    gene expression

19
Changes in Histones
  • Acetylation is the addition of an acetyl group to
    the R groups on histone amino acids
  • See increase in acetylation in active gene areas
  • Treat cells with Na Butyrate increases the
    acetylation and causes changes in nucleosome
    formation and DNA becomes more susceptible to
    DNase 1 activity
  • Phosphorylation and -CH3 also can influence gene
    expression
  • no acetyl or methyl group leads to
    heterochromatin formation
  • H1 histone absence also leads to transcription
  • the looser the packing of DNA the more accessible
    to RNA polymerase and other machinery

20
High-Mobility Group (HMG) Proteins
  • Non-histone proteins that move rapidly in
    electrophoresis
  • Remove the HMG proteins and loose gene activity
  • add HMG protein from a different tissue, get gene
    expression similar to that cell type
  • tissue specific proteins

21
Association With Nuclear Matrix
  • Active genes are found in association with the
    nuclear matrix
  • DNA sequences called matrix attachment regions
    (MARs) hold the active genes near the nuclear
    matrix

22
Transcriptional Control
  • 2nd main level of control
  • Different gene sets in different cell types
  • See differential gene expression in different
    cells
  • see a different set of proteins in different
    cells so you would assume a different set of
    nuclear RNA in those cells if it was
    transcriptional control rather than translational
    control

23
Nuclear Run-On Transcription
24
RNA Determination
  • Northern analysis can tell how much mRNA is being
    made in a cell
  • Use microarrays now for more information and no
    radioactivity
  • Normal green
  • Abnormal red
  • Yellow equal
  • Black none

25
Proximal Control Elements
  • Close to the promoter, may be upstream or
    downstream depending on gene
  • Seen in protein-coding genes that require RNA
    polymerase II
  • Transcription factors are responsible for
    determining the start of transcription, not RNA
    pol II
  • transcription factor is not part of pol like
    sigma factor in prokayotes
  • Transcription factors and pol assemble at only
    the core promoter, get basal level of
    transcription

26
3 Common Types
  • CAAT box, GC box and the octamer
  • Transcription factors bind outside core promoter
    are called regulatory TF
  • usually increase transcription or may decrease
  • Combination of reg. TF and proximal control
    elements is specific to each gene

27
Enhancers/Silencers
  • Lie variable distances from the core promoter and
    proximal control elements
  • near or great distance
  • upstream or downstream
  • can even be in a reverse orientation
  • Enhancer stimulates expression of gene
  • Silencer inhibits expression of gene

28
Enhancers
  • Sequence varies but have common properties
  • Octamer and GC box can also act as enhancer
    region
  • TF that bind enhancers are called activators
  • Study by moving enhancer around and see what
    happens to gene expression levels

29
Silencers
  • Bind reg. TF and repress gene expression
  • TF is called a repressor
  • SIR gene products is a repressor and HML? and
    HMRa are the silencers

30
Coactivators
  • Reg. TF and RNA pol complex
  • Enhancer loops around to be near promoter and
    coactivator proteins mediate the interaction
  • Coactivators make the promoter more accessible to
    the pol complex

31
Coactivator Molecules
  • Histone acetyl transferase (HAT) acetylates
    histones and nucleosome decondenses
  • Chromatin remodeling proteins
  • SWI/SNF different families
  • Mediator bridge both activator proteins and
    enhancer along with RNA pol II

32
Mediator
  • Activator bind enhancer and form an enhanceosome
    that causes DNA to bend
  • Enhanceosome interacts with SWI/SNF and HAT to
    alter chromatin structure
  • Activator binds mediator and positions the RNA
    pol and TF for transcription

33
  • Hunter is awesome

34
Combinatorial Model
  • Multiple DNA control elements and TF in
    combinations establish a specific and precise
    control of gene expression
  • General TF and reg. TF used for constitutive
    genes and frequently used genes
  • Tissue specific genes have TF or combinations of
    them are unique for that cell type

35
(No Transcript)
36
Structural Motifs
  • Portions of TF that bind DNA and activate or
    repress transcription
  • Regulatory factors have 2 activities in separate
    protein domains
  • bind specific DNA sequence DNA binding domain
  • ability to regulate transcription transcription
    regulation or activation domain

37
Activation Domain
  • Figured out using swapping experiments
  • take DNA binding domain and place in various
    parts of TF
  • see gene expression only if the activation domain
    was present
  • Activation domain has a high proportion of acidic
    amino acids on one side of the ? helix
  • mutations that increase acidity increases
    expression
  • mutations that decrease acidity decrease
    expression

38
DNA Binding Domains
  • 2 structure or motif
  • 4 common patterns
  • helix-turn-helix
  • zinc finger
  • leucine zipper
  • helix-loop-helix

39
Helix-Turn-HelixMotif
  • 2 ? helices and a turn
  • 1 ? helix is recognition helix and binds by
    H-bonds
  • 1 ? helix stabilizes structure with hydrophobic
    interactions

40
Zinc Finger Motif
  • ? helix and 2 segments of ? sheet with a Zn
    between them on a Csy or His residue
  • May have 2 to several dozen per TF
  • Protrude from protein and interact with specific
    DNA sequence

41
Leucine Zipper Motif
  • 2 polypeptides (homomeric or heteromeric) with ?
    helix that has regularly spaced Leu residues
  • Form coiled-coil structure by zipping up the
    Leu
  • 2 ? helices at end of each peptide interacts with
    specific DNA sequence

42
Helix-Loop-Helix Motif
  • Short ? helix, long loop of amino acids and long
    ? helix
  • hydrophobic regions that connect 2 polypeptides
    (same or different)
  • 4 helix bundle and 2 DNA recognition sequences
    2-part DNA binding domain
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