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Chromatin Modification

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Title: Chromatin Modification


1
Chromatin Modification
Reading Seminar in Computational Biology Naomi
Habib 5.1.2006
2
Chromatin Structure
Nucleosome (histone octamer wrapped with 146 bp
of DNA).
3
Chromatin Roles
  • Compactization
  • Packing 2 meters of DNA in to a 10 micron
    diameter nucleus.
  • Different compactization levels euchromatin and
    heterochromatin.
  • Regulation of gene expression
  • Influencing DNA accessibility through Nucleosome
    Occupancy.
  • Histone variants.
  • Nucleosome tail modifications.
  • Co-regulation Effect common chromatin regions.
  • Regulation of DNA replication, repair,
    recombination and more

4
Nucleosome tail modifications
  • Lysine acetylations.
  • Histone Acetyl-Transferases (HAT) Histone
    Deacetylases (HDAC).
  • Lysine and Argenine Metylations.
  • Modified by histone-metyl-transferase.
  • Phosphorilation.
  • Ubiquitination.
  • H2A ubiquitination affects 10-15 of this
    histone in most eukaryotic cells
  • ADP-ribosylation.

5
Possible regulation mechanisms
  • Histone modifications modulate the accessibility
    of DNA through structural changes of the
    chromatin (Horn and Peterson, 2002 Tse et al.,
    1998).
  • Modifications on different residues provide
    specific binding surfaces for transcription
    regulators. (Kurdistani and Grunstein, 2003
    Corona et al., 2002 Deuring et al., 2000).
  • Histone code? number, variety, and
    interdependence of modifications.
  • Part of the process of protein signaling, promote
    switch-like behavior and ensure robustness of the
    signal (Schreiber and Bernstei,2002).
  • Epigenetic inheritance of information histone
    modifications pattern inherited partially by the
    daughter cell (Jenuwein T Allis C.D. 2001).

6
Articles Outline
  • Mapping Global Histone Acetylation Patterns to
    Gene ExpressionKurdistani,1 et al. Cell, June
    2004.
  • Genome-wide Map of NucleosomeAcetylation and
    Methylation in YeastPokholok Et al. Cell, August
    2005.
  • Genomic Maps and Comparative Analysis of Histone
    Modifications in Human and MouseBernstein et al.
    Cell January 2005.

7
MethodsChip-Chip (Location analysis)
8
Previous studies
  • Yeast nucleosomes occupancy is less dense in
    intergenic regions than ORF. (Lee et al., 2004).
  • Promotores and coding regions of transcribed
    genes had lower nucleosome occupancy (Lee et al.,
    2004).
  • Many works focusing on one or two Lysine residues
    or on a few genomic loci
  • Acetylation of Lysine residues on H3 and H4
    primarily associated with gene activation.
    (Grunstein,1997.Braunstein et at., 1993)
  • histone methylation associated with
    transcriptional activity or repression, depending
    on the specific residue (Zhang and Reinberg,
    2001).

9
Previous studies (continued)
  • Genome wide analysis in D. melanogaster revealed
    parallel action of several active modifications
    all linked to one another and to transcription
    levels (Schubeler D. et al, 2004)
  • Genome wide mapping of HATs and HDACs binding
    sites (review by Bas Van Steensel, 2005).
  • HATs bind to all active promoters.
  • HDACs have a preferences for distinct gene
    classes

10
Mapping Global Histone Acetylation Patterns to
Gene ExpressionSiavash K. Kurdistani,1 Saeed
Tavazoie,2, Michael Grunstein1Cell, June 2004
11
Description of the work
  • Determining acetylation level of 11 Lysine
    residues in Saccharomyces cerevisiae.
  • Location analysis Intergenic region ORF
    arrays.
  • Normalizing the data for each array and
    variance-normalized across 11 sites arrays.
  • Clustered the data into clusters of
    modifications state.
  • Checked in each cluster
  • Enrichment of co-expressed genes
  • Enrichment of genes from specific functional
    categories.
  • Search for unique cis DNA motifs.
  • Enrichment for binding of specific transcription
    factors.

12
Results
  • Lysines Acetylations are positively and
    negatively correlated.
  • H4K8 and K12 are strongly correlated in IGRs and
    ORFs.
  • Some significant differences between IGRs and
    ORFs.
  • hyper- and hypoacetylation lysines associated
    with transcription
  • hyperacetylation of histone H3K9/18/27 but
    hypoacetylation of H4K16 and H2BK11/16 are
    correlated with transcription.

13
Results (continued)
  • Acetylation patterns define groups of
    biologically related genes.
  • co-expressed, functional categories enrichment,
    Unique DNA motifs, Specific transcription factors
    binding.
  • Clusters distinguish groups with similar
    expression in one condition and differentially
    expressed in others.
  • TF Bdf1 binding is associated with acetylation
    (specifically H4K16). ? Model Acetylation
    patterns used as surfaces for specific protein
    binding.

14
Genome-wide Map of NucleosomeAcetylation and
Methylation in Yeast
  • Dmitry K. Pokholok, Christopher T. Harbison,
  • Stuart Levine, Megan Cole, Nancy M. Hannett, P.
    Alex Rolfe, Elizabeth Herbolsheimer,Julia
    Zeitlinger,Fran Lewitter, David K. Gifford,and
    Richard A. Young.
  • Cell, August 2005

15
General Description
  • Genome-wide location analysis of nucleosome
    acetylation and methylation in Yeast.
  • Location analysis, array design
  • Tile array of 44,00 probes (85 of the genome).
  • 60-mer oligonucleotide, average probe density of
    266 bp.
  • Improved resolution and accuracy.
  • Compared Histone-modifications-antibody data to a
    control with core-histone-antibody.

16
Checking Resolution -Gcn4 Location Analysis
  • Gcn4 TF of amino acid-biosynthetic genes.
  • FPR of 1 and FNR of 25 over a set of 84
    positive and 945 negatives genes.
  • Gene sets chosen according to location analysis
    data, DNA binding site motif and 2-fold change in
    mRNA levels dependent on Gcn4.

17
Nucleosome Occupancy
  • 20 reduction on average in histone occupancy in
    intergenic sequences relative to genic sequences.
  • No difference after normalization using control
    no-antibody data
  • 40 of promoters have difference from their gene.

18
Occupancy Expression
  • Nucleosome occupancy inversely correlates with
    transcription.
  • Occupancy is reduced maximally at promoters of
    active genes.
  • In cells after oxidative stress, nucleosome
    occupancy dropped at genes know to be activated.
    ? Model gene activation leads to reduced
    nucleosome density.

19
Histone Acetylation
  • Histone acetylation enriched at promoter regions
    and transcriptional start sites of active genes.
  • Acetylation at Gcn5 targets H3K9 and H3K14 and
    Esa1 targets H4 at Lys 5,8,12 and16.
  • ? Model transcriptional activators recruit Gcn5
    and Esa1 to promoters of genes upon their
    Activation (Robert et al., 2004) .

20
Histone Acetylation
  • In general strong correlation between
    acetylation of histone H3 and H4 (targeted by
    Gcn5 and Esa1) and transcriptional activity.
  • In contrast to Kurdistani et al.
  • After oxidative stress, histone acetylation
    increased at genes know to be activated and
    targeted by Gcn5 or Esa1.

21
Histone Metylation (H3K4me)
  • Previously shown methyltransferase Set1
    recruited to the 5 end of actively transcribed
    genes targets H3K4.
  • H3K4me3 peaks at beginning of genes, with high
    correlation to transcription rates.
  • H3K4me2 is enriched in the middle of genes, and
    H3K4me at the end of genes.

22
Histone Metylation (H3K36me3)
  • Previously shown H3K36 trimethylation targeted
    by Set2 (associated with the later stages of
    elongation).
  • H3K36me3 enriched throughout the coding region,
    peaking near the 3 ends, correlated with
    transcription.
  • ? model Set2 is recruited by the elongation
    apparatus and that it methylates during active
    transcription.

23
Histone Metylation (H3K79me3)
  • Previously shown The Dot1 histone
    methyltransferase modifies H3K79, within the core
    domain in 90 of all H3.
  • H3K79me3 enriched within the transcribed regions
    of genes with little correlation to
    transcription.

24
Genomic Maps and Comparative Analysis ofHistone
Modifications in Human and Mouse
  • Bradley E. Bernstein, Michael Kamal, Kerstin
    Lindblad-Toh, Stefan Bekiranov, Dione K. Bailey,
    Dana J. Huebert, Scott McMahon, Elinor K.
    Karlsson, Edward J. Kulbokas III, Thomas R.
    Gingeras, reStuart L. Schreiber, and Eric S.
    Lander.
  • Cell, January 2005.

25
General Description
  • Maping the nonrepetitive portions of human
    chromosomes 21 and 22 for H3 Lys 4
    di-,tri-methylation and Lys 9/14 acetylation.
  • Hepatoma cell line.
  • Compared lysine 4 dimethylation for several
    orthologous human and mouse loci.
  • cytokine cluster, IL-4 receptor region, and all
    four Hox clusters.
  • human and mouse primary fibroblasts.
  • Location analysis using tile arrays at 35 bp
    intervals.
  • Assessing results and threshold reliability using
    real time PCR.

26
Maps of Histone Modifications
  • Genomic maps that detail more than 39Mbp.
  • Modification sites cover 1 of the nonrepetitive
    portion of chromosome 21 and 22.
  • ChiP sample compared to whole genome DNA.
  • Relatively Uniform Histone Density across the
    Chromosomes.
  • no depletion on active promoters detected.

27
Di-,Tri-methylated H3K4
  • Trimethyl Lys4 Correlate with 5 Ends of active
    Genes.
  • 1 kb upstream to TSS of known genes / predicted
    genes / proximal to mRNA hybridization on the
    tile array.
  • 5 end significantly enriched (6- to 8-fold) for
    polII Ser5-phosphorylated CTD. ? possible
    mechanism.
  • Dimethyl Lys4 Sites in the Vicinity of Active
    Genes and dependent on cell type. ? novel markers
    for cell state?

28
H3 Acetylation
  • H3 Acetylation Enriched at 5 Ends of Genes and
    Strongly Correlates with Lys4 Methylation.
  • Consistent with previous studies.
  • ? Systematic colocalization of methyl and acetyl
    marks reflect recruitment of complexes containing
    methylases and acetylases, and/or crosstalk
    between modifications.

29
Conservation
Sequence identity
cytokine and IL4R regions
  • Lys4-Methylated Sites Show Stronger Conservation
    of Location than Underlying Sequence.
  • Conserved 7-fold higher than expected at random.

30
Unique Profile for HOX Clusters
  • Broad Methylated Regions Overlay Substantial
    Portions of the Human and Mouse Hox Clusters
  • For example 60kb region in HOXA with 85 K4me2.

31
HOX clusters (continued)
  • distinct expression patterns in other fibroblast
    lineage.
  • ? lineage-dependent active chromatin domains
    created at differentiation to maintain
    expression.
  • Detected transcription at 33 of methylated
    intergenic bases, 10 in nonmethylated.
  • - hybridizing RNA to the tiling arrays.

32
Summary
  • Nucleosome Occupancy
  • Human Uniform punctate Histone Density.
  • Yeast Reduced histone occupancy in IGRs relative
    to ORFs.
  • Histone acetylation
  • Human Enriched at 5 Ends of Genes.
  • Yeast Enriched at promoter regions and TSS of
    active genes.
  • Histone methylation
  • Human Yeast H3K4me3 peaks at 5 Ends of active
    Genes.
  • Human H3K4me2 in the Vicinity of Active Genes. /
    Yeast H3K4me2 enriched in middle of genes
  • Yeast Additional data regarding H3K4me 3K79me3
    and H3K36me3.
  • Conservation
  • Human Mouse H3K4me show stronger conservation
    of location than underlying sequence.
  • HOX cluster
  • Human Mouse Broad methylated
    lineage-dependent regions

33
Open questions
  • How are the acetylation patters established?
  • In IGRs may involve recruitment of specific sets
    of HATs and HDACs.
  • In ORFs determined by promoter regulatory motifs
    or association of HATs and HDACs with the RNAPII
    (elongating complex or Ser5-phosphorylated CTD).
  • What is the regulatory mechanism? Does the
    histone code exist?
  • ?

34
(No Transcript)
35
Kurdistani - additional data
36
Kurdistani - additional data
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