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Transcript 
Epigenetics Continued
Xiaole Shirley Liu
STAT115, STAT215, BIO298, BIST520
Components
• DNA-methylation
• Nucleosome
position
• Histone
modifications
• Chromatin
accessibility
• Higher order
chromatin
interactions
• Analogy
Nucleosome Occupancy & Histone
Modification Influence Factor Binding
MNase-seq
Zentner & Henikoff, Nat Rev Genet 2014
MNase-seq Analysis
Park, Nat Rev Genet 2009
MNase-seq Analysis
Park, Nat Rev Genet 2009
Factors Influencing Nucleosome Positioning
• Rotational
positioning
from sequence
• Statistical positioning from
trans-factors (e.g. TF
binding)
Break
Jiang & Pugh, Nat Rev Genet 2009
Components
• DNA-methylation
• Nucleosome
position
• Histone
modifications
• Chromatin
accessibility
• Higher order
chromatin
interactions
• Analogy
Mapping Histone Modifications
• Histone tails
• Histone mark ChIP-seq
Park, Nat Rev Genet 2009
Histone Modifications
• Different modifications at different locations by
different enzymes
Histone Modifications in Relation to Gene Transcription
Bisulfite-Seq
H3K27ac
H3K4me1
H3K4me3
H3K36me3
H3K27me3
H3K9me3
RefSeq genes
SRPK1
SLC26A8
MAPK14
From Ting Wang, Wash U
Histone Modifications
• Gene body mark: H3K36me3, H3K79me3
• Active promoter (TSS) mark: H3K4me3
• Active enhancer (TF binding) mark: H3K4me1,
H3K27ac
• Both enhancers and promoters: H3K4me2,
H3/H4ac, H2AZ
• Repressive mark: H3K27me3, H3K9me3
Annotate / segment the genome based on histone
marks
12
13
lncRNA Identification
• H3K4me3 active promoters
• H3K36me3 transcription elongation
Guttman et al, Nat 2009
14
Nucleosome Occupancy & Histone
Modification Influence Factor Binding
MNase digest
Antibody for
TF
Combine Tags From All ChIP-Seq
Extend Tags 3’ to 146 nt
Check Tag Count Across Genome
Take the middle 73 nt
Use H3K4me2 / H3K27ac Nucleosome
Dynamics to Infer TF Binding Events
/ac
/ac
/ac
/ac
/ac
Condition 1
Condition 2
Nucleosome Stabilization-Destabilization (NSD) Score
He et al, Nat Genet, 2010; Meyer et al, Bioinfo 2011
19
Condition-Specific Binding,
Epigenetics and Gene Expression
C1
C1
C2
C2
• Condition-specific TF bindings are associated
with epigenetic signatures
• Can we use the epigenetic profile and TF motif
analysis to simultaneous guess the binding of
many TFs together?
Genes
TF1
TF2
TF3
Epigenetics
20
Predict Driving TFs and
Bindings for Gut Differentiation
21
Identify Major TF Modules Regulating
Gut Differentiation and Function
GATA6
Cdx2
Embryonic and organ
development genes
Cdx2
HNF4
Metabolic and
digestive genes
• Nucleosome dynamics now applied to hematopoiesis and
cancer cell reprogramming
Break
22
Verzi et al, Dev Cell, 2010
Components
• DNA-methylation
• Nucleosome
position and
histone
modifications
• Chromatin
accessibility
• Higher order
chromatin
interactions
• Analogy
DNase Hypersensitive (HS) Mapping
• DNase randomly cuts genome (more often in
open chromatin region)
• Select short fragments (two nearby cuts) to
sequence
• Map to
active
promoters
and
enhancers
Ling et al, MCB 2010
DHS Peaks
Capture Most TF
Binding Sites
• Motif occurrence in the
DHS peaks suggest TF
binding
• Quantitative signal
strength also suggest
binding stability
Thurman et al, Nat 2012
TF Network from DNase Footprint
26
DnaseI Cleavage vs Footprint
• Footprint occupancy score: FOS = (C + 1)/L + (C + 1)/R
• Smaller FOS value better footprint, for
L C R
predicting base resolution TF binding
GAT ACA
CTA TGT
27
DnaseI Cleavage vs Footprint
• Footprint occupancy score: FOS = (C + 1)/L + (C + 1)/R
• Smaller FOS value better footprint, for
L C R
predicting base resolution TF binding
• Intrinsic DNase cutting bias could
have 300-fold difference, creating fake footprints
GAT ACA
CTA TGT
CAGATA
CAGATC
…
ACTTAC
ACTTGT
0.004
0.004
1.225
1.273
28
Using DNaseI “Footprint” to
Predict TF Binding
• Using base-pair resolution cleavage pattern
(“footprint”) hurts TF binding prediction when it
is similar to intrinsic DNaseI cutting bias
29
Using DNaseI “Footprint” to
Predict Novel TF Motifs
Break
30
He et al, Nat Meth 2013
Components
• DNA-methylation
• Nucleosome
position and
histone
modifications
• Chromatin
accessibility
• Higher order
chromatin
interactions
• Analogy
HiC
• In situ HiC has excellent resolution
• Domains conserved between cells and even species
32
HiC
• Loops are
condition-specific
– Assign binding
to genes
• Convergent
CTCF at domain
anchors
– CTCF as
insulators
Epigenetics and Chromatin
34
Transcription and Epigenetic Regulation
• Stem cell differentiation
• Aging brain
• Cancer
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