Chromatin Features and Gene Expression

1. Chromatin Features and Gene Expression ENCODE AWG, March 2011 Zhiping, Gernstein, Guigo

2. goals • 1 figure with panels in the main paper • Chromatin marks in transcription • Chromatin marks in splicing • Evidence for the relationship between transcription and splicing • Companion paper(s) • Specific calls. Gernstein, Zhiping, Guigo, everybody interested.

3. messages • Expression (transcription) levels from chromatin status can be predicted quite accurately • Even with very simple linear models involving few modifictions • In same cases, quite impressively (?) • The model relating chromatin modifications with gene expression is broadly independent from cell line • H3K79me2 • H3K9ac • H3K27ac • H3K4me3

4. messages • Chromatin status plays a role (maybe weak, but a role) in alternative splicing • Splicing is intimately coupled to transcription (can we quantify this?)

5. Prediction transcription levels based on chromatin marks • Transcription levels can be measured • Different RNA fractions • polyA+, polyA-, nuclear, cytosol, whole cell • Different technologies • CAGE, RNASeq, ditags • Different cell lines • In principle, CAGE in nuclear polyA- should provide the most accurate read out of the action of transcription

7. Future work • Gernstein/Zhiping model on exactly the same RNA datasets. Compare SVM with linear model • Train model in one cell line and test in all others • Subdivide gene classes according to regulation model • Protein coding genes vs long non coding RNAs • Investigate features that may impact the model • Levels of gene expression, GC content, etc • Investigate behaviour in novel TSS • CAGE clusters classified in TSS or post-processing sites (Timo Lassmann). • Can we use histone marks to identify novel promoters?

8. Future work • Model expression as a function of TF binding. • How to relate TF binding with chromatin modifications with transcription/expresion.

9. Promoter vs Enhancer A Basal Promoter Model B Enhancer Model C Chroperon Model p g e p g p g e p g chr1:173829000-173844000 chr6:28850000-28961000 chr2:220000000-220180000 1 2 • Identify promoter to promoter connections by ChIA-PET • Correlate chromatin marks in the distal promoter with gene expresion. • Cooperativity beetween the proximal and distal promoters trigering transcription 3 F Number of chromatin structures D 930 (15%) E BP e p g p g g p g p e chr17:80150000-80430000 C 3967 (64%) 1329 (21%) 1 Number of genes involved 2 1103 (6%) E 11778 (66%) C 3 BP 4973 (28%) 200 C 00 50 1M 10K 100K 10M

10. Differential exon inclusion correlates with differential histone modifications EXON INCUSION BLUE: GM12878 > K562 RED: K562 > GM12878 DIFFERENTIAL H3k9ac OCCUPANCYacross the Acceptor Site GM12878-K562 “CONSTITUTIVE” EXON “CONSTITUTIVE” EXON ALTERNATIVE EXON

11. Chromatin marks in alternative splicing

12. Predicting exon inclusion from histone modifications

13. Quantitative predictions: Linear models

14. Future work • For each histone mark, identify the region across the exon that has major influence in • Exon specific models. Histone Modifiations may play a role only on the inclusion of a subset of exons

15. Qualitative predictionsDecission Trees

16. Evidence for co-transcriptional splicing

17. Evidence for co-transriptional splicing • Compare COSI in polyA- nuclear and PolyA+ cytosol. Across all cell lines d e c