heterochromatin

1. heterochromatin euchromatin (and facultative heterochromatin) Different types of chromatin • Constitutive heterochromatin: • constitute ~ 10% of nuclear DNA • highly compacted, transcriptionally inert, replicates late in S phase • Euchromatin + facultative heterochromatin: • constitute ~ 90% of nuclear DNA • less condensed, rich in genes, replicates early in S phase • however, • only small fraction of euchromatin is transcriptionally active • the rest is transcriptionally inactive/silenced (but can be activated in certain tissues or • developmental stages) • these inactive regions are also known as “facultative heterochromatin”

2. Gene silencing and why is it important • In any given cell, only a small percentage of all genes are expressed • vast majority of the genome has to be shut down or silenced • knowing which genes to keep on and which ones to silence is • critical for a cell to survive and proliferate normally

3. Gene silencing and why is it important Wolffe and Matzke, Science, 1999

4. Epigenetics and development n + n 2n DNA content Differentiation same DNA content, > 200 cell types

5. Epigenetics and development 2n DNA content De-differentiation? same DNA content, > 200 cell types examples: • Cloning by nuclear transfer --> regenerate entire organism from transfer of single nucleus (e.g. Dolly) • Induced pluripotent stem cells (iPS) --> expression of 4 genes are sufficient to transform differentiated cells to “stem” cells • Both processes must involve reprogramming of epigenome!

6. Epigenetics and epigenetic regulation Definition of Epigenetics: • heritable changes in gene expression that do not involve changes • in DNA sequences • mechanisms: • DNA methylation • histone modifications • examples: • Developmentally regulated or tissue specific gene expression • X chromosome dosage compensation • Drosophila position effect variegation (PEV)

7. Epigenetic mechanism #1: DNA methylation • DNA methylation has long been correlated with repression of gene expression • DNA methylation mostly occurs on CpG dinucleotides DNMTs methyl group is added to the cytosine methylation status is maintained during replication by DNMTs

8. Mechanism of how DNA methylation silences gene expression: • steric hindrance? • methylated DNA recruits histone de-acetylases TF DNA methylation and gene silencing

9. A class of proteins called MBD bind methylated DNA • MeCP2 is the first protein found to bind to methylated DNA • mutation of MeCP2 gene causes Rett Syndrome in humans shifted probes unmethylated probe methylated probe

10. MBD proteins interact with histone deacetylases • MBD2 and HDACs co-purify • in the same complex • MBD2 co-IPs with • HDAC activity • MBD2 physically co-IPs • with HDACs

11. DNA methylation recruits histone deacetylases

12. Epigenetic mechanism #2: histone methylation • histone H3 is methylated at several lysine residues • H3 K4-methylation is associated with transcriptional activation • whereas K9-, K27-methylation is associated with repression • these H3 methylation sites define the transcriptional/epigenetic states • of the associated genes/chromatin domains

13. Epigenetics example #1: Tissue-specific and developmentally regulated gene expression • globin genes are expressed only in erythroid cells • hemoglobin made up of 2 copies each of a- and b-chains

14. HS-40 LCR Gene order of globin clusters mirror expression pattern during development

15. Globin genes are tissue-specific and developmentally regulated • Distinct isoforms of the globin genes are expressed at different developmental stages • e.g., for the b-globin family, expression goes from e- to g- to b-isoforms • mutations in adult isoforms of globin genes result in thalassemia

16. Globin LCR and adult b-globin promoters are hyperacetylated in adult mouse erythroid leukemia cells upon induction Forsberg et al, PNAS, 2000

17. Epigenetics example #2 Dosage compensation of X chromosome • for many organisms, females have 2 copies of the X chromosome whereas males • only have single copy • how to balance expression dosage of X-linked genes?

18. bands inter-bands Drosophila polytene chromosomes • Drosophila genome has 4 chromosomes • polytene chromosomes result from endoreplication • (DNA replication without cytokinesis) • giant chromosomes that are easily visible 2048 identical DNA strands

19. X X Ac H4 DAPI (DNA) X chromosome in Drosophila • the X chromosome of male Drosophila is transcriptionally twice as active • increased transcription of the active X chromosome is marked by • hyper-acetylated histones

20. X chromosome inactivation • In female mammals, one of the two X chromosomes in the genome is transcriptionally inactivated • in order to equalize expression of X-linked genes in males and females (dosage compensation) • Inactivation of the maternal or paternal chromosome is random

21. X chromosome inactivation • In X inactivation, almost the entire X chromosome is transcriptionally silenced • Transcriptional silencing of this chromosome correlates with distinct histone modification patterns • eg. histone H4 is hypo-acetylated on the inactive X chromosome metaphase chromosome immunofluorescence Jeppesen et al, Cell, 1993

22. The inactive X chromosome is depleted of K4-methylated H3, but is enriched for K27-methylated H3 DAPI DAPI a-MeK27 H3 a-MeK4 H3 MeK4 H3 + DAPI MeK27 H3 + DAPI

23. X inactivation involves sequential epigenetic modifications of the silenced chromosome

24. w+/+ w-/- w+/+ w+/+ mosaic due to PEV Epigenetics example #3 Position effect variegation in Drosophila White gene encodes red pigment in eye

25. spreading of heterochromatin silencing leads to inactivation of white gene --> mosaic eye patches Position effect variegation in Drosophila example of epigenetic regulation since silencing of white gene is NOT due to DNA mutation, but due to translocation and spreading of heterochromatin

26. Position effect variegation in Drosophila Su(var) mutations = Suppressors of PEV e.g. Su(var)2-5 = HP1 Su(var)3-9 = SET-domain protein

27. Identification of H3 Lys9 methyltransferase • The first lysine-specific HMT was identified by IP-in vitro activity assays 1 9 • The SET domain of the SUV39H1 is required for histone methyltransferase activity • and this enzyme methylates H3 at Lys9 Rea et al, Nature, 2000

28. Identification of other H3 methyltransferases • The SET domain is the conserved catalytic core of histone methyltransferases ... ... ARTKQTARKSTGGKAPRK ARKSA H3: 4 9 27 Me Me Me Suv39H1/2 Su(var) 3-9 human Drosophila SET domain

29. Mutations of some histone methyltransferases cancer Identification of H3 methyltransferases • The SET domain is the conserved catalytic core of histone methyltransferases ... ... ARTKQTARKSTGGKAPRK ARKSA H3: 4 9 27 Me Me Me MLL Trx Suv39H1/2 Su(var) 3-9 EZH2 E(Z) human Drosophila SET domain

30. How does H3 K9-methylation functions in heterochromatin assembly? • back to early genetics studies in Drosophila: • Su(Var) 2-5 (gene) codes for heterochromatin protein 1 (HP1) • HP1 in Drosophila is localized to the chromocenter HP1 DNA

31. Ectopic expression of SUV39H1 causes redistribution of HP1 Melcher et al, MCB, 2000

32. Lys9-methylated H3 binds to the conserved motif called chromodomain • Using the peptide pull-down assay, it was found that Lys9-methylated H3 binds to • heterochromatin protein 1 (HP1) • HP1 is a protein previously identified to be enriched in and important for • heterochromatin assembly • Lys9-methylated H3 binds to HP1 via the chromodomain motif in HP1 Bannister et al, Nature, 2001

33. H3 K9-methylation is required for HP1 localization Lachner et al, Nature, 2001

34. H3 K9-methylation is required for HP1 localization Lachner et al, Nature, 2001

35. Ac ARKSTGGK ... ... H3 9 14 Histone modification-dependent recruitment of proteins Transcriptional activation TAFII250 Bromodomain

36. Histone modification-dependent recruitment of proteins Heterochromatin assembly, Transcriptional silencing Transcriptional activation HP1 TAFII250 Chromodomain Bromodomain Me Ac ARKSTGGK ... ... H3 9 14

37. Histone methylation is important for defining and maintaining epigenetic states

38. a = candidate approach identify by Western blotting b = unbiased approach identify by Mass Spec Identifying methyl-H3 binding proteins • histone peptide pulldown assay: b a ? b b a ?

39. Me Me Me ... ... ARTKQTARKSTGGKAPRK ARKSA H3: 4 9 27 Site specific methylation of the H3 tail has different functions HP1 BPTF polycomb CD CD PhD transcriptional “competence” transcription repression transcription repression euchromatin constitutive heterochromatin facultative heterochromatin

40. Heterochromatin and euchromatin constitutive heterochromatin facultative heterochromatin euchromatin K9-methylated H3 K27-methylated H3 K4-methylated H3 HP1 polycomb BPTF Yng2

41. HATs Ac-histone histone HDACs kinases Phos-histone histone phosphatases Different dynamics of histone modifications highly dynamic HMT more stable Me-histone histone de-methylase

42. The search for histone demethylases • LSD1 is a transcriptional co-repressor and its repression function is • mediate through the amine-oxidase domain Transcription ? luciferase 5X Gal4 binding sites Shi et al, Cell, 2004

43. The search for histone demethylases • LSD1 is a histone H3-K4 demethylase Shi et al, Cell, 2004

44. The search for histone demethylases • LSD1 is a histone H3-K4 demethylase Shi et al, Cell, 2004

45. The search for histone demethylases Adapted from Tsukada and Zhang, Methods, 2006

46. Purifcation of histone demethylases Release of radioactive formaldehyde Adapted from Tsukada and Zhang, Methods, 2006

47. Identifying site of histone demethylation • JHDM1A demethylates di-MeK36 on H3 Adapted from Tsukada and Zhang, Methods, 2006

48. Overexpression of JHDM1A results in loss of K36Me-H3 Adapted from Tsukada and Zhang, Methods, 2006

49. Histone de-methylases are found for all these sites: LSD1 JARID1a-d JMJD2b UTX JMJD3 Apart from LSD1, all other histone de-methylases identified so far belong to the JmjC domain-containing family of enzymes

50. Epienetics and diseases diseases • b-globin thalassemia • leukemia adapted from Nature 429, 2004