• The Notion of Epigenetics
• 43 min
  1. Cytoplasmic epigenetics: inheritance by cytoplasmic continuity

  • Prof. Philippe Silar
  • Dr. Fabienne Malagnac
• Epigenetics: Paradigms
• 38 min
  2. The molecular mechanism of X chromosome inactivation

  • Prof. Neil Brockdorff
• 29 min
  3. Genomic imprinting: history and embryology

  • Prof. Davor Solter
• 48 min
  4. X chromosome inactivation in human cells

  • Prof. Barbara Migeon
• 41 min
  5. RNAi and heterochromatin in plants and fission yeast

  • Prof. Robert Martienssen
• 45 min
  6. DNA methylation and genome defense in Neurospora crassa

  • Prof. Eric Selker
• Epigenetics: Mechanisms
• 23 min
  7. Polycomb epigenetic mechanisms: role of PcG complexes

  • Prof. Vincenzo Pirrotta
• 29 min
  8. Polycomb epigenetic mechanisms: methylation of DNA

  • Prof. Vincenzo Pirrotta
• 56 min
  9. Histone modifications and prospects for an epigenetic code

  • Prof. Bryan Turner
• 68 min
  10. Epigenetic control by histone methylation

  • Prof. Thomas Jenuwein
• 38 min
  11. Histone dynamics, heritability and variants

  • Dr. Genevieve Almouzni
• 51 min
  12. Gene silencing in budding yeast

  • Prof. Susan Gasser
• Epigenetics: Heritability and Reversibility
• 51 min
  13. Nuclear cloning, stem cells and epigenetic reprogramming

  • Prof. Rudolf Jaenisch
• 64 min
  14. Stem cell memory

  • Prof. James Sherley
• Archived Lectures *These may not cover the latest advances in the field
• 24 min
  15. Epigenetics: a historical overview

  • Dr. Robin Holliday
• 43 min
  16. DNA methylation

  • Prof. Adrian Bird
• 34 min
  17. A historical perspective on ideas on X-chromosome inactivation

  • Dr. Mary Lyon
• 40 min
  18. Evolution of mammal epigenetic control systems

  • Prof. Jenny Graves
• 60 min
  19. Genomic imprinting and its regulation

  • Dr. Anne Ferguson-Smith
• 40 min
  20. Nuclear organization and gene expression

  • Prof. David Spector
• 39 min
  21. Germ cells

  • Prof. Azim Surani
• 41 min
  22. Epigenetic regulation of phenotype

  • Prof. Emma Whitelaw
• 68 min
  23. Epigenetically mediated gene silencing: a companion to genetic alterations in driving tumorigenesis

  • Prof. Stephen Baylin
• 36 min
  24. Cytoplasmic epigenetics: proteins acting as genes

  • Prof. Reed Wickner

Printable Handouts

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Navigable Slide Index

1. RNAi and heterochromatin: plants, fission yeast
2. Heterochromatic/transposon silencing
3. Transposons regulate genes via DNA methylation
4. Arabidopsis/fission yeast: gene silencing models
5. Arabidopsis chromosomes in meiosis
6. knob: model for high eukaryotic heterochromatin
7. Transposons/repeats/genes in heterochromatin
8. ddm1/met1 (ddm2) required for DNA methylation
9. Genomic tiling microarrays
10. ddm1 silences heterochromatin via methylation
11. ddm1 distinguishes genes from transposons
12. Some genes are methylated, but not by ddm1
13. siRNA, H3mK9/DNA methylation are correlated
14. 24 nt transposon siRNA in met1/ddm1
15. The process of RNAi
16. RNAi genes dcl1/ago1 interact in Arabidopsis
17. Argonautes in Arabidopsis
18. The argonaute gene family
19. RNAi genes in S. pombe
20. Centromeric silencing requires RNAi
21. S. pombe centromeres are transcribed
22. Centromeric silencing: histone H3 methylation
23. Heterochromatin silences genes via RNAi
24. Gene silencing by dh repeats in S. pombe
25. Tf2 retrotransposons and nearby genes (wtf)
26. Centromeric silencing requires Pol II (Rpb2)
27. Centro. repeats transcr., not proces. in rpb2-m203
28. Rik1 required for H3K9 methylation and RNAi
29. Rik1 interacts with Dos1 (localized via Dos2)
30. RNAi and heterochromatin
31. RNAi required for chromosome segregation
32. Centromeres
33. Co-transcription of 106B LTR/satellite repeats
34. Centromere repeat siRNA require dcl3/rdr2/ddm1
35. Satellite transcripts localized in subnuclear dots
36. Tandem repeats and RNAi
37. Single copies cannot maintain siRNA
38. Tandem repeats maintain siRNA
39. Tandem repeat siRNA depends on met1/ddm1
40. Imprinted fwa gene regulated by ddm1/met1
41. fwa tandem repeats from SINE retrotransposon
42. Active heterochromatin is inherited from ddm1
43. Summary
44. Acknowledgments

Topics Covered

• Heterochromatin is composed of transposable elements (TEs) and related repeats
• heterochromatic gene silencing and TE-mediated silencing are related and may be important in large genomes
• tiling microarrays can be used to examine heterochromatic transcripts as well as DNA and histone modification
• small interfering RNA (siRNA) corresponds to transposons and repeats
• in plants TE siRNA depend on DNA methyltransferase MET1 and the SWI/SNF ATPase DDM1 which silence TEs via DNA and histone H3 lysine-9 (H3K9) methylation
• in fission yeast and plants centromeric repeats are transcribed on one strand but rapidly turned over by RNA interference (RNAi)
• RNAi of centromeric transcripts is required for transcriptional silencing of reporter genes
• RNA polymerase II, the Argonaute (RITS) and RNA dependent RNA polymerase (RDRC) complexes are associated with heterochromatin and required for silencing
• H3K9me2 depends on RNAi and on the Rik1-Clr4 complex
• Clr4 is the histone H3K9 dimethyltransferase
• Rik1 resembles both DNA and RNA binding proteins and is required for RNAi along with Clr4
• LTR retrotransposon silencing depends on histone deacetylation and silences pericentromeric repeats in Arabidopsis in addition to RNAi

Links

Series:

• Epigenetics
• RNA Interference

Categories:

• Biochemistry
• Cell Biology
• Genetics & Epigenetics

Talk Citation

Publication History

• Published on October 1, 2007
• Reviewed on October 13, 2016

Financial Disclosures

• Prof. Robert Martienssen has not informed HSTalks of any commercial/financial relationship that it is appropriate to disclose.