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- View the Talks
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1. The basal transcription machinery for RNA polymerase II
- Prof. H. T. Marc Timmers
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2. The Myc transcription factor network
- Prof. Robert N. Eisenman
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3. Role of polycomb proteins in gene transcription, stem cell and human diseases
- Prof. Luciano Di Croce
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4. Heterochromatin, epigenetics and gene expression
- Prof. Joel C. Eissenberg
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5. Histone dynamics, heritability and variants
- Dr. Genevieve Almouzni
-
6. Hox gene regulation in vertebrate hindbrain development
- Prof. Robb Krumlauf
-
7. Enhancer malfunction in cancer
- Dr. Ali Shilatifard
-
8. Maintaining the silenced state of master regulatory genes during development
- Prof. Robert Kingston
-
9. Genomic insights into gene regulation by cohesin
- Prof. Dale Dorsett
- Archived Lectures *These may not cover the latest advances in the field
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11. DNA methylation
- Prof. Steve Jacobsen
-
12. Accessing and using ENCODE data
- Prof. Peggy Farnham
-
13. Visualization of transcription factor interactions in living cells
- Prof. Tom Kerppola
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14. The beta-globin locus
- Dr. Ann Dean
Printable Handouts
Navigable Slide Index
- Introduction
- Cytosine DNA methylation
- DNA methylation and epigenetics
- Evolution
- Loss in key organisms
- Epigenetic phenomena
- Methylation processes
- Sequences methylated in eukaryotes
- de novo methylation
- Model systems studied
- DNA methylatransferases
- Domain architectures
- Phylogeny
- DNMT1 family
- DNMT1 knockout mice
- MET1 knockout in Arabidopsis
- FWA gene regulation
- Ectopic methylation
- DIM2 of Neurospora
- Mouse Dnmt3 and Arabidopsis DRMs
- DNMT3 knockouts mice
- De novo methylation assay in mice
- De novo methylation assay in plants
- FWA transformants
- Southern blot analysis
- Chromomethylase 3
- Mechanisms of targeting methyltranferases
- DIM5 H3K9 methylation
- Kryptonite
- ChIP assays
- Order of gene action
- CMT3 possible model
- H3K9 methylation in mammals
- RNA directed DNA methylation
- Agronaute 5
- RNAi pathway
- AGO4 and H3K9 methylation
- RNAi and de novo methylation
- RNAi and asymmetric methylation
- Methyltransferase summary
- RdDM in other systems
- Swi2/Snf2 proteins
- Future questions
Topics Covered
- Roles of DNA methylation
- Evolution of eukaryotic DNA methyltransferases
- Mechanism of action of DNA methyltransferases
- Specific loci targeting
- Histone modification
- Small interfering RNA
Links
Series:
Categories:
Talk Citation
Jacobsen, S. (2021, October 5). DNA methylation [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved December 26, 2024, from https://doi.org/10.69645/XJJX9843.Export Citation (RIS)
Publication History
- Published on October 1, 2007
- Updated on April 2, 2014
- Reviewed on October 5, 2021
- Archived on April 13, 2022
Financial Disclosures
- Prof. Steve Jacobsen has not informed HSTalks of any commercial/financial relationship that it is appropriate to disclose.
A selection of talks on Genetics & Epigenetics
Transcript
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0:00
DNA Methylation, presented by Steve Jacobsen.
0:04
Cytosine DNA methylation at the
fifth position of the cytosine ring
is the most prevalent
modification of DNA
found in eukaryotic organisms.
And DNA methylation
is a major determinant
of so-called epigenetic
gene regulation.
0:18
Epigenetics is defined
as heritable changes
in gene expression
which are not associated
with changes in the
sequence of the DNA.
Instead, epigenetic
inheritance is based
on stable, alternative chromatin
architectures at specific loci.
DNA methylation plays a major
role in epigenetic inheritance,
because DNA methylation patterns
can be stably inherited from cell
to cell during mitosis, and
in some cases from generation
to generation during meiosis.
While there are a few
exceptions to this general rule,
DNA methylation is usually
associated with gene silencing.
0:53
DNA methylation is a
very ancient phenomenon
and in fact evolved
first in bacteria
as restriction
modification systems that
serve as a defense against
foreign DNA, such as viruses.
These methylation
restriction systems
are composed of specific DNA
methyltransferase enzymes that
act at short, palindromic sequences
and restriction enzymes that cleave
this same sequence only
if it is unmethylated.
In this way, bacteria
can distinguish
self DNA from non-self DNA.
And foreign, incoming,
unmethylated DNA
can thus be recognized
and destroyed.
In eukaryotic organisms,
DNA methylation
has evolved into a mechanism
that allows dividing cells
to stably inherit
states of gene activity.
DNA methylation is
involved in a great number
of epigenetic regulatory
processes found throughout all
of the major eukaryotic
groups, including
fungi, plants, and animals.