Registration for a live webinar on 'Precision medicine treatment for anticancer drug resistance' is now open.
See webinar detailsWe noted you are experiencing viewing problems
-
Check with your IT department that JWPlatform, JWPlayer and Amazon AWS & CloudFront are not being blocked by your network. The relevant domains are *.jwplatform.com, *.jwpsrv.com, *.jwpcdn.com, jwpltx.com, jwpsrv.a.ssl.fastly.net, *.amazonaws.com and *.cloudfront.net. The relevant ports are 80 and 443.
-
Check the following talk links to see which ones work correctly:
Auto Mode
HTTP Progressive Download Send us your results from the above test links at access@hstalks.com and we will contact you with further advice on troubleshooting your viewing problems. -
No luck yet? More tips for troubleshooting viewing issues
-
Contact HST Support access@hstalks.com
-
Please review our troubleshooting guide for tips and advice on resolving your viewing problems.
-
For additional help, please don't hesitate to contact HST support access@hstalks.com
We hope you have enjoyed this limited-length demo
This is a limited length demo talk; you may
login or
review methods of
obtaining more access.
Printable Handouts
Navigable Slide Index
- Introduction
- Gene silencing
- Epigenome
- Chromatin remodeling
- Why study silent heterochromatin?
- Biological functions of repressed chromatin
- Where is silent chromatin in budding yeast?
- Mating type regulation in haploid S.cerevisiae
- Diploids express both mating-types (MAT) loci
- Silent information regulators
- 10 principles of “silent” chromatin
- Heterotrimeric complex
- Limiting pools of Sir factors act at multiple sites
- Silencing requires specific sequence elements
- Nucleation: RAP1 recruits Sir4 which binds Sir2
- The promoter sequence is not important
- Telomeric genes show variegated expression
- Telomeric position effect (TPE)
- The variegated eye phenotype
- Principles 1-8 of “silent” chromatin
- Spreading: deacetylation of histone tails by Sir2
- Overexpression of Sir3
- Limited Sir2 and presence of H3K79me effects
- Sir-bound nucleosomes - DNA protectors
- Principles 5-8 of heterochromatin
- Principles 9-10 of heterochromatin
- Heterochromatin similarity in all species
- Telomeres and HM loci form foci of repression
- Telomeric foci depend on Sir3 interactions
- Anchoring telomeres at the nuclear envelope
- Concentration of SIR proteins & repression
- Silencer function is linear position dependent
- Peripheral anchoring & SIR-mediated silencing
- What causes facilitated silencing?
- Dual reporters: ADE2 and URA3
- Anchoring, telomere clusters and SIR dispersal
- Conclusion
- Concentration thresholds importance for repression
- What happens when SIRs are dispersed?
- Summary
- Contributors in yeast heterochromatin formation
- References (1)
- References (2)
Topics Covered
- Gene silencing: an epigenetic phenomenon
- Chromatin remodeling: heterochromatin and euchromatin
- Silent chromatin in budding yeast: mating-type loci
- Silent information regulation: telomeric genes and Sir proteins
Talk Citation
Gasser, S. (2016, August 31). Gene silencing in budding yeast [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved December 26, 2024, from https://doi.org/10.69645/IBAO7520.Export Citation (RIS)
Publication History
Financial Disclosures
- Prof. Susan Gasser has not informed HSTalks of any commercial/financial relationship that it is appropriate to disclose.
Gene silencing in budding yeast
A selection of talks on Cell Biology
Transcript
Please wait while the transcript is being prepared...
0:00
Hello, I'm Susan Gasser.
And I'm going
to you speak to you today
about Gene Silencing
in Budding Yeast.
0:07
Gene silencing
is an epigenetic phenomenon
whereby a gene is silenced
or not transcribed
in a manner that is heritable
from one cell to the next.
In the lower right-hand corner,
you see colonies of yeast
where a gene that will turn
the yeast cell red
is either expressed
or not expressed
in these colonies.
The sectoring shows
heritable repression.
The same phenomenon occurs
in the eye of the Drosophila
when a gene is transferred
or emplaced
near centromeric head
or chromatin.
Today, I'll explain
how this phenomenon occurs.
0:44
First of all, our genome
is made-up of DNA
complexed with histone proteins
in a complex called chromatin.
This protein DNA complex
carries an additional level
of organization
and information in an epigenome.
When the histone tails
are acetylated
or transcription factors
are bound,
we call this euchromatin,
it's accessible and plastic
to transcription machinery
and usually
transcriptionally active.
On the other hand,
if the histone tails
are methylated,
the other proteins bind,
turning this chromatin
into heterochromatin.
It is inaccessible.
It shows restricted expression
and can be inherited
in a silent state.
1:30
The active chromatin is composed
of a number of modifications
across all species correlated
with active genes.
Histone H3 can be methylated
on lysine 4,
on lysine 36,
and the histone H4 tail
can be acetylated
on a number of lysine residues.
These modifications
attract nucleosome remodelers
which they can shift or evict
nucleosomes, and finally,
is the binding of proteins
that keep the domain
in an active state.
In repressed chromatin,
histone tails are modified
with other kinds
of modifications.
Histone H3 is modified
by methylation on lysine 9
or lysine 27,
and histone H4 on lysine 20.
These methylation sites
can attract repressive proteins
that then mask
the DNA polymerases
from the activity
of transcription.
In higher eukaryotes,
cytosine residues
become methylated
and this correlates
with a repressed state
as well as the stable binding
of general repressors.
Finally, in some species,
double-stranded RNAs
are transcribed
from heterochromatic regions
and this again nucleates
repression of the genes.
In budding yeast,
which we'll be talking
about today,
all the modifications
here listed are present
and they're conserved
from yeast to man.
The phenomenon, however,
of active or inactive chromatin
is largely the same.
So why should we study silent
heterochromatin
in a small organism
like budding yeast?