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Printable Handouts
Navigable Slide Index
- Introduction
- Eukaryotic RNA polymerases I, II and III
- Introduction to transcription
- Transcriptional complexity
- Fundamental questions
- Pol II machinery: overview of topics
- DNA sequence elements
- The RNA polymerase "promoter"
- Pol II machinery: the core promoter
- Pol ll core promoter elements
- Pol ll machinery: the proximal promoter
- Proximal promoter element: CpG islands
- Summary: core promoter elements
- Pol ll machinery: enhancer and silencers
- Enhancer elements
- The enhanceosome
- UAS elements (yeast)
- Silencer elements
- URS elements (yeast)
- Pol ll machinery: the GTFs
- Discovery of the GTFs
- The Pol ll GTFs
- GTF functions
- Assembly of the Pol ll PIC
- The GTFs: analogous to sigma factor
- TFIID
- TBP
- TAFs
- TAF functions
- TFIID 3D structure
- Class ll promoters
- TBP-less TAF complexes
- TBP-like factors (TLFs)
- TFIIA
- TFIIB
- The "finger" domain
- TFIIF
- TFIIE
- TFIIH
- TFIIH: subunit structure
- Key questions: how does Pol ll identify a gene?
- Pol II machinery: Pol ll itself
- Pol II
- Yeast Pol II 3D structure
- Yeast RNA Pol II - 12 subunit structure
- A marvellous machine for making messages
- The Pol II CTD
- Regulation of the Pol II CTD
- Pol II machinery: activators and repressors
- Transcription activators: bipartite structure
- Nuclear receptor family
- Activator specificity
- Pol II machinery: coactivators
- Mechanisms of activation
- Coactivators of transcription
- Transcriptional repression
- Another repression mechanism
- Poll ll machinery: mechanism of initiation
- Pol ll transcription cycle
- The Pol ll scaffold
- How does Pol ll initiate transcription?
- How is transcription activated or repressed?
- Unanswered questions
- Scheme of key elements and factors
- Appendix
Topics Covered
- Overview of RNA polymerase II transcription
- Core promoter elements
- Proximal promoters
- Enhancers and silencers
- General transcription factors
- Activators and repressors
- Coactivator complexes
- RNA polymerase II structure and function
- Mechanisms of transcription initiation
- Steroid hormone receptors
- Chromatin remodellers including SWI/SNF
- Covalent histone modifiers, including histone acetyltransferases, methyltransferases and deacetylases
- Update interview: RNAP II carboxy-terminal domain (CTD)
- Update interview: Mediator complex
- Update interview: Gene silencing
- Update interview: Transcription termination
- Update interview: Coupled transcription and mRNA processing
- Update interview: Transcriptional memory
Talk Citation
Hampsey, M. (2021, April 8). Mechanisms of transcription: the eukaryotic pre-initiation complex [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved December 26, 2024, from https://doi.org/10.69645/JAGQ3172.Export Citation (RIS)
Publication History
Financial Disclosures
- Prof. Michael Hampsey has not informed HSTalks of any commercial/financial relationship that it is appropriate to disclose.
Update Available
The speaker addresses developments since the publication of the original talk. We recommend listening to the associated update as well as the lecture.
- Full lecture Duration: 43:50 min
- Update Interview Duration: 14:54 min
A selection of talks on Cell Biology
Transcript
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0:00
Mechanisms of Transcription; The Eukaryotic Pre-initiation Complex by Michael Hampsey.
0:08
In this talk, I focus on basic aspects of transcription,
specifically transcription of eukaryotic class II genes,
those transcribed by RNA polymerase II.
I want to start by reminding you that transcription in
eukaryotic cells is catalyzed by three distinct RNA polymerases,
Pol I, Pol II, and Pol III.
Pol I is dedicated to the synthesis of ribosomal RNAs,
except the smallest of them, 5S RNA.
Pol II transcribes protein encoding genes to yield
messenger RNA as well as a few small nuclear RNAs,
and Pol III synthesizes transfer RNAs, 5S ribosomal RNA,
and also a few small nuclear RNAs. Whereas
only messenger RNA is translated to yield protein,
the ribosomal and transfer RNAs are also
directly involved in protein synthesis by the ribosome.
0:60
In 2001, the complete DNA sequence of the human genome was published,
revealing approximately 30,000 protein encoding genes.
This was an extraordinary achievement,
but like so many scientific milestones raised as many questions as were answered.
Notable are the questions of how these 30,000 genes are expressed to affect
cell growth and differentiation and how expression of these genes is regulated.
1:26
There are interesting implications regarding
transcription mechanisms inherent in the DNA sequences of eukaryotic genomes.
As I just mentioned,
there are about 30,000 genes in the human genome and an
estimated 3,000 Pol II transcription factors.
On the other hand, the DNA sequence of the yeast genome revealed about 6,000 genes,
but fewer than 300 transcription factors.
Accordingly, there is less than one transcription factor for
every 20 yeast genes compared to about one for every 10 genes in human cells.
As you will see in the context of the Pol II enhanceosome,
this two fold increase in the number of transcription factors per gene,
affords the potential for an enormous increase in
transcriptional regulatory complexity and is likely to
underlie at least in part
the dramatic expansion in organismal complexity from yeast to man.
This talk addresses several fundamental questions regarding Pol II transcription.