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Printable Handouts
Navigable Slide Index
- Introduction
- Estrogen receptor and breast cancer
- Estrogen-ER action in breast cancer cells
- In vivo mapping of binding events: (ChIP)
- Chromatin Immunoprecipitation on pS2/TFF1
- Limitations with this approach
- Model of ChIP-chip assay
- ER ChIP using the tiling array
- Characteristics of affymetrix chr 21and 22 arrays
- Processing of ER ChIP-chip data
- Summary of data from chromosome 21 and 22
- ER binding sites on chromosome 21
- ER binding sites on chromosome 22
- Directed ChIP against novel ER binding sites
- Chromosome conformation capture (with ChIP)
- TFF-1 and NRIP-1 enhancers and promoters
- Conservation of binding sites in T-47D cells
- Human-mouse conservation of ER binding sites
- What defines a genuine ER binding site?
- Recruitment of FoxA1 to ER binding sites
- FoxA1 ChIP on 57 ER binding sites
- Targeted knockdown of FoxA1 inhibits ER binding
- siFoxA1 inhibits estrogen-mediated transcription
- Model of ER action
- Genome-wide mapping of ER and RNAPolII binding
- ER and PolII binding relative to transcription start
- ER and RNA PolII binding conservation
- ER and RNA PolII on specific target genes
- Validation of ER binding to defined regions
- Enrichment of motifs at ER binding sites
- Validation of co-operating factor binding
- Distribution of motifs in ER binding sites
- Pairwise analysis of motif clustering
- Estrogen regulated gene expression changes
- ER and PolII binding relative to transcription start
- The direct ER binding in down regulated genes
- Does siRNA to NRIP-1 influence down regulation?
- siRNA to NRIP-1 and late down-regulation genes
- Model of gene regulation via NRIP-1
- Extending data to primary tumours
- Conclusions
- Acknowledgments
- References
Topics Covered
- Estrogen receptor-chromatin interactions
- Cis-regulatory elements that function from a distance
- ER binding sites and gene transcription
- Co-operating transcription factors
- Pioneer factors that maintain ER-chromatin interactions
- Update interview: Consequence of transcription factors moving around genome
- Update interview: Key proteins that are used during transcription
- Update interview: What is impact of mutations in ER components
- Update interview: Does ER complex cycle on the chromatin?
- Update interview: Role of FOXA1 in mediating enhancer elements in cancer
Talk Citation
Carroll, J. (2020, September 18). Genome-wide mapping of estrogen: receptor binding sites and activity [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved December 22, 2024, from https://doi.org/10.69645/EEGN3048.Export Citation (RIS)
Publication History
Financial Disclosures
- Prof. Jason Carroll 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: 50:55 min
- Update Interview Duration: 26:07 min
Genome-wide mapping of estrogen: receptor binding sites and activity
A selection of talks on Oncology
Transcript
Please wait while the transcript is being prepared...
0:00
My name is Jason Carroll.
I'm a group leader at Cancer Research UK,
at the Cambridge Research Institute at the University of Cambridge.
What I'm going to talk about today is some work that's come from ChIP-on-chip experiments
over the last couple of years, where we've mapped
oestrogen receptor binding sites on a genome-wide level,
and we've been mining these binding sites to learn about
underlying properties and features of
oestrogen receptor transcription in breast cancer cells.
0:27
We are interested in the role of the oestrogen receptor in breast cancer.
We know from the genomic revolution about seven or eight years ago
that when researchers performed gene expression profiling in primary breast cancers
and looked for patterns within the gene expression profiles,
they found that
primary breast cancers could be subcategorised into various subtypes.
This included basal tumours that were driven by ERBB2,
but by far the largest category of tumours were those that were called 'luminal tumours'.
These were tumours that expressed
the oestrogen receptor, and tended to express oestrogen receptor target genes.
This shows the large percentage of breast cancers that are
represented by luminal or ER-positive breast cancers (n.b., the abbreviation ER uses the US spelling 'estrogen').
1:11
On a molecular level, this is probably the most simplified version of how oestrogen and
oestrogen receptor can generate
gene transcription events, that can culminate in cell division in breast cancer cells.
We know that oestrogen is a steroid.
It can diffuse into breast cancer cells and it
binds to an intracellular protein, namely oestrogen receptor.
Oestrogen receptor can dimerize and
these homodimers can bind to the promoters of target genes.
These target genes are subsequently transcribed by the transcription machinery,
and the gene transcription events that culminate from these pathways represent
the gene expression profiles that you see in luminal or ER-positive breast cancers.
With the knowledge that oestrogen receptor
bound to promoters of specific target genes,
we could use technology and
technological advances (such as chromatin immunoprecipitations) to map
oestrogen receptor binding sites, and to guess about particular
co-factors or proteins that might be on the promoters of these target genes.