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
- How do we capture the complexity of GPCR signalling?
- Biased signalling
- Two approaches
- Strategy for signalling signatures
- Sensors based on donor-acceptor proximity (1)
- Sensors based on donor-acceptor proximity (2)
- Substrate-based: ERK sensors
- Biased ARBs reduce cardiac hypertrophy while preserving contractility
- Biased ARB did not meet primary endpoint
- Signalling signatures for the AT1R
- Maybe TRV027 failed for a different reason?
- Considerations for biosensor panels that capture signalling events
- Using conformational biosensors
- What can conformational profiling tell us? (1)
- FlAsHwalk- using BRET- AT1R
- Tagged AT1R constructs must remain functional
- Generating conformational signatures (1)
- Parallel responses in Gq sensor
- Generating conformational signatures (2)
- Biased signalling is reflected in the FlAsHwalk signatures
- A tool to examine G protein-specific signalling- G protein CRISPR KO cells
- ICL2 and ICL3 sensors when both Gq and G11 are absent
- ICL2 sensor becomes sensitive to Ang II when both Gq/11 are absent
- ICL2 sensor not affected by the loss of β-arrestin
- Moving the sensors to a different cell type
- What can conformational profiling tell us? (2)
- Prostaglandin receptors
- PDC113.824, a new allosteric FP ligand
- PDC113.824 delays preterm labour
- What we know…
- Tagging FP for FLAsHwalk
- Pre-treatment with PDC113.824 leads to potentiation of conformational change
- What can conformational profiling tell us? (3)
- GPCR heterodimers and hetero-oligomers
- FP and AT1R can both regulate BP
- FP and AT1R form heterodimers
- Allostery between GPCRs measured using conformational biosensors
- Conformational rearrangements in FP/AT1R heterodimers
- OTR activation does not induce a conformational change in FP ICL3 P4-RlucII
- OTR can activate Gαq activation sensor
- Conformational asymmetry in GPCR heterodimers
- Signalling consequences of receptor asymmetry
- Signalling consequences of receptor asymmetry-phospho ERK
- Signalling consequences of receptor asymmetry-AngII
- Signalling consequences of receptor asymmetry-PGF2 alpha
- Trafficking consequences of receptor asymmetry (1)
- Trafficking consequences of receptor asymmetry (2)
- Signalling asymmetries- targettable?
- What did conformational profiling tell us? (3)
- What can we learn from conformational biosensors?
- My amazing group
- Acknowledgements
Topics Covered
- Biased signaling will have an impact in clinical medicine
- Pharma is moving into using signaling signatures to capture information during drug discovery process
- The information of signaling signatures can never be “complete”
- Conformational profiling may offer a huge time savings rather than extending signaling signatures
- Conformational profiling needs to be done in relevant cell, tissue and animal models
Links
Series:
Categories:
Talk Citation
Hébert, T. (2020, January 30). What can we learn from conformational profiling of GPCRs? [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved December 21, 2024, from https://doi.org/10.69645/KNQC9980.Export Citation (RIS)
Publication History
Financial Disclosures
- There are no commercial/financial matters to disclose.
Other Talks in the Series: G Protein-Coupled Receptors (GPCRs) Signaling in Health and Disease
Transcript
Please wait while the transcript is being prepared...
0:00
My name is Terry Hebert.
I'm a professor in the Department of Pharmacology and Therapeutics
at McGill University in Montreal, Quebec.
What I'm going to talk to you about today is what we
can learn from conformational profiling of GPCRs.
So the idea is that GPCRs are coupled through multiple signaling pathways.
We're learning to capture a lot more of that signaling complexity.
But I think there's something also to be gained from understanding them as
dynamic conformational machine and what I'm going to talk to you
about is both of those aspects of screening and how they can
combine to get us at drug candidate in a more efficient manner.
0:39
We can see from this slide that yes,
there are multiple proteins that
a given GPCR will interact with as part of its working life.
That includes other GPCRs in the context of
receptor heterodimers, homodimers, homo-and-hetero-oligomers.
There are multiple proteins that the intracellular domain of G proteins interact with.
The canonical heterotrimeric G proteins on the left,
alpha, beta, and gamma subunits,
lots of adaptor proteins or other signaling molecules like beta-Arrestin,
multiple kinases, multiple small GTPases, multiple scaffolding proteins.
So the question becomes that in the drug discovery contexts,
how do we capture this complexity when we think about GPCRs as drug targets?
1:24
Let's bring this out in a pharmacological problem.
The field has become intensely interested in an idea called biased signaling.
That says that if there are multiple pathways downstream of a receptors.
So on this graph you can see pathway A, B, and C,
and there are three logins for that receptor,
but they drive different effects.
So obviously the one you want is ligand 2
because it will activate a pathway which is associated with therapeutic efficacy.
The model here and the paper referred to here talks about opioid receptors.
So one of the problems with opioid receptors is that if there are other pathways engaged,
so pathway B on the left in addition to pathway A,
we could get some efficacy but the patient or the receptor developed tolerance.
So you need more and more of the drug,
like one in this case,
to maintain the clinical effect.
Then on the far right,
there's another ligand which is also an opioid receptor ligand,
but it mainly drives the pathways that lead to tolerance and adverse effects.
So things like gastrointestinal disorders,
respiratory depression, and again,
tolerance, and sometimes addiction.
So if we could devise ligands that favored pathway A and spared pathways B and C,
we would call that a biased ligand and we would see that
that particular drug was much more effective than say the drugs we currently use now.
So that's the idea in pharma,
that's what people are thinking about doing,
is trying to bias signalling toward
therapeutically relevant pathways and away from
pathways that cause side effects or adverse effects.