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PubMed Publications| Keyword search (4,163 papers available) |  |
"Smith E" Authored Publications:
| Title | Authors | PubMed ID | |
|---|---|---|---|
| 1 | Exploiting fluctuations in gene expression to detect causal interactions between genes | Joly-Smith E; Talpur MM; Allard P; Papazotos F; Potvin-Trottier L; Hilfinger A; | 41401079 BIOLOGY |
| 2 | Impact of a national dementia research consortium: The Canadian Consortium on Neurodegeneration in Aging (CCNA) | Chertkow H; Phillips N; Rockwood K; Anderson N; Andrew MK; Bartha R; Beaudoin C; Bélanger N; Bellec P; Belleville S; Bergman H; Best S; Bethell J; Bherer L; Black S; Borrie M; Camicioli R; Carrier J; Cashman N; Chan S; Crowshoe L; Cuello C; Cynader M; Dang-Vu T; Das S; Dixon RA; Ducharme S; Einstein G; Evans AC; Fahnestock M; Feldman H; Ferland G; Finger E; Fisk JD; Fogarty J; Fon E; Gan-Or Z; Gauthier S; Greenwood C; Henri-Bellemare C; Herrmann N; Hogan DB; Hsiung R; Itzhak I; Jacklin K; Lanctôt K; Lim A; MacKenzie I; Masellis M; Maxwell C; McAiney C; McGilton K; McLaurin J; Mihailidis A; Mohades Z; Montero-Odasso M; Morgan D; Naglie G; Nygaard H; O' Connell M; Petersen R; Pilon R; Rajah MN; Rapoport M; Roach P; Robillard JM; Rogaeva E; Rosa-Neto P; Rylett J; Sadavoy J; St George-Hyslop P; Seitz D; Smith E; Stefanovic B; Vedel I; Walker JD; Wellington C; Whitehead V; Wittich W; | 39636028 HKAP |
| 3 | Measuring prion propagation in single bacteria elucidates mechanism of loss | Jager K; Orozco-Hidalgo MT; Springstein BL; Joly-Smith E; Papazotos F; McDonough E; Fleming E; McCallum G; Hilfinger A; Hochschild A; Potvin-Trottier L; | 36712035 BIOLOGY |
| 4 | Measuring prion propagation in single bacteria elucidates a mechanism of loss | Jager K; Orozco-Hidalgo MT; Springstein BL; Joly-Smith E; Papazotos F; McDonough E; Fleming E; McCallum G; Yuan AH; Hilfinger A; Hochschild A; Potvin-Trottier L; | 37738299 PHYSICS |
| 5 | Ligne directrice C-CHANGE pour l’harmonisation des lignes directrices nationales de prévention et de prise en charge des maladies cardiovasculaires en contexte de soins primaires au Canada: mise à jour 2022 | Jain R; Stone JA; Agarwal G; Andrade JG; Bacon SL; Bajaj HS; Baker B; Cheng G; Dannenbaum D; Gelfer M; Habert J; Hickey J; Keshavjee K; Kitty D; Lindsay P; L' Abbé MR; Lau DCW; Macle L; McDonald M; Nerenberg K; Pearson GJ; Pham T; Poppe AY; Rabi DM; Sherifali D; Selby P; Smith E; Stern S; Thanassoulis G; Terenzi K; Tu K; Udell J; Virani SA; Ward RA; Warburton DER; Wharton S; Zymantas J; Hua-Stewart D; Liu PP; Tobe SW; | 36623864 HKAP |
| 6 | Canadian Cardiovascular Harmonized National Guideline Endeavour (C-CHANGE) guideline for the prevention and management of cardiovascular disease in primary care: 2022 update | Jain R; Stone JA; Agarwal G; Andrade JG; Bacon SL; Bajaj HS; Baker B; Cheng G; Dannenbaum D; Gelfer M; Habert J; Hickey J; Keshavjee K; Kitty D; Lindsay P; L' Abbé MR; Lau DCW; Macle L; McDonald M; Nerenberg K; Pearson GJ; Pham T; Poppe AY; Rabi DM; Sherifali D; Selby P; Smith E; Stern S; Thanassoulis G; Terenzi K; Tu K; Udell J; Virani SA; Ward RA; Warburton DER; Wharton S; Zymantas J; Hua-Stewart D; Liu PP; Tobe SW; | 36343954 HKAP |
| Title: | Exploiting fluctuations in gene expression to detect causal interactions between genes | ||||
| Authors: | Joly-Smith E, Talpur MM, Allard P, Papazotos F, Potvin-Trottier L, Hilfinger A | ||||
| Link: | https://pubmed.ncbi.nlm.nih.gov/41401079/ | ||||
| DOI: | 10.7554/eLife.92497 | ||||
| Publication: | eLife | ||||
| Keywords: | E coli; causal effects; computational biology; gene regulation; network inference; physics of living systems; stochastic fluctuations; systems biology; | ||||
| PMID: | 41401079 | Category: | Date Added: | 2025-12-16 | |
| Dept Affiliation: |
BIOLOGY
1 Department of Physics, University of Toronto, Toronto, Canada. 2 Department of Chemical & Physical Sciences, University of Toronto Mississauga, Mississauga, Canada. 3 Centre for Applied Synthetic Biology, Concordia University, Montreal, Canada. 4 Department of Biology, Concordia University, Montreal, Canada. 5 Department of Physics, Concordia University, Montreal, Canada. 6 Department of Mathematics, University of Toronto, Toronto, Canada. 7 Department of Cell & Systems Biology, University of Toronto, Toronto, Canada. |
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Description: |
Characterizing and manipulating cellular behavior requires a mechanistic understanding of the causal interactions between cellular components. We present an approach to detect causal interactions between genes without the need to perturb the physiological state of cells. This approach exploits naturally occurring cell-to-cell variability which is experimentally accessible from static population snapshots of genetically identical cells without the need to follow cells over time. Our main contribution is a simple mathematical relation that constrains the propagation of gene expression noise through biochemical reaction networks. This relation allows us to rigorously interpret fluctuation data even when only a small part of a complex gene regulatory process can be observed. We show how this relation can, in theory, be exploited to detect causal interactions by synthetically engineering a passive reporter of gene expression, akin to the established 'dual reporter assay'. While the focus of our contribution is theoretical, we also present an experimental proof-of-principle to demonstrate the real-world applicability of our approach in certain circumstances. Our experimental data suggest that the method can detect causal interactions in specific synthetic gene regulatory circuits in Escherichia coli, confirming our theoretical result in a narrow set of controlled experimental settings. Further work is needed to show that the approach is practical on a large scale, with naturally occurring gene regulatory networks, or in organisms other than E. coli. |
