Brian K. Kobilka
Affiliations: | Molecular & Cellular Physiology | Stanford University, Palo Alto, CA |
Area:
Adrenergic receptorsWebsite:
http://med.stanford.edu/kobilkalab/index.htmlGoogle:
"Brian Kobilka"Bio:
The Nobel Prize in Chemistry 2012 was awarded jointly to Robert J. Lefkowitz and Brian K. Kobilka "for studies of G-protein-coupled receptors"
Mean distance: 14.61 (cluster 11) | S | N | B | C | P |
Cross-listing: Chemistry Tree - Physiology Academic Tree
Parents
Sign in to add mentorRobert M. Carlson | research assistant | University of Minnesota Duluth (Chemistry Tree) | ||
Conrad E. Firling | research assistant | University of Minnesota Duluth (Physiology Academic Tree) | ||
(A medium for the maintenance of Chironomus tentans salivary glands in vitro.) | ||||
Robert J. Lefkowitz | post-doc | 1984-1989 | Duke |
Children
Sign in to add traineeAndrew Kruse | grad student | Stanford (Chemistry Tree) | |
Aashish Manglik | grad student | Stanford (Chemistry Tree) | |
Yoon Seok Kim | grad student | 2015- | Stanford |
Pejman Ghanouni | grad student | 2001 | Stanford (Chemistry Tree) |
Thomas P. Finsterbach | grad student | 2007 | Stanford (Chemistry Tree) |
Carl M. Hurt | grad student | 2007 | Stanford (Chemistry Tree) |
Juan J. Fung | grad student | 2009 | Stanford (Chemistry Tree) |
Daniel Hilger | post-doc | Stanford (Chemistry Tree) | |
Søren G.F. Rasmussen | post-doc | Stanford (Chemistry Tree) | |
Daniel M. Rosenbaum | post-doc | Stanford (Chemistry Tree) | |
Mark von Zastrow | post-doc | Stanford Medical School | |
John Janetzko | post-doc | 2017- | Stanford Medical School (Chemistry Tree) |
Haoqing Wang | post-doc | 2019- | Stanford (Chemistry Tree) |
Uwe Klein | post-doc | 1995-1998 | Stanford |
Peter Nollert | post-doc | 1999-2001 | Stanford (Chemistry Tree) |
Ka Young Chung | post-doc | 2008-2011 | Stanford |
Hideaki E. Kato | post-doc | 2014-2019 | Stanford School of Medicine (Chemistry Tree) |
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Publications
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Toyoda Y, Zhu A, Kong F, et al. (2023) Structural basis of α-adrenergic receptor activation and recognition by an extracellular nanobody. Nature Communications. 14: 3655 |
Zhao J, Elgeti M, O'Brien ES, et al. (2023) Conformational dynamics of the μ-opioid receptor determine ligand intrinsic efficacy. Biorxiv : the Preprint Server For Biology |
Krishna Kumar K, Robertson MJ, Thadhani E, et al. (2023) Structural basis for activation of CB1 by an endocannabinoid analog. Nature Communications. 14: 2672 |
Xu X, Shonberg J, Kaindl J, et al. (2023) Constrained catecholamines gain βAR selectivity through allosteric effects on pocket dynamics. Nature Communications. 14: 2138 |
Heng J, Hu Y, Pérez-Hernández G, et al. (2023) Function and dynamics of the intrinsically disordered carboxyl terminus of β2 adrenergic receptor. Nature Communications. 14: 2005 |
Krishna Kumar K, O'Brien ES, Habrian CH, et al. (2023) Negative allosteric modulation of the glucagon receptor by RAMP2. Cell. 186: 1465-1477.e18 |
Papasergi-Scott MM, Pérez-Hernández G, Batebi H, et al. (2023) Time-resolved cryo-EM of G protein activation by a GPCR. Biorxiv : the Preprint Server For Biology |
Xu J, Wang Q, Hübner H, et al. (2023) Structural and dynamic insights into supra-physiological activation and allosteric modulation of a muscarinic acetylcholine receptor. Nature Communications. 14: 376 |
Faouzi A, Wang H, Zaidi SA, et al. (2022) Structure-based design of bitopic ligands for the µ-opioid receptor. Nature |
Qu Q, Huang W, Aydin D, et al. (2022) Insights into distinct signaling profiles of the µOR activated by diverse agonists. Nature Chemical Biology |