Author
Listed:
- Olivier Soubias
(National Institutes of Health
National Institutes of Health)
- Samuel L. Foley
(The Johns Hopkins University)
- Xiaoying Jian
(National Institutes of Health)
- Rebekah A. Jackson
(National Institutes of Health)
- Yue Zhang
(National Institutes of Health
Ring Therapeutics, Inc.)
- Eric M. Rosenberg
(National Institutes of Health)
- Benjamin J. Hu
(National Institutes of Health)
- Jess Li
(National Institutes of Health)
- Frank Heinrich
(Department of Physics Carnegie Mellon University
NIST Center for Neutron Research)
- Margaret E. Johnson
(The Johns Hopkins University)
- Alexander J. Sodt
(National Institutes of Health)
- Paul A. Randazzo
(National Institutes of Health)
- R. Andrew Byrd
(National Institutes of Health)
Abstract
GTPase-activating proteins are important regulators of small GTPases; among these, ASAP1 stimulates GTP hydrolysis on Arf1 and is implicated in cancer progression. ASAP1 contains a Pleckstrin Homology (PH) domain essential for maximum Arf·GTP hydrolysis. The prevailing view of PH domains is that they regulate proteins through passive mechanisms like membrane recruitment. In sharp contrast, we show that the PH domain of ASAP1 actively contributes to Arf1 GTP hydrolysis. By combining NMR, molecular dynamics simulations, kinetic assays, and mutational analysis, we find that the PH domain binds Arf·GTP at the membrane, to establish an active state primed for GTP hydrolysis. We identify key residues on the PH domain and Arf that drive this allosteric mechanism, which mathematical modeling shows contributes as much to GTPase activation as membrane recruitment. The finding that PH domains directly modulate small GTPases has broad implications for the Ras and Rho oncoprotein families.
Suggested Citation
Olivier Soubias & Samuel L. Foley & Xiaoying Jian & Rebekah A. Jackson & Yue Zhang & Eric M. Rosenberg & Benjamin J. Hu & Jess Li & Frank Heinrich & Margaret E. Johnson & Alexander J. Sodt & Paul A. R, 2025.
"An active allosteric mechanism in ASAP1-mediated Arf1 GTP hydrolysis redefines PH domain function,"
Nature Communications, Nature, vol. 16(1), pages 1-19, December.
Handle:
RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-63764-w
DOI: 10.1038/s41467-025-63764-w
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