%0 Journal Article %1 pmid33007266 %A Masuho, I. %A Balaji, S. %A Muntean, B. S. %A Skamangas, N. K. %A Chavali, S. %A Tesmer, J. J. G. %A Babu, M. M. %A Martemyanov, K. A. %D 2020 %J Cell %K imported %N 2 %P 503--521 %T A Global Map of G Protein Signaling Regulation by RGS Proteins %V 183 %X The control over the extent and timing of G protein signaling is provided by the regulator of G protein signaling (RGS) proteins that deactivate G protein α subunits (Gα). Mammalian genomes encode 20 canonical RGS and 16 Gα genes with key roles in physiology and disease. To understand the principles governing the selectivity of Gα regulation by RGS, we examine the catalytic activity of all canonical human RGS proteins and their selectivity for a complete set of Gα substrates using real-time kinetic measurements in living cells. The data reveal rules governing RGS-Gα recognition, the structural basis of its selectivity, and provide principles for engineering RGS proteins with defined selectivity. The study also explores the evolution of RGS-Gα selectivity through ancestral reconstruction and demonstrates how naturally occurring non-synonymous variants in RGS alter signaling. These results provide a blueprint for decoding signaling selectivity and advance our understanding of molecular recognition principles.

@article{pmid33007266, abstract = {The control over the extent and timing of G protein signaling is provided by the regulator of G protein signaling (RGS) proteins that deactivate G protein α subunits (Gα). Mammalian genomes encode 20 canonical RGS and 16 Gα genes with key roles in physiology and disease. To understand the principles governing the selectivity of Gα regulation by RGS, we examine the catalytic activity of all canonical human RGS proteins and their selectivity for a complete set of Gα substrates using real-time kinetic measurements in living cells. The data reveal rules governing RGS-Gα recognition, the structural basis of its selectivity, and provide principles for engineering RGS proteins with defined selectivity. The study also explores the evolution of RGS-Gα selectivity through ancestral reconstruction and demonstrates how naturally occurring non-synonymous variants in RGS alter signaling. These results provide a blueprint for decoding signaling selectivity and advance our understanding of molecular recognition principles.}, added-at = {2021-01-14T21:21:20.000+0100}, author = {Masuho, I. and Balaji, S. and Muntean, B. S. and Skamangas, N. K. and Chavali, S. and Tesmer, J. J. G. and Babu, M. M. and Martemyanov, K. A.}, biburl = {https://www.bibsonomy.org/bibtex/287879b4d79ed614c298209cbb3384730/mbgroup}, interhash = {15b7953df2a5e5d3ca8da249db00b181}, intrahash = {87879b4d79ed614c298209cbb3384730}, journal = {Cell}, keywords = {imported}, month = Oct, number = 2, pages = {503--521}, timestamp = {2021-01-14T21:21:20.000+0100}, title = {{{A} {G}lobal {M}ap of {G} {P}rotein {S}ignaling {R}egulation by {R}{G}{S} {P}roteins}}, volume = 183, year = 2020 }