TY - JOUR
T1 - Basis of Mutual Domain Inhibition in a Bacterial Response Regulator
AU - Corrêa, Fernando
AU - Gardner, Kevin H.
N1 - Funding Information:
NMR data presented herein were collected at the UT Southwestern and at the City University of New York Advanced Science Research Center Biomolecular NMR Facilities, with the generous assistance of Qiong Wu (UT Southwestern) and James Aramini (CUNY ASRC). We thank Lewis E. Kay (University of Toronto) for providing us the pulse sequences used to acquire PRE and certain triple resonance data. We additionally thank Victor Ocasio, Giomar Rivera-Cancel, Arati Ramesh, Yirui Guo, and Doeke Hekstra for providing constructive comments for this manuscript, and all the members of Gardner laboratory for their helpful discussions. This work was supported by grants from the NIH ( R01 GM106239 ) and the Robert A. Welch Foundation ( I-1424 ).
Publisher Copyright:
© 2016 Elsevier Ltd
PY - 2016/8/18
Y1 - 2016/8/18
N2 - Information transmission in biological signaling networks is commonly considered to be a unidirectional flow of information between protein partners. According to this view, many bacterial response regulator proteins utilize input receiver (REC) domains to “switch” functional outputs, using REC phosphorylation to shift pre-existing equilibria between inactive and active conformations. However, recent data indicate that output domains themselves also shift such equilibria, implying a “mutual inhibition” model. Here we use solution nuclear magnetic resonance to provide a mechanistic basis for such control in a PhyR-type response regulator. Our structure of the isolated, non-phosphorylated REC domain surprisingly reveals a fully active conformation, letting us identify structural and dynamic changes imparted by the output domain to inactivate the full-length protein. Additional data reveal transient structural changes within the full-length protein, facilitating activation. Our data provide a basis for understanding the changes that REC and output domains undergo to set a default “inactive” state.
AB - Information transmission in biological signaling networks is commonly considered to be a unidirectional flow of information between protein partners. According to this view, many bacterial response regulator proteins utilize input receiver (REC) domains to “switch” functional outputs, using REC phosphorylation to shift pre-existing equilibria between inactive and active conformations. However, recent data indicate that output domains themselves also shift such equilibria, implying a “mutual inhibition” model. Here we use solution nuclear magnetic resonance to provide a mechanistic basis for such control in a PhyR-type response regulator. Our structure of the isolated, non-phosphorylated REC domain surprisingly reveals a fully active conformation, letting us identify structural and dynamic changes imparted by the output domain to inactivate the full-length protein. Additional data reveal transient structural changes within the full-length protein, facilitating activation. Our data provide a basis for understanding the changes that REC and output domains undergo to set a default “inactive” state.
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U2 - 10.1016/j.chembiol.2016.07.010
DO - 10.1016/j.chembiol.2016.07.010
M3 - Article
C2 - 27524295
AN - SCOPUS:84982199287
SN - 2451-9448
VL - 23
SP - 945
EP - 954
JO - Cell Chemical Biology
JF - Cell Chemical Biology
IS - 8
ER -