RCSB PDB - 2V55: Mechanism of multi-site phosphorylation from a ROCK-I:RhoE complex structure (original) (raw)
Mechanism of Multi-Site Phosphorylation from a Rock-I:Rhoe Complex Structure.
[Komander, D.](/search?q=citation.rcsb%5Fauthors:Komander, D.), [Garg, R.](/search?q=citation.rcsb%5Fauthors:Garg, R.), [Wan, P.T.C.](/search?q=citation.rcsb%5Fauthors:Wan, P.T.C.), [Ridley, A.J.](/search?q=citation.rcsb%5Fauthors:Ridley, A.J.), [Barford, D.](/search?q=citation.rcsb%5Fauthors:Barford, D.)
(2008) EMBO J 27: 3175
PubMed Abstract:
The ROCK-I serine/threonine protein kinase mediates the effects of RhoA to promote the formation of actin stress fibres and integrin-based focal adhesions. ROCK-I phosphorylates the unconventional G-protein RhoE on multiple N- and C-terminal sites. These phosphorylation events stabilise RhoE, which functions to antagonise RhoA-induced stress fibre assembly. Here, we provide a molecular explanation for multi-site phosphorylation of RhoE from the crystal structure of RhoE in complex with the ROCK-I kinase domain. RhoE interacts with the C-lobe alphaG helix of ROCK-I by means of a novel binding site remote from its effector region, positioning its N and C termini proximal to the ROCK-I catalytic site. Disruption of the ROCK-I:RhoE interface abolishes RhoE phosphorylation, but has no effect on the ability of RhoE to disassemble stress fibres. In contrast, mutation of the RhoE effector region attenuates RhoE-mediated disruption of the actin cytoskeleton, indicating that RhoE exerts its inhibitory effects on ROCK-I through protein(s) binding to its effector region. We propose that ROCK-I phosphorylation of RhoE forms part of a feedback loop to regulate RhoA signalling.
Organizational Affiliation:
Section of Structural Biology, The Institute of Cancer Research, Chester Beatty Laboratories, London, UK.