Abstract
BackgroundFormin proteins utilize a conserved formin homology 2 (FH2) domain to nucleate new actin filaments. In mammalian diaphanous-related formins (DRFs) the FH2 domain is inhibited through an unknown mechanism by intramolecular binding of the diaphanous autoinhibitory domain (DAD) and the diaphanous inhibitory domain (DID).Methodology/Principal FindingsHere we report the crystal structure of a complex between DID and FH2-DAD fragments of the mammalian DRF, mDia1 (mammalian diaphanous 1 also called Drf1 or p140mDia). The structure shows a tetrameric configuration (4 FH2 + 4 DID) in which the actin-binding sites on the FH2 domain are sterically occluded. However biochemical data suggest the full-length mDia1 is a dimer in solution (2 FH2 + 2 DID). Based on the crystal structure, we have generated possible dimer models and found that architectures of all of these models are incompatible with binding to actin filament but not to actin monomer. Furthermore, we show that the minimal functional monomeric unit in the FH2 domain, termed the bridge element, can be inhibited by isolated monomeric DID. NMR data on the bridge-DID system revealed that at least one of the two actin-binding sites on the bridge element is accessible to actin monomer in the inhibited state.Conclusions/SignificanceOur findings suggest that autoinhibition in the native DRF dimer involves steric hindrance with the actin filament. Although the structure of a full-length DRF would be required for clarification of the presented models, our work here provides the first structural insights into the mechanism of the DRF autoinhibition.
Highlights
Formins are conserved actin regulators, which function in formation of stress fibers, actin cables, the cytokinetic ring and filopodia [1,2,3,4]
Full-length mDia1 Forms a Dimer in Solution Structural and biochemical studies have revealed that formin homology 2 (FH2) domains and the N-terminal regulatory fragment of mDia1 (GDID-dimerization domain (DD)-coiled coil region (CC), Fig. 1A) form dimers in isolation [32,34,35]
The mass of 332 kDa is close to that of the (DID-DD/FH2-diaphanous autoinhibitory domain (DAD))4 tetramer, 362 kDa. On this basis we conclude that the DIDDDNFH2-DAD complex likely equilibrates between a dimer and a tetramer in solution
Summary
Formins are conserved actin regulators, which function in formation of stress fibers, actin cables, the cytokinetic ring and filopodia [1,2,3,4]. Formins modulate actin dynamics through two biochemical activities They accelerate nucleation of new filaments de novo from actin monomers. Following nucleation they remain stably associated at the barbed-ends of growing filaments as actin monomers are added, in a process termed ‘‘processive capping’’ [10,11,12,13,14,15]. Both in cells and in vitro, processive capping allows formins to protect the filament barbed ends from capping proteins and to modulate rates of filament elongation [11,12,16,17]. In mammalian diaphanous-related formins (DRFs) the FH2 domain is inhibited through an unknown mechanism by intramolecular binding of the diaphanous autoinhibitory domain (DAD) and the diaphanous inhibitory domain (DID)
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