Specificity of interactions between mDia isoforms and Rho proteins.

Formins are key regulators of actin nucleation and polymerization. They contain formin homology 1 (FH1) and 2 (FH2) domains as the catalytic machinery for the formation of linear actin cables. A subclass of formins constitutes the Diaphanous-related formins, members of which are regulated by the binding of a small GTP-binding protein of the Rho subfamily. Binding of these molecular switch proteins to the regulatory N-terminal mDia(N), including the GTPase-binding domain, leads to the release of auto-inhibition. From the three mDia isoforms, mDia1 is activated only by Rho (RhoA, -B, and -C), in contrast to mDia2 and -3, which is also activated by Rac and Cdc42. Little is known about the determinants of specificity. Here we report on the interactions of RhoA, Rac1, and Cdc42 with mDia1 and an mDia1 mutant (mDia(N)-Thr-Ser-His (TSH)), which based on structural information should mimic mDia2 and -3. Specificity is analyzed by biochemical studies and a structural analysis of a complex between Cdc42.Gpp(NH)p and mDia(N)-TSH. A triple NNN motif in mDia1 (amino acids 164-166), corresponding to the TSH motif in mDia2/3 (amino acids 183-185 and 190-192), and the epitope interacting with the Rho insert helix are essential for high affinity binding. The triple N motif of mDia1 allows tight interaction with Rho because of the presence of Phe-106, whereas the corresponding His-104 in Rac and Cdc42 forms a complementary interface with the TSH motif in mDia2/3. We also show that the F106H and H104F mutations drastically alter the affinities and thermodynamics of mDia interactions.

Structural insight into filament formation by mammalian septins.

Septins are GTP-binding proteins that assemble into homo- and hetero-oligomers and filaments. Although they have key roles in various cellular processes, little is known concerning the structure of septin subunits or the organization and polarity of septin complexes. Here we present the structures of the human SEPT2 G domain and the heterotrimeric human SEPT2-SEPT6-SEPT7 complex. The structures reveal a universal bipolar polymer building block, composed of an extended G domain, which forms oligomers and filaments by conserved interactions between adjacent nucleotide-binding sites and/or the amino- and carboxy-terminal extensions. Unexpectedly, X-ray crystallography and electron microscopy showed that the predicted coiled coils are not involved in or required for complex and/or filament formation. The asymmetrical heterotrimers associate head-to-head to form a hexameric unit that is nonpolarized along the filament axis but is rotationally asymmetrical. The architecture of septin filaments differs fundamentally from that of other cytoskeletal structures.

The core FH2 domain of diaphanous-related formins is an elongated actin binding protein that inhibits polymerization.

Diaphanous-related formins (Drf) are activated by Rho GTP binding proteins and induce polymerization of unbranched actin filaments. They contain three formin homology domains. Evidence as to the effect of formins on actin polymerization were obtained using FH2/FH1 constructs of various length from different Drfs. Here we define the core FH2 domain as a proteolytically stable domain of approximately 338 residues. The monomeric FH2 domains from mDia1 and mDia3 inhibit polymerization of actin and can bind in a 1:1 complex with F-actin at micromolar concentrations. The X-ray structure analysis of the domain shows an elongated, crescent-shaped molecule consisting of three helical subdomains. The most highly conserved regions of the domain span a distance of 75 A and are both required for barbed-end inhibition. A construct containing an additional 72 residue linker has dramatically different properties: It oligomerizes and induces actin polymerization at subnanomolar concentration.

Rap-specific GTPase activating protein follows an alternative mechanism.

Rap1 is a small GTPase that is involved in signal transduction cascades. It is highly homologous to Ras but it is down-regulated by its own set of GTPase activating proteins (GAPs). To investigate the mechanism of the GTP-hydrolysis reaction catalyzed by Rap1GAP, a catalytically active fragment was expressed in Escherichia coli and characterized by kinetic and mutagenesis studies. The GTPase reaction of Rap1 is stimulated 10(5)-fold by Rap1GAP and has a k(cat) of 6 s(-1) at 25 degrees C. The catalytic effect of GAPs from Ras, Rho, and Rabs depends on a crucial arginine which is inserted into the active site. However, all seven highly conserved arginines of Rap1GAP can be mutated without dramatically reducing V(max) of the GTP-hydrolysis reaction. We found instead two lysines whose mutations reduce catalysis 25- and 100-fold, most likely by an affinity effect. Rap1GAP does also not supply the crucial glutamine that is missing in Rap proteins at position 61. The Rap1(G12V) mutant which in Ras reduces catalysis 10(6)-fold is shown to be efficiently down-regulated by Rap1GAP. As an alternative, Rap1(F64A) is shown by kinetic and cell biological studies to be a Rap1GAP-resistant mutant. This study supports the notion of a completely different mechanism of the Rap1GAP-catalyzed GTP-hydrolysis reaction on Rap1.