Abstract
Rho GDP dissociation inhibitors (rhoGDIs) are postulated to regulate the activity of small G proteins of the Rho family by a shuttling process involving the extraction of Rho from donor membranes, the formation of the inhibitory cytosolic Rho/rhoGDI complexes, and delivery of Rho to target membranes. However, the role of rhoGDIs in site-specific membrane targeting or extraction of Rho is still poorly understood. Here we investigated the molecular functions of two rhoGDIs, the specific rhoGDI-3 and the less specific but well studied rhoGDI-1, in HeLa cells using structure-based mutagenesis of the rhoGDI protein. We identified two sites in rhoGDI, which form conserved interactions with their Rho target, whose mutation results in the uncoupling of inhibitory and shuttling functions of rhoGDIs: D66GDI-3 (equivalent to D45GDI-1), a conserved residue in the helix-loop-helixGDI/switch 1Rho interface, and D206GDI-3 (equivalent to D185GDI-1) in the beta-sandwichGDI/switch 2Rho interface. Mutations of both sites result in the loss of rhoGDI-3 or rhoGDI-1 inhibitory activity but not of their ability to form cytosolic complexes with RhoG or Cdc42 in vivo. Remarkably, the mutants were detected at Rho-induced membrane ruffles or protrusions where they co-localized with RhoG or Cdc42, likely identifying for the first time the site of extraction of a Rho protein by a rhoGDI in vivo. We propose that these mutations act by modifying the steady-state kinetics of the shuttling process regulated by rhoGDIs, such that transient steps at the cell membranes now become detectable. They should provide valuable tools for future investigations of the dynamics of membrane extraction or delivery of Rho proteins and their regulation by cellular partners.
Highlights
Cleotide exchange factors (GEFs)1 and GTPase-activating proteins and determines the conformational differences between inactive and active Rho proteins, while the cytosol/membrane alternation is regulated by Rho GDP dissociation inhibitors
Structure-based Mutagenesis of GDI-3—The RhoG/GDI-3 system was selected for a mutagenesis study of the interactions between the Rho GDP dissociation inhibitors (rhoGDIs) domains and the Rho proteins because it provides a specific phenotypic readout of GDI activity and Rho activation together with limited cellular toxicity upon overexpression [36]
Since the structure of the RhoG/GDI-3 complex is not known, we took advantage of the high sequence identity between GDI-3 and GDI-1 (65% taking into account the helixloop-helix module and the -sandwich domains) and RhoG and Cdc42 (61%) to generate a model of the complex based on the high resolution crystal structure of the Cdc42/GDI-1 complex [15]
Summary
Materials—Monoclonal antibodies against Myc and HA epitopes were from Sigma (clone 9E10 and HA-7, respectively). DNA Constructs—For expression in eukaryotic cells, the GDI-3 sequence containing a Myc tag at the C terminus was cloned in the pCDNA3.1Zeo(ϩ) plasmid (Invitrogen) as described previously [36]. Incubations with anti-Myc mouse monoclonal antibody (1:400) and anti-HA rabbit polyclonal antibody (1:200) were performed in PBS containing 0.25% bovine serum albumin, 0.01% Tween, and 0.01% saponin overnight at 4 °C. After staining with secondary antibody, fixed cells were incubated with a 2 g/ml FITC-labeled lectin solution for 30 min and washed with PBS. The L40 yeast strain was transfected with pFBL23 plasmids containing either GDI-3wt or GDI-3 mutant cDNAs and grown in DO minus tryptophan. The AMR70 yeast strain was transfected with pGAD1318 plasmids containing the RhoG coding sequence and grown in DO minus leucine. The ability of a LexA-fused protein to interact with a protein fused to the GAL4 activation domain was taken into account only when both LacZ and HIS3 reporter genes were activated in the yeast mating assay
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