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Small GTPases are G-proteins in the cytosol which are homologous to the alpha subunit of heterotrimeric G-proteins. Unlike them they can function on their own. The most well-known members are the Ras GTPases and hence they are sometimes called Ras superfamily GTPases.
A typical G-protein is active when bound to GTP and inactive when bound to GDP (i.e. when the GTP is hydrolyzed to GDP). The GDP can be then replaced by free GTP. Therefore, a G-protein can be switched on and off. GTP hydrolysis is accelerated by GTPase activating proteins (GAPs), while GTP exchange is catalyzed by Guanine nucleotide exchange factors (GEFs). Activation of a GEF typically activates its cognate G-protein, while activation of a GAP results in inactivation of the cognate G-protein. Guanosine nucleotide dissociation inhibitors (GDI) maintain small GTP-ases in the inactive state.
Small GTPases regulate a wide variety of processes in the cell, including growth, cellular differentiation, cell movement and lipid vesicle transport.
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The Ras superfamily
There are more than a hundred proteins in the Ras superfamily.[1] Based on structure, sequence and function, the Ras superfamily is divided into eight main families, each of which is further divided into subfamilies: Ras, Rho, Rab, Rap, Arf, Ran, Rheb, Rad and Rit. Miro is a recent contributor to the superfamily.
Each subfamily shares the common core G domain, which provides essential GTPase and nucleotide exchange activity.
The surrounding sequence helps determine the functional specificity of the small GTPase, for example the 'Insert Loop', common to the Rho subfamily, specifically contributes to binding to effector proteins such as IQGAP and WASP.
The Ras family is generally responsible for cell proliferation, Rho for cell morphology, Ran for nuclear transport and Rab and Arf for vesicle transport.[2]
Human proteins containing Ras domain
ARHE; ARHGAP5; CDC42; DIRAS1; DIRAS2; DIRAS3; ERAS; GEM; GRLF1; HRAS; KRAS; LOC393004; MRAS; NKIRAS1; NRAS; RAB10; RAB11A; RAB11B; RAB12; RAB13; RAB14; RAB15; RAB17; RAB18; RAB19; RAB1A; RAB1B; RAB2; RAB20; RAB21; RAB22A; RAB23; RAB24; RAB25; RAB26; RAB27A; RAB27B; RAB28; RAB2B; RAB30; RAB31; RAB32; RAB33A; RAB33B; RAB34; RAB35; RAB36; RAB37; RAB38; RAB39; RAB39B; RAB3A; RAB3B; RAB3C; RAB3D; RAB40A; RAB40AL; RAB40B; RAB40C; RAB41; RAB42; RAB43; RAB4A; RAB4B; RAB5A; RAB5B; RAB5C; RAB6A; RAB6B; RAB6C; RAB7A; RAB7B; RAB7L1; RAB8A; RAB8B; RAB9; RAB9B; RABL2A; RABL2B; RABL4; RAC1; RAC2; RAC3; RALA; RALB; RAN; RANP1; RAP1A; RAP1B; RAP2A; RAP2B; RAP2C; RASD1; RASD2; RASEF; RASL11A; RASL12; RBJ; REM1; REM2; RERG; RHEB; RHEBL1; RHOA; RHOB; RHOBTB1; RHOBTB2; RHOC; RHOD; RHOF; RHOG; RHOH; RHOJ; RHOQ; RHOU; RHOV; RIT1; RIT2; RND1; RND2; RND3; RRAD; RRAS; RRAS2;
See also
References
- ^ Wennerberg K, Rossman KL, Der CJ (March 2005). "The Ras superfamily at a glance". J. Cell. Sci. 118 (Pt 5): 843–6. doi:. PMID 15731001.
- ^ Munemitsu S, Innis M, Clark R, McCormick F, Ullrich A, Polakis P. (1990). "Molecular cloning and experssion of a G25K cDNA, the human homolog of the yeast cell cycle gene CDC42". Mol Cell Biol 10 (11): 5977–82. ISSN 0270-7306. PMID 2122236.
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