Identification and Characterization of RBEL1 Subfamily of GTPases in the Ras Superfamily Involved in Cell Growth Regulation

Recently, we reported the identification of a novel gene named RBEL1 (Rab-like protein 1) and characterized its two encoded isoforms, RBEL1A and RBEL1B, that function as novel GTPases of Ras superfamily. Here we report the identification of two additional splice variants of RBEL1 that we have named RBEL1C and -D. All four RBEL1 isoforms (A, B, C, and D) have identical N termini harboring the Rab-like GTPase domains but contain variable C termini. Although all isoforms can be detected in both cytoplasm and nucleus, RBEL1A is predominantly cytoplasmic, whereas RBEL1B is mostly nuclear. RBEL1C and -D, by contrast, are evenly distributed between the cytoplasm and nucleus. Furthermore, all four RBEL1 proteins are also capable of associating with cellular membrane. The RBEL1 proteins also exhibit a unique nucleotide-binding potential and, whereas the larger A and B isoforms are mainly GTP-bound, the smaller C and D variants bind to both GTP and GDP. Furthermore, a regulatory region at amino acid position 236–302 immediately adjacent to the GTP-binding domain is important for GTP-binding potential of RBEL1A, because deletion of this region converts RBEL1A from predominantly GTP-bound to GDP-bound. RBEL1 knockdown via RNA interference results in marked cell growth suppression, which is associated with morphological and biochemical features of apoptosis as well as inhibition of extracellular signal-regulated kinase phosphorylation. Taken together, our results indicate that RBEL1 proteins are linked to cell growth and survival and possess unique biochemical, cellular, and functional characteristics and, therefore, appear to form a novel subfamily of GTPases within the Ras superfamily.The Ras superfamily is known to comprise five structurally distinct subfamilies of small GTPases, including Ras, Rho, Rab, Sar1/Arf, and Ran, and each subfamily of these GTPases possess distinct functions in the regulation of a variety of cellular processes such as cell proliferation, cell differentiation, cytoskeletal organization, protein transport, and trafficking (1–4). The Ras subfamily of GTPases (N-, H-, and K-Ras) function predominantly in relaying signals from receptors at the plasma membrane and modulating cell signaling pathways that regulate cell proliferation, differentiation, and survival (5). Ran GTPase, on other hand, is a key regulator of nucleocytoplasmic transport that regulates protein transport across the nuclear pore complex (6, 7). The Rab subfamily is the largest subfamily among the Ras superfamily and contains more than 60 members. The key functions of the Rab GTPases are to regulate protein exocytic and endocytic pathways and modulate intracellular protein transport/trafficking (8–13).In general, the Ras superfamily GTPases cycle between an active GTP-bound state and an inactive GDP-bound state. There are five N-terminal motifs involved in the binding and hydrolysis of GTP that are highly conserved among all GTPases: G1 (GXXXXGK(S/T)), G2 (T), G3 (DXXG), G4 ((N/T)(K/Q)XD), and G5 (EXSAX). Each sequence has particular functions involved in binding nucleotides (GTP or GDP) and facilitating hydrolysis (4, 14, 15). In general, the intrinsic GTPase activity (converting GTP to GDP) and exchange of GDP for GTP are slow processes for these GTPases and thus require regulatory proteins such as GTPase-activating proteins and GDP/GTP exchange factors to facilitate these processes (16–18).For the last two decades, the Ras superfamily has been a major focus in the cancer field as many of the members are either mutated or dysregulated in cancer. The founding members of the Ras superfamily, H-Ras and K-Ras, were first identified as viral oncogenes (1, 4). Later studies demonstrated that mutations of the Ras proteins (H-, N-, and K-Ras) occur frequently in human cancers, and the mutations identified are mostly clustered within the GTP-binding domains of the proteins thus locking Ras proteins in a GTP-bound configuration. GTP-bound Ras is constitutively active; it constantly activates its effector proteins to transduce cell proliferative signals (1, 4). Unlike Ras subfamily genes, mutations occurring in Rab and Rab-like genes are less common, yet alterations in gene expression of a number of Rab genes have been reported in multiple human malignancies. For example, Rab25 overexpression has been linked to prostate cancer progression (19). Rab2 overexpression has been found in lung adenomas and adenocarcinomas (20). In addition, alterations in Rab gene expression have also been linked to cancer drug resistance. For instance, resistance to the anticancer drug doxorubicin in MCF-7 cells has been linked with reduced expression of Rab6C, and introduction of exogenous Rab6C restores drug sensitivity (21).We have recently reported the identification two novel Ras superfamily GTPases, RBEL1A and RBEL1B (22). RBEL1A and RBEL1B are two splice variants of the RBEL1 gene and are highly homologous to the Rab and Ran GTPases within their N-terminal GTP-binding domains (22). Our studies show that both RBEL1A and -B predominantly bind to GTP. A single point mutation (T57N) in the GTP-binding domain of RBEL1A and -B abolishes their ability to bind to both GTP and GDP. Both RBEL1A and RBEL1B localize in the nucleus as well as in the cytosol. Whereas RBEL1A is predominantly cytosolic, RBEL1B is primarily nuclear. Interestingly, our studies also suggested that nucleotide (GTP or GDP)-binding could be important for the nuclear distribution of RBEL1B, because the nucleotide binding-deficient mutant form (T57N) of RBEL1B did not reside in the nucleus but rather became largely cytosolic (22).In our continuous efforts to fully elucidate the function of RBEL1, we have identified two additional splice variants that we have named RBEL1C and RBEL1D. Here we report further characterization of all four RBEL1 splice variants in terms of their GTPase activities, subcellular localizations, regulations, and potential functions. Our results indicate that RBEL1 GTPases, although sharing some common features with other Ras superfamily members, also harbor unique characteristics that are significantly different from other Ras superfamily GTPases. Based on our findings, we suggest that RBEL1 proteins appear to form a novel subfamily of GTPases within the Ras superfamily.