Structural changes induced in p21Ras upon GAP-334 complexation as probed by ESEEM spectroscopy and molecular-dynamics simulation

BACKGROUND: The means by which the protein GAP accelerates GTP hydrolysis, and thereby downregulates growth signaling by p21Ras, is of considerable interest, particularly inasmuch as p21 mutants are implicated in a number of human cancers. A GAP "arginine finger," identified by X-ray crystallography, has been suggested as playing the principal role in the GTP hydrolysis. Mutagenesis studies, however, have shown that the arginine can only partially account for the 10(5)-fold increase in the GAP-accelerated GTPase rate of p21. RESULTS: We report electron spin-echo envelope modulation (ESEEM) studies of GAP-334 complexed with GMPPNP bound p21 in frozen solution, together with molecular-dynamics simulations. Our results indicate that, in solution, the association of GAP-334 with GTP bound p21 induces a conformational change near the metal ion active site of p21. This change significantly reduces the distances from the amide groups of p21 glycine residues 60 and 13 to the divalent metal ion. CONCLUSIONS: The movement of glycine residues 60 and 13 upon the binding of GAP-334 in solution provides a physical basis to interpret prior mutagenesis studies, which indicated that Gly-60 and Gly-13 of p21 play important roles in the GAP-dependent GTPase reaction. Gly-60 and Gly-13 may play direct catalytic roles and stabilize the attacking water molecule and beta,gamma-bridging oxygen, respectively, in p21. The amide proton of Gly-60 could also play an indirect role in catalysis by supplying a crucial hydrogen bonding interaction that stabilizes loop L4 and therefore the position of other important catalytic residues.     

A C-terminal domain of GAP is sufficient to stimulate ras p21 GTPase activity.

The cDNA for bovine ras p21 GTPase activating protein (GAP) has been cloned and the 1044 amino acid polypeptide encoded by the clone has been shown to bind the GTP complexes of both normal and oncogenic Harvey (Ha) ras p21. To identify the regions of GAP critical for the catalytic stimulation of ras p21 GTPase activity, a series of truncated forms of GAP protein were expressed in Escherichia coli. The C-terminal 343 amino acids of GAP (residues 702-1044) were observed to bind Ha ras p21-GTP and stimulate Ha ras p21 GTPase activity with the same efficiency (kcat/KM congruent to 1 x 10(6) M-1 s-1 at 24 degrees C) as GAP purified from bovine brain or full-length GAP expressed in E. coli. Deletion of the final 61 amino acid residues of GAP (residues 986-1044) rendered the protein insoluble upon expression in E. coli. These results define a distinct catalytic domain at the C terminus of GAP. In addition, GAP contains amino acid similarity with the B and C box domains conserved among phospholipase C-II, the crk oncogene product, and the non-receptor tyrosine kinase oncogene products. This homologous region is located in the N-terminal half of GAP outside of the catalytic domain that stimulates ras p21 GTPase activity and may constitute a distinct structural or functional domain within the GAP protein.     

Mutations of Ha-ras p21 that define important regions for the molecular mechanism of the SDC25 C-domain, a guanine nucleotide dissociation stimulator.

The SDC25 C-domain is a very active guanine nucleotide dissociation stimulator (GDS) isolated from Saccharomyces cerevisiae which acts equally well on Ha-ras p21 and yeast RAS2. These properties make the SDC25 C-domain a suitable tool to study the basic mechanism of a GDS. The action of the SDC25 C-domain was analysed by mutation of structurally important regions of p21. Substitutions that influence the coordination of Mg2+.GDP or the interaction of the guanine ring were found to stimulate the intrinsic dissociation of GDP and suppress the action of the SDC25 C-domain. No relevant effects were observed with mutations in the phosphate binding loop L1 or by deleting the last 23 C-terminal residues of p21. Substitutions in the switch region 1 (loop L2) and 2 (loop L4) of p21 strongly impaired the action of this GDS; however, we show that this effect is not related to a decreased affinity of the SDC25 C-domain for the mutated p21. No functional competition could be found between this GDS and the catalytic domain of the human GTPase activating protein (GAP). This indicates that GDS and GAP bind to different sites of the p21.nucleotide complex, even though the same mutations in loops L2 and L4 regions affect the activity of both effectors. Since these two regions appear not to be involved directly in the interaction with GDS, we conclude that the negative effect induced by their mutation is related to their function as switches of selective conformations during the GDP to GTP exchange reaction catalysed by GDS.     

Localization of the rap1GAP catalytic domain and sites of phosphorylation by mutational analysis.

rap1GAP is a GTPase-activating protein that specifically stimulates the GTP hydrolytic rate of p21rap1. We have defined the catalytic domain of rap1GAP by constructing a series of cDNAs coding for mutant proteins progressively deleted at the amino- and carboxy-terminal ends. Analysis of the purified mutant proteins shows that of 663 amino acid residues, only amino acids 75 to 416 are necessary for full GAP activity. Further truncation at the amino terminus resulted in complete loss of catalytic activity, whereas removal of additional carboxy-terminal residues dramatically accelerated the degradation of the protein in vivo. The catalytic domain we have defined excludes the region of rap1GAP which undergoes phosphorylation on serine residues. We have further defined this phosphoacceptor region of rap1GAP by introducing point mutations at specific serine residues and comparing the phosphopeptide maps of the mutant proteins. Two of the sites of phosphorylation by cyclic AMP (cAMP)-dependent kinase were localized to serine residues 490 and 499, and one site of phosphorylation by p34cdc2 was localized to serine 484. In vivo, rap1GAP undergoes phosphorylation at four distinct sites, two of which appear to be identical to the sites phosphorylated by cAMP-dependent kinase in vitro.     

The BNIP-2 and Cdc42GAP Homology (BCH) Domain of p50RhoGAP/Cdc42GAP Sequesters RhoA from Inactivation by the Adjacent GTPase-activating Protein Domain

The BNIP-2 and Cdc42GAP homology (BCH) domain is a novel regulator for Rho GTPases, but its impact on p50-Rho GTPase-activating protein (p50RhoGAP or Cdc42GAP) in cells remains elusive. Here we show that deletion of the BCH domain from p50RhoGAP enhanced its GAP activity and caused drastic cell rounding. Introducing constitutively active RhoA or inactivating GAP domain blocked such effect, whereas replacing the BCH domain with endosome-targeting SNX3 excluded requirement of endosomal localization in regulating the GAP activity. Substitution with homologous BCH domain from Schizosaccharomyces pombe, which does not bind mammalian RhoA, also led to complete loss of suppression. Interestingly, the p50RhoGAP BCH domain only targeted RhoA, but not Cdc42 or Rac1, and it was unable to distinguish between GDP and the GTP-bound form of RhoA. Further mutagenesis revealed a RhoA-binding motif (residues 85-120), which when deleted, significantly reduced BCH inhibition on GAP-mediated cell rounding, whereas its full suppression also required an intramolecular interaction motif (residues 169-197). Therefore, BCH domain serves as a local modulator in cis to sequester RhoA from inactivation by the adjacent GAP domain, adding to a new paradigm for regulating p50RhoGAP signaling.     

Structural fingerprints of the Ras-GTPase activating proteins neurofibromin and p120GAP

Ras specific GTPase activating proteins (GAPs), neurofibromin and p120GAP, bind GTP bound Ras and efficiently complement its active site. Here we present comparative data from mutations and fluorescence-based assays of the catalytic domains of both RasGAPs and interpret them using the crystal structures. Three prominent regions in RasGAPs, the arginine-finger loop, the phenylalanine-leucine-arginine (FLR) region and alpha7/variable loop contain structural fingerprints governing the GAP function. The finger loop is crucial for the stabilization of the transition state of the GTPase reaction. This function is controlled by residues proximal to the catalytic arginine, which are strikingly different between the two RasGAPs. These residues specifically determine the orientation and therefore the positioning of the arginine finger in the Ras active site. The invariant FLR region, a hallmark for RasGAPs, indirectly contributes to GTPase stimulation by forming a scaffold, which stabilizes Ras switch regions. We show that a long hydrophobic side-chain in the FLR region is crucial for this function. The alpha7/variable loop uses several conserved residues including two lysine residues, which are involved in numerous interactions with the switch I region of Ras. This region determines the specificity of the Ras-RasGAP interaction.     

Comparison of the average structures,from molecular dynamics,of complexes of GTPase activating protein (GAP) with oncogenic and wild-type ras-p21: identification of potential effector domains

GTPase activating protein (GAP) is a known regulator of ras-p21 activity and is a likely target of ras-induced mitogenic signaling. The domains of GAP that may be involved in this signaling are unknown. In order to infer which domains of GAP may be involved, we have performed molecular dynamics calculations of GAP complexed to wild-type and oncogenic (Val 12–containing) ras-p21, both bound to GTP. We have computed and superimposed the average structures for both complexes and find that there are four domains of GAP that undergo major changes in conformation: residues 821–851, 917–924, 943–953, and 1003–1020. With the exception of the 943–953 domain, none of these domains is involved in making contacts with ras-p21, and all of them occur on the surface of the protein, making them good candidates for effector domains. In addition, three ras-p21 domains undergo major structural changes in the oncogenic p21-GAP complex: 71–76 from the switch 2 domain; 100–108, which interacts with SOS, jun and jun kinase (JNK); and residues 122–138. The change in conformation of the 71–76 domain appears to be induced by changes in conformation in the switch 1 domain (residues 32–40) and in the adjacent domain involving residues 21–31. In an accompanying paper, we present results from microinjection of peptides corresponding to each of these domains into oocytes induced to undergo maturation by oncogenic ras-p21 and by insulin-activated wild-type cellular p21 to determine whether these domain peptides may be involved in ras signaling through GAP.     

Dynamic interaction between Arf GAP and PH domains of ASAP1 in the regulation of GAP activity

ASAP family Arf GAPs induce the hydrolysis of GTP bound to the Ras superfamily protein Arf1, regulate cell adhesion and migration and have been implicated in carcinogenesis. The ASAP proteins have a core catalytic domain of PH, Arf GAP and Ank repeat domains. The PH domain is necessary for both biological and catalytic functions of ASAP1 and has been proposed to be integrally folded with the Arf GAP domain. Protection studies and analytical ultracentrifugation studies previously reported indicated that the domains are, at least partly, folded together. Here, using NMR spectroscopy and biochemical analysis, we have further tested this hypothesis and characterized the interdomain interaction. A comparison of NMR spectra of three recombinant proteins comprised of either the isolated PH domain of ASAP1, the Arf GAP and ankyrin repeat domain or all three domains indicated that the PH domain did interact with the Arf GAP and Ank repeat domains; however, we found a significant amount of dynamic independence between the PH and Arf GAP domains, consistent with the interactions being transient. In contrast, the Arf GAP and Ank repeat domains form a relatively rigid structure. The PH-Arf GAP domain interaction partially occluded the phosphoinositide binding site in the soluble protein, but binding studies indicated the PIP2 binding site was accessible in ASAP1 bound to a lipid bilayer surface. Phosphoinositide binding altered the conformation of the PH domain, but had little effect on the structure of the Arf GAP domain. Mutations in a loop of the PH domain that contacts the Arf GAP domain affected PIP2 binding and the K(m) and k(cat) for converting Arf1 GTP to Arf1 GDP. Based on these results, we generated a homology model of a composite PH/Arf GAP/Ank repeat domain structure. We propose that the PH domain contributes to Arf GAP activity by either binding to or positioning Arf1 GTP that is simultaneously bound to the Arf GAP domain.     

Three-dimensional structures of H-ras p21 mutants: molecular basis for their inability to function as signal switch molecules

The X-ray structures of the guanine nucleotide binding domains (amino acids 1-166) of five mutants of the H-ras oncogene product p21 were determined. The mutations described are Gly-12----Arg, Gly-12----Val, Gln-61----His, Gln-61----Leu, which are all oncogenic, and the effector region mutant Asp-38----Glu. The resolutions of the crystal structures range from 2.0 to 2.6 A. Cellular and mutant p21 proteins are almost identical, and the only significant differences are seen in loop L4 and in the vicinity of the gamma-phosphate. For the Gly-12 mutants the larger side chains interfere with GTP binding and/or hydrolysis. Gln-61 in cellular p21 adopts a conformation where it is able to catalyze GTP hydrolysis. This conformation has not been found for the mutants of Gln-61. Furthermore, Leu-61 cannot activate the nucleophilic water because of the chemical nature of its side chain. The D38E mutation preserves its ability to bind GAP.     

GAP1 family members constitute bifunctional Ras and Rap GTPase-activating proteins

GAP1(IP4BP) is a member of the GAP1 family of Ras GTPase-activating proteins (Ras GAPs) that includes GAP1(m), CAPRI, and RASAL. Composed of a central Ras GAP domain, surrounded by amino-terminal C(2) domains and a carboxyl-terminal pleckstrin homology/Bruton's tyrosine kinase domain, GAP1(IP4BP) has previously been shown to possess an unexpected GAP activity on the Ras-related protein Rap, besides the predicted Ras GAP activity (Cullen, P. J., Hsuan, J. J., Truong, O., Letcher, A. J., Jackson, T. R., Dawson, A. P., and Irvine, R. F. (1995) Nature 376, 527-530). Here we have shown that GAP1(IP4BP) is indeed an efficient Ras/Rap GAP, having K(m)s of 213 and 42 microm and estimated k(cat)s of 48 and 16 s(-1) for Ras and Rap, respectively. For this dual activity, regions outside the Ras GAP domain are required, as the isolated domain (residues 291-569) retains a pronounced Ras GAP activity yet has very low activity toward Rap. Interestingly, mutagenesis of the Ras GAP arginine finger, and surrounding residues important in Ras binding, inhibit both Ras and Rap GAP activity of GAP1(IP4BP). Although the precise details by which GAP1(IP4BP) can function as a Rap GAP remain to be determined, these data are consistent with Rap associating with GAP1(IP4BP) through the Ras-binding site within the Ras GAP domain. Finally, we have established that such dual Ras/Rap GAP activity is not restricted to GAP1(IP4BP). Although GAP1(m) appears to constitute a specific Ras GAP, CAPRI and RASAL display dual activity. For CAPRI, its Rap GAP activity is modulated upon its Ca(2+)-induced association with the plasma membrane.     

Asparagine 26, glutamic acid 31, valine 45, and tyrosine 64 of Ras proteins are required for their oncogenicity.

Ras and Rap1 proteins are related GTP-dependent signal transducers which require Gly-12, the effector domain (residues 32-40), and Ala-59 for stimulation of their GTPase activities by GAP1 and GAP3, respectively. The replacement of Gly-12 by Val or Ala-59 by Thr potentiates the Ras oncogenicity and Rap1A antioncogenicity. However, the mutations in the effector domain, in particular the replacement of Thr-35 by Ala, abolish both Ras oncogenicity and Rap1A antioncogenicity, indicating that the effector domain is involved in interactions of these signal transducers with their targets as well as the GAPs. In this paper, we demonstrate that (i) replacement of Tyr-64 of the Ha-Ras protein or Phe-64 of the Rap1A protein by Glu or other non-hydrophobic amino acids reduces their intrinsic GTPase activities and abolishes their stimulation by GAP1 or GAP3, respectively, (ii) replacement of Tyr-64 by Gly and other non-hydrophobic amino acids results in complete loss of the oncogenicity of the v-Ha-Ras protein, indicating that the hydrophobic residue 64, in addition to the known effector domain, is essential for the Ras protein to interact with its target as well as GAP1. In addition we have found that Asn-26, Glu-31, and Val-45 of the v-Ha-Ras protein are required for its oncogenicity. Replacement of the Ras residues at either positions 26, 31, or 45 by the corresponding Rap1A residues abolishes the Ras oncogenicity.     

Investigating the role played by protein-lipid and protein-protein interactions in the membrane association of the p120GAP CaLB domain.

The GTPase activating protein, p120GAP, contains an amino acid sequence motif called the Ca2+-dependent lipid binding domain (CaLB) which mediates a protein-protein interaction between p120GAP and annexin VI and also binds to negatively charged phospholipids. Because membrane association of p120GAP is important for the regulation of p21 Ras activity, we have studied the roles played by Ca2+, phospholipids and annexin VI in the membrane association of p120GAP. Here we demonstrate that a truncated CaLB domain GST fusion protein (GSTGAP618-632), lacking the ability to bind to phospholipids, is able to bind to rat fibroblast membranes in a Ca2+- and concentration-dependent manner. In addition, this fusion protein also binds to annexin VI in an amino acid sequence specific but Ca2+ independent manner. Also, when bound to annexin VI in the presence of Ca2+, this fusion protein has the ability to co-bind to phosphatidylserine vesicles. Thus, annexin VI may simultaneously mediate an interaction with p120GAP and also an interaction with membrane phospholipids. This may in part explain the mechanism by which p120GAP associates with membranes in response to Ca2+ elevation and suggests the potential importance of annexin VI in the regulation of p21 Ras and the role CaLB domains may play in the specific recognition of cellular membranes.     

The N-terminal region of GAP regulates cytoskeletal structure and cell adhesion.

Ras GTPase activating protein (GAP) possesses a C-terminal domain that interacts with GTP-bound Ras, and an N-terminal region containing two SH2 domains and an SH3 domain. In addition to its association with Ras, GAP binds stably to autophosphorylated beta PDGF receptors, and to two cytoplasmic phosphoproteins: p62, an RNA binding protein, and p190, which possesses GAP activity towards small guanine nucleotide binding proteins in the Rho/Rac family. To define the region of GAP that mediates these interactions with cellular phosphoproteins, and to investigate the biological significance of these complexes, a truncated GAP polypeptide (GAP-N) containing residues 1-445 was stably expressed in Rat-2 fibroblasts. GAP-N contains the SH2 and SH3 domains, but lacks the Ras GTPase activating domain. Stimulation of cells expressing GAP-N with PDGF induced association of GAP-N with the beta PDGF receptor, and phosphorylation of GAP-N on tyrosine, consistent with the notion that GAP SH2 domains direct binding to the autophosphorylated beta PDGF receptor in vivo. GAP-N bound constitutively to p190 in both serum-deprived and growth factor-stimulated cells. This GAP-N-p190 complex had Rho GAP activity in vitro. The expression of GAP-N in Rat-2 cells correlated with changes in the cytoskeleton and in cell adhesion, typified by the disruption of action stress fibres, a reduction in focal contacts, and an impaired ability to adhere to fibronectin. These results suggest that the N-terminal domain of GAP can direct interactions with cellular phosphoproteins in vivo, and thereby exert an effector function which modulates the cytoskeleton and cell adhesion.(ABSTRACT TRUNCATED AT 250 WORDS)     

The epidermal growth factor receptor phosphorylates GTPase-activating protein (GAP) at Tyr-460, adjacent to the GAP SH2 domains.

GTPase-activating protein (GAP) stimulates the ability of p21ras to hydrolyze GTP to GDP. Since GAP is phosphorylated by a variety of activated or oncogenic protein-tyrosine kinases, it may couple tyrosine kinases to the Ras signaling pathway. The epidermal growth factor (EGF) receptor cytoplasmic domain phosphorylated human GAP in vitro within a single tryptic phosphopeptide. The same GAP peptide was also apparently phosphorylated on tyrosine in EGF-stimulated rat fibroblasts. Circumstantial evidence suggested that residue 460 might be the site of GAP tyrosine phosphorylation. This possibility was confirmed by phosphorylation of a synthetic peptide corresponding to the predicted tryptic peptide containing Tyr-460. Alteration of Tyr-460 to phenylalanine by site-directed mutagenesis diminished the in vitro phosphorylation of a bacterial GAP polypeptide by the EGF receptor. We conclude that Tyr-460 is a site of GAP tyrosine phosphorylation by the EGF receptor in vitro and likely in vivo. GAP Tyr-460 is located immediately C terminal to the second GAP SH2 domain, suggesting that its phosphorylation might have a role in regulating protein-protein interactions.     

The Ras/p120 GTPase-activating protein (GAP) interaction is regulated by the p120 GAP pleckstrin homology domain

Pleckstrin homology domains are structurally conserved functional domains that can undergo both protein/protein and protein/lipid interactions. Pleckstrin homology domains can mediate inter- and intra-molecular binding events to regulate enzyme activity. They occur in numerous proteins including many that interact with Ras superfamily members, such as p120 GAP. The pleckstrin homology domain of p120 GAP is located in the NH(2)-terminal, noncatalytic region of p120 GAP. Overexpression of the noncatalytic domains of p120 GAP may modulate Ras signal transduction pathways. Here, we demonstrate that expression of the isolated pleckstrin homology domain of p120 GAP specifically inhibits Ras-mediated signaling and transformation but not normal cellular growth. Furthermore, we show that the pleckstrin homology domain binds the catalytic domain of p120 GAP and interferes with the Ras/GAP interaction. Thus, we suggest that the pleckstrin homology domain of p120 GAP may specifically regulate the interaction of Ras with p120 GAP via competitive intra-molecular binding.     

Rsr1 and Rap1 GTPases are activated by the same GTPase-activating protein and require threonine 65 for their activation

The Rsr1 protein of Saccharomyces cerevisiae has been shown to be essential for bud site selection (Bender, A., and Pringle, J. (1989) Proc. Natl. Acad. Sci. U.S.A. 86, 9976-9980). This protein of 272 amino acids shares approximately 50% sequence identity with both Ras and Rap GTPases. However, neither GTP binding nor GTPase activity of the Rsr1 protein has been reported. The Rsr1 protein shares with human Rap1 GTPases the four specific motifs, i.e. Gly-12, residues 32-40, Ala-59, and residues 64-70, that are required for GAP3-dependent activation of the Rap1 GTPases. In this paper we demonstrate that the intrinsic GTPase activity of the Rsr1 protein is stimulated by GAP3 purified from bovine brain cytosol. The Rsr1 GTPase is not activated by either GAP1 or GAP2 which are specific for the Ras and Rho GTPases, respectively. Thus, it appears that the Rsr1 GTPase is a new member of the Rap1 GTPase family. Replacement of Gly-12 by Val in the Rsr1 GTPase completely abolishes the GAP3-dependent activation. The chimeric GTPases, Ras(1-60)/Rsr1(61-168) and Rsr1(1-65)/Ras(66-189), are activated by GAP3 but not by GAP1. Replacement of Thr-65 by Ser in the latter chimeric GTPase completely abolishes the GAP3-dependent activation, indicating that Thr-65 is required for distinguishing GAP3 from GAP1. We have previously shown that Gln-61 and Ser-65 are sufficient to determine the GAP1 specificity. Replacement of Thr-35 by Ala in the common effector domain (residues 32-40) of the chimeric Ras/Rsr1 GTPases completely abolishes GAP3-dependent activation.     

Evidence for a novel Cdc42GAP domain at the carboxyl terminus of BNIP-2

We recently identified BNIP-2, a previously cloned Bcl-2- and E1B-associated protein, as a putative substrate of the FGF receptor tyrosine kinase and showed that it possesses GTPase-activating activity toward Cdc42 despite the lack of homology to previously described catalytic domains of GTPase-activating proteins (GAPs). BNIP-2 contains many arginine residues at the carboxyl terminus, which includes the region of homology to the noncatalytic domain of Cdc42GAP, termed BNIP-2 and Cdc42GAP homology (BCH) domain. Using BNIP-2 glutathione S-transferase recombinants, it was found that its BCH bound Cdc42, and contributed the GAP activity. This domain was predicted to fold into alpha-helical bundles similar to the topology of the catalytic GAP domain of Cdc42GAP. Alignment of exposed arginine residues in this domain helped to identify Arg-235 and Arg-238 as good candidates for catalysis. Arg-238 matched well to the arginine "finger" required for enhanced GTP hydrolysis in homodimerized Cdc42. Site-directed mutagenesis confirmed that an R235K or R238K mutation severely impaired the BNIP-2 GAP activity without affecting its binding to Cdc42. From deletion studies, a region adjacent to the arginine patch ((288)EYV(290) on BNIP-2) and the Switch I and Rho family-specific "Insert" region on Cdc42 are involved in the binding. The results indicate that the BCH domain of BNIP-2 represents a novel GAP domain that employs an arginine patch motif similar to that of the Cdc42-homodimer.     

Studies on the structure and mechanism of H-ras p21.

Current knowledge of the structure of H-ras p21 is reviewed with particular emphasis on the interaction between guanine nucleotides and the active site of the protein. The nature of the conformational change induced by GTP hydrolysis is discussed. The major change is seen in the region known as the effector loop (loop 2), with significant but less well-defined changes occurring in loop 4, which is implicated in the GTPase reaction. Other evidence concerning the mechanism of GTP hydrolysis and its activation by GAP (GTPase-activating protein) is also discussed. Evidence regarding the rate limiting step in the p21 GTPase reaction, and the manner in which this and possibly other steps are accelerated by GAP, is inconclusive.     

Distinct phosphoinositide binding specificity of the GAP1 family proteins: characterization of the pleckstrin homology domains of MRASAL and KIAA0538

GAP1, one of the Ras GTPase-activating protein families, includes four distinct genes (GAP1(m), GAP1(IP4BP), MRASAL (murine Ras GTPase-activating-like), and KIAA0538). It contains an amino-terminal tandem C2 domain, a GAP-related domain, and a carboxyl-terminal pleckstrin homology (PH) domain. Although the PH domains of GAP1(m) and GAP1(IP4BP) have been shown to be essential for membrane targeting via binding of specific phospholipids, little is known about the functions of the PH domains of MRASAL and KIAA0538. Herein, we show that the PH domain of MRASAL has binding activity toward PI(4,5)P(2) and PI(3,4,5)P(3), while the PH domain of KIAA0538 does not bind these phospholipids due to an amino acid substitution at position 592 (Leu-592). Mutation of the corresponding position of MRASAL (Arg-to-Leu substitution at position 591) resulted in loss of the phospholipid binding activity. MRASAL proteins were localized at the plasma membrane in NIH3T3 cells, and this plasma membrane association was unchanged even after cytochalasin B or wortmannin treatment. By contrast, KIAA0538 and MRASAL (R591L) proteins were present in the cytosol. Our data indicate that the distinct phosphoinositide binding specificity of the PH domain is attributable to the distinct subcellular localization of the GAP1 family.     

Subcellular location, phosphorylation and assembly into the motor complex of GAP45 during Plasmodium falciparum schizont development

An actomyosin motor complex assembled below the parasite's plasma membrane drives erythrocyte invasion by Plasmodium falciparum merozoites. The complex is comprised of several proteins including myosin (MyoA), myosin tail domain interacting protein (MTIP) and glideosome associated proteins (GAP) 45 and 50, and is anchored on the inner membrane complex (IMC), which underlies the plasmalemma. A ternary complex of MyoA, MTIP and GAP45 is formed that then associates with GAP50. We show that full length GAP45 labelled internally with GFP is assembled into the motor complex and transported to the developing IMC in early schizogony, where it accumulates during intracellular development until merozoite release. We show that GAP45 is phosphorylated by calcium dependent protein kinase 1 (CDPK1), and identify the modified serine residues. Replacing these serine residues with alanine or aspartate has no apparent effect on GAP45 assembly into the motor protein complex or its subcellular location in the parasite. The early assembly of the motor complex suggests that it has functions in addition to its role in erythrocyte invasion.