ARAP1: a point of convergence for Arf and Rho signaling.

We have identified ARAP1 and ARAP2 and examined ARAP1 as a possible link between phosphoinositide-, Arf-, and Rho-mediated cell signaling. ARAP1 contains Arf GAP, Rho GAP, Ankyrin repeat, Ras-associating, and five PH domains. In vitro, ARAP1 had Rho GAP and phosphatidylinositol (3,4,5) trisphosphate (PIP3)-dependent Arf GAP activity. ARAP1 associated with the Golgi. The Rho GAP activity mediated cell rounding and loss of stress fibers when ARAP1 was overexpressed. The Arf GAP activity mediated changes in the Golgi apparatus and the formation of filopodia, the latter a consequence of increased cellular activity of Cdc42. The Arf GAP and Rho GAP activities both contributed to inhibiting cell spreading. Thus, ARAP1 is a PIP3-dependent Arf GAP that regulates Arf-, Rho-, and Cdc42-dependent cell activities.     

ARAP2 Signals through Arf6 and Rac1 to Control Focal Adhesion Morphology

Focal adhesions (FAs) are dynamic structures that connect the actin cytoskeleton with the extracellular matrix. At least six ADP-ribosylation factor (Arf) GTPase-activating proteins (GAPs), including ARAP2 (an Arf6 GAP), are implicated in regulation of FAs but the mechanisms for most are not well defined. Although Rac1 has been reported to function downstream of Arf6 to control membrane ruffling and cell migration, this pathway has not been directly examined as a regulator of FAs. Here we test the hypothesis that ARAP2 promotes the growth of FAs by converting Arf6·GTP to Arf6·GDP thereby preventing the activation of the Rho family GTP-binding protein Rac1. Reduced expression of ARAP2 decreased the number and size of FAs in cells and increased cellular Arf6·GTP and Rac1·GTP levels. Overexpression of ARAP2 had the opposite effects. The effects of ARAP2 on FAs and Rac1 were dependent on a functional ArfGAP domain. Constitutively active Arf6 affected FAs in the same way as did reduced ARAP2 expression and dominant negative mutants of Arf6 and Rac1 reversed the effect of reduced ARAP2 expression. However, neither dominant negative Arf6 nor Rac1 had the same effect as ARAP2 overexpression. We conclude that changes in Arf6 and Rac1 activities are necessary but not sufficient for ARAP2 to promote the growth of FAs and we speculate that ARAP2 has additional functions that are effector in nature to promote or stabilize FAs.     

Regulation of ASAP1 by phospholipids is dependent on the interface between the PH and Arf GAP domains

ASAP1 is an Arf GAP with a PH domain immediately N-terminal to the catalytic Arf GAP domain. PH domains are thought to regulate enzymes by binding to specific phosphoinositide lipids in membranes, thereby recruiting the enzyme to a site of action. Here, we have examined the functional relationship between the PH and Arf GAP domains. We found that GAP activity requires the cognate PH domain of ASAP1, leading us to hypothesize that the Arf GAP and PH domains directly interact to form the substrate binding site. This hypothesis was supported by the combined results of protection and hydrodynamic studies. We then examined the role of the PH domain in the regulation of Arf GAP activity. The results of saturation kinetics, limited proteolysis, FRET and fluorescence spectrometry support a model in which regulation of the GAP activity of ASAP1 involves a conformational change coincident with recruitment to a membrane surface, and a second conformational change following the specific binding of phosphatidylinositol 4,5-bisphosphate.     

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.     

Autoinhibition of Arf GTPase-activating Protein Activity by the BAR Domain in ASAP1

ASAP1 is an Arf GTPase-activating protein (GAP) that functions on membrane surfaces to catalyze the hydrolysis of GTP bound to Arf. ASAP1 contains a tandem of BAR, pleckstrin homology (PH), and Arf GAP domains and contributes to the formation of invadopodia and podosomes. The PH domain interacts with the catalytic domain influencing both the catalytic and Michaelis constants. Tandem BAR-PH domains have been found to fold into a functional unit. The results of sedimentation velocity studies were consistent with predictions from homology models in which the BAR and PH domains of ASAP1 fold together. We set out to test the hypothesis that the BAR domain of ASAP1 affects GAP activity by interacting with the PH and/or Arf GAP domains. Recombinant proteins composed of the BAR, PH, Arf GAP, and Ankyrin repeat domains (called BAR-PZA) and the PH, Arf GAP, and Ankyrin repeat domains (PZA) were compared. Catalytic power for the two proteins was determined using large unilamellar vesicles as a reaction surface. The catalytic power of PZA was greater than that of BAR-PZA. The effect of the BAR domain was dependent on the N-terminal loop of the BAR domain and was not the consequence of differential membrane association or changes in large unilamellar vesicle curvature. The K_m for BAR-PZA was greater and the k_cat was smaller than for PZA determined by saturation kinetics. Analysis of single turnover kinetics revealed a transition state intermediate that was affected by the BAR domain. We conclude that BAR domains can affect enzymatic activity through intraprotein interactions.The Bin, amphiphysin, RSV161/167 (BAR)² domain is a recently identified structural element in proteins that regulate membrane trafficking (1–7). The BAR superfamily comprises three subfamilies: F-BAR, I-BAR, and BAR. The BAR group can be further subdivided into BAR, N-BAR, PX-BAR, and BAR-pleckstrin homology (PH). The BAR group domains consist of three bundled α-helices that homodimerize to form a banana-shaped structure. The inner curved face can bind preferentially to surfaces with similar curvatures. As a consequence, BAR domains can function as membrane curvature sensors or as inducers of membrane curvature. BAR domains also bind to proteins (8, 9). Several proteins contain a BAR domain immediately N-terminal to a PH domain, which also mediates regulated membrane association (10–13). In the protein APPL1 (9), the BAR-PH domains fold together forming a binding site for the small GTP-binding protein Rab5. Arf GTPase-activating proteins (GAPs) are regulators of Arf family GTP-binding proteins (14–18). Two subtypes of Arf GAPs have N-terminal BAR and PH domains similar to that found in APPL1.Thirty-one genes encode Arf GAPs in humans (16–18). Each member of the family has an Arf GAP domain that catalyzes the hydrolysis of GTP bound to Arf family GTP-binding proteins. The Arf GAPs are otherwise structurally diverse. ASAP1 is an Arf GAP that affects membrane traffic and actin remodeling involved in cell movement and has been implicated in oncogenesis (19–22). ASAP1 contains, from the N terminus, BAR, PH, Arf GAP, Ankyrin repeat, proline-rich, and SH3 domains.ASAP1 contains a BAR domain immediately N-terminal to a PH domain. The PH domain of ASAP1 is functionally integrated with the Arf GAP domain and may form part of the substrate binding pocket (23, 24). The PH domain binds specifically to phosphatidylinositol 4,5-bisphosphate (PIP₂), a constituent of the membrane, leading to stimulation of GAP activity by a mechanism that is, in part, independent of recruitment to membranes (23, 25). The BAR domain of ASAP1 is critical for in vivo function of ASAP1, but the molecular functions of the BAR domain of ASAP1 have not been extensively characterized. Hypotheses related to membrane curvature have been examined. Recombinant ASAP1 can induce the formation of tubules from large unilamellar vesicles, which may be related to a function of ASAP1 in membrane traffic. The BAR domain might also regulate GAP activity of ASAP1. We have considered two mechanisms based on the known properties of BAR domains. First the BAR domain could regulate association of ASAP1 with membrane surfaces containing the substrate Arf1·GTP. The BAR domain could also affect GAP activity through an intramolecular association. In one BAR-PH protein that has been crystallized (APPL1), the two domains fold together to form a protein binding site (9). In ASAP1, the PH domain is functionally integrated with the GAP domain, raising the possibility that the BAR domain affects GAP activity by folding with the PH domain.Here we compared the kinetics of recombinant proteins composed of the PH, Arf GAP, and Ankyrin repeat (PZA)³ or BAR, PH, Arf GAP, and Ankyrin repeat (BAR-PZA) domains of ASAP1 to test the hypothesis that the BAR domain affects enzymatic activity. We found kinetic differences between the proteins that could not be explained by membrane association properties. The results were consistent with a model in which the BAR domain affects transition of ASAP1 through its catalytic cycle.     

Arf GTPase-activating proteins and their potential role in cell migration and invasion

Cell migration is central to normal physiology in embryogenesis, the inflammatory response and wound healing. In addition, the acquisition of a motile and invasive phenotype is an important step in the development of tumors and metastasis. Arf GTPase-activating proteins (GAPs) are nonredundant regulators of specialized membrane surfaces implicated in cell migration. Part of Arf GAP function is mediated by regulating the ADP ribosylation factor (Arf) family GTP-binding proteins. However, Arf GAPs can also function independently of their GAP enzymatic activity, in some cases working as Arf effectors. In this commentary, we discuss examples of Arf GAPs that function either as regulators of Arfs or independently of the GTPase activity to regulate membrane structures that mediate cell adhesion and movement.Key words: Arf GAP, Arf, effector, ADP-ribosylation factor, GTPase-activating protein, focal adhesions, podosomes, invadopodia, cell migrationCell migration involves adhesive structures in which the cell membrane is integrated with the actin cytoskeleton.¹ Cells acquire a spatial asymmetry to enable them to turn intracellular generated forces into a net cell body translocation. With the asymmetry, there is a clear distinction between the cell front and rear. Active membrane processes, including lamellipodia and filopodia, take place primarily around the cell front. Extension of both filopodia and lamellipodia is coupled with local actin polymerization, which generates protrusive force. In some cells, focal complexes form at the leading edge of lamellipodia and filopodia. Focal complexes are specialized surfaces of the plasma membrane that mediate attachment to the substratum, providing traction and allowing the cell edge to protrude. Focal complexes mature with cell migration to form another specialized surface in the plasma membrane, focal adhesions (FAs). FAs localize to the termini of stress fiber bundles and serve in longer-term anchorage at the rear of the cell.² A contractile force is generated at the rear of the cell by the myosin motors to move the cell forward and cell-substratum (extracellular matrix) attachments are released to retract the cell rear. In some cells, podosomes are adhesive structures that mediate cell migration and sometimes invasion.The structures involved in cell migration that are affected by Arf GAPs are FAs, podosomes and invadopodia. FAs contain multiple proteins, including integrins, which are transmembrane proteins.³ The extracellular part of integrins binds to the extracellular matrix. The cytoplasmic domains of integrins associate with multiple signaling proteins as well as proteins that are part of the actin cytoskeleton, thereby coordinating signaling events involved in cell migration and linking the extracellular matrix to the cytoskeleton. Cytoplasmic proteins critical to the function of FAs and that are often used as markers of FAs include vinculin, paxillin and focal adhesion kinase. At least five distinct Arf GAPs have been found to associate with FAs, including GIT1, GIT2, ASAP1, ASAP3 and ARAP2.⁴Podosomes and invadopodia are related structures induced by action of Src (reviewed in ref. ⁵). They contain some proteins in common with FAs, but do have some differences that likely reflect different function and/or regulation. For example, podosomes contain ASAP1 but not ASAP3.⁶ Podosomes and invadopodia have not been examined for the presence of other Arf GAPs. Like FAs, podosomes and invadopodia mediate adhesion to extracellular surfaces. In addition, they are points of degradation of the extracellular matrix and may transfer tension along the extracellular matrix to enable the cell to move. Consistent with the function in motility, podosomes and invadopodia are dynamic structures, turning over in minutes. Podosomes are found in normal physiology of cells including smooth muscle cells, osteoclasts and macrophages and in Src-transformed fibroblasts. Invadopodia are observed in transformed cells, such as cells derived from breast cancers.Two families of GTP-binding proteins within the Ras superfamily, Rho and Arf, are involved in both actin and membrane remodeling. RhoA regulates stress fibers (bundles of actin filaments that traverse the cell and are linked to the extracellular matrix through FAs) and the assembly of FAs.⁷ Rac1 regulates membrane ruffling and lamellipodia formation.⁸ Cdc42 regulates filopodia formation.⁹ Activation of Cdc42 has been shown to lead to the sequential activation of Rac1 and then RhoA in growth factor stimulated fibroblasts.Arf proteins regulate membrane traffic and the actin cytoskeleton.¹⁰ There are six mammalian Arf proteins, divided into three classes based on their amino-acid sequence. Arf12 and 3 are class I, Arf4 and Arf5 are class II and Arf6 is the single member of the class III group. Arf1 and Arf6 have been the most extensively studied. Most work has focused on Arf1 function in the Golgi apparatus and endocytic compartments although Arf1 has been found to affect paxillin recruitment to FAs and trafficking of epidermal growth factor receptor from the plasma membrane. Arf6 affects the endocytic pathway and the peripheral actin cytoskeleton.The function of Rho and Arf family proteins depends on a cycle of binding and hydrolyzing GTP. However, Rho and Arf family proteins have slow intrinsic nucleotide exchange. Rho family proteins have slow intrinsic GTPase activity and Arf family proteins have no detectable intrinsic GTPase activity. The cycle of GTP binding and hydrolysis is driven by accessory proteins called guanine nucleotide exchange factors (GEFs) and GTPase-activating proteins (GAPs). Rho family proteins are also regulated by guanine nucleotide dissociation inhibitors, which prevent spontaneous activation in the cytoplasm.Arf GAPs are enzymes that catalyze the hydrolysis of GTP bound to Arf proteins, thereby converting Arf•GTP to Arf•GDP. Thirty-one genes in human encode proteins with Arf GAP domains (Fig. 1). The Arf GAP family is divided into ten subgroups based on domain structure and phylogenetic analysis.¹¹ Six subgroups contain the Arf GAP domain at the N-terminus of the protein. Four groups contain a tandem of a PH, Arf GAP and Ankyrin repeat domains. The Arf GAP nomenclature is mostly based on the protein domain structure. For instance, the ASAP first identified, ASAP1, contains Arf GAP, SH3, Ank repeat and PH domains; ARAPs contain Arf GAP, Rho GAP, Ank repeat and PH domains; ACAPs contain Arf GAP, coiled-coil (later identified as BAR domain), Ank repeat and PH domains; and AGAPs contain Arf GAP, GTP-binding protein-like, Ank repeat and PH domains.Open in a separate windowFigure 1Domain structure of the Arf GAP family. The schematic representation of the ten groups of proteins containing the Arf GAP domain is not drawn to scale. Abbreviations used are: ALPS, ArfGAP1 lipid-packing sensor domain; Ank, Ankyrin repeats; Arf GAP, Arf GTPase activating domain; BAR, Bin/Amphiphysin/Rvs domain; CALM, CALM binding domain; CB, clathrin box; CC, coiled-coiled domain; FG repeats, multiple copies of the XXFG motif; GLD, GTP-binding protein-like domain; PBS, paxillin binding site; PH, pleckstrin homology domain; Pro (PxxP)₃, cluster of three proline-rich (PxxP) motifs; Pro (D/ELPPKP)₈, eigth tandem Prolin-rich (D/ELPPKP) motifs; RA, Ras association motif; Rho GAP, Rho GTPase activating domain; SAM, sterile α-motif; SH3, Src homology 3 domain; SHD, Spa homology domain. *ASAP2 and ASAP3 lack the Pro (D/ELPPKP)₈ motifs. ASAP3 has no SH3 domain. ^&AGAP2 has a splice variant with three N-terminal PxxP motifs, called PIKE-L. @ARAP2 has an inactive Rho GAP domain.The subcellular localization and function of a number of Arf GAPs have been identified. Arf GAP1, Arf GAP2 and Arf GAP3 are found in the Golgi apparatus where they control membrane traffic by regulating Arf1•GTP levels.^12,13 Arf GAP1 has also been proposed to directly contribute to the formation of transport intermediates.¹⁴ SMAPs and AGAP1 and AGAP2 are associated with endosomes and regulate endocytic trafficking.^14,15 ASAPs, ARAPs and Gits are associated with FAs. ASAPs, ARAPs and ACAPs are found in actin-rich membrane ruffles. ASAP1 is also found in invadopodia and podosomes.⁴ We propose that common to all Arf GAPs is that they laterally organize membranes, which maintain surfaces of specialized functions such as FAs and podosomes/invadopodia. Some Arf GAPs function primarily as Arf effectors with the turnover rate of the specialized membrane surface being determined by the catalytic rate of the GAP. Other Arf GAPs function as Arf regulators that integrate several signals.ASAP1 is an example of an Arf GAP that may function as an Arf effector to regulate podosomes and invadopodia. ASAP1 is encoded by a gene on the short arm of chromosome 8. The gene is amplified in aggressive forms of uveal melanoma and cell migration rates correlate with ASAP1 expression levels in uveal melanoma¹⁶ and other cell types. ASAP1 function depends on cycling among four cellular locations, cytosol, FAs, lamellipodia and podosomes/invadopodia. ASAP1 is necessary for the formation of podosomes/invadopodia.^17,18The structural features of ASAP1 that are required to support podosome formation have been examined.^17,18 ASAP1 contains, from the N-terminus, BAR, PH, Arf GAP, Ank repeat, proline rich and SH3 domains (Fig. 2A).¹⁹ There are two major isoforms, ASAP1a and ASAP1b that differ in the proline rich domain. ASAP1a contains three SH3 binding motifs within the proline rich region including an atypical SH3 binding motif with 6 consecutive prolines. The atypical SH3 binding motif is absent in ASAP1b (Fig. 2A). ASAP1 also has a highly conserved tyrosine between the Ank repeat and proline rich domains that is a site of phosphorylation by the oncogene Src.¹⁸Open in a separate windowFigure 2ASAP1 function in podosome and invadopodia formation. (A) Domain structure of ASAP1 splice variants. ASAP1a contains three proline-rich motifs, P1, P2 and P3. P1 and P3 contain a typical (PxxP) motif. P2 contains six prolines. ASAP1b contains only P1 and P3. (B) Model of ASAP1 functioning as an Arf effector to regulate podosome and invadopodia formation. ASAP1 integrates signals from Src, PIP₂ and Arf•GTP. For abbreviations of the domain structure of ASAP1 see Figure 1. Other abbreviations: PIP₂, phosphoinositides 4,5-biphosphate; Arf1, ADP-ribosylation factor 1.The BAR domain is a bundle of 3 α-helices that homodimerizes to form a boomerang-shaped structure.^20,21 BAR domains sense or induce membrane curvature.²⁰ ASAP1 has been found to induce curvature dependent on its BAR domain.²² BAR domains are also protein binding sites.²¹ The BAR domain of ASAP1 binds to FIP3, a Rab11 and Arf6 binding proteins.²³ Arf6-dependent targeting of ASAP1 is likely mediated by FIP3.²³ Deletion of or introduction of point mutations into the BAR domain render ASAP1 inactive in supporting podosome formation. The relative role of membrane tubulation and protein binding in mediating the effect of the BAR domain on podosome formation has not been explored.The SH3 domain of ASAP1 binds to focal adhesion kinase²⁴ and pyk2.²⁵ Either deletion of or introduction of point mutations into the SH3 domain abrogates the ability of ASAP1 to support podosome formation.¹⁸ The molecular basis for the function of the SH3 domain in podosome formation is not known. The proline rich domain binds to Src¹⁹ and CrkL.²⁶ Whether it also binds to cortactin has not been resolved. Reports also conflict regarding the importance of the proline rich domain for podosomes/invadopodia formation.^17,18Three signals impinge on ASAP1 to drive podosome formation (Fig. 2B). A conserved tyrosine between the Ank and proline rich motifs is phosphorylated by Src.^18,25 Mutation of the tyrosine to phenylalanine results in a protein that functions as a dominant negative blocking podosome formation. ASAP1 with the tyrosine changed to glutamate can support podosome formation, but the mutant ASAP1 is not sufficient to drive podosome formation.¹⁸ Based on these results, phosphorylation of the conserved tyrosine is necessary but not sufficient to support podosome formation. Phosphatidylinositol 4,5-bisphosphate (PIP₂) binds to the PH domain, which stimulates GAP activity in vitro.²⁷ ASAP1 with mutations in the PH domain that abrogate binding, does not support podosome formation (Jian, Bharti and Randazzo PA, unpublished observations). Point mutations in the PH domain affect both the K_m and the k_cat for GAP activity. The effect of mutating the PH domain on the ability of ASAP1 to support podosome formation may be consequent to changes in binding Arf1•GTP; it is not likely the result of loss of GAP activity. ASAP1 with a point mutation in the GAP domain that prevents GAP activity but not Arf1•GTP binding is able to support podosome formation whereas a point mutant of ASAP1 that cannot bind Arf1•GTP does not (Jian, Bharti and Randazzo PA, unpublished observations).¹⁸ These data support the idea that ASAP1 integrates three signals, (1) PIP₂, (2) Src and (3) Arf1•GTP. In response to the signals, ASAP1 functions as a scaffold and directly alters the lipid bilayer to create a domain within the plasma membrane that becomes a podosome. In this model, ASAP1 is functioning as an Arf effector and the GAP activity may regulate the turnover of podosomes.ASAP3, another ASAP-type protein, is found in FAs.⁶ Reducing ASAP3 expression also reduces cell migration and invasion of Arf GAPs in cell migration mammary carcinoma cells through matrigel. Although ASAP3 does not affect the ability to form FAs, it does affect stress fiber formation and may affect focal adhesion maturation (Ha, Chen and Randazzo PA, unpublished observations).⁶ The molecular mechanisms underlying the effects of ASAP3 on the cytoskeleton are being examined including the possibility that, like ASAP1, ASAP3 integrates several signals and functions as an Arf effector.ARAPs are examples of Arf GAP family proteins that function as Arf regulators. In common with ASAPs, they integrate a number of signaling pathways and affect the actin cytoskeleton. Three genes encode ARAPs in humans.¹¹ Each of the ARAPs is comprised of a SAM, five PH, Arf GAP, Rho GAP, Ank repeat and Ras association domains. Two of the five PH domains have the consensus sequence for binding to the signaling lipid phosphoinositide 3,4,5-triphosphate (PIP₃); however, when examined for ARAP1, PIP₃ was not involved in membrane targeting (Campa F, Balla and Randazzo PA, unpublished observations).Examination of the role of ARAP2 in FA formation has provided information about the function of the GAP activity in the cellular function of an Arf GAP. ARAP2 selectively uses Arf6 as a substrate and, different from ARAP1 and ARAP3, has an inactive Rho GAP domain. The Rho GAP domain, however, retains the ability to selectively bind to RhoA•GTP. Also different from ARAP1 and ARAP3, ARAP2 associates with FAs. Cells with reduced expression of ARAP2, consequent to siRNA treatment, have fewer FAs and stress fibers and more focal complexes than control cells. The formation of FAs and stress fibers can be restored by expressing recombinant wild type ARAP2. A mutant of ARAP2 that lacks Arf GAP activity, while retaining the ability to bind to Arf6•GTP, cannot restore FA and stress fiber formation. Similarly, expression of a mutant of ARAP2 that is not able to bind RhoA•GTP cannot reverse the effect of reducing expression of endogenous ARAP2.²⁸ These results support the idea that ARAP2 functions as an Arf GAP that is an effector of RhoA.The model of ARAP2 functioning as a RhoA effector can explain the effects of ARAP2 on FAs (Fig. 3). Arf6•GTP is involved in the formation of Rac1•GTP.²⁹ Rac1•GTP drives lamellipodia and focal complex formation. The conversion of focal complexes to FAs is accompanied by an increase in RhoA•GTP and a decrease in Rac1•GTP. ARAP2 could function to mediate the reciprocal changes in RhoA and Rac1. RhoA•GTP formation leads to the activation of ARAP2. As a consequence of Arf6 GAP activity, Arf6•GTP is converted to Arf6•GDP. With reduced Arf6•GTP, Rac1•GTP concentration also decreases.Open in a separate windowFigure 3Model of ARAP2 as an Arf regulator that controls focal adhesion formation. In this model, ARAP2 functions as a RhoA effector. The inactive Rho GAP domain of ARAP2 binds to RhoA•GTP, which contributes to activation of Arf6 GAP activity. ARAP2 hydrolyzes its substrate Arf6•GTP into Arf6•GDP. Subsequent to Arf6•GTP hydrolysis, Rac1•GTP concentration decreases. For abbreviations of the domain structure of ARAP2 see Figure 1.The Arf GAP activity of other ARAPs may also be critical for cellular functions of the protein. Furthermore, the Rho GAP activity is slow for ARAP1 and ARAP3. It is possible that ARAP1 and ARAP3 can function as Rho effectors with an active Rho GAP domain analogously to ASAP1 functioning as an Arf effector. Further definition of the cellular function of ARAP1 and ARAP3 will provide opportunities to test this idea.We have provided two examples of Arf GAPs that affect cell adhesion and migration. In one case, the Arf GAP appears to function as an Arf effector. In the other case, the Arf GAP functions as a regulator of Arf. The difference in function was discerned using Arf GAP mutants. If functioning as an Arf effector, an Arf GAP mutant that can bind Arf•GTP but not induce hydrolysis can reverse the effect of reduced endogenous Arf GAP, whereas a mutant that cannot bind Arf•GTP cannot replace endogenous Arf GAP. When working as an Arf regulator, a mutant that can bind Arf•GTP but not induce GTP hydrolysis cannot replace endogenous Arf GAP. Whether functioning as an effector or regulator, the rate of GAP activity determines the turnover rate of a specialized membrane surface maintained by Arf.The Arf GAPs have specific sites of action within cells. Some contribute to malignancy, such as ASAP1, ASAP3, AGAP2 and SMAP1.³⁰ The molecular basis of cellular function of each Arf GAPs is distinct. Here, we describe one Arf GAP that functions as an Arf effector and another that functions as an Arf regulator. Each class of Arf GAP has distinct sets of protein binding partners. Furthermore, catalytic mechanism differs among the GAPs. Because of these differences, Arf GAPs may be useful therapeutic targets for cancer therapy.     

A BAR domain in the N terminus of the Arf GAP ASAP1 affects membrane structure and trafficking of epidermal growth factor receptor

BACKGROUND: Arf GAPs are multidomain proteins that function in membrane traffic by inactivating the GTP binding protein Arf1. Numerous Arf GAPs contain a BAR domain, a protein structural element that contributes to membrane traffic by either inducing or sensing membrane curvature. We have examined the role of a putative BAR domain in the function of the Arf GAP ASAP1. RESULTS: ASAP1's N terminus, containing the putative BAR domain together with a PH domain, dimerized to form an extended structure that bound to large unilamellar vesicles containing acidic phospholipids, properties that define a BAR domain. A recombinant protein containing the BAR domain of ASAP1, together with the PH and Arf GAP domains, efficiently bent the surface of large unilamellar vesicles, resulting in the formation of tubular structures. This activity was regulated by Arf1*GTP binding to the Arf GAP domain. In vivo, the tubular structures induced by ASAP1 mutants contained epidermal growth factor receptor (EGFR) and Rab11, and ASAP1 colocalized in tubular structures with EGFR during recycling of receptor. Expression of ASAP1 accelerated EGFR trafficking and slowed cell spreading. An ASAP1 mutant lacking the BAR domain had no effect. CONCLUSIONS: The N-terminal BAR domain of ASAP1 mediates membrane bending and is necessary for ASAP1 function. The Arf dependence of the bending activity is consistent with ASAP1 functioning as an Arf effector.     

A PH Domain in the Arf GTPase-activating Protein (GAP) ARAP1 Binds Phosphatidylinositol 3,4,5-Trisphosphate and Regulates Arf GAP Activity Independently of Recruitment to the Plasma Membranes

ARAP1 is a phosphatidylinositol 3,4,5-trisphosphate (PtdIns(3,4,5)P₃)-dependent Arf GTPase-activating protein (GAP) with five PH domains that regulates endocytic trafficking of the epidermal growth factor receptor (EGFR). Two tandem PH domains are immediately N-terminal of the Arf GAP domain, and one of these fits the consensus sequence for PtdIns(3,4,5)P₃ binding. Here, we tested the hypothesis that PtdIns(3,4,5)P₃-dependent recruitment mediated by the first PH domain of ARAP1 regulates the in vivo and in vitro function of ARAP1. We found that PH1 of ARAP1 specifically bound to PtdIns(3,4,5)P₃, but with relatively low affinity (≈1.6 μm), and the PH domains did not mediate PtdIns(3,4,5)P₃-dependent recruitment to membranes in cells. However, PtdIns(3,4,5)P₃ binding to the PH domain stimulated GAP activity and was required for in vivo function of ARAP1 as a regulator of endocytic trafficking of the EGFR. Based on these results, we propose a variation on the model for the function of phosphoinositide-binding PH domains. In our model, ARAP1 is recruited to membranes independently of PtdIns(3,4,5)P₃, the subsequent production of which triggers enzymatic activity.Pleckstrin homology (PH)² domains are a common structural motif encoded by the human genome (1, 2). Approximately 10% of PH domains bind to phosphoinositides. These PH domains are thought to mediate phosphoinositide-dependent recruitment to membranes (1–3). Most PH domains likely have functions other than or in addition to phosphoinositide binding. For example, PH domains have been found to bind to protein and DNA (4–12). In addition, some PH domains have been found to be structurally and functionally integrated with adjacent domains (13, 14). A small fraction of PH domain-containing proteins (about 9% of the human proteins) have multiple PH domains arranged in tandem, which have been proposed to function as adaptors but have only been examined in one protein (15, 16). Arf GTPase-activating proteins (GAPs) of the ARAP family are phosphatidylinositol 3,4,5-trisphosphate (PtdIns(3,4,5)P₃)-dependent Arf GAPs with tandem PH domains (17, 18). The function of specific PH domains in regulating Arf GAP activity and for biologic activity has not been described.Arf GAPs are proteins that induce the hydrolysis of GTP bound to Arfs (19–23). The Arf proteins are members of the Ras superfamily of GTP-binding proteins (24–27). The six Arf proteins in mammals (five in humans) are divided into three classes based on primary sequence: Arf1, -2, and -3 are class 1, Arf4 and -5 are class 2, and Arf6 is class 3 (23, 24, 27–29). Class 1 and class 3 Arf proteins have been studied more extensively than class 2. They have been found to regulate membrane traffic and the actin cytoskeleton.The Arf GAPs are a family of proteins with diverse domain structures (20, 21, 23, 30). ARAPs, the most structurally complex of the Arf GAPs, contain, in addition to an Arf GAP domain, the sterile α motif (SAM), five PH, Rho GAP, and Ras association domains (17, 18, 31, 32). The first and second and the third and fourth PH domains are tandem (Fig. 1). The first and third PH domains of the ARAPs fit the consensus for PtdIns(3,4,5)P₃ binding (33–35). ARAPs have been found to affect actin and membrane traffic (21, 23). ARAP3 regulates growth factor-induced ruffling of porcine aortic endothelial cells (31, 36, 37). The function is dependent on the Arf GAP and Rho GAP domains. ARAP2 regulates focal adhesions, an actin cytoskeletal structure (17). ARAP2 function requires Arf GAP activity and a Rho GAP domain capable of binding RhoA·GTP. ARAP1 has been found to have a role in membrane traffic (18). The protein associates with pre-early endosomes involved in the attenuation of EGFR signals. The function of the tandem PH domains in the ARAPs has not been examined.Open in a separate windowFIGURE 1.ARAP1 binding to phospholipids. A, schematic of the recombinant proteins used in this study. Domain abbreviations: Ank, ankyrin repeat; PLCδ-PH, PH domain of phospholipase C δ; RA, Ras association motif; RhoGAP, Rho GTPase-activating domain. B, ARAP1 phosphoinositide binding specificity. 500 nm PH1-Ank recombinant protein was incubated with sucrose-loaded LUVs formed by extrusion through a 1-μm pore filter. LUVs contained PtdIns alone or PtdIns with 2.5 μm PtdIns(3,4,5)P₃, 2.5 μm PtdIns(3)P, 2.5 μm PtdIns(4)P, 2.5 μm PtdIns(5)P, 2.5 μm PtdIns(3,4)P₂, 2.5 μm PtdIns(3,5)P₂, or 2.5 μm PtdIns(4,5)P₂ with a total phosphoinositide concentration of 50 μm and a total phospholipid concentration of 500 μm. Vesicles were precipitated by ultracentrifugation, and associated proteins were separated by SDS-PAGE. The amount of precipitated protein was determined by densitometry of the Coomassie Blue-stained gels with standards on each gel. C, PtdIns(3,4,5)P₃-dependent binding of ARAP1 to LUVs. 1 μm PH1-Ank or ArfGAP-Ank recombinant protein was incubated with 1 mm sucrose-loaded LUVs formed by extrusion through a 1-μm pore size filter containing varying concentration of PtdIns(3,4,5)P₃. Precipitation of LUVs and analysis of associated proteins were performed as described in B. The average ± S.E. of three independent experiments is presented.Here we investigated the role of the first two PH domains of ARAP1 for catalysis and in vivo function. The first PH domain fits the consensus sequence for PtdIns(3,4,5)P₃ binding (33–35). The second does not fit a phosphoinositide binding consensus but is immediately N-terminal to the GAP domain. We have previously reported that the PH domain that occurs immediately N-terminal of the Arf GAP domain of ASAP1 is critical for the catalytic function of the protein (38, 39). We tested the hypothesis that the two PH domains of ARAP1 function independently; one recruits ARAP1 to PtdIns(3,4,5)P₃-rich membranes, and the other functions with the catalytic domain. As predicted, PH1 interacted specifically with PtdIns(3,4,5)P₃, and PH2 did not. However, both PH domains contributed to catalysis independently of recruitment to membranes. None of the PH domains in ARAP1 mediated PtdIns(3,4,5)P₃-dependent targeting to plasma membranes (PM). PtdIns(3,4,5)P₃ stimulated GAP activity, and the ability to bind PtdIns(3,4,5)P₃ was required for ARAP1 to regulate membrane traffic. We propose that ARAP1 is recruited independently of PtdIns(3,4,5)P₃ to the PM where PtdIns(3,4,5)P₃ subsequently regulates its GAP activity to control endocytic events.     

The Arf6 GTPase-activating Proteins ARAP2 and ACAP1 Define Distinct Endosomal Compartments That Regulate Integrin α5β1 Traffic

Arf6 and the Arf6 GTPase-activating protein (GAP) ACAP1 are established regulators of integrin traffic important to cell adhesion and migration. However, the function of Arf6 with ACAP1 cannot explain the range of Arf6 effects on integrin-based structures. We propose that Arf6 has different functions determined, in part, by the associated Arf GAP. We tested this idea by comparing the Arf6 GAPs ARAP2 and ACAP1. We found that ARAP2 and ACAP1 had opposing effects on apparent integrin β1 internalization. ARAP2 knockdown slowed, whereas ACAP1 knockdown accelerated, integrin β1 internalization. Integrin β1 association with adaptor protein containing a pleckstrin homology (PH) domain, phosphotyrosine-binding (PTB) domain, and leucine zipper motif (APPL)-positive endosomes and EEA1-positive endosomes was affected by ARAP2 knockdown and depended on ARAP2 GAP activity. ARAP2 formed a complex with APPL1 and colocalized with Arf6 and APPL in a compartment distinct from the Arf6/ACAP1 tubular recycling endosome. In addition, although ACAP1 and ARAP2 each colocalized with Arf6, they did not colocalize with each other and had opposing effects on focal adhesions (FAs). ARAP2 overexpression promoted large FAs, but ACAP1 overexpression reduced FAs. Taken together, the data support a model in which Arf6 has at least two sites of opposing action defined by distinct Arf6 GAPs.     

Arf1 dissociates from the clathrin adaptor GGA prior to being inactivated by Arf GTPase-activating proteins

The effectors of monomeric GTP-binding proteins can influence interactions with GTPase-activating proteins (GAPs) in two ways. In one case, effector and GAP binding to the GTP-binding protein is mutually exclusive. In another case, the GTP-binding protein bound to an effector is the substrate for the GTPase-activating protein. Here predictions for these two mechanisms were tested for the Arf1 effector GGA and ASAP family Arf GAPs. GGA inhibited Arf GAP activity of ASAP1, AGAP1, ARAP1, and Arf GAP1 and inhibited binding of Arf1.GTPgammaS to AGAP1 with K(i) values correlating with the K(d) for the GGA.Arf1 complex. ASAP1 blocked Arf1.GTPgammaS binding to GGA with a K(i) similar to the K(d) for the ASAP.Arf1.GTPgammaS complex. No interaction of GGA with ASAP1 was detected. Consistent with GGA sequestering Arf from GAPs, overexpression of GGA slowed the rate of Arf dissociation from the Golgi apparatus following treatment with brefeldin A. Mutational analysis revealed the amino-terminal alpha-helix and switch I of Arf1 contributed to interaction with both GGA and GAPs. These data exclude the mechanism previously documented for Arf GAP1/coatomer in which Arf1 is inactivated in a tripartite complex. Instead, termination of Arf1 signals mediated through GGA require that Arf1.GTP dissociates from GGA prior to interaction with GAP and consequent hydrolysis of GTP.     

Identification of ARAP3, a novel PI3K effector regulating both Arf and Rho GTPases, by selective capture on phosphoinositide affinity matrices.

We show that matrices carrying the tethered homologs of natural phosphoinositides can be used to capture and display multiple phosphoinositide binding proteins in cell and tissue extracts. We present the mass spectrometric identification of over 20 proteins isolated by this method, mostly from leukocyte extracts: they include known and novel proteins with established phosphoinositide binding domains and also known proteins with surprising and unusual phosphoinositide binding properties. One of the novel PtdIns(3,4,5)P3 binding proteins, ARAP3, has an unusual domain structure, including five predicted PH domains. We show that it is a specific PtdIns(3,4,5)P3/PtdIns(3,4)P2-stimulated Arf6 GAP both in vitro and in vivo, and both its Arf GAP and Rho GAP domains cooperate in mediating PI3K-dependent rearrangements in the cell cytoskeleton and cell shape.     

Substrate specificities and activities of AZAP family Arf GAPs in vivo

The ADP-ribosylation factor (Arf) GTPases are important regulators of vesicular transport in eukaryotic cells. Like other GTPases, the Arfs require guanine nucleotide exchange factors to facilitate GTP loading and GTPase-activating proteins (GAPs) to promote GTP hydrolysis. Whereas there are only six mammalian Arfs, the human genome encodes over 20 proteins containing Arf GAP domains. A subset of these, referred to as AZAPs (Randazzo PA, Hirsch DS. Cell Signal 16: 401-413, 2004), are characterized by the presence of at least one NH(2)-terminal pleckstrin homology domain and two or more ankyrin repeats following the GAP domain. The substrate specificities of these proteins have been previously characterized by using in vitro assay systems. However, a limitation of such assays is that they may not accurately represent intracellular conditions, including posttranslational modifications, or subcellular compartmentalization. Here we present a systematic analysis of the GAP activity of seven AZAPs in vivo, using an assay for measurement of cellular Arf-GTP (Santy LC, Casanova JE. J Cell Biol 154: 599-610, 2001). In agreement with previous in vitro results, we found that ACAP1 and ACAP2 have robust, constitutive Arf6 GAP activity in vivo, with little activity toward Arf1. In contrast, although ARAP1 was initially reported to be an Arf1 GAP, we found that it acts primarily on Arf6 in vivo. Moreover, this activity appears to be regulated through a mechanism involving the NH(2)-terminal sterile-alpha motif. AGAP1 is unique among the AZAPs in its specificity for Arf1, and this activity is dependent on its NH(2)-terminal GTPase-like domain. Finally, we found that expression of AGAP1 induces a surprising reciprocal activation of Arf6, which suggests that regulatory cross talk exists among Arf isoforms.     

Structural basis and mechanism of autoregulation in 3-phosphoinositide-dependent Grp1 family Arf GTPase exchange factors

Arf GTPases regulate membrane trafficking and actin dynamics. Grp1, ARNO, and Cytohesin-1 comprise a family of phosphoinositide-dependent Arf GTPase exchange factors with a Sec7-pleckstrin homology (PH) domain tandem. Here, we report that the exchange activity of the Sec7 domain is potently autoinhibited by conserved elements proximal to the PH domain. The crystal structure of the Grp1 Sec7-PH tandem reveals a pseudosubstrate mechanism of autoinhibition in which the linker region between domains and a C-terminal amphipathic helix physically block the docking sites for the switch regions of Arf GTPases. Mutations within either element result in partial or complete activation. Critical determinants of autoinhibition also contribute to insulin-stimulated plasma membrane recruitment. Autoinhibition can be largely reversed by binding of active Arf6 to Grp1 and by phosphorylation of tandem PKC sites in Cytohesin-1. These observations suggest that Grp1 family GEFs are autoregulated by mechanisms that depend on plasma membrane recruitment for activation.     

Specific regulation of the adaptor protein complex AP-3 by the Arf GAP AGAP1

Arf1 regulates membrane trafficking at several membrane sites by interacting with at least seven different vesicle coat proteins. Here, we test the hypothesis that Arf1-dependent coats are independently regulated by specific interaction with Arf GAPs. We find that the Arf GAP AGAP1 directly associates with and colocalizes with AP-3, a coat protein complex involved in trafficking in the endosomal-lysosomal system. Binding is mediated by the PH domain of AGAP1 and the delta and sigma3 subunits of AP-3. Overexpression of AGAP1 changes the cellular distribution of AP-3, and reduced expression of AGAP1 renders AP-3 resistant to brefeldin A. AGAP1 overexpression does not affect the distribution of other coat proteins, and AP-3 distribution is not affected by overexpression of other Arf GAPs. Cells overexpressing AGAP1 also exhibit increased LAMP1 trafficking via the plasma membrane. Taken together, these results support the hypothesis that AGAP1 directly and specifically regulates AP-3-dependent trafficking.     

Phosphoinositide-dependent activation of the ADP-ribosylation factor GTPase-activating protein ASAP1. Evidence for the pleckstrin homology domain functioning as an allosteric site

The ADP-ribosylation factor (Arf) family of GTP-binding proteins are regulators of membrane traffic and the actin cytoskeleton. Both negative and positive regulators of Arf, the centaurin beta family of Arf GTPase-activating proteins (GAPs) and Arf guanine nucleotide exchange factors, contain pleckstrin homology (PH) domains and are activated by phosphoinositides. To understand how the activities are coordinated, we have examined the role of phosphoinositide binding for Arf GAP function using ASAP1/centaurin beta4 as a model. In contrast to Arf exchange factors, phosphatidylinositol 4, 5-bisphosphate (PtdIns-4,5-P(2)) specifically activated Arf GAP. D3 phosphorylated phosphoinositides were less effective. Activation involved PtdIns-4,5-P(2) binding to the PH domain; however, in contrast to the Arf exchange factors and contrary to predictions based on the current paradigm for PH domains as independently functioning recruitment signals, we found the following: (i) the PH domain was dispensable for targeting to PDGF-induced ruffles; (ii) activation and recruitment could be uncoupled; (iii) the PH domain was necessary for activity even in the absence of phospholipids; and (iv) the Arf GAP domain influenced localization and lipid binding of the PH domain. Furthermore, PtdIns-4,5-P(2) binding to the PH domain caused a conformational change in the Arf GAP domain detected by limited proteolysis. Thus, these data demonstrate that PH domains can function as allosteric sites. In addition, differences from the published properties of the Arf exchange factors suggest a model in which feedforward and feedback loops involving lipid metabolites coordinate GTP binding and hydrolysis by Arf.     

Kinetic studies of the Arf activator Arno on model membranes in the presence of Arf effectors suggest control by a positive feedback loop

Proteins of the cytohesin/Arno/Grp1 family of Arf activators are positive regulators of the insulin-signaling pathway and control various remodeling events at the plasma membrane. Arno has a catalytic Sec7 domain, which promotes GDP to GTP exchange on Arf, followed by a pleckstrin homology (PH) domain. Previous studies have revealed two functions of the PH domain: inhibition of the Sec7 domain and membrane targeting. Interestingly, the Arno PH domain interacts not only with a phosphoinositide (phosphatidylinositol 4,5-bisphosphate or phosphatidylinositol 3,4,5-trisphosphate) but also with an activating Arf family member, such as Arf6 or Arl4. Using the full-length membrane-bound forms of Arf1 and Arf6 instead of soluble forms, we show here that the membrane environment dramatically affects the mechanism of Arno activation. First, Arf6-GTP stimulates Arno at nanomolar concentrations on liposomes compared with micromolar concentrations in solution. Second, mutations in the PH domain that abolish interaction with Arf6-GTP render Arno completely inactive when exchange reactions are reconstituted on liposomes but have no effect on Arno activity in solution. Third, Arno is activated by its own product Arf1-GTP in addition to a distinct activating Arf isoform. Consequently, Arno activity is strongly modulated by competition with Arf effectors. These results show that Arno behaves as a bistable switch, having an absolute requirement for activation by an Arf protein but, once triggered, becoming highly active through the positive feedback effect of Arf1-GTP. This property of Arno might provide an explanation for its function in signaling pathways that, once triggered, must move forward decisively.     

ARAP1 regulates EGF receptor trafficking and signalling

The activation state of the EGF receptor (EGF-R) is tightly controlled in the cell so as to prevent excessive signalling, with the dangerous consequences that this would have on cell growth and proliferation. This control occurs at different levels, with a key level being the trafficking and degradation of the EGF-R itself. Multiple guanosine triphosphatases belonging to the Arf, Rab and Rho families and their accessory proteins have key roles in these processes. In this study, we have identified ARAP1, a multidomain protein with both Arf GTPase-activating protein (GAP) and Rho GAP activities, as a novel component of the machinery that controls the trafficking and signalling of the EGF-R. We show that ARAP1 localizes to multiple cell compartments, including the Golgi complex, as previously reported, and endosomal compartments, where it is enriched in the internal membranes of multivesicular bodies. ARAP1 distribution is controlled by its phosphorylation and by its interactions with the 3- and 4-phosphorylated phosphoinositides through its five PH domains. We provide evidence that ARAP1 controls the late steps of the endocytic trafficking of the EGF-R, with ARAP1 knockdown leading to EGF-R accumulation in a sorting/late endosomal compartment and to the inhibition of EGF-R degradation that is accompanied by prolonged signalling.     

Kinetic analysis of Arf GAP1 indicates a regulatory role for coatomer

Arf GAPs are a family of enzymes that catalyze the hydrolysis of GTP bound to Arf. Arf GAP1 is one member of the family that has a critical role in membrane traffic at the Golgi apparatus. Two distinct models for the regulation of Arf GAP1 in membrane traffic have been proposed. In one model, Arf GAP1 functions in a ternary complex with coat proteins and is inhibited by cargo proteins. In another model, Arf GAP1 is recruited to a membrane surface that has defects created by the increased membrane curvature that accompanies transport vesicle formation. Here we have used kinetic and mutational analysis to test predictions of models of regulation of Arf GAP1. We found that Arf GAP1 has a similar affinity for Arf1.GTP as another Arf GAP, ASAP1, but the catalytic rate is approximately 0.5% that of ASAP1. Coatomer stimulated Arf GAP1 activity; however, different from that predicted from the current model, coatomer affected the K(m) and not the k(cat) values. Effects of most mutations in Arf GAP1 paralleled those in ASAP1. Mutation of an arginine that aligned with an arginine presumed to be catalytic in ASAP1 abrogated activity. Peptide from the cytoplasmic tail of cargo proteins inhibited Arf GAP1; however, the unrelated Arf GAP ASAP1 was also inhibited. The curvature of the lipid bilayer had a small effect on activity of Arf GAP1 under the conditions of our experiments. We conclude that coatomer is an allosteric regulator of Arf GAP1. The relevance of the results to the two models of Arf GAP1-mediated regulation of Arf1 is discussed.     

Kinetic analysis of GTP hydrolysis catalysed by the Arf1-GTP-ASAP1 complex

Arf (ADP-ribosylation factor) GAPs (GTPase-activating proteins) are enzymes that catalyse the hydrolysis of GTP bound to the small GTP-binding protein Arf. They have also been proposed to function as Arf effectors and oncogenes. We have set out to characterize the kinetics of the GAP-induced GTP hydrolysis using a truncated form of ASAP1 [Arf GAP with SH3 (Src homology 3) domain, ankyrin repeats and PH (pleckstrin homology) domains 1] as a model. We found that ASAP1 used Arf1-GTP as a substrate with a k(cat) of 57+/-5 s(-1) and a K(m) of 2.2+/-0.5 microM determined by steady-state kinetics and a kcat of 56+/-7 s(-1) determined by single-turnover kinetics. Tetrafluoroaluminate (AlF4-), which stabilizes complexes of other Ras family members with their cognate GAPs, also stabilized a complex of Arf1-GDP with ASAP1. As anticipated, mutation of Arg-497 to a lysine residue affected kcat to a much greater extent than K(m). Changing Trp-479, Iso-490, Arg-505, Leu-511 or Asp-512 was predicted, based on previous studies, to affect affinity for Arf1-GTP. Instead, these mutations primarily affected the k(cat). Mutants that lacked activity in vitro similarly lacked activity in an in vivo assay of ASAP1 function, the inhibition of dorsal ruffle formation. Our results support the conclusion that the Arf GAP ASAP1 functions in binary complex with Arf1-GTP to induce a transition state towards GTP hydrolysis. The results have led us to speculate that Arf1-GTP-ASAP1 undergoes a significant conformational change when transitioning from the ground to catalytically active state. The ramifications for the putative effector function of ASAP1 are discussed.     

The arf6 GAP centaurin alpha-1 is a neuronal actin-binding protein which also functions via GAP-independent activity to regulate the actin cytoskeleton

Centaurin alpha-1 is a high-affinity PtdIns(3,4,5)P3-binding protein enriched in brain. Sequence analysis indicates centaurin alpha-1 contains two pleckstrin homology domains, ankyrin repeats and an Arf GAP homology domain, placing it in the AZAP family of phosphoinositide-regulated Arf GAPs. Other members of this family are involved in actin cytoskeletal and focal adhesion organization. Recently, it was reported that centaurin alpha-1 expression diminishes cortical actin and decreases Arf6GTP levels consistent with it functioning as an Arf6 GAP in vivo. In the current report, we show that centaurin alpha-1 binds Arfs in vitro and colocalizes with Arf6 and Arf5 in vivo, further supporting an interaction with Arfs. Centaurin alpha-1 expression produces dramatic effects on the actin cytoskeleton, decreasing stress fibers, diminishing cortical actin, and enhancing membrane ruffles and filopodia. Expression of centaurin alpha-1 also enhances cell spreading and disrupts focal adhesion protein localization. The effects of centaurin alpha-1 on stress fibers and cell spreading are reminiscent of those of Arf6GTP. Consistent with this, we show that many of the centaurin alpha-1-induced effects on the actin cytoskeleton and actin-dependent activities do not require GAP activity. Thus, centaurin alpha-1 likely functions via both GAP-dependent and GAP-independent mechanisms to regulate the actin cytoskeleton. Furthermore, we demonstrate that in vitro, centaurin alpha-1 binds F-actin directly, with actin binding activity localized to the PtdIns(3,4,5)P3-binding PH domain. Our data suggest that centaurin alpha-1 may be a component of the neuronal PI 3-kinase cascade that leads to regulation of the neuronal actin cytoskeleton.