The CDM protein DOCK2 in lymphocyte migration

T and B lymphocytes migrate hundreds of micrometers each day to survey the body's lymphoid tissues for antigens. No other mammalian cell type undergoes such extensive and continual movement, raising the question of whether lymphocytes have specializations to support their migratory behavior. This possibility has recently gained support from studies of mice deficient in DOCK2, a member of the Caenorhabditis elegans Ced-5, mammalian DOCK180 and Drosophila melanogaster myoblast city (CDM) family of scaffolding proteins. Migration of lymphocytes, but not other cell types, is severely disrupted in DOCK2-deficient mice. Despite the conserved role of CDM molecules in regulating Rac activation and actin assembly, relatively little is known about how these molecules function. Here, we review the role of DOCK2 in lymphocyte homing to lymphoid tissues and discuss recent findings for other CDM family molecules that provide a basis for understanding how DOCK2 might function in lymphocytes.     

The Drosophila DOCK family protein sponge is involved in differentiation of R7 photoreceptor cells

The Drosophila sponge (spg)/CG31048 gene belongs to the dedicator of cytokinesis (DOCK) family genes that are conserved in a wide variety of species. DOCK family members are known as DOCK1–DOCK11 in mammals. Although DOCK1 and DOCK2 involve neurite elongation and immunocyte differentiation, respectively, the functions of other DOCK family members are not fully understood. Spg is a Drosophila homolog of mammalian DOCK3 and DOCK4. Specific knockdown of spg by the GMR-GAL4 driver in eye imaginal discs induced abnormal eye morphology in adults. To mark the photoreceptor cells in eye imaginal discs, we used a set of enhancer trap strains that express lacZ in various sets of photoreceptor cells. Immunostaining with anti-Spg antibodies and anti-lacZ antibodies revealed that Spg is localized mainly in R7 photoreceptor cells. Knockdown of spg by the GMR-GAL4 driver reduced signals of R7 photoreceptor cells, suggesting involvement of Spg in R7 cell differentiation. Furthermore, immunostaining with anti-dpERK antibodies showed the level of activated ERK signal was reduced extensively by knockdown of spg in eye discs, and both the defects in eye morphology and dpERK signals were rescued by over-expression of the Drosophila raf gene, a component of the ERK signaling pathway. Furthermore, the Duolink in situ Proximity Ligation Assay method detected interaction signals between Spg and Rap1 in and around the plasma membrane of the eye disc cells. Together, these results indicate Spg positively regulates the ERK pathway that is required for R7 photoreceptor cell differentiation and the regulation is mediated by interaction with Rap1 during development of the compound eye.     

Spg5 Protein Regulates the Proteasome in Quiescence

The ubiquitin-proteasome system is the major pathway for selective protein degradation in eukaryotes. Despite extensive study of this system, the mechanisms by which proteasome function and cell growth are coordinated remain unclear. Here, we identify Spg5 as a novel component of the ubiquitin-proteasome system. Spg5 binds the regulatory particle of the proteasome and the base subassembly in particular, but it is excluded from mature proteasomes. The SPG5 gene is strongly induced in the stationary phase of budding yeast, and spg5Δ mutants show a progressive loss of viability under these conditions. Accordingly, during logarithmic growth, Spg5 appears largely dispensable for proteasome function, but during stationary phase the proteasomes of spg5Δ mutants show both structural and functional defects. This loss of proteasome function is reflected in the accumulation of oxidized proteins preferentially in stationary phase in spg5Δ mutants. Thus, Spg5 is a positive regulator of the proteasome that is critical for survival of cells that have ceased to proliferate due to nutrient limitation.     

An alpha-helical extension of the ELMO1 pleckstrin homology domain mediates direct interaction to DOCK180 and is critical in Rac signaling

The mammalian DOCK180 protein belongs to an evolutionarily conserved protein family, which together with ELMO proteins, is essential for activation of Rac GTPase-dependent biological processes. Here, we have analyzed the DOCK180-ELMO1 interaction, and map direct interaction interfaces to the N-terminal 200 amino acids of DOCK180, and to the C-terminal 200 amino acids of ELMO1, comprising the ELMO1 PH domain. Structural and biochemical analysis of this PH domain reveals that it is incapable of phospholipid binding, but instead structurally resembles FERM domains. Moreover, the structure revealed an N-terminal amphiphatic α-helix, and point mutants of invariant hydrophobic residues in this helix disrupt ELMO1-DOCK180 complex formation. A secondary interaction between ELMO1 and DOCK180 is conferred by the DOCK180 SH3 domain and proline-rich motifs at the ELMO1 C-terminus. Mutation of both DOCK180-interaction sites on ELMO1 is required to disrupt the DOCK180-ELMO1 complex. Significantly, although this does not affect DOCK180 GEF activity toward Rac in vivo, Rac signaling is impaired, implying additional roles for ELMO in mediating intracellular Rac signaling.     

Fine-Tuning of the Actin Cytoskeleton and Cell Adhesion During Drosophila Development by the Unconventional Guanine Nucleotide Exchange Factors Myoblast City and Sponge

The evolutionarily conserved Dock proteins function as unconventional guanine nucleotide exchange factors (GEFs). Upon binding to engulfment and cell motility (ELMO) proteins, Dock–ELMO complexes activate the Rho family of small GTPases to mediate a diverse array of biological processes, including cell motility, apoptotic cell clearance, and axon guidance. Overlapping expression patterns and functional redundancy among the 11 vertebrate Dock family members, which are subdivided into four families (Dock A, B, C, and D), complicate genetic analysis. In both vertebrate and invertebrate systems, the actin dynamics regulator, Rac, is the target GTPase of the Dock-A subfamily. However, it remains unclear whether Rac or Rap1 are the in vivo downstream GTPases of the Dock-B subfamily. Drosophila melanogaster is an excellent genetic model organism for understanding Dock protein function as its genome encodes one ortholog per subfamily: Myoblast city (Mbc; Dock A) and Sponge (Spg; Dock B). Here we show that the roles of Spg and Mbc are not redundant in the Drosophila somatic muscle or the dorsal vessel. Moreover, we confirm the in vivo role of Mbc upstream of Rac and provide evidence that Spg functions in concert with Rap1, possibly to regulate aspects of cell adhesion. Together these data show that Mbc and Spg can have different downstream GTPase targets. Our findings predict that the ability to regulate downstream GTPases is dependent on cellular context and allows for the fine-tuning of actin cytoskeletal or cell adhesion events in biological processes that undergo cell morphogenesis.     

An isoform of GTPase regulator DOCK4 localizes to the stereocilia in the inner ear and binds to harmonin (USH1C)

The driving forces for the regulation of cell morphology are the Rho family GTPases that coordinate the assembly of the actin cytoskeleton. This dynamic feature is a result of tight coupling between the cytoskeleton and signal transduction and is facilitated by actin-binding proteins (ABPs). Mutations in the actin bundling and PDZ domain-containing protein harmonin are the causes of Usher syndrome type 1C (USH1C), a syndrome of congenital deafness and progressive blindness, as well as certain forms of non-syndromic deafness. Here, we have used the yeast two-hybrid assay to isolate molecular partners of harmonin and identified DOCK4, an unconventional guanine exchange factor for the Rho family of guanosine triphosphatases (Rho GEF GTPases), as a protein interacting with harmonin. Detailed molecular analysis revealed that a novel DOCK4 isoform (DOCK4-Ex49) is expressed in the brain, eye and inner ear tissues. We have further provided evidence that the DOCK4-Ex49 binds to nucleotide free Rac as effectively as DOCK2 and DOCK4 and it is a potent Rac activator. By immunostaining using a peptide antibody specific to DOCK4-Ex49, we showed its localization in the inner ear within the hair bundles along the stereocilia (SC). Together, our data indicate a possible Rac-DOCK4-ABP harmonin-activated signaling pathway in regulating actin cytoskeleton organization in stereocilia.     

Non-adherent cell-specific expression of DOCK2, a member of the human CDM-family proteins

Human DOCK180, which was originally identified as a major protein bound to the Crk oncogene product, is an archetype of the CDM family of proteins, including Ced-5 of Caenorhabditis elegans and Mbc of Drosophila melanogaster. After DOCK180, at least three putative human proteins that manifest high amino acid sequence similarity to DOCK180 have been registered in the GenBank/EMBL database. We have designated one of them, KIAA0209, as DOCK2 and characterize here. DOCK2 mRNA was expressed mostly in peripheral blood cells, followed by slight expression in the spleen and thymus, whereas DOCK180 was expressed in all tissues tested except in peripheral blood cells. Immunostaining of human cadaver tissues revealed that the expression of DOCK2 was limited to the lymphocytes and macrophages of various organs. DOCK2 bound to and activated Rac1, as did DOCK180; however, DOCK2 did not bind to CrkII, which transduces signals at focal adhesions. Thus, DOCK180 and DOCK2 are regulators of Rac and function in adherent and non-adherent cells, respectively.     

Activation of Rac1 by paxillin-Crk-DOCK180 signaling complex is antagonized by Rap1 in migrating NBT-II cells

Induction of epithelial cell motility is a fundamental morphogenetic event that is recapitulated during carcinoma metastasis. Random motility of NBT-II carcinoma cells on collagen critically depends on paxillin phosphorylation at Tyr-31 and Tyr-118, the binding sites for the adapter protein CrkII. Two constitutive partners of CrkII are the exchange factors DOCK180 and C3G. CrkII bound to DOCK180 formed a signaling complex with phosphorylated paxillin that was necessary for cell migration as inferred from the inhibition caused by a DOCK180-interfering mutant. DOCK180, which acts predominantly on the Rho family GTPase Rac1, restored cell locomotion in cells expressing Phe-31/118 paxillin mutants deficient in Rac1 GTP-loading, suggesting that formation of paxillin-Crk-DOCK180 signaling complex controls collagen-dependent migration mainly through Rac1 activation. In migrating cells, CrkII constitutive association with C3G was not sufficient to stimulate its GDP/GTP exchange activity toward the Ras family GTPase Rap1. However, when constitutively active RapV12 was overexpressed, it negatively regulated cell motility. Activation of the C3G/Rap1 signaling pathway resulted in down-regulation of the paxillin-Crk-DOCK180 complex and reduction of Rac1-GTP, suggesting that Rap1 activation could suppress the Rac1 signaling pathway in epithelial cells.     

PTPμ‐dependent growth cone rearrangement is regulated by Cdc42

PTPμ is expressed in the developing nervous system and promotes growth and guidance of chick retinal ganglion cells. Using a newly developed growth cone rearrangement assay, we examined whether the small G‐proteins were involved in PTPμ‐dependent signaling. The stimulation of retinal cultures with purified PTPμ resulted in a striking morphological change in the growth cone, which becomes dominated by filopodia within 5 min of addition. This rearrangement in response to PTPμ stimulation was mediated by homophilic binding. We perturbed GTPase signaling using Toxin B, which inhibits Cdc42, Rac, and Rho, as well as the toxin Exoenzyme C3 that inhibits Rho. The PTPμ‐induced growth cone rearrangement was blocked by Toxin B, but not by Exoenzyme C3. This result suggests that either Cdc42 or Rac are required but not Rho. To determine which GTPase was involved in PTPμ signaling, we utilized dominant‐negative mutants of Cdc42 and Rac. Dominant‐negative Cdc42 blocked PTPμ‐induced rearrangement, while wild‐type Cdc42 and dominant‐negative Rac did not. Together, these results suggest a molecular signaling cascade beginning with PTPμ homophilic binding at the plasma membrane and the activation of Cdc42, which acts on the actin cytoskeleton to result in rearrangement of the growth cone. © 2003 Wiley Periodicals, Inc. J Neurobiol 56:199–208, 2003     

An evolutionarily conserved autoinhibitory molecular switch in ELMO proteins regulates Rac signaling

Dedicator of cytokinesis (DOCK) proteins are guanine nucleotide exchange factors (GEFs) controlling the activity of Rac1/Cdc42 during migration, phagocytosis, and myoblast fusion [1-4]. Engulfment and cell motility (ELMO) proteins bind a subset of DOCK members and are emerging as critical regulators of Rac signaling [5-10]. Although formation of a DOCK180/ELMO complex is not essential for Rac1 activation, ELMO mutants deficient in binding to DOCK180 are unable to promote cytoskeleton remodeling [11]. How ELMO regulates signaling through DOCK GEFs is poorly understood. Here, we identify an autoinhibitory switch in ELMO presenting homology to a regulatory unit described for Dia formins. One part of the switch, composed of a Ras-binding domain (RBD) and Armadillo repeats, is positioned N-terminally while the other is housed in the C?terminus. We demonstrate interaction between these fragments, suggesting autoinhibition of ELMO. Using a bioluminescence resonance energy transfer biosensor, we establish that ELMO undergoes conformational changes upon disruption of autoinhibition. We found that engagement of ELMO to RhoG, or with DOCK180, promotes the relief of autoinhibition in ELMO. Functionally, we found that ELMO mutants with impaired autoregulatory activity promote cell?elongation. These results demonstrate an unsuspected level of regulation for Rac1 signaling via autoinhibition of ELMO.     

Cell Migration Is Regulated by Platelet-Derived Growth Factor Receptor Endocytosis

Cell migration requires spatial and temporal processes that detect and transfer extracellular stimuli into intracellular signals. The platelet-derived growth factor (PDGF) receptor is a cell surface receptor on fibroblasts that regulates proliferation and chemotaxis in response to PDGF. How the PDGF signal is transmitted accurately through the receptor into cells is an unresolved question. Here, we report a new intracellular signaling pathway by which DOCK4, a Rac1 guanine exchange factor, and Dynamin regulate cell migration by PDGF receptor endocytosis. We showed by a series of biochemical and microscopy techniques that Grb2 serves as an adaptor protein in the formation of a ternary complex between the PDGF receptor, DOCK4, and Dynamin, which is formed at the leading edge of cells. We found that this ternary complex regulates PDGF-dependent cell migration by promoting PDGF receptor endocytosis and Rac1 activation at the cell membrane. This study revealed a new mechanism by which cell migration is regulated by PDGF receptor endocytosis.Chemoattractants bind to cell surface receptors, resulting in the cytoskeletal reorganization that permits the migration of cells toward a stimulus. In fibroblasts, the platelet-derived growth factor receptor β (PDGFRβ) is a cell surface receptor tyrosine kinase (RTK) that regulates cell proliferation and chemotaxis in response to PDGF. PDGF binding activates PDGF receptor autophosphorylation, which in turn mediates a series of intracellular signaling cascades initiated by the association of SH2 domain-containing adaptor proteins (25). The adaptor protein Grb2 at the plasma membrane binds to Ras exchange factor Sos1, activating mitogen-activated protein kinase (MAPK) and cell proliferation signals (19). Grb2 also plays a critical role in receptor internalization via its interaction with dynamin, an exchange factor that facilitates receptor entry into endocytic vesicles (32). Grb2 regulates ubiquitination and the degradation of the receptor via its interaction with Cbl, an E3 ubiquitin ligase (33). While the role of Grb2 in modulating receptor levels and facilitating growth factor-dependent mitogenic signals is defined, its role in coordinating receptor-dependent chemotaxis has not been elucidated.The small GTPase Rac1 plays a crucial role in PDGF-mediated chemotaxis by regulating cortical actin at the leading edge of cells. PDGF receptor activation promotes GTP loading and the translocation of Rac1 to the cell membrane via guanine exchange factors (GEFs). The DOCK family of Rac1 GEFs, also called CDM proteins (for Caenorhabditis elegans ced-5, vertebrate DOCK180, and Drosophila myoblast city), are regulators of cell migration and have been implicated in various biological processes, such as lymphocyte migration, phagocytosis, and cancer progression (6, 10, 30, 35). In migrating fibroblasts, DOCK proteins localize to the cell''s leading edge via their interaction with the phospholipid PIP3, but a direct molecular link to PDGF has not been established (5). Biochemical studies show that Rac activation requires the DHR2/docker domain of DOCK proteins and the expression of the PH domain-containing protein Ced-12/ELMO. Previously we identified DOCK4 in a screen for novel tumor suppressor genes using representational difference analysis on mouse tumor cell lines (35). DOCK4, like other CDM proteins, binds ELMO and exerts its biochemical effects on the small GTPases Rac and Rap1 (30, 35). An interesting observation is that the amino acid sequence toward the C terminus is not conserved among individual DOCK family members. The alternate splicing of the DOCK4 gene has been reported, but how amino acid sequence variation alters the signaling properties of DOCK4 for the regulation of cell migration is unknown.Members of the Nck family of adaptor proteins, CrkII and Nck, have been reported to bind to the C terminus of DOCK180 (12, 29). Here, we show that the third member of the family of Nck adaptors, namely Grb2, binds to wild-type DOCK4. We found that a ternary complex formed by Grb2-DOCK4-Dynamin2 interacts with PDGF-activated PDGFβ receptor and promotes growth factor-dependent migration without altering cell proliferation. PDGF-dependent migration requires receptor endocytosis and is regulated by the formation of a DOCK4-Grb2-Dynamin2-PDGFRβ complex at the cell''s leading edge. These studies provide novel mechanistic insights into PDGFRβ regulation and cell migration.     

A role for POR1, a Rac1-interacting protein, in ARF6-mediated cytoskeletal rearrangements.

The ARF6 GTPase, the least conserved member of the ADP ribosylation factor (ARF) family, associates with the plasma membrane and intracellular endosome vesicles. Mutants of ARF6 defective in GTP binding and hydrolysis have a marked effect on endocytic trafficking and the gross morphology of the peripheral membrane system. Here we report that expression of the GTPase-defective mutant of ARF6, ARF6(Q67L), remodels the actin cytoskeleton by inducing actin polymerization at the cell periphery. This cytoskeletal rearrangement was inhibited by co-expression of ARF6(Q67L) with deletion mutants of POR1, a Rac1-interacting protein involved in membrane ruffling, but not with the dominant-negative mutant of Rac1, Rac1(S17N). A synergistic effect between POR1 and ARF6 for the induction of actin polymerization was detected. Furthermore, we observed that ARF6 interacts directly with POR1 and that this interaction was GTP dependent. These findings indicate that ARF6 and Rac1 function on distinct signaling pathways to mediate cytoskeletal reorganization, and suggest a role for POR1 as an important regulatory element in orchestrating cytoskeletal rearrangements at the cell periphery induced by ARF6 and Rac1.     

PTP mu-dependent growth cone rearrangement is regulated by Cdc42

PTP mu is expressed in the developing nervous system and promotes growth and guidance of chick retinal ganglion cells. Using a newly developed growth cone rearrangement assay, we examined whether the small G-proteins were involved in PTP mu-dependent signaling. The stimulation of retinal cultures with purified PTP mu resulted in a striking morphological change in the growth cone, which becomes dominated by filopodia within 5 min of addition. This rearrangement in response to PTP mu stimulation was mediated by homophilic binding. We perturbed GTPase signaling using Toxin B, which inhibits Cdc42, Rac, and Rho, as well as the toxin Exoenzyme C3 that inhibits Rho. The PTP mu-induced growth cone rearrangement was blocked by Toxin B, but not by Exoenzyme C3. This result suggests that either Cdc42 or Rac are required but not Rho. To determine which GTPase was involved in PTP mu signaling, we utilized dominant-negative mutants of Cdc42 and Rac. Dominant-negative Cdc42 blocked PTP mu-induced rearrangement, while wild-type Cdc42 and dominant-negative Rac did not. Together, these results suggest a molecular signaling cascade beginning with PTP mu homophilic binding at the plasma membrane and the activation of Cdc42, which acts on the actin cytoskeleton to result in rearrangement of the growth cone.     

Recessive mutations in DOCK6, encoding the guanidine nucleotide exchange factor DOCK6, lead to abnormal actin cytoskeleton organization and Adams-Oliver syndrome

Adams-Oliver syndrome (AOS) is defined by the combination of aplasia cutis congenita (ACC) and terminal transverse limb defects (TTLD). It is usually inherited as an autosomal-dominant trait, but autosomal-recessive inheritance has also been documented. In an individual with autosomal-recessive AOS, we combined autozygome analysis with exome sequencing to identify a homozygous truncating mutation in dedicator of cytokinesis 6 gene (DOCK6) which encodes an atypical guanidine exchange factor (GEF) known to activate two members of the Rho GTPase family: Cdc42 and Rac1. Another homozygous truncating mutation was identified upon targeted sequencing of DOCK6 in an unrelated individual with AOS. Consistent with the established role of Cdc42 and Rac1 in the organization of the actin cytoskeleton, we demonstrate a cellular phenotype typical of a defective actin cytoskeleton in patient cells. These findings, combined with a Dock6 expression profile that is consistent with an AOS phenotype as well as the very recent demonstration of dominant mutations of ARHGAP31 in AOS, establish Cdc42 and Rac1 as key molecules in the pathogenesis of AOS and suggest that other regulators of these Rho GTPase proteins might be good candidates in the quest to define the genetic spectrum of this genetically heterogeneous condition.     

DOCK4, a GTPase activator,is disrupted during tumorigenesis

We used representational difference analysis to identify homozygous genomic deletions selected during tumor progression in the mouse NF2 and TP53 tumor model. We describe a deletion targeting DOCK4, a member of the CDM gene family encoding regulators of small GTPases. DOCK4 specifically activates Rap GTPase, enhancing the formation of adherens junctions. DOCK4 mutations are present in a subset of human cancer cell lines; a recurrent missense mutant identified in human prostate and ovarian cancers encodes a protein that is defective in Rap1 activation. The engulfment defect of C. elegans mutants lacking the CDM gene ced-5 is rescued by wild-type DOCK4, but not by the mutant allele. Expression of wild-type, but not mutant, DOCK4 in mouse osteosarcoma cells with a deletion of the endogenous gene suppresses growth in soft agar and tumor invasion in vivo. DOCK4 therefore encodes a CDM family member that regulates intercellular junctions and is disrupted during tumorigenesis.     

Immune regulatory functions of DOCK family proteins in health and disease

DOCK proteins constitute a family of evolutionarily conserved guanine nucleotide exchange factors (GEFs) for Rho family of GTPases. Although DOCK family proteins do not contain the Dbl homology domain typically found in GEFs, they mediate the GTP–GDP exchange reaction through DHR-2 domain. Accumulating evidence indicates that the DOCK proteins act as major GEFs in varied biological settings. For example, DOCK2, which is predominantly expressed in hematopoietic cells, regulates migration and activation of leukocytes through Rac activation. On the other hand, it was recently reported that mutations of DOCK8, another member of the DOCK family proteins, cause a combined immunodeficiency syndrome in humans. This article reviews the structure, functions and signaling of DOCK2 and DOCK8, especially focusing on their roles in immune responses.     

Byr4 localizes to spindle-pole bodies in a cell cycle-regulated manner to control Cdc7 localization and septation in fission yeast

Cytokinesis and septation in the fission yeast Schizosaccharomyces pombe are studied as a model for mammalian cell division. In fission yeast, septation is positively regulated by Spg1, a Ras family GTPase that localizes to spindle-pole bodies (SPBs) throughout the cell cycle. As cells enter mitosis, Spg1 accumulates in an active, GTP-bound form and binds the Cdc7 protein kinase to cause Cdc7 translocation to SPBs. Cdc7 disappears from one SPB in mid-anaphase and from the second SPB in late mitosis. Byr4 plus Cdc16 negatively regulate septation by forming a two-component GTPase-activating protein for Spg1. These results led us to hypothesize that Byr4 localization to SPBs regulated the nucleotide state of Spg1, due to its ability to form Spg1GAP activity with Cdc16 and thus the binding of Cdc7 to Spg1 at SPBs. To test this hypothesis, Byr4 localization was determined using indirect immunofluorescence. This analysis revealed that Byr4 was localized to SPBs that did not contain Cdc7. In byr4(-) mutants, Cdc7 localized to interphase SPBs and only symmetrically localized to mitotic SPBs. In contrast, Byr4 overexpression prevented Spg1 and Cdc7 localization to SPBs. These results suggest that Byr4 localization to SPBs maintains Spg1 in an inactive form, presumably by stimulating Spg1 GTPase activity with Cdc16, and that loss of Byr4 from mitotic SPBs increases the active fraction of Spg1 and thereby increases Spg1-Cdc7 binding. Byr4 localization to SPBs was decreased in spg1, cdc16, sid4, and cdc11 mutants as well as in several mutants that affect medial F-actin structures, suggesting that multiple pathways regulate Byr4 localization to SPBs.     

The Arf family GTPase Arl4A complexes with ELMO proteins to promote actin cytoskeleton remodeling and reveals a versatile Ras-binding domain in the ELMO proteins family

The prototypical DOCK protein, DOCK180, is an evolutionarily conserved Rac regulator and is indispensable during processes such as cell migration and myoblast fusion. The biological activity of DOCK180 is tightly linked to its binding partner ELMO. We previously reported that autoinhibited ELMO proteins regulate signaling from this pathway. One mechanism to activate the ELMO-DOCK180 complex appears to be the recruitment of this complex to the membrane via the Ras-binding domain (RBD) of ELMO. In the present study, we aimed to identify novel ELMO-interacting proteins to further define the molecular events capable of controlling ELMO recruitment to the membrane. To do so, we performed two independent interaction screens: one specifically interrogated an active GTPase library while the other probed a brain cDNA library. Both methods converged on Arl4A, an Arf-related GTPase, as a specific ELMO interactor. Biochemically, Arl4A is constitutively GTP-loaded, and our binding assays confirm that both wild-type and constitutively active forms of the GTPase associate with ELMO. Mechanistically, we report that Arl4A binds the ELMO RBD and acts as a membrane localization signal for ELMO. In addition, we report that membrane targeting of ELMO via Arl4A promotes cytoskeletal reorganization including membrane ruffling and stress fiber disassembly via an ELMO-DOCK1800-Rac signaling pathway. We conclude that ELMO is capable of interacting with GTPases from Rho and Arf families, leading to the conclusion that ELMO contains a versatile RBD. Furthermore, via binding of an Arf family GTPase, the ELMO-DOCK180 is uniquely positioned at the membrane to activate Rac signaling and remodel the actin cytoskeleton.