Golgi-localized GAP for Cdc42 functions downstream of ARF1 to control Arp2/3 complex and F-actin dynamics

The small GTP-binding ADP-ribosylation factor 1 (ARF1) acts as a master regulator of Golgi structure and function through the recruitment and activation of various downstream effectors. It has been proposed that members of the Rho family of small GTPases also control Golgi function in coordination with ARF1, possibly through the regulation of Arp2/3 complex and actin polymerization on Golgi membranes. Here, we identify ARHGAP10--a novel Rho GTPase-activating protein (Rho-GAP) that is recruited to Golgi membranes through binding to GTP-ARF1. We show that ARHGAP10 functions preferentially as a GAP for Cdc42 and regulates the Arp2/3 complex and F-actin dynamics at the Golgi through the control of Cdc42 activity. Our results establish a role for ARHGAP10 in Golgi structure and function at the crossroads between ARF1 and Cdc42 signalling pathways.     

Coatomer-bound Cdc42 regulates dynein recruitment to COPI vesicles

Cytoskeletal dynamics at the Golgi apparatus are regulated in part through a binding interaction between the Golgi-vesicle coat protein, coatomer, and the regulatory GTP-binding protein Cdc42 (Wu, W.J., J.W. Erickson, R. Lin, and R.A. Cerione. 2000. Nature. 405:800-804; Fucini, R.V., J.L. Chen, C. Sharma, M.M. Kessels, and M. Stamnes. 2002. Mol. Biol. Cell. 13:621-631). The precise role of this complex has not been determined. We have analyzed the protein composition of Golgi-derived coat protomer I (COPI)-coated vesicles after activating or inhibiting signaling through coatomer-bound Cdc42. We show that Cdc42 has profound effects on the recruitment of dynein to COPI vesicles. Cdc42, when bound to coatomer, inhibits dynein binding to COPI vesicles whereas preventing the coatomer-Cdc42 interaction stimulates dynein binding. Dynein recruitment was found to involve actin dynamics and dynactin. Reclustering of nocodazole-dispersed Golgi stacks and microtubule/dynein-dependent ER-to-Golgi transport are both sensitive to disrupting Cdc42 mediated signaling. By contrast, dynein-independent transport to the Golgi complex is insensitive to mutant Cdc42. We propose a model for how proper temporal regulation of motor-based vesicle translocation could be coupled to the completion of vesicle formation.     

Structural basis for ARF1-mediated recruitment of ARHGAP21 to Golgi membranes

ARHGAP21 is a Rho family GTPase-activating protein (RhoGAP) that controls the Arp2/3 complex and F-actin dynamics at the Golgi complex by regulating the activity of the small GTPase Cdc42. ARHGAP21 is recruited to the Golgi by binding to another small GTPase, ARF1. Here, we present the crystal structure of the activated GTP-bound form of ARF1 in a complex with the Arf-binding domain (ArfBD) of ARHGAP21 at 2.1 A resolution. We show that ArfBD comprises a PH domain adjoining a C-terminal alpha helix, and that ARF1 interacts with both of these structural motifs through its switch regions and triggers structural rearrangement of the PH domain. We used site-directed mutagenesis to confirm that both the PH domain and the helical motif are essential for the binding of ArfBD to ARF1 and for its recruitment to the Golgi. Our data demonstrate that two well-known small GTPase-binding motifs, the PH domain and the alpha helical motif, can combine to create a novel mode of binding to Arfs.     

Retrograde Shiga Toxin Trafficking Is Regulated by ARHGAP21 and Cdc42

Shiga-toxin–producing Escherichia coli remain a food-borne health threat. Shiga toxin is endocytosed by intestinal epithelial cells and transported retrogradely through the secretory pathway. It is ultimately translocated to the cytosol where it inhibits protein translation. We found that Shiga toxin transport through the secretory pathway was dependent on the cytoskeleton. Recent studies reveal that Shiga toxin activates signaling pathways that affect microtubule reassembly and dynein-dependent motility. We propose that Shiga toxin alters cytoskeletal dynamics in a way that facilitates its transport through the secretory pathway. We have now found that Rho GTPases regulate the endocytosis and retrograde motility of Shiga toxin. The expression of RhoA mutants inhibited endocytosis of Shiga toxin. Constitutively active Cdc42 or knockdown of the Cdc42-specific GAP, ARHGAP21, inhibited the transport of Shiga toxin to the juxtanuclear Golgi apparatus. The ability of Shiga toxin to stimulate microtubule-based transferrin transport also required Cdc42 and ARHGAP21 function. Shiga toxin addition greatly decreases the levels of active Cdc42-GTP in an ARHGAP21-dependent manner. We conclude that ARHGAP21 and Cdc42-based signaling regulates the dynein-dependent retrograde transport of Shiga toxin to the Golgi apparatus.     

CLN3 Deficient Cells Display Defects in the ARF1-Cdc42 Pathway and Actin-Dependent Events

Juvenile Batten disease (juvenile neuronal ceroid lipofuscinosis, JNCL) is a devastating neurodegenerative disease caused by mutations in CLN3, a protein of undefined function. Cell lines derived from patients or mice with CLN3 deficiency have impairments in actin-regulated processes such as endocytosis, autophagy, vesicular trafficking, and cell migration. Here we demonstrate the small GTPase Cdc42 is misregulated in the absence of CLN3, and thus may be a common link to multiple cellular defects. We discover that active Cdc42 (Cdc42-GTP) is elevated in endothelial cells from CLN3 deficient mouse brain, and correlates with enhanced PAK-1 phosphorylation, LIMK membrane recruitment, and altered actin-driven events. We also demonstrate dramatically reduced plasma membrane recruitment of the Cdc42 GTPase activating protein, ARHGAP21. In line with this, GTP-loaded ARF1, an effector of ARHGAP21 recruitment, is depressed. Together these data implicate misregulated ARF1-Cdc42 signaling as a central defect in JNCL cells, which in-turn impairs various cell functions. Furthermore our findings support concerted action of ARF1, ARHGAP21, and Cdc42 to regulate fluid phase endocytosis in mammalian cells. The ARF1-Cdc42 pathway presents a promising new avenue for JNCL therapeutic development.     

Golgi vesicle proteins are linked to the assembly of an actin complex defined by mAbp1

Recent studies indicate that regulation of the actin cytoskeleton is important for protein trafficking, but its precise role is unclear. We have characterized the ARF1-dependent assembly of actin on the Golgi apparatus. Actin recruitment involves Cdc42/Rac and requires the activation of the Arp2/3 complex. Although the actin-binding proteins mAbp1 (SH3p7) and drebrin share sequence homology, they are differentially segregated into two distinct ARF-dependent actin complexes. The binding of Cdc42 and mAbp1, which localize to the Golgi apparatus, but not drebrin, is blocked by occupation of the p23 cargo-protein-binding site on coatomer. Exogenously expressed mAbp1 is mislocalized and inhibits Golgi transport in whole cells. The ability of ARF, vesicle-coat proteins, and cargo to direct the assembly of cytoskeletal structures helps explain how only a handful of vesicle types can mediate the numerous trafficking steps in the cell.     

Dlg1 binds GKAP to control dynein association with microtubules, centrosome positioning, and cell polarity

Centrosome positioning is crucial during cell division, cell differentiation, and for a wide range of cell-polarized functions including migration. In multicellular organisms, centrosome movement across the cytoplasm is thought to result from a balance of forces exerted by the microtubule-associated motor dynein. However, the mechanisms regulating dynein-mediated forces are still unknown. We show here that during wound-induced cell migration, the small G protein Cdc42 acts through the polarity protein Dlg1 to regulate the interaction of dynein with microtubules of the cell front. Dlg1 interacts with dynein via the scaffolding protein GKAP and together, Dlg1, GKAP, and dynein control microtubule dynamics and organization near the cell cortex and promote centrosome positioning. Our results suggest that, by modulating dynein interaction with leading edge microtubules, the evolutionary conserved proteins Dlg1 and GKAP control the forces operating on microtubules and play a fundamental role in centrosome positioning and cell polarity.     

Golgin160 recruits the dynein motor to position the Golgi apparatus

Membrane motility is a fundamental characteristic of all eukaryotic cells. One of the best-known examples is that of the mammalian Golgi apparatus, where constant inward movement of Golgi membranes results in its characteristic position near the centrosome. While it is clear that the minus-end-directed motor dynein is required for this process, the mechanism and regulation of dynein recruitment to Golgi membranes remains unknown. Here, we show that the Golgi protein golgin160 recruits dynein to Golgi membranes. This recruitment confers centripetal motility to membranes and is regulated by the GTPase Arf1. Further, during cell division, motor association with membranes is regulated by the dissociation of the receptor-motor complex from membranes. These results identify a cell-cycle-regulated membrane receptor for a molecular motor and?suggest a mechanistic basis for achieving the dramatic changes in organelle positioning seen during cell division.     

GTP-dependent binding of ADP-ribosylation factor to coatomer in close proximity to the binding site for dilysine retrieval motifs and p23.

A site-directed photocross-linking approach was employed to determine components that act downstream of ADP-ribosylation factor (ARF). To this end, a photolabile phenylalanine analog was incorporated at various positions of the putative effector region of the ARF molecule. Depending on the position of incorporation, we find specific and GTP-dependent interactions of ARF with two subunits of the coatomer complex, beta-COP and gamma-COP, as well as an interaction with a cytosolic protein (approximately 185 kDa). In addition, we observe homodimer formation of ARF molecules at the Golgi membrane. These data suggest that the binding site of ARF to coatomer is at the interface of its beta- and gamma-subunits, and this is in close proximity to the second site of interaction of coatomer with the Golgi membrane, the binding site within gamma-COP for cytosolic dibasic/diphenylalanine motifs.     

Regulation of GTP hydrolysis on ADP-ribosylation factor-1 at the Golgi membrane

The interaction of the coatomer coat complex with the Golgi membrane is initiated by the active, GTP-bound state of the small GTPase ADP-ribosylation factor 1 (ARF1), whereas GTP hydrolysis triggers coatomer dissociation. The hydrolysis of GTP on ARF1 depends on the action of members of a family of ARF1-directed GTPase-activating proteins (GAPs). Previous studies in well defined systems indicated that the activity of a mammalian Golgi membrane-localized ARF GAP (GAP1) might be subjected to regulation by membrane lipids as well as by the coatomer complex. Coatomer was found to strongly stimulate GAP-dependent GTP hydrolysis on a membrane-independent mutant of ARF1, whereas we reported that GTP hydrolysis on wild type, myristoylated ARF1 loaded with GTP in the presence of phospholipid vesicles was coatomer-independent. To investigate the regulation of ARF1 GAPs under more physiological conditions, we studied GTP hydrolysis on Golgi membrane-associated ARF1. The activities at the Golgi of recombinant GAP1 as well as coatomer-depleted fractions from rat brain cytosol resembled those observed in the presence of liposomes; however, unlike in liposomes, GAP activities on Golgi membranes were approximately doubled upon addition of coatomer. By contrast, endogenous GAP activity in Golgi membrane preparations was unaffected by coatomer. Cytosolic GAP activity was partially reduced following immunodepletion of GAP1, indicating that GAP1 plays a significant although not exclusive role in the regulation of GTP hydrolysis at the Golgi. Unlike the activities of the mammalian proteins, the Saccharomyces cerevisiae Glo3 ARF GAP displayed activity at the Golgi that was highly dependent on coatomer. We conclude that ARF GAPs in themselves can efficiently stimulate GTP hydrolysis on ARF1 at the Golgi, and that coatomer may play an auxiliary role in this reaction, which would lead to an increased cycling rate of ARF1 in COPI-coated regions of the Golgi membrane.     

Role of coatomer and phospholipids in GTPase-activating protein-dependent hydrolysis of GTP by ADP-ribosylation factor-1

The binding of the coat protein complex, coatomer, to the Golgi is mediated by the small GTPase ADP-ribosylation factor-1 (ARF1), whereas the dissociation of coatomer, requires GTP hydrolysis on ARF1, which depends on a GTPase-activating protein (GAP). Recent studies demonstrate that when GAP activity is assayed in a membrane-free environment by employing an amino-terminal truncation mutant of ARF1 (Delta17-ARF1) and a catalytic fragment of the ARF GTPase-activating protein GAP1, GTP hydrolysis is strongly stimulated by coatomer (Goldberg, J., (1999) Cell 96, 893-902). In this study, we investigated the role of coatomer in GTP hydrolysis on ARF1 both in solution and in a phospholipid environment. When GTP hydrolysis was assayed in solution using Delta17-ARF1, coatomer stimulated hydrolysis in the presence of the full-length GAP1 as well as with a Saccharomyces cerevisiae ARF GAP (Gcs1) but had no effect on hydrolysis in the presence of the phosphoinositide dependent GAP, ASAP1. Using wild-type myristoylated ARF1 loaded with GTP in the presence of phospholipid vesicles, GAP1 by itself stimulated GTP hydrolysis efficiently, and coatomer had no additional effect. Disruption of the phospholipid vesicles with detergent resulted in reduced GAP1 activity that was stimulated by coatomer, a pattern that resembled Delta17-ARF1 activity. Our findings suggest that in the biological membrane, the proximity between ARF1 and its GAP, which results from mutual binding to membrane phospholipids, may be sufficient for stimulation of ARF1 GTPase activity.     

A Conserved N‐terminal Arginine‐Motif in GOLPH3‐Family Proteins Mediates Binding to Coatomer

Vps74p, a member of the GOLPH3 protein family, binds directly to coatomer and the cytoplasmic tails of a subset of Golgi‐resident glycosyltransferases to mediate their Golgi retention. We identify a cluster of arginine residues at the N‐terminal end of GOLPH3 proteins that are necessary and sufficient to mediate coatomer binding. While loss of coatomer binding renders Vps74p non‐functional for glycosyltransferase retention, the Golgi membrane‐binding capabilities of the mutant protein are not significantly reduced. We establish that the oligomerization status and phosphatidylinositol‐4‐phosphate‐binding properties of Vps74p largely account for the membrane‐binding capacity of the protein and identify an Arf1p–Vps74p interaction as a potential contributing factor in Vps74p Golgi membrane association .     

Binding and functions of ADP-ribosylation factor on mammalian and yeast peroxisomes

We have analyzed in vitro the binding characteristics of members of the ADP-ribosylation factor (ARF) family of proteins to a highly purified rat liver peroxisome preparation void of Golgi membranes and studied in vivo a role these proteins play in the proliferation of yeast peroxisomes. Although both ARF1 and ARF6 were found on peroxisomes, coatomer recruitment only depended on ARF1-GTP. Recruitment of ARF1 and coatomer to peroxisomes was significantly affected both by pretreating the animals with peroxisome proliferators and by ATP and a cytosolic fraction designated the intermediate pool fraction depleted of ARF and coatomer. In the presence of ATP, the concentrations of ARF1 and coatomer on peroxisomes were reduced, whereas intermediate pool fraction led to a concentration-dependent decrease in ARF and increase in coatomer. Brefeldin A, a fungal toxin that is known to reduce ARF1 binding to Golgi membranes, did not affect ARF1 binding to peroxisomes. In Saccharomyces cerevisiae, both ScARF1 and ScARF3, the yeast orthologs of mammalian ARF1 and ARF6, were implicated in the control of peroxisome proliferation. ScARF1 regulated this process in a positive manner, and ScARF3 regulated it in a negative manner.     

Evidence that phospholipase D mediates ADP ribosylation factor- dependent formation of Golgi coated vesicles

Formation of coatomer-coated vesicles from Golgi-enriched membranes requires the activation of a small GTP-binding protein, ADP ribosylation factor (ARF). ARF is also an efficacious activator of phospholipase D (PLD), an activity that is relatively abundant on Golgi- enriched membranes. It has been proposed that ARF, which is recruited onto membranes from cytosolic pools, acts directly to promote coatomer binding and is in a 3:1 stoichiometry with coatomer on coated vesicles. We present evidence that cytosolic ARF is not necessary for initiating coat assembly on Golgi membranes from cell lines with high constitutive PLD activity. Conditions are also described under which ARF is at most a minor component relative to coatomer in coated vesicles from all cell lines tested, including Chinese hamster ovary cells. Formation of coated vesicles was sensitive to ethanol at concentrations that inhibit the production of phosphatidic acid (PA) by PLD. When PA was produced in Golgi membranes by an exogenous bacterial PLD, rather than with ARF and endogenous PLD, coatomer bound to Golgi membranes. Purified coatomer also bound selectively to artificial lipid vesicles that contained PA and phosphatidylinositol (4,5)-bisphosphate (PIP2). We propose that activation of PLD and the subsequent production of PA are key early events for the formation of coatomer-coated vesicles.     

Correct targeting of plant ARF GTPases relies on distinct protein domains

Indispensable membrane trafficking events depend on the activity of conserved small guanosine triphosphatases (GTPases), anchored to individual organelle membranes. In plant cells, it is currently unknown how these proteins reach their correct target membranes and interact with their effectors. To address these important biological questions, we studied two members of the ADP ribosylation factor (ARF) GTPase family, ARF1 and ARFB, which are membrane anchored through the same N-terminal myristoyl group but to different target membranes. Specifically, we investigated how ARF1 is targeted to the Golgi and post-Golgi structures, whereas ARFB accumulates at the plasma membrane. While the subcellular localization of ARFB appears to depend on multiple domains including the C-terminal half of the GTPase, the correct targeting of ARF1 is dependent on two domains: an N-terminal ARF1 domain that is necessary for the targeting of the GTPase to membranes and a core domain carrying a conserved MxxE motif that influences the relative distribution of ARF1 between the Golgi and post-Golgi compartments. We also established that the N-terminal ARF1 domain alone was insufficient to maintain an interaction with membranes and that correct targeting is a protein-specific property that depends on the status of the GTP switch. Finally, an ARF1-ARFB chimera containing only the first 18 amino acids from ARF1 was shown to compete with ARF1 membrane binding loci. Although this chimera exhibited GTPase activity in vitro, it was unable to recruit coatomer, a known ARF1 effector, onto Golgi membranes. Our results suggest that the targeting of ARF GTPases to the correct membranes may not only depend on interactions with effectors but also relies on distinct protein domains and further binding partners on the Golgi surface.     

Microtubule nucleation at the cis‐side of the Golgi apparatus requires AKAP450 and GM130

We report that microtubule (MT) nucleation at the Golgi apparatus requires AKAP450, a centrosomal γ‐TuRC‐interacting protein that also forms a distinct network associated with the Golgi. Depletion of AKAP450 abolished MT nucleation at the Golgi, whereas depletion of the cis‐Golgi protein GM130 led to the disorganisation of AKAP450 network and impairment of MT nucleation. Brefeldin‐A treatment induced relocalisation of AKAP450 to ER exit sites and concomitant redistribution of MT nucleation capacity to the ER. AKAP450 specifically binds the cis‐side of the Golgi in an MT‐independent, GM130‐dependent manner. Short AKAP450‐dependent growing MTs are covered by CLASP2. Like for centrosome, dynein/dynactin complexes are necessary to anchor MTs growing from the Golgi. We further show that Golgi‐associated AKAP450 has a role in cell migration rather than in cell polarisation of the centrosome–Golgi apparatus. We propose that the recruitment of AKAP450 on the Golgi membranes through GM130 allows centrosome‐associated nucleating activity to extend to the Golgi, to control the assembly of subsets of MTs ensuring specific functions within the Golgi or for transporting specific cargos to the cell periphery.     

Dynein,Lis1 and CLIP‐170 counteract Eg5‐dependent centrosome separation during bipolar spindle assembly

Bipolar spindle assembly critically depends on the microtubule plus‐end‐directed motor Eg5 that binds antiparallel microtubules and slides them in opposite directions. As such, Eg5 can produce the necessary outward force within the spindle that drives centrosome separation and inhibition of this antiparallel sliding activity results in the formation of monopolar spindles. Here, we show that upon depletion of the minus‐end‐directed motor dynein, or the dynein‐binding protein Lis1, bipolar spindles can form in human cells with substantially less Eg5 activity, suggesting that dynein and Lis1 produce an inward force that counteracts the Eg5‐dependent outward force. Interestingly, we also observe restoration of spindle bipolarity upon depletion of the microtubule plus‐end‐tracking protein CLIP‐170. This function of CLIP‐170 in spindle bipolarity seems to be mediated through its interaction with dynein, as loss of CLIP‐115, a highly homologous protein that lacks the dynein–dynactin interaction domain, does not restore spindle bipolarity. Taken together, these results suggest that complexes of dynein, Lis1 and CLIP‐170 crosslink and slide microtubules within the spindle, thereby producing an inward force that pulls centrosomes together.     

ARF1 is directly involved in dynamin-independent endocytosis

Endocytosis of glycosylphosphatidyl inositol (GPI)-anchored proteins (GPI-APs) and the fluid phase takes place primarily through a dynamin- and clathrin-independent, Cdc42-regulated pinocytic mechanism. This mechanism is mediated by primary carriers called clathrin-independent carriers (CLICs), which fuse to form tubular early endocytic compartments called GPI-AP enriched endosomal compartments (GEECs). Here, we show that reduction in activity or levels of ARF1 specifically inhibits GPI-AP and fluid-phase endocytosis without affecting other clathrin-dependent or independent endocytic pathways. ARF1 is activated at distinct sites on the plasma membrane, and by the recruitment of RhoGAP domain-containing protein, ARHGAP10, to the plasma membrane, modulates cell-surface Cdc42 dynamics. This results in the coupling of ARF1 and Cdc42 activity to regulate endocytosis at the plasma membrane. These findings provide a molecular basis for a crosstalk of endocytosis with secretion by the sharing of a key regulator of secretory traffic, ARF1.     

Overexpression of wild-type and mutant ARF1 and ARF6: distinct perturbations of nonoverlapping membrane compartments

The ARF GTP binding proteins are believed to function as regulators of membrane traffic in the secretory pathway. While the ARF1 protein has been shown in vitro to mediate the membrane interaction of the cytosolic coat proteins coatomer (COP1) and gamma-adaptin with the Golgi complex, the functions of the other ARF proteins have not been defined. Here, we show by transient transfection with epitope-tagged ARFs, that whereas ARF1 is localized to the Golgi complex and can be shown to affect predictably the assembly of COP1 and gamma-adaptin with Golgi membranes in cells, ARF6 is localized to the endosomal/plasma membrane system and has no effect on these Golgi-associated coat proteins. By immuno-electron microscopy, the wild-type ARF6 protein is observed along the plasma membrane and associated with endosomes, and overexpression of ARF6 does not appear to alter the morphology of the peripheral membrane system. In contrast, overexpression of ARF6 mutants predicted either to hydrolyze or bind GTP poorly shifts the distribution of ARF6 and affects the structure of the endocytic pathway. The GTP hydrolysis-defective mutant is localized to the plasma membrane and its overexpression results in a profound induction of extensive plasma membrane vaginations and a depletion of endosomes. Conversely, the GTP binding-defective ARF6 mutant is present exclusively in endosomal structures, and its overexpression results in a massive accumulation of coated endocytic structures.