Structural insights into the dual nucleotide exchange and GDI displacement activity of SidM/DrrA

GDP‐bound prenylated Rabs, sequestered by GDI (GDP dissociation inhibitor) in the cytosol, are delivered to destined sub‐cellular compartment and subsequently activated by GEFs (guanine nucleotide exchange factors) catalysing GDP‐to‐GTP exchange. The dissociation of GDI from Rabs is believed to require a GDF (GDI displacement factor). Only two RabGDFs, human PRA‐1 and Legionella pneumophila SidM/DrrA, have been identified so far and the molecular mechanism of GDF is elusive. Here, we present the structure of a SidM/DrrA fragment possessing dual GEF and GDF activity in complex with Rab1. SidM/DrrA reconfigures the Switch regions of the GTPase domain of Rab1, as eukaryotic GEFs do toward cognate Rabs. Structure‐based mutational analyses show that the surface of SidM/DrrA, catalysing nucleotide exchange, is involved in GDI1 displacement from prenylated Rab1:GDP. In comparison with an eukaryotic GEF TRAPP I, this bacterial GEF/GDF exhibits high binding affinity for Rab1 with GDP retained at the active site, which appears as the key feature for the GDF activity of the protein.     

Rab35: GEFs,GAPs and Effectors

Rabs are the largest family of small GTPases and are master regulators of membrane trafficking. Following activation by guanine‐nucleotide exchange factors (GEFs), each Rab binds a specific set of effector proteins that mediate the various downstream functions of that Rab. Then, with the help of GTPase‐activating proteins, the Rab converts GTP to GDP, terminating its function. There are over 60 Rabs in humans and only a subset has been analyzed in any detail. Recently, Rab35 has emerged as a key regulator of cargo recycling at endosomes, with an additional role in regulation of the actin cytoskeleton. Here, we will focus on the regulation of Rab35 activity by the connecdenn/DENND1 family of GEFs and the TBC1D10/EPI64 family of GTPase‐activating proteins. We will describe how analysis of these proteins, as well as a plethora of Rab35 effectors has provided insights into Rab35 function. Finally, we will describe how Rab35 provides a novel link between the Rab and Arf family of GTPases with implications for tumor formation and invasiveness .      

Guanine Nucleotide Exchange Factors (GEFs) Have a Critical but Not Exclusive Role in Organelle Localization of Rab GTPases

Membrane fusion at eukaryotic organelles is initiated by Rab GTPases and tethering factors. Rabs in their GDP-bound form are kept soluble in the cytoplasm by the GDP dissociation inhibitor (GDI) chaperone. Guanine nucleotide exchange factors (GEFs) are found at organelles and are critical for Rab function. Here, we surveyed the overall role of GEFs in Rab localization. We show that GEFs, but none of the proposed GDI displacement factors, are essential for the correct membrane localization of yeast Rabs. In the absence of the GEF, Rabs lost their primary localization to the target organelle. Several Rabs, such as vacuolar Ypt7, were found at the endoplasmic reticulum and thus were still membrane-bound. Surprisingly, a Ypt7 mutant that undergoes facilitated nucleotide exchange localized to vacuoles independently of its GEF Mon1-Ccz1 and rescued vacuole morphology. In contrast, wild-type Ypt7 required its GEF for localization and to counteract the extraction by GDI. Our data agree with the emerging model that GEFs are critical for Rab localization but raise the possibility that additional factors can contribute to this process.     

Establishing a Role for the GTPase Ypt1p at the Late Golgi

GTPases of the Rab family cycle between an inactive (GDP‐bound) and active (GTP‐bound) conformation. The active form of the Rab regulates a variety of cellular functions via multiple effectors. Guanine nucleotide exchange factors (GEFs) activate Rabs by accelerating the exchange of GDP for GTP, while GTPase activating proteins (GAPs) inactivate Rabs by stimulating the hydrolysis of GTP. The GTPase Ypt1p is required for endoplasmic reticulum (ER)–Golgi and intra‐Golgi traffic in the yeast Saccharomyces cerevisiae. Recent findings, however, have shown that Ypt1p GEF, GAP and an effector are all required for traffic from the early endosome to the Golgi. Here we describe a screen for ypt1 mutants that block traffic from the early endosome to the late Golgi, but not general secretion. This screen has led to the identification of a collection of recessive and dominant mutants that block traffic from the early endosome. While it has long been known that Ypt1p regulates the flow of biosynthetic traffic into the cis side of the Golgi, these findings have established a role for Ypt1p in the regulation of early endosome–Golgi traffic. We propose that Ypt1p regulates the flow of traffic into the cis and trans side of the Golgi via multiple effectors.     

Structure of the Legionella effector AnkX reveals the mechanism of phosphocholine transfer by the FIC domain

The FIC motif and the eukaryotic‐like ankyrin repeats are found in many bacterial type IV effectors, yet little is known about how these domains enable bacteria to modulate host cell functions. Bacterial FIC domains typically bind ATP and transfer adenosine monophosphate moiety onto target proteins. The ankyrin repeat‐containing protein AnkX encoded by the intracellular pathogen Legionella pneumophila is unique in that its FIC domain binds to CDP‐choline and transfers a phosphocholine residue onto proteins in the Rab1 GTPase family. By determining the structures of unbound AnkX and AnkX with bound CDP‐choline, CMP/phosphocholine and CMP, we demonstrate that the orientation of substrate binding in relation to the catalytic FIC motif enables this protein to function as a phosphocholinating enzyme rather than a nucleotidyl transferase. Additionally, the structure reveals that the ankyrin repeats mediate scaffolding interactions that resemble those found in protein–protein interactions, but are unprecedented in intramolecular interactions. Together with phosphocholination experiments, our structures unify a general phosphoryl transferase mechanism common to all FIC enzymes that should be conserved from bacteria to human.     

Identification of a GDI displacement factor that releases endosomal Rab GTPases from Rab-GDI.

Prenylated Rab GTPases occur in the cytosol in their GDP-bound conformations bound to a cytosolic protein termed GDP-dissociation inhibitor (GDI). Rab-GDI complexes represent a pool of active, recycling Rab proteins that can deliver Rabs to specific and distinct membrane-bound compartments. Rab delivery to cellular membranes involves release of GDI, and the membrane-associated Rab protein then exchanges its bound GDP for GTP. We report here the identification of a novel, membrane-associated protein factor that can release prenylated Rab proteins from GDI. This GDI-displacement factor (GDF) is not a guanine nucleotide exchange factor because it did not influence the intrinsic rates of nucleotide exchange by Rabs 5, 7 or 9. Rather, GDF caused the release of each of these endosomal Rabs from GDI, permitting them to exchange nucleotide at their intrinsic rates. GDF displayed the greatest catalytic rate enhancement on Rab9-GDI complexes. However, catalytic rate enhancement paralleled the potency of GDI in blocking nucleotide exchange: GDI was shown to be most potent in blocking nucleotide exchange by Rab9. The failure of GDF to act on Rab1-GDI complexes suggests that it may be specific for endosomal Rab proteins. This novel, membrane-associated activity may be part of the machinery used to localize Rabs to their correct intracellular compartments.     

Biochemical characterization of rab proteins from Bombyx mori

The small GTPases known as Rab proteins are key regulators of membrane trafficking. We used RT-PCR to isolate cDNA clones of insect-specific Rab proteins (BRabN1 and BRabN2) showing low homology with known Rab proteins from other animals, from mRNA of Bombyx mori. These 2 Rabs were produced in Escherichia coli and purified. BRabN1 bound [(3)H]-GDP and [(35)S]-GTPgammaS with dissociation constants of 0.087 x 10(-6) M and 1.02 x 10(-6) M, respectively, whereas those of BRabN2 were 0.546 x 10(-6) M and 1.02 x 10(-6) M, respectively. Binding of [(35)S]-GTPgammaS to BRabN1 and N2 was inhibited by GDP and GTP. The GTP-hydrolysis activities of BRabN1 and N2 were 154 and 35.5 mmol/min/mole, respectively, and bound [(35)S]-GTPgammaS was exchanged efficiently with GTP. BRabN1 also showed ATPase activity and exchange of [(35)S]-GTPgammaS with ATP. Monoclonal antibodies against BRabN1 and N2 did not recognize any other Rab proteins, and Western blotting using the anti-BRabN1 antibody revealed a single band in the testis of B. mori. These results suggest that BRabN1 and N2 of B. mori bind GTP, convert from the GTP-bound state to the GDP-bound state by intrinsic GTP hydrolysis activity, and return to the GTP-bound state with the exchange, and that BRabN1 is specifically expressed in testis. Arch. Insect Biochem. Physiol. 2008. (c) 2008 Wiley-Liss, Inc.     

Binding of Rab3A to synaptic vesicles

Prenylated Rab GTPases cycle between membrane-bound and soluble forms. Membrane-bound GDP-Rabs interact with GDP dissociation inhibitor (GDI), resulting in the dissociation of a Rab.GDI complex, which in turn serves as a precursor for the membrane re-association of Rabs. We have now characterized the binding of Rab3A to synaptic vesicles in vitro using either purified complexes or rat brain cytosol as source for GDI.Rab3A. Binding of Rab3A results in the immediate release of GDI from the membrane. Furthermore, binding does not require the presence of additional guanine nucleotides (GDP or GTP) or of cytosolic factors. Although nucleotide exchange follows binding, binding is initially reversible, suggesting that binding of GDP-Rab3A and nucleotide exchange are separate and independent events. Comparison with the binding of Rab1B revealed that both Rab proteins bind preferentially to their respective resident membranes although some promiscuity was observable. Binding is saturable and involves a protease-sensitive binding site that is tightly associated with the vesicle membrane.     

Interactions between Transport Protein Particle (TRAPP) complexes and Rab GTPases in Arabidopsis

Transport Protein Particle II (TRAPPII) is essential for exocytosis, endocytosis, protein sorting and cytokinesis. In spite of a considerable understanding of its biological role, little information is known about Arabidopsis TRAPPII complex topology and molecular function. In this study, independent proteomic approaches initiated with TRAPP components or Rab‐A GTPase variants converge on the TRAPPII complex. We show that the Arabidopsis genome encodes the full complement of 13 TRAPPC subunits, including four previously unidentified components. A dimerization model is proposed to account for binary interactions between TRAPPII subunits. Preferential binding to dominant negative (GDP‐bound) versus wild‐type or constitutively active (GTP‐bound) RAB‐A2a variants discriminates between TRAPPII and TRAPPIII subunits and shows that Arabidopsis complexes differ from yeast but resemble metazoan TRAPP complexes. Analyzes of Rab‐A mutant variants in trappii backgrounds provide genetic evidence that TRAPPII functions upstream of RAB‐A2a, allowing us to propose that TRAPPII is likely to behave as a guanine nucleotide exchange factor (GEF) for the RAB‐A2a GTPase. GEFs catalyze exchange of GDP for GTP; the GTP‐bound, activated, Rab then recruits a diverse local network of Rab effectors to specify membrane identity in subsequent vesicle fusion events. Understanding GEF?Rab interactions will be crucial to unravel the co‐ordination of plant membrane traffic.     

Comprehensive Screening for Novel Rab‐Binding Proteins by GST Pull‐Down Assay Using 60 Different Mammalian Rabs‡

The Rab family belongs to the Ras‐like small GTPase superfamily and is implicated in membrane trafficking through interaction with specific effector molecules. Because of the large number of Rab isoforms in mammals, however, the effectors of most of the mammalian Rabs are yet to be identified. In this study, we systematically screened five different cell or tissue lysates for novel Rab effectors by a combination of glutathione S‐transferase (GST) pull‐down assay with 60 different mammalian Rabs and mass spectroscopic analysis. Three of the 21 Rab‐binding proteins we identified, mKIAA1055/TBC1D2B (Rab22‐binding protein), GAPCenA/TBC1D11 (Rab36‐binding protein) and centaurin β2/ACAP2 (Rab35‐binding protein), are GTPase‐activating proteins (GAPs) for Rab or Arf. Although it has recently been proposed that the Rab–GAP (Tre‐2 /Bub2/Cdc16) domain physically interacts with its substrate Rab, these three GAPs interacted with specific Rabs via a domain other than a GAP domain, e.g. centaurin β2 binds GTP‐Rab35 via the ankyrin repeat (ANKR) domain. Although centaurin β2 did not exhibit any Rab35–GAP activity in vitro, the Rab35‐binding ANKR domain of centaurin β2 was found to be required for its plasma membrane localization and regulation of Rab35‐dependent neurite outgrowth of PC12 cells through inactivation of Arf6. These findings suggest a novel mode of interaction between Rab and GAP.     

Important relationships between Rab and MICAL proteins in endocytic trafficking

The internalization of essential nutrients, lipids and receptors is a crucial process for all eukaryotic cells. Accordingly, endocytosis is highly conserved across cell types and species. Once internalized, small cargo-containing vesicles fuse with early endosomes (also known as sorting endosomes), where they undergo segregation to distinct membrane regions and are sorted and transported on through the endocytic pathway. Although the mechanisms that regulate this sorting are still poorly understood, some receptors are directed to late endosomes and lysosomes for degradation, whereas other receptors are recycled back to the plasma membrane; either directly or through recycling endosomes. The Rab family of small GTP-binding proteins plays crucial roles in regulating these trafficking pathways. Rabs cycle from inactive GDP-bound cytoplasmic proteins to active GTP-bound membrane-associated proteins, as a consequence of the activity of multiple specific GTPase-activating proteins (GAPs) and GTP exchange factors (GEFs). Once bound to GTP, Rabs interact with a multitude of effector proteins that carry out Rab-specific functions. Recent studies have shown that some of these effectors are also interaction partners for the C-terminal Eps15 homology (EHD) proteins, which are also intimately involved in endocytic regulation. A particularly interesting example of common Rab-EHD interaction partners is the MICAL-like protein, MICAL-L1. MICAL-L1 and its homolog, MICAL-L2, belong to the larger MICAL family of proteins, and both have been directly implicated in regulating endocytic recycling of cell surface receptors and junctional proteins, as well as controlling cytoskeletal rearrangement and neurite outgrowth. In this review, we summarize the functional roles of MICAL and Rab proteins, and focus on the significance of their interactions and the implications for endocytic transport.     

The biological roles of small GTPases and interacting proteins in plants

Extensive studies on the molecular mechanisms of vesicular trafficking have revealed that molecules involved in this cellular function are remarkably well conserved from yeast to higher plants. However, it is not clear at all how a variety of organisms maintain the individual divergent systems using the common machinery of vesicular traffic. We have been attempting to understand the roles and regulatory mechanisms of vesicular traffic in plants through the study of Rab/Ypt GTPases. Ara proteins are Rab/Ypt homologues ofArabidopsis, which are implicated in the regulation of vesicular traffic. Their biochemical properties are similar to those of the Rab/Ypt proteins from animal and yeast cells. The overexpression ofARA2 orARA4 causes pleiotropic morphological abnormalities in the transgenic tobacco plants. The GTPase cycle of Ara proteins has to be strictly controlled for their proper functions. We have identified two classes of regulator molecules of Ara2 and Ara4. One is the GTPase activating protein (GAP), and the other is the GDP dissociation inhibitor (GDI). GAP has been identified as an activity accelerating the hydrolysis of GTP by Ara2 or Ara4. GDI (AtGDI1) has been isolated as a molecule interacting with Ara4 using a novel method for detecting interactions between foreign molecules in yeast. Further studies on the interacting molecules should unveil the regulatory system of and signal transduction pathway via Ara proteins. The extended abstract of a paper presented at the 13th International Symposium in Conjugation with Award of the Internation Prize for Biology “Frontier of Plant Biology”     

Specific interactions of Mss4 with members of the Rab GTPase subfamily.

Mss4 is a mammalian protein that was identified as a suppressor of a yeast secretory mutant harboring a mutation in the GTPase Sec4 and was found to stimulate GDP release from this protein. We have now performed a biochemical characterization of the Mss4 protein and examined the specificity of its association with mammalian GTPases. Mss4 is primarily a soluble protein with a widespread tissue distribution. Recombinant Mss4 binds GTPases present in tissue extracts, and by a gel overlay assay binds specifically Rab Rab10proteins. We further define the Mss4-GTPase interaction to a subset of Rabs belonging to the same subfamily branch which include Rab1, Rab3, Rab8, Rab10, Sec4 and Ypt1 but not Rab2, Rab4, Rab5, Rab6, Rab9 and Rab11. Accordingly, Mss4 co-precipitates from a brain extract with Rab3a but not Rab5. Mss4 only stimulates GDP release from, and the association of GTP gamma S with, this Rab subset. Recombinant Mss4 and Rab3a form a stable complex in solution that is dissociated with either GDP or GTP gamma S. Injection of Mss4 into the squid giant nerve terminal enhances neurotransmitter release. These results suggest that Mss4 behaves as a guanylnucleotide exchange factor (GEF) for a subset of Rabs to influence distinct vesicular transport steps along the secretory pathway.     

Functional interactions of stimulatory and inhibitory GDP/GTP exchange proteins and their common substrate small GTP-binding protein.

smg GDS and rho GDI are stimulatory and inhibitory GDP/GTP exchange proteins, respectively, for a group of ras p21-related small GTP-binding proteins (G proteins). rho p21 is a common substrate small G protein for both GDP/GTP exchange proteins. We examined here the functional interactions of these GDP/GTP exchange proteins with rho p21 as a substrate. smg GDS and rho GDI interacted with the GDP-bound form of rho p21 and thereby stimulated and inhibited, respectively, the dissociation of GDP. The inhibitory effect of rho GDI was much stronger than the stimulatory effect of smg GDS. The GDP-bound form of rho p21 formed a complex with rho GDI but not with smg GDS in their simultaneous presence. Since the content of smg GDS was generally less than that of rho GDI in cells, these results suggest that there is some mechanism to release the inhibitory action of rho GDI and to make rho p21 sensitive to the smg GDS action during the conversion of rhoA p21 from the GDP-bound inactive form to the GTP-bound active form in intact cells. On the other hand, rho p21 was previously shown to be ADP-ribosylated by bacterial ADP-ribosyltransferases, named C3 and EDIN, at Asn41 in the putative effector region of rho p21. This ADP-ribosylation was inhibited by rho GDI much more efficiently than by smg GDS. These results suggest that rho GDI may mask the putative effector region of rho p21 and thereby inhibit its interaction with the target protein even in the presence of smg GDS. Thus, both smg GDS and rho GDI are important to regulate the rho p21 activity and action in cooperation with each other.     

Rab35 GTPase: A Central Regulator of Phosphoinositides and F‐actin in Endocytic Recycling and Beyond

Rab35 is one of the first discovered members of the large Rab GTPase family, yet it received little attention for 10 years being considered merely as a Rab1‐like GTPase. In 2006, Rab35 was recognized as a unique Rab GTPase localized both at the plasma membrane and on endosomes, playing essential roles in endocytic recycling and cytokinesis. Since then, Rab35 has become one of the most studied Rabs involved in a growing number of cellular functions, including endosomal trafficking, exosome release, phagocytosis, cell migration, immunological synapse formation and neurite outgrowth. Recently, Rab35 has been acknowledged as an oncogenic GTPase with activating mutations being found in cancer patients. In this review, we provide a comprehensive summary of known Rab35‐dependent cellular functions and detail the few Rab35 effectors characterized so far. We also review how the Rab35 GTP/GDP cycle is regulated, and emphasize a newly discovered mechanism that controls its tight activation on newborn endosomes. We propose that the involvement of Rab35 in such diverse and apparently unrelated cellular functions can be explained by the central role of this GTPase in regulating phosphoinositides and F‐actin, both on endosomes and at the plasma membrane.      

Structural insights into Rab21 GTPase activation mechanism by molecular dynamics simulations

Rab proteins belong to the family of monomeric GTPases which are involved in the cellular membrane trafficking. Rab21 protein exists in interchangeable GTP- and GDP-bound states. Rabs switch between two active and inactive conformations like other GTPases. The inactive form of Rab is bound to GDP while its active form is bounded with the GTP. Interexchange between active and inactive form is mediated by the GDP/GTP exchange factor (GEF) which catalyses the conversion from GDP-bound to GTP-bound form, thereby activating the Rab. While the GTP hydrolysis of Rabs is regulated by a GTPase-activating protein (GAP) which causes Rab inactivation. Here, we report the structural flexibility of the Rab21-GTP and Rab21-GDP complexes by docking and molecular dynamics (MD) simulations. Structural analysis of exchange mechanisms of the co-factors complexed with Rab21 reveals that Cys29, Thr33, His48, Gln78 and Lys133 are essentially important in the activation of proteins. Furthermore, a significant change in the orientation of the interacting co-factors, with slight variation in the free energy of binding was observed. Complexation of GEF with Rab21-GTP and Rab21-GDP reveal a flipping of the switchable residues. Finally, 50 ns MD simulations confirm that the GTP-bound Rab21 complex is thermodynamically more favoured than the corresponding GDP-bound complex. This study provides a detailed understanding of the structural elements involved in the conformational changes of Rab21.     

Purification and characterization from bovine brain cytosol of a novel regulatory protein inhibiting the dissociation of GDP from and the subsequent binding of GTP to rhoB p20, a ras p21-like GTP-binding protein

A novel regulatory protein for the rho proteins (rhoA p21 and rhoB p20), belonging to a ras p21/ras p21-like small molecular weight (Mr) GTP-binding protein (G protein) superfamily, was purified to near homogeneity from bovine brain cytosol and characterized. This regulatory protein, designated here as GDP dissociation inhibitor (GDI) for the rho proteins (rho GDI), inhibited the dissociation of GDP from rhoB p20 and the binding of guanosine 5'-(3-O-thio)triphosphate (GTP gamma S) to the GDP-bound form of rhoB p20 but not of that to the guanine nucleotide-free form. The Mr value of rho GDI was estimated to be about 27,000 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and from the S value, indicating that rho GDI is composed of a single polypeptide without a subunit structure. The isoelectric point was about pH 5.7. rho GDI made a complex with the GDP-bound form of rhoB p20 with a molar ratio of 1:1 but not with the GTP gamma S-bound or guanine nucleotide-free form. rho GDI did not stimulate the GTPase activity of rhoB p20 and by itself showed neither GTP gamma S-binding nor GTPase activity. rho GDI was equally active for rhoA p21 and rhoB p20 but was inactive for other ras p21/ras p21-like G proteins including c-Ha-ras p21, smg p25A, and smg p21. rho GDI activity was detected in the cytosol fraction of various rat tissues. These results indicate that, in mammalian tissues, there is a novel type of regulatory protein specific for the rho proteins that interacts with the GDP-bound form of the rho proteins and thereby regulates the GDP/GTP exchange reaction of the rho proteins by inhibiting the dissociation of GDP from and the subsequent binding of GTP to them. Since there is a GTPase-activating protein for the rho proteins stimulating the GTPase activity of the rho proteins in mammalian tissues, the rho proteins appear to be regulated at least by GTPase-activating protein and GDI in a dual manner.     

Probing the GTPase cycle with real-time NMR: GAP and GEF activities in cell extracts

The Ras superfamily of small GTPases is a large family of switch-like proteins that control diverse cellular functions, and their deregulation is associated with multiple disease processes. When bound to GTP they adopt a conformation that interacts with effector proteins, whereas the GDP-bound state is generally biologically inactive. GTPase activating proteins (GAPs) promote hydrolysis of GTP, thus impeding the biological activity of GTPases, whereas guanine nucleotide exchange factors (GEFs) promote exchange of GDP for GTP and activate GTPase proteins. A number of methods have been developed to assay GTPase nucleotide hydrolysis and exchange, as well as the activity of GAPs and GEFs. The kinetics of these reactions are often studied with purified proteins and fluorescent nucleotide analogs, which have been shown to non-specifically impact hydrolysis and exchange. Most GAPs and GEFs are large multidomain proteins subject to complex regulation that is challenging to reconstitute in vitro. In cells, the activities of full-length GAPs or GEFs are typically assayed indirectly on the basis of nucleotide loading of the cognate GTPase, or by exploiting their interaction with effector proteins. Here, we describe a recently developed real-time NMR method to assay kinetics of nucleotide exchange and hydrolysis reactions by direct monitoring of nucleotide-dependent structural changes in an isotopically labeled GTPase. The unambiguous readout of this method makes it possible to precisely measure GAP and GEF activities from extracts of mammalian cells, enabling studies of their catalytic and regulatory mechanisms. We present examples of NMR-based assays of full-length GAPs and GEFs overexpressed in mammalian cells.     

Ric1-Rgp1 Complex Is a Guanine Nucleotide Exchange Factor for the Late Golgi Rab6A GTPase and an Effector of the Medial Golgi Rab33B GTPase

Rab GTPases are master regulators of membrane trafficking events and template the directionality of protein transport through the secretory and endocytic pathways. Certain Rabs recruit the guanine nucleotide exchange factor (GEF) that activates a subsequent acting Rab protein in a given pathway; this process has been termed a Rab cascade. We show here that the medial Golgi-localized Rab33B GTPase has the potential to link functionally to the late Golgi, Rab6 GTPase, by its capacity for association with Ric1 and Rgp1 proteins. In yeast, Ric1p and Rgp1p form a complex that catalyzes guanine nucleotide exchange by Ypt6p, the Rab6 homolog. Human Ric1 and Rgp1 both bind Rab6A with preference for the GDP-bound conformation, characteristic of a GEF. Nevertheless, both Ric1 and Rgp1 proteins are needed to catalyze nucleotide exchange on Rab6A protein. Ric1 and Rgp1 form a complex, but unlike their yeast counterparts, most of the subunits are not associated, and most of the proteins are cytosolic. Loss of Ric1 or Rgp1 leads to destabilization of Rab6, concomitant with a block in Rab6-dependent retrograde transport of mannose 6-phosphate receptors to the Golgi. The C terminus of Ric1 protein contains a distinct binding site for Rab33B-GTP, supporting the existence of a Rab cascade between the medial and trans Golgi. This study thus identifies a GEF for Rab6A in human cells.     

Rab27a targeting to melanosomes requires nucleotide exchange but not effector binding

Rab GTPases are important determinants of organelle identity and regulators of vesicular transport pathways. Consequently, each Rab occupies a highly specific subcellular localization. However, the precise mechanisms governing Rab targeting remain unclear. Guanine nucleotide exchange factors (GEFs), putative membrane-resident targeting factors and effector binding have all been implicated as critical regulators of Rab targeting. Here, we address these issues using Rab27a targeting to melanosomes as a model system. Rab27a regulates motility of lysosome-related organelles and secretory granules. Its effectors have been characterized extensively, and we have identified Rab3GEP as the non-redundant Rab27a GEF in melanocytes (Figueiredo AC et al. Rab3GEP is the non-redundant guanine nucleotide exchange factor for Rab27a in melanocytes. J Biol Chem 2008;283:23209-23216). Using Rab27a mutants that show impaired binding to representatives of all four Rab27a effector subgroups, we present evidence that effector binding is not essential for targeting of Rab27a to melanosomes. In contrast, we observed that knockdown of Rab3GEP resulted in mis-targeting of Rab27a, suggesting that Rab3GEP activity is required for correct targeting of Rab27a. However, the identification of Rab27a mutants that undergo efficient GDP/GTP exchange in the presence of Rab3GEP in vitro but are mis-targeted in a cellular context indicates that nucleotide loading is not the sole determinant of subcellular targeting of Rab27a. Our data support a model in which exchange activity, but not effector binding, represents one essential factor that contributes to membrane targeting of Rab proteins.