Rab32 is an A-kinase anchoring protein and participates in mitochondrial dynamics

doi:10.1083/jcb.200204081

Published 19 August 2002. doi:10.1083/jcb.200204081

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© The Rockefeller University Press, 0021-9525/2002/8/659 $5.00
The Journal of Cell Biology, Volume 158, Number 4, August 19, 2002 659-668

Article

Rab32 is an A-kinase anchoring protein and participates in mitochondrial dynamics

Neal M. Alto², Jacquelyn Soderling¹ and John D. Scott¹

¹ Howard Hughes Medical Institute, Vollum Institute
² Department of Cellular and Developmental Biology, Oregon Health and Sciences University, Portland, OR 97201

Address correspondence to John D. Scott, Howard Hughes Medical Institute, Vollum Institute, Oregon Health and Sciences University, 3181 S.W. Sam Jackson Park Road, Portland, OR 97201. Tel.: (503) 494-4652. Fax: (503) 494-0519. E-mail: scott{at}ohsu.edu

Abstract

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Abstract
Introduction
Results
Discussion
Materials and methods
References

A-kinase anchoring proteins (AKAPs) tether the cAMP-dependentprotein kinase (PKA) and other signaling enzymes to distinctsubcellular organelles. Using the yeast two-hybrid approach,we demonstrate that Rab32, a member of the Ras superfamily ofsmall molecular weight G-proteins, interacts directly with thetype II regulatory subunit of PKA. Cellular and biochemicalstudies confirm that Rab32 functions as an AKAP inside cells.Anchoring determinants for PKA have been mapped to sites withinthe conserved ${alpha}$ 5 helix that is common to all Rab family members.Subcellular fractionation and immunofluorescent approaches indicatethat Rab32 and a proportion of the cellular PKA pool are associatedwith mitochondria. Transient transfection of a GTP binding–deficientmutant of Rab32 promotes aberrant accumulation of mitochondriaat the microtubule organizing center. Further analysis of thismutant indicates that disruption of the microtubule cytoskeletonresults in aberrantly elongated mitochondria. This implicatesRab32 as a participant in synchronization of mitochondrial fission.Thus, Rab32 is a dual function protein that participates inboth mitochondrial anchoring of PKA and mitochondrial dynamics.

Key Words: protein kinase; cAMP; anchoring protein; Rab protein; mitochondria

Introduction

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Abstract
Introduction
Results
Discussion
Materials and methods
References

The transmission of environmental cues to precise sites withinthe cell frequently involves the assembly of multiprotein signalingcomplexes (Pawson, 1995; Hunter, 2000; Jordan et al., 2000).These transduction units, which often include effector proteins,signal transduction enzymes, and their substrate proteins, aremaintained by scaffolding or anchoring proteins (Smith and Scott, 2002).These "signal-organizing" molecules ensure that theircomplement of anchored enzymes are optimally positioned to receiveactivation signals and are placed in close proximity to theirsubstrates. One example is the A-kinase anchoring proteins (AKAPs)^*that sequester the cAMP-dependent protein kinase (PKA) and othersignaling enzymes at a variety of intracellular sites (Colledge and Scott, 1999;Feliciello et al., 2001).

Although a principle function of many kinase anchoring proteinsis to orchestrate protein phosphorylation events, it is nowevident that they participate in a wider range of signalingevents. For example, several anchoring proteins have been implicatedin the recruitment and localization of Ras family small molecularweight GTPases. AKAP-Lbc binds PKA and functions as a Rho-selectiveguanine nucleotide exchange factor (GEF) to induce actin stressfiber formation in fibroblasts (Diviani et al., 2001). Scar/WAVE-1assembles a signaling complex that includes PKA, the Abelsontyrosine kinase, Rac-1, and the Arp2/3 complex to coordinatelamellapodial extension at the leading edge of motile cells(Westphal et al., 2000). Anchoring proteins that bind to othersecond messenger–regulated protein kinases apparentlyperform analogous functions. The mammalian orthologue of theCaenorhabditis elegans cell polarity gene, mPAR-6, interactswith either Cdc42 or Rac1 and an atypical PKC to establish cellshape and polarity in the developing embryo (Etemad-Moghadam et al., 1995;Kuchinke et al., 1998; Joberty et al., 2000; Lin et al., 2000;Qiu et al., 2000). Collectively, these findingshighlight a secondary role for kinase anchoring proteins inthe coordination of small G-protein location and signaling todownstream effectors.

Here we report that Rab32, a member of the Rab subfamily ofRas small molecular weight G-proteins, functions as an AKAPin vivo. Most Rab proteins have been implicated in membranedynamics, where they coordinate the assembly of protein networksthat regulate membrane fusion/fission, exocytosis, and cytoskeletaltrafficking (Takai et al., 2001). These events require the Rabproteins to cycle from a cytoplasmic-localized GDP-bound "off"state to a membrane-localized GTP-bound "on" state (Novick and Zerial, 1997).Accordingly, Rab proteins have been found atvarious intracellular sites including the endoplasmic reticulum,the Golgi apparatus, endosomes, intracellular vesicles, andthe plasma membrane (Takai et al., 2001). Our cell-based studiesdemonstrate that Rab32 is associated with the mitochondria throughpotential lipid modification of two COOH-terminal cysteines.Furthermore, ectopic expression of a GTP binding–defectivemutant of Rab32 perturbs mitochondrial distribution, suggestinga specific role for this Rab protein at mitochondria.

Results

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Abstract
Introduction
Results
Discussion
Materials and methods
References

Identification and characterization of Rab32 as a type II regulatory subunit (RII) binding protein
Biochemical and structural analyses have indicated that thefirst 45 amino acids of the type II regulatory subunit (RII)comprise the primary determinants for interacting with AKAPs(Hausken et al., 1994; Newlon et al., 1999). To identify newAKAPs, the first 45 amino acids of the murine RII ${alpha}$ were usedas "bait" to screen a human brain cDNA library using the yeasttwo-hybrid assay. 50 positive colonies were identified from2 x 10⁶ cotransformants, as assessed by activation of both theHIS3 and LacZ genes. 40 of these positive colonies encoded previouslyidentified AKAPs, including Yotiao, AKAP220, and S-AKAP84 (Fig. 1A). One positive colony encoded residues 106–225 ofRab32 that, based on primary amino acid similarity and domainarchitecture, is believed to be a small molecular weight G-proteinof the Rab family (GenBank/EMBL/DDBJ accession no. NP_006825)(Bao et al., 2002). Independent confirmation of this resultwas provided when the bacterially expressed Rab32 106–225fragment bound recombinant [³²P]RII ${alpha}$ , as assessed by a solid-phasebinding assay (Fig. 1 B).

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Figure 1. Identification of Rab32 as a putative AKAP. Murine RII ${alpha}$ 1–45/LexA fusion was used as bait to screen a human brain cDNA library using the yeast two-hybrid assay. (A) Detection of positive colonies expressing Rab32 and other AKAP fragments were detected by ß-galactosidase. The name of each AKAP is indicated. (B) Control and bacterial extracts expressing the Rab32 106–225 fragment (indicated above each lane) were separated on SDS-PAGE (4–15%) and electrotransferred to nitrocellulose. RII binding was assessed by overlay using ³²P-labeled RII ${alpha}$ and detected by autoradiography. Molecular weight markers are indicated.

The PKA anchoring site on AKAPs includes a region of 14–18residues that forms an amphipathic helix (Carr et al., 1991;Newlon et al., 2001). To define this region within Rab32, anarray of overlapping 20-mer peptides (offset by three aminoacids) covering residues 151–225 were synthesized on amembrane support using an AutoSpot robot (Fig. 2 A). A singlepeptide corresponding to amino acids 178–197 (NINIEEAARFLVEKILVNHQ)strongly bound RII ${alpha}$ , as assessed by the solid-phase binding assay(Fig. 2 B). Computer predictions of its secondary structuresuggest that residues 178–197 form an amphipathic helix(Fig. 2 C). All Ras family members share a similar structurewith an arrangement of six central strands of ß-sheetand five ${alpha}$ -helical regions. Structural analysis of Rab3a, a proteinwith 71% identity to Rab32, suggests that the RII binding regionfalls within the conserved ${alpha}$ 5 helix (Ostermeier and Brunger, 1999).Modeling studies using the coordinates from the Rab3astructure suggest that the ${alpha}$ 5 helix of these proteins are locatedon an exposed surface of the molecule and would be availablefor docking to RII (Fig. 2 D). Experimental confirmation ofthese observations was provided when the Rab32 175–205peptide blocked RII ${alpha}$ interaction with a full-length Rab32 GSTfusion protein (Fig. 2 E, middle). A control peptide, whereleucine 188 was replaced with proline to disrupt secondary structure,was unable to block RII interaction (Fig. 2 E, right). Thesedata imply that RII interacts with Rab32 through an amphipathichelix formed by residues 178–197 of the protein. Solutionbinding assays confirmed that recombinant Rab32 bound [³²P]RII ${alpha}$ ,whereas the Rab32L188P mutant did not (Fig. 2 F). Together,these results show that Rab32 can interact with full-lengthRII in vitro and this interaction occurs through a predictedamphipathic helix in a manner similar to other AKAPs.

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Figure 2. Mapping the RII binding domain of Rab32. (A) Schematic representation of the mapping strategy to identify the RII binding domain of Rab32. A family of 20-mer peptides (each offset by three residues) spanning the region 153–224 of Rab32 were synthesized and immobilized to a membrane support. (B) Solid-phase binding of RII was assessed by the RII overlay procedure. The sequence of the RII binding peptide is indicated using the one letter amino acid code (*). (C) Ribbon diagram of the Rab3a backbone based upon coordinates provided by Ostermeier and Brunger (1999). Top (left) and side (right) views are presented. The ${alpha}$ 5 helix is marked (red). (D) Helical wheel alignment of residues 181–193 of Rab32. Hydrophobic (white circles) and hydrophilic (yellow circles) residues are indicated. (E) Purified recombinant GST–Rab32 fusion protein (2 µg) was separated by SDS-PAGE and electrotransferred to nitrocellulose. RII overlays were performed in the absence of competitor peptide (left), in the presence of 10 µM Rab32 175–205 peptide (middle), or in the presence of 10 µM Rab32 175–205 L188P peptide (right). Molecular weight markers are indicated. (F) Solution binding of recombinant RII and Rab32. [³²P]RII ${alpha}$ was incubated with either GST–Rab32 or GST–Rab32L188P mutant followed by glutathione-Sepharose purification of the complex. RII binding was assessed by measuring the counts per minute (cpm) corresponding to [³²P]RII ${alpha}$ bound to Rab32 (top). Equal amounts of GST fusion proteins were used in these experiments (bottom).

We next sought to determine if Rab32 is an AKAP in vivo. Flag-taggedversions of wild-type Rab32 and Rab32L188P mutant were expressedin HEK-293 cells. Immune complexes were isolated, and coprecipitationof PKA activity was measured by the filter paper assay (Corbin and Reimann, 1974).PKA activity was enriched 7.1 ± 2–fold(n = 3) in Rab32 immune complexes, whereas there was no enhancementof kinase activity in the Rab32L188P mutant immunoprecipitates(Fig. 3 A). Control experiments confirmed that this was specificPKA activity, because the PKI (5–24) peptide, a specificinhibitor of the kinase, blocked all activity (Fig. 3 A). Inparallel studies, only wild-type Rab32 bound RII in the Flagimmunoprecipitates, as assessed by the RII overlay (Fig. 3 B),suggesting that Rab32 is the only AKAP responsible for the PKAactivity. Thus, Rab32 associates with endogenous PKA holoenzymeinside mammalian cells.

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Figure 3. Rab32 can interact with the holoenzyme of PKA in mammalian cells. HEK-293 cells were transiently transfected with Flag–Rab32 or Flag–Rab32L188P cDNA. Triton X-100–soluble extracts were immunoprecipitated with Sepharose-conjugated antiFlag antibody. (A) Copurification of the PKA holoenzyme was measured by assaying for PKA catalytic subunit activity stimulated by exogenous cAMP. PKA activity was measured as pmol/min/mg of ³²P incorporated into the PKA substrate kemptide using a filter paper binding assay (Corbin and Reimann, 1974). Specific PKA activity was blocked by 10 µM of the inhibitor PKI (5–24) peptide. (B) AntiFlag immunoprecipitates were separated on SDS-PAGE after the catalytic subunit had been eluted from the complex with exogenous cAMP and electrotransferred to nitrocellulose. RII overlay assays (top) were performed to determine if Rab32 was the only AKAP present in these fractions. Control experiments confirmed that equal levels of protein were immunoprecipitated in these experiments (bottom). A representative example of three independent experiments is shown.

Rab32 and closely related orthologues are the only Rab family members that function as AKAPs
Each of the 60 genes that encode Rab proteins in the human genomeis highly conserved in the ${alpha}$ 5 helix (Bock et al., 2001). Therefore,peptides corresponding to the ${alpha}$ 5 helix region from nine otherRab proteins (sequences are presented in Fig. 4 A as a clustalalignment) were synthesized by the AutoSpot robot to determineif other Rab family members could interact with RII. Solid-phasebinding to RII was only detected for the Rab32 peptide (Fig. 4, B and C).Likewise only full-length Rab32 bound RII, as assessedby the two-hybrid assay (Fig. 4 D). Structural studies on severalAKAPs have established that alanines at position 6 of the PKAbinding helix are critical anchoring determinants (Newlon et al., 2001).The methyl group of the alanine side chain insertsinto a hydrophobic pocket formed by the RII dimer. Rab32 hasan alanine at this position, whereas most Rab family membershave a phenylalanine at this site in the ${alpha}$ 5 helix (Fig. 4 A,star). To test the role of Ala 185 as an anchoring determinant,we introduced a phenylalanine by site-directed mutagenesis.The Rab32A185F mutant protein was unable to bind RII in theoverlay procedure (Fig. 4 E), and an A185F-substituted peptidewas also unable to interact with RII ${alpha}$ (unpublished data). Databasesearches identified a Drosophila orthologue, Rab-RP1, that containedan alanine in a position analogous to residue 185 of Rab32.Peptide array analysis confirmed that Rab-RP1 bound RII in theoverlay assay, whereas two closely related Rab proteins lackingthe conserved phenylalanine (Rab38 and Rab7L1) did not bindRII (Fig. 4, F and G). Collectively, these data suggest thatRab32 and orthologues are AKAPs.

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Figure 4. Only Rab32 and RabRP-1 contain determinants for PKA anchoring. (A) The sequences of Rab32 and nine other Rab proteins are aligned within the ${alpha}$ 5 helix region. The first and last residues of each sequence and the name of each Rab protein are indicated. Boxed and shaded regions depict sequence identity and similarity. Star indicates the conserved phenylalanine in most Rab proteins. (B) A solid-phase peptide array of these Rab sequences was screened for RII binding by the overlay assay. Binding of [³²P]RII ${alpha}$ was detected by autoradiography. (C) Quantitation of RII binding was assessed by densitometry. Arbitrary units were normalized to one, indicating the highest level of RII binding. The data presented are an amalgamation of two independent experiments. (D) Yeast two-hybrid analysis was used to determine if RII interacts with selected, full-length Rab family members. Two-hybrid crosses of RII ${alpha}$ 1–45 fragment with full-length cDNAs for Rab32, Rab32L188P, Rab5, Rab6, or Rab7 fused to the LexA DNA binding domain. Interactions were assayed by growth on minimal media plates in the absence of histidine (left). As a toxicity control, all cotransformed yeast strains were able to grow in the presence of histidine (right). (E) HEK-293 cell extracts expressing Flag-tagged Rab32 and mutants (indicated above each lane) were separated by SDS-PAGE on 4–15% gels and electrotransferred to nitrocellulose. Binding of [³²P]RII ${alpha}$ was assessed by the overlay assay. (Top) RII binding was detected by autoradiography. Equal loading of recombinant Rab32 proteins was confirmed by Western blot using antiFlag antibodies. (F) Sequence alignment of Rab32 and its most closely related family members. The first and last residues of each sequence and the name of each Rab protein are indicated. Boxed and shaded regions depict sequence similarity and identity. Star indicates the position of alanine 185 in the Rab32 sequence. (G) A solid-phase peptide array of these closely related Rab sequences was screened for RII binding by the overlay assay. Binding of [³²P]RII ${alpha}$ was detected by autoradiography.

Rab32 is associated with mitochondria
The tissue distribution of Rab32 mRNA was determined by Northernblot using a specific 113-bp probe. An mRNA species of 1.4 kbwas detected prominently in the liver and, to a lesser extent,in other tissues (Fig. 5 A). RNA dot blot analysis detectedhigh levels of Rab32 mRNA in bone marrow, testis, colon, andfetal lung (unpublished data). This latter observation promptedus to examine the subcellular distribution of the Rab32 proteinin the human fetal lung fibroblast cell line WI-38. As a preludeto these studies, antipeptide antibodies were raised againstresidues 202–220 of Rab32 and affinity purified againstthe recombinant protein. A single protein band of 27 kD wasdetected in cell extracts as assessed by immunoblot (Fig. 5B, left). Preincubation with the antigenic peptide blocked antibodyrecognition of this 27-kD protein (unpublished data). Controlexperiments using the preimmune serum were negative (Fig. 5B, right).

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Figure 5. The cellular and subcellular distribution of Rab32. The tissue distribution of Rab32 mRNA was assessed by Northern blot analysis. (A) A human multi-tissue (tissue sources indicated above each lane) was screened using a 113-bp cDNA probe that corresponds to the COOH-terminal hypervariable region of Rab32. Hybridization was detected by autoradiography. The sizes of DNA markers are indicated. (B) Triton X-100–soluble extracts from the WI-38 human fetal lung fibroblasts were immunoblotted with affinity-purified anti-Rab32 antibody (left) or preimmune sera (right). Signals were detected by chemiluminescence. Molecular weight standards are indicated. Confocal immunofluorescence microscopy of WI-38 fibroblasts triple labeled with polyclonal antibodies against Rab32 (C, green), cell-permeable dye MitoTracker Red^TM (D, red), and a monoclonal antibody against ${alpha}$ -tubulin (E, blue). A merged image (F) indicates the cellular distribution of all three signals. (G) Subcellular fractionation of WI-38 cells was performed according to the Materials and methods. Protein (20 µg each) from whole cell (W), nuclear (P1), and mitochondria-enriched (P2) fractions were subjected to SDS-PAGE and electrotransferred to nitrocellulose. Membranes were immunoblotted using affinity-purified polyclonal anti-Rab32 antibody (top) and a monoclonal anticytochrome oxidase subunit I (bottom) as a marker for mitochondria. Immunocytochemistry and confocal analysis were used to demonstrate the subcellular location of RII (H) and Rab32 (I). A merged image shows a significant overlap of the signals (J).

Immunofluorescent analysis of Rab32 in WI-38 fibroblasts revealeda staining pattern (Fig. 5 C) that overlapped with the mitochondrialmarker MitoTracker Red^TM (Fig. 5 D) but was distinct from tubulin(Fig. 5 E). This is most clearly demonstrated in a compositeimage (Fig. 5 F). In support of this observation, Rab32 wasenriched in the P2 fraction (Fig. 5 G, top) when WI-38 cellextracts were subjected to subcellular fractionation. The partitioningof Rab32 correlated with the detection of the mitochondrialmarker cytochrome oxidase subunit 1 (Fig. 5 G, bottom). Immunofluorescencedata also suggested that a proportion of cellular RII signalis present at mitochondria (Fig. 5 H) and overlaps with theRab32 signal (Fig. 5, I and J). Collectively, these resultssuggest that Rab32 and RII associate with mitochondria.

Mitochondria are arranged around the microtubule organizingcenter and utilize microtubules for their movement. However,Rab32 association with mitochondria is not dependent on theintegrity of the microtubule cytoskeleton (Fig. 6 , A–H).Cos7 cells were treated with the microtubule depolymerizingagent nocodazole and the location of Rab32, mitochondria, andmicrotubules were visualized by immunofluorescence detection(Fig. 6, E–H). As expected, nocodazole treatment disruptedthe microtubule network (Fig. 6 G) and promoted a redistributionof mitochondria (Fig. 6, F and H), when compared with controlcells (Fig. 6, B–D). Importantly, Rab32 was retained onthe mitochondria after drug treatment (Fig. 6, E and H), indicatingthat it specifically associates with this organelle.

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Figure 6. Mitochondrial targeting of Rab32. Immunofluorescence analysis of Rab 32 location upon depolymerization of microtubules in Cos7 cells. Control (A–D) or Cos7 cells treated with 5 µM nocodazole for 30 min (E–H) were fixed and stained. Immunocytochemistry was performed using anti-Rab32 (A and E, green), MitoTracker Red^TM (B and F, red), and a monoclonal antibody against ${alpha}$ -tubulin (C and G, blue). Composite images are shown for each sample (D and H). (I) Schematic representation of a nucleotide binding site, GTPase domain, and sites of putative lipid modification are indicated. Arrows indicate an amino acid substitution. (J) Flag-tagged wild-type or Rab32 ${Delta}$ CC mutant were expressed in Cos7 cells. The subcellular distribution of recombinant Rab32 ${Delta}$ CC (J) or Rab32 (M) were analyzed using confocal fluorescence microscopy with an antiFlag monoclonal antibody and Texas red–conjugated secondary (J and M). Mitochondria were visualized by using Mito–GFP targeting construct (K and N). Merged images are presented (L and O).

Mitochondrial targeting sequences have been identified in anumber of proteins, including other AKAPs (Lin et al., 1995;Huang et al., 1999), yet no such sequences were evident in Rab32.Previous studies have proposed that lipid modification of twoCOOH-terminal cysteines may participate in the membrane targetingof Rab proteins (Takai et al., 2001). We generated a Flag-taggedform of Rab32 that lacked the pair of COOH-terminal cysteineresidues (Fig. 6 J). The Rab32 ${Delta}$ CC mutant did not associate withmitochondria when expressed in Cos7 cells (Fig. 6, K and L).Mitochondria were detected by coexpression of a GFP fusion proteinthat contained a mitochondrial targeting signal (Fig. 6, K and N).Control experiments demonstrated that wild-type Rab32 codistributedwith the Mito–GFP tag when both constructs were transfectedinto Cos7 cells (Fig. 6, M–O). Additional controls demonstratedthat the Rab32L188P mutant, which is unable to anchor PKA, wascorrectly targeted to mitochondria (unpublished data). Thesefindings suggest that COOH-terminal lipid modification of Rab32contributes to mitochondrial targeting, most likely to the outermitochondrial membrane.

Biochemical and cellular analyses of Rab32
Rab32 has four conserved guanine nucleotide binding regionsincluding a possible GTPase domain (Fig. 7 A). Using an invitro binding assay we found that [³H]GDP dissociated from Rab32with a t_1/2 of 7.5 min (n = 3; Fig. 7 B). Using a similar assay,GTP binding was measured with a t_1/2 of 12 min (n = 3; Fig. 7C). These studies show, as predicted, that Rab32 is a guaninenucleotide binding protein. On the basis of homology to otherRas family members, we predicted that mutation of threonine39, which lies within the GTP binding domain, would abolishinteraction with this nucleotide (Fig. 7 A). As expected, theRab32T39N mutant bound GTP to a 12-fold lesser extent when comparedwith the wild-type protein (Fig. 7 D). Equal amounts of bothRab32 forms were used in these assays (Fig. 7 D, insert). Wenext sought to determine if RII preferentially interacts withRab32 in a nucleotide-dependent manner. Rab32 was preloadedwith either GDP or the nonhydrolyzable GTP analogue, GTP ${gamma}$ S. Rab32could associate with RII whether it was loaded with GDP or GTP ${gamma}$ S(Fig. 7 E). Yeast two-hybrid assay confirmed this result, asthe Rab32T39N mutant and Rab32Q85L, a potential GTPase inactiveform, interacted with RII (Fig. 7 F). These data show that Rab32interacts with RII in a nucleotide-independent state.

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Figure 7. Nucleotide binding properties and GTPase activity of Rab32. Bacterially purified GST fusion proteins were assayed for guanine nucleotide binding. (A) Schematic diagram depicting a mutation in the nucleotide binding domain of Rab32. A nucleotide binding site, GTPase domain, and sites of putative lipid modifications are indicated. (B) GST–Rab32 (2 µg) was preloaded with 2 µCi of [³H]GDP. GDP off rate is presented as percent GDP bound to Rab32 over time. (C) Nucleotide-depleted Rab32 was incubated with [ ${gamma}$ ³²P]GTP. The GTP on rate for GST–Rab32 was measured and is presented as the percentage of GTP bound over time. Amalgamated data from three experiments are presented. (D) Biochemical characterization of guanine nucleotide binding to recombinant wild-type GST–Rab32 and GST–Rab32T39N mutant. [³H]GDP binding (gray bars) and [ ${gamma}$ ³²P]GTP binding (black bars) to Rab32 and Rab32T39N are indicated. Results are presented as the percent nucleotide bound normalized to 1. 2 µg of GST recombinant proteins were used and shown in the inset. A representative experiment from three independent analyses is presented. (E) GST pulldowns of GDP-loaded Rab32 or GTP ${gamma}$ S-loaded Rab32 in the presence of recombinant RII (1 µg). Proteins were separated by SDS-PAGE and transferred to nitrocellulose. (Top) Coprecipitation of RII was detected by Western blot using an anti-RII monoclonal antibody. (Bottom) Control experiments showing equal loading of proteins. (F) Yeast coexpressing pLexA Rab32 mutants and pACT2 RII 1–45 were assayed for growth on minimal media without histidine (left). As a toxicity control, yeast harboring these plasmids can grow in media supplemented with histidine (right).

In cellular studies, overexpression of the GTP binding–deficientmutant Rab32T39N caused the condensation of mitochondria atthe microtubule organizing centers, as assessed by immunofluorescencetechniques (Fig. 8 , A–C). In contrast, overexpressionof the wild-type protein had little or no effect on mitochondrialdistribution (Fig. 8, D and E). The frequency of mitochondrialcollapse was measured in transfected cells (50 cells each) fromthree separate experiments (Fig. 8 G). Mitochondrial collapsewas detected in 56 ± 4% of cells expressing the Rab32T39Nmutant (Fig. 8 G), and only 8.6 ± 2% of the wild-typecells exhibited this phenomena (Fig. 8, D, E, and G). Mitochondrialcollapse did not appear to involve PKA anchoring because expressionof the PKA binding–deficient mutant, Rab32L188P, did notalter the incidence of mitochondrial collapse (Fig. 8 G). Inaddition, expression of a Rab32T39N, L188P double mutant causedthe same degree of mitochondrial collapse as the Rab32T39N mutant(Fig. 8 G). However, correct targeting to the mitochondria appearsto contribute to this phenomena, as expression of Rab32T39N ${Delta}$ CC,a GTP binding deficient–mutant lacking the COOH-terminalcysteine pair, displayed a reduced incidence of mitochondrialcollapse (32 ± 2%; Fig. 8 G). Because endogenous Rab32was detected in Cos7 cells (Fig. 6, A and E), our cellular experimentssuggest that Rab32T39N acts as a dominant negative mutant. Inspecificity control experiments, we did not observe any abnormalclustering of endosomes (Fig. 8, H–J), lysosomes (Fig. 8,K–M), or endoplasmic reticulum (Fig. 8, N–P)in cells exhibiting a Rab32T39N-induced mitochondrial collapse.

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Figure 8. The GTP binding mutant Rab32T39N induces mitochondrial collapse around the microtubule organizing center. Cos7 cells were transiently transfected with Flag–Rab32 or Flag–Rab32T39N. Cells were labeled with MitoTracker Red^TM for 30 min, fixed, and permeabilized before the Rab proteins were detected with a FITC-conjugated antiFlag antibody. (A) Rab32T39N mutant or (D) Rab32 and (B and E) mitochondria are shown. (C and F) Composite images are presented. A mitochondrial collapse phenotype is observed in Rab32T39N-expressing cells (B, inset). (G) Mitochondrial collapse was scored in cells expressing various Rab32 mutants (indicated below each column). Data are presented as the number of cells exhibiting the phenotype per number of cells transfected. 50 Rab-expressing cells were analyzed in three independent experiments for each construct. Control experiments were performed to determine if expression of Rab32T39N (H, K, and N) alters the morphology or distribution of other organelles. (I, L, and O) Mitochondria were visualized with MitoTracker Red^TM. (J) Endosomes were stained with antibodies against the marker protein EEA-1. (M) Lysosomes were stained with antibodies against the marker protein LAMP-1. (P) Endoplasmic reticulums were stained with antibodies against the marker protein calnexin.

Rab proteins can function in membrane fusion, membrane fission,and regulate organelle motility. Our data thus far do not distinguishbetween these events. Expression of Rab32T39N at low levelspromotes an intermediate phenotype in which the mitochondriaare elongated and highly interconnected (Fig. 9 , A–D).To further explore this effect, Rab32T39N-transfected cellswere subjected to nocodazole treatment for 1 h before fixation(Fig. 9 E). Depolymerization of the microtubules did not resultin a dispersion of the mitochondria (Fig. 9, F and G), but therewas a preponderance of highly interconnected and elongated mitochondria(Fig. 9 G). Often there were fewer mitochondria per cell, suggestingthat expression of Rab32T39N promoted abnormal fusion (unpublisheddata). In contrast, Cos7 cells expressing wild-type Rab32 areindividually dispersed throughout the cytoplasm upon nocodazoletreatment (Fig. 9, I–L).

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Figure 9. Expression of Rab32T39N leads to aberrant mitochondrial fusion. Analysis of mitochondrial morphology was performed on cells expressing various levels of Rab32T39N (A–H) and the wild-type protein (I–L). (A) Analysis of collapsed mitochondrial morphology in Cos7 cells expressing low levels of Flag–Rab32T39N. (B) Mitochondria were detected with MitoTracker Red^TM stain. (C) A 3x enlargement of the boxed region shown in B (yellow box). (D) Composite image of A and B is presented. (E) Analysis of collapsed mitochondrial morphology in Cos7 cells expressing Flag–Rab32T39N treated with 5 µM nocodazole for 1 h. (F) Mitochondria were detected with MitoTracker Red^TM stain. (G) A 3x enlargement of the boxed region shown in F (yellow box). (H) Composite image of E and F is presented. (I) Analysis of dispersed mitochondrial morphology in Cos7 cells expressing Flag–Rab32 treated with 5 µM nocodazole for 1 h. (J) Mitochondria were detected with MitoTracker Red^TM stain. (K) A 3x enlargement of the boxed region shown in J (yellow box). (L) Composite image of I and J is presented.

	Discussion

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Rab32 is a member of the Ras superfamily of small molecularweight G-proteins and belongs to a subclass of these proteinsthat have a nonconsensus catalytic domain (Bao et al., 2002).We now show that Rab32 functions as an AKAP as it associateswith the cAMP-dependent protein kinase (PKA) inside cells. Althoughwe have previously shown that two Rho family GTPases interactwith AKAPs (Westphal et al., 2000; Diviani et al., 2001), weprovide the first evidence for a direct interaction betweena small molecular weight G-protein and the PKA holoenzyme. Interestingly,two other Rab family members interact with protein kinases.Rab8 binds to a GC kinase in a GTP-dependent manner (Ren et al., 1996),and Rab3d copurifies with a ser/thr kinase in theRBL-2H3 mast cell line (Pombo et al., 2001). Our study furtheremphasizes two additional properties of Rab32: it is localizedto mitochondria and it participates in the control of mitochondrialdynamics.

AKAPs are a growing family of functionally related proteinsthat are classified on the basis of their interaction with theR subunits of the PKA holoenzyme. Common properties includea conserved helical region of 14–18 residues that bindsto the R subunit dimer (Carr et al., 1991; Newlon et al., 2001).Our mutagenesis and peptide-binding experiments have locatedPKA anchoring determinants between residues 178 and 197 of Rab32,which includes the ${alpha}$ 5 helical region that is conserved in allRas family members (Bourne et al., 1991). Our modeling studiesused the coordinates from the crystal structure of Rab3a topredict that the ${alpha}$ 5 helix of Rab32 is exposed and available toparticipate in PKA anchoring. Interestingly, other members ofthe Ras superfamily utilize this helix in a variety of protein–proteininteractions (Maesaki et al., 1999; Morreale et al., 2000).However, only Rab32 and Rab RP-1, a closely related Drosophilaorthologue, bind to RII experimentally. This indicates thatdeterminants reside within the ${alpha}$ 5 helices of both isoforms thataccommodate PKA anchoring. Surprisingly, the ability to bindPKA may be determined by a single amino acid side chain. Rab32and RabRP-1 contain an alanine at position 185 within the helix(numbering based on the Rab32 sequence), whereas most otherRab proteins have a phenylalanine at this position. In fact,substitution with phenylalanine at this site abolishes PKA bindingto Rab32, suggesting that a bulky hydrophobic side chain atthis site perturbs PKA anchoring. Likewise, introduction ofphenylalanine at the corresponding sites in AKAP79, mAKAP, AKAP-KL,AKAP18, or AKAP-Lbc abolishes interaction with RII, as assessedby peptide array analysis (unpublished data). These findingsemphasize the high degree of specificity that is built intothe PKA anchoring regions.

A proposed function for AKAPs is to direct PKA and other signalingenzymes close to their substrates (Colledge and Scott, 1999;Smith and Scott, 2002). This is generally achieved by targetingdomains that direct the AKAP signaling complex to discrete cellularenvironments. Our subcellular fractionation and immunolocalizationdata indicate that Rab32 is localized at the mitochondria. Althoughthis is the first report of a Rab protein associated with thisorganelle, other AKAPs, such as sAKAP84/D-AKAP-1 and D-AKAP-2,are targeted to the outer mitochondrial membranes (Huang et al., 1997a, b). Mitochondrial targeting of sAKAP84/D-AKAP-1 ismediated by a consensus mitochondrial targeting sequence (Lin et al., 1995;Huang et al., 1999). Rab32 does not contain thissequence, but rather has a pair of cysteines at the COOH terminusthat are necessary for correct targeting. Both residues areconserved in most Rab proteins and are likely to be sites oflipid modification. Such modifications may be required for insertionand retention of Rab32 in the mitochondrial membrane (Glomset and Farnsworth, 1994).However, additional protein–proteininteractions are likely to specify mitochondrial targeting,because high-level expression of Rab32 leads to the detectionof the protein throughout the cytoplasm (Fig. 8 D). Overexpressionof Rab32 may saturate its "receptor protein" on the mitochondrialmembrane, leading to an excess accumulation in the cytoplasm.It is likely that the COOH-terminal hypervariable domain ofRab32 is responsible for such interactions (Chavrier et al., 1991),however the exact mechanism of targeting remains to bedetermined.

Most Rab proteins cycle between an on state, where GTP is bound,and an off state, where GDP is bound. Accordingly, Rabs canelicit GTP-dependent biological responses by activating a downstreameffector. We show that PKA can associate with Rab32 in the presenceof GTP or GDP. This is consistent with the notion that Rab32functions as a conventional AKAP, as there are several examplesof anchoring proteins that bind PKA and contain functionallyindependent domains that possess other biological activities(Westphal et al., 2000; Diviani et al., 2001). Alternatively,there may be multiple pools of Rab32, some of which harbor anchoredPKA. This is supported by our immunolocalization data indicatingthat not all of the mitochondrial-targeted Rab32 is associatedwith PKA. Thus, the Rab32–PKA complex may participatein distinct cellular processes from the free Rab protein. Definingthe molecular interactions regulated by Rab32 should give insightinto the PKA function of this complex. For example, specificRab32 effector proteins, GTPase activating proteins, and GEFsmay serve as PKA substrates.

Rab family members participate in membrane trafficking eventsthat are often associated with organelles such as the endoplasmicreticulum, the Golgi network, endosomes, and membrane vesicles.Functions for some of these proteins have been described bygenetic analyses in yeast, flies, and mice or by the expressionof interfering mutants in mammalian cells. Using the latterapproach, we have established that transient transfection ofa GTP binding–deficient form, Rab32T39N, selectively inducesthe collapse of mitochondria at microtubule organizing centers,yet has no effect on the distribution of other organelles (Fig. 8).We propose that the Rab32T39N mutant acts as a dominantnegative inhibitor of the endogenous Rab32 protein. Consistentwith this notion, endogenous Rab32 is found in Cos7 cells andlocalizes to the mitochondria (Fig. 6 A). Furthermore, expressionof the nonmitochondrial-targeted double mutant Rab32T39N ${Delta}$ CC exhibiteda significant reduction in the incidence of mitochondrial collapse.These data suggest that mitochondrial localization of the Rab32T39Nmutant contributes to the phenotype. It is possible that Rab32T39Ninterferes with an upstream activator, such as a GEF, that islocalized at mitochondria. This proposition is analogous tothe mechanism by which GTP binding–deficient Ras mutantsact as dominant inhibitors of specific Ras-GEF proteins (Farnsworth and Feig, 1991).

Our analysis of the Rab32T39N mutant points toward a role forRab32 in the regulation of mitochondrial fission events, aswe detect perinuclear clusters of mitochondria upon overexpressionof this interfering mutant. Similar effects are observed incells expressing an interfering mutant of the dynamin-relatedGTPase Drp1, which functions to sever the outer mitochondrialmembrane in yeast, C. elegans, and mammalian cells (Labrousse et al., 1999;Sesaki and Jensen, 1999; Smirnova et al., 2001).Expression of Drp-1–interfering mutants results in a frequencyof collapsed mitochondria, and disruption of the microtubulenetwork with nocodazole reveals a fewer number of elongatedorganelles (Smirnova et al., 2001). These observations are remarkablysimilar to the changes in mitochondrial morphology that we recordedupon drug treatment in Rab32T39N-expressing cells. Furthermore,low expression of Rab32T39N reveals an intermediate phenotypein which the mitochondria are partially collapsed. We observeda dense network of seemingly fused mitochondria in these cells.A potential mechanism for the action of the Rab32T39N mutantis to shift the balance of mitochondrial fusion and fissionevents toward increased fusion. Therefore, the cellular processregulated by Rab32 is most likely mitochondrial division. Futurestudies will be aimed at elucidating the complement of effectorproteins involved in the assembly of a Rab32-mediated mitochondrialfission complex, and the role of anchored PKA in the regulationof these events.

Materials and methods

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Results
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Materials and methods
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Yeast two-hybrid
The cDNA from the RII ${alpha}$ dimerization/AKAP-binding domain was PCRamplified and subcloned into the EcoRI-BamHI sites in the pLexAyeast expression vector. This gene encodes an NH₂-terminal LexADNA binding domain fused to the first 45 amino acids of RII ${alpha}$ .500 µg of a human brain MATCHMAKER cDNA library (CLONTECH Laboratories, Inc.)was screened for AKAPs using the yeast two-hybridassay as described by Hollenberg et al. (1995).

Cloning full-length Rab32
An EST clone for Rab32 was obtained from Genome Systems (GenBank/EMBL/DDBJaccession no. AI281920; Image 1882928). This clone containedthe cDNA sequence representing amino acids 19–225 of Rab32including the termination codon. A synthetic oligonucleotidewas designed to contain the 90 base pairs corresponding to the5' region of Rab32 cDNA. The partial Rab32 EST was used as atemplate for PCR amplification with the 90-mer 5' primer anda reverse primer that corresponds to the 3' end of the Rab32coding sequence. The resulting PCR product was subcloned intothe bacterial expression vector pGex4T-1. Full-length Rab32was confirmed by sequencing.

Construction of expression vectors
The full-length Rab32 cDNA was PCR amplified from the pGEX4Ttemplate with synthetic oligonucleotide primers and directlysubcloned into mammalian and yeast expression vectors. For theyeast expression vector (pLexA) and the mammalian expressionvector (Flag-pcDNA3.1), PCR fragments were subcloned into the5' EcoRI sites and 3' BamHI sites. All Rab32 mutants were generatedusing Quick-Change^TM mutagenesis (Stratagene) with specificprimers. All PCR reactions were performed using Pfu Turbo polymerase(Stratagene). Each expression construct was sequenced to determinecorrect reading frame and the existence of appropriate mutations.

Bacterial expression and purification of recombinant Rab32
Recombinant Rab32 and mutants were expressed from the bacterialexpression vector pGex4T in the BL-21/DE3 strain of Escherichiacoli and purified as NH₂-terminal GST fusions using glutathione-Sepharose(Amersham Biosciences).

RII interaction assays
RII overlays were performed using murine [³²P]RII ${alpha}$ as previouslydescribed (Carr and Scott, 1992). For yeast two-hybrid analysis,the cDNA encoding RII ${alpha}$ 1–45 was subcloned into the Gal4activation domain containing yeast expression vector pACT2.This gene encodes an NH₂-terminal Gal4 activation domain fusedto RII ${alpha}$ 1–45. Each pLexA-Rab32, -Rab32L188P, -Rab5, -Rab6,or -Rab7 was cotransformed with the pACT2-RII ${alpha}$ 1–45 intothe yeast strain L40 as described above.

Autospot peptide array
Peptide arrays were synthesized on cellulose paper using anAuto-Spot robot ASP222 (ABiMED) as previously described (Frank and Overwin, 1996).After synthesis, the NH₂ termini were acetylatedwith 2% acetic acid anhydride in DMF. The peptides were thendeprotected by a 1-h treatment with DCM–TFA, 1:1, containing3% triisopropylsilane and 2% water.

Immunoprecipitations and PKA activity assay
Cells 50–80% confluent were transfected using LipofectaminePlus reagents (Invitrogen) according to the manufacturer's instruction.5 µg of plasmid DNA (Flag–Rab32 or Flag–Rab32L188P)was used to transfect HEK-293 cells in 10-cm dishes. Transfectionswere performed for 24 h, followed by lysis in IP buffer (20mM Hepes, pH 7.5, 150 mM NaCl, 1 mM EDTA, 1% Triton X-100).Recombinant proteins were immunoprecipitated using Sepharose-conjugatedantiFlag monoclonal antibody (Sigma-Aldrich). PKA kinase assayswere performed as previously described (Corbin and Reimann, 1974).

Northern blot
A Northern blot containing immobilized samples of mRNA fromseveral human tissues (CLONTECH Laboratories, Inc.) was assayedusing a ³²P-radiolabeled 113-bp probe corresponding to the COOH-terminalhypervariable domain of Rab32. Human RNA dot blot analysis wasperformed according to the manufacturer's instructions (CLONTECH Laboratories, Inc.).

Western blot analysis and subcellular fractionation of WI-38 cells
Antibodies to Rab32 were raised in rabbits (Covance) againstthe unique peptide CEENDVDKIKLDQETLRAEN (Princeton Biomolecules).Anti-Rab32 antibodies were affinity purified against recombinantRab32 coupled to Affigel-10/15 according to the manufacturer'sinstructions (Bio-Rad Laboratories). WI-38 cell extracts wereprepared by lysing confluent cells in buffer (20 mM Hepes, 150mM NaCl, 1 mM EDTA, 1% Triton X-100, and protease inhibitorcocktail [Roche]). Lysates were incubated on ice for 10 minand centrifuged for 20 min at 20,000 g. 20 µg of supernatantwas subjected to Western blot analysis. Subcellular fractionationstudies were performed as previously described (Lutsenko and Cooper, 1998).In brief, a 10-cm dish of confluent WI38 cellswas harvested by trypsin digestion, washed, and resuspendedin 1 ml of HB buffer (10 mM Hepes-NaOH, 250 mM sucrose, andprotease cocktail, pH 7.5). Cells were dounce homogenized (10–15strokes) and subjected to differential centrifugation as previouslydescribed. 20 µg of proteins from whole cell extract andP1 (nuclear pellet) and P2 (mitochondria enriched) fractionswere subjected to Western blot analysis. Control experimentswere performed using anti–COX subunit I antibody (MolecularProbes).

Confocal microscopy
Cells were seeded on glass coverslips and incubated overnightat 37°C under 5% CO₂. To detect mitochondria, coverslipswere incubated with MitoTracker Red^TM (Molecular Probes) for30 min at 37°C under 5% CO_2. In recombinant Rab32 localizationstudies, mitochondria were detected by coexpression of the plasmidpEYFP-Mito (CLONTECH Laboratories, Inc.). RII monoclonal antibodies(Transduction Labs) were used in colocalization studies. Coverslipswere washed twice with PBS and fixed for 10 min in PBS–3.7%formaldehyde. Immunocytochemistry was performed as describedby Westphal et al. (2000). FITC-, Texas red–, or Cy5-conjugatedsecondary antibodies were used for detection of the primaryantibody (Jackson ImmunoResearch Laboratories). Cells were washedand mounted using the Prolong system (Molecular Probes). Immunofluorescentstaining, MitoTracker Red^TM, or intrinsic YFP fluorescence wasvisualized on a Bio-Rad Laboratories MRC1024 UV laser-scanningconfocal microscope.

GDP and GTP binding assays
GDP off and GTP on rates were measured as previously described(Self and Hall, 1995). In brief, purified recombinant GST–Rab32was resuspended in assay buffer (50 mM Tris-HCl, 50 mM NaCl,5 mM MgCl₂, 5 mM DTT, pH 7.5) supplemented with 10 mM EDTA.GDP off rate was determined in high magnesium conditions. GTPon rates were determined in low magnesium conditions. Sampleswere dissolved in scintillation fluid, followed by countingthe radioactive emissions. Data are expressed as the percentnucleotide bound, normalized to time 0 (100%). The nucleotide-dependentRII binding studies were conducted as follows: 1 mg of GST–Rab32bound to glutathione-Sepharose was nucleotide depleted in 50mM Tris-HCl, 50 mM NaCl, 10 mM EDTA, 5 mM MgCl₂, 5 mM DTT, pH7.5, followed by loading with 1 mM GDP or 1 mM GTP ${gamma}$ S for 30 minat room temperature. The nucleotides were stabilized on Rab32by extensive washing in high magnesium buffer (50 mM Tris-HCl,50 mM NaCl, 5 mM MgCl₂, 5 mM DTT, pH 7.5, plus either 1 mM GDPor 1 mM GTP ${gamma}$ S). 1 µg of recombinant RII ${alpha}$ was incubated with1 µg nucleotide-loaded Rab32 for 1 h at room temperature,followed by extensive washing in high magnesium buffer. Theextent of RII binding was determined by Western blot analysisusing a monoclonal anti-RII ${alpha}$ antibody (Transduction Labs).

Rab32 functional experiments
Cos7 cells at 50–80% confluence were transfected with1 µg of the mammalian expression vectors Flag–Rab32,–Rab32T39N, –Rab32 ${Delta}$ CC, –Rab32T39N ${Delta}$ CC, or –Rab32L188Pusing Lipofectamine Plus (Invitrogen). Transfected cells wereincubated at 37°C, 5% CO₂ for 8 h. Cells were labeled withMitoTracker Red^TM (Molecular Probes) for 30 min, and processedfor immunocytochemistry. Recombinant Rab32 and mutants weredetected using a FITC-conjugated antiFlag antibody. 50 Rab32-and mutant-expressing cells were scored for a mitochondrialcollapse phenotype, in which the mitochondrial stain was predominantlyfound at the microtubule organizing center or around the nucleus.Three independent experiments were performed and the resultsare shown as the percentage of transfected cells with the observedphenotype for each Rab32 construct. To detect cellular markers,primary antibodies against EEA-1 (Transduction Labs), LAMP-1(Transduction Labs), Calnexin (StressGen Biotechnologies), andGM130 (Transduction Labs) were used in immunocytochemistry assays,and detected by Cy5-conjugated secondary antibodies. Immunofluorescentstaining and MitoTracker Red^TM was visualized on a Bio-Rad LaboratoriesMRC1024 UV laser-scanning confocal microscope. For microtubuledepolymerization studies, transfected Cos7 cells were treatedwith 5 µM nocodazole (Sigma-Aldrich) for 1 h before fixation.

Footnotes

^* Abbreviations used in this paper: AKAP, A-kinase anchoring protein;GEF, guanine nucleotide exchange factor; PKA, cAMP-dependentprotein kinase; RIIa, type II regulatory subunit.

Acknowledgments

We thank Dr. Bruno Goud (Institut Curie, Paris, France) forproviding the Rab yeast expression vectors and Dr. Philip Stork(Vollum Institute) for providing the Flag-pcDNA3.1 mammalianexpression vector. Special thanks go to Lorene Langeberg forconfocal microscopy assistance and preparation of the manuscript,Robert Mouton for tissue culture support, and all members ofthe Scott Lab for insightful discussion and critical reviewof the manuscript.

This research was supported by DK54441 to J.D. Scott.

Submitted: 17 April 2002

Revised: 11 July 2002

Accepted: 11 July 2002

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Discussion
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