Arl2 and Arl3 Regulate Different Microtubule-dependent Processes

Chengjing Zhou^*, Leslie Cunningham^*, Adam I. Marcus, Yawei Li^*, and Richard A. Kahn^*

^* Department of Biochemistry, Emory University School of Medicine, Atlanta, GA 30322-3050; Department of Winship Cancer Institute, Emory University School of Medicine, Atlanta, GA 30322-3050

Submitted October 14, 2005; Revised February 21, 2006; Accepted February 27, 2006
Monitoring Editor: Sean Munro

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

Arl2 and Arl3 are closely related members of the Arf familyof regulatory GTPases that arose from a common ancestor earlyin eukaryotic evolution yet retain extensive structural, biochemical,and functional features. The presence of Arl3 in centrosomes,mitotic spindles, midzones, midbodies, and cilia are all supportiveof roles in microtubule-dependent processes. Knockdown of Arl3by siRNA resulted in changes in cell morphology, increased acetylationof ${alpha}$ -tubulin, failure of cytokinesis, and increased number ofbinucleated cells. We conclude that Arl3 binds microtubulesin a regulated manner to alter specific aspects of cytokinesis.In contrast, an excess of Arl2 activity, achieved by expressionof the [Q70L]Arl2 mutant, caused the loss of microtubules andcell cycle arrest in M phase. Initial characterization of theunderlying defects suggests a defect in the ability to polymerizetubulin in the presence of excess Arl2 activity. We also showthat Arl2 is present in centrosomes and propose that its actionin regulating tubulin polymerization is mediated at centrosomes.Somewhat paradoxically, no phenotypes were observed Arl2 expressionwas knocked down or Arl3 activity was increased in HeLa cells.We conclude that Arl2 and Arl3 have related but distinct rolesat centrosomes and in regulating microtubule-dependent processes.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

The ADP-ribosylation factor (Arf) family of $~$ 20-kDa GTPases iscomprised of the Arf, Arf-like (Arl), and Sar proteins (Li etal., 2004b; Logsdon and Kahn, 2004; Kahn et al., 2006). Althoughbest known for their actions as regulators of membrane trafficand lipid metabolism, these are primarily functions of the sixArfs, though Arl1 and Sar proteins also share related rolesin membrane traffic. Much less is known about the functionsof the Arl proteins, though they are more numerous (>15).Within the Arf family are groups of proteins that share higherpercent identities with each other than to the rest of the family.This is true of the six Arfs and also of Arl2 and Arl3. Thiscloser relationship could result either from a more recent geneduplication or from constraints on primary sequence imposedby a common set of functional criteria. The latter appears tobe the case for the Arl2/Arl3 group as Arl2 and Arl3 genes arepresent in the protist Giardia lamblia and orthologues of eachare found in most eukaryotes (Li et al., 2004b; Logsdon andKahn, 2004; Kahn et al., 2006), revealing a very early emergencein eukaryotes. Arl2 has been implicated as a regulator of microtubulesin a number of model genetic organisms (Hoyt et al., 1990; McElveret al., 2000; Radcliffe et al., 2000; Antoshechkin and Han,2002) and in the regulation of tubulin folding and destructionfrom in vitro and cell-based assays (Bhamidipati et al., 2000),whereas much less is known about Arl3.

Human Arl2 and Arl3 retain 53% identity in primary sequenceand a high degree of structural conservation that includes residuesinvolved in nucleotide and magnesium binding (Hillig et al.,2000; Hanzal-Bayer et al., 2002). This high degree of structuralconservation extends to some functions and interactions, butnot all. With only one exception (cofactor D; Bhamidipati etal., 2000; Shern et al., 2003) binding partners identified forArl2 or Arl3 also bind the other GTPase; including Binder ofArl2 (Bart), a subunit of a phosphodiesterase (PDE ${delta}$ 6; Linariet al., 1999; Renault et al., 2001), and HRG4/UNC-119 (Kobayashiet al., 2003). In addition, a partially purified Arl2 GTPase-activatingprotein (Arl2 GAP) was found to stimulate the GTPase activityof either Arl2 or Arl3 (J. B. Bowzard, J. Shern, and R. A. Kahn;unpublished observation). Thus, at the biochemical level Arl2and Arl3 appear remarkably closely related.

Arl2 has been repeatedly implicated as a regulator of microtubulefolding or dynamics in a number of different assays and geneticscreens. Orthologues of Arl2 have emerged from four differentgenetic screens, most designed to identify regulators of microtubulesor mitotic segregation. Mutations in the Saccharomyces cerevisiaeCIN4 gene are supersensitive to benomyl, the microtubule poison,and are defective in chromosome segregation (Hoyt et al., 1990).Alp41 is the Arl2 ortholog in Schizosaccharomyces pombe andmutations in it result in short microtubules and defects incell division and cytokinesis (Radcliffe et al., 2000). Similarly,mutations in the Arabidopsis thaliana ortholog, TITAN5, resultin greatly enlarged embryos and nuclei and defects in cellularizationthat may be traced to cytoskeletal problems (McElver et al.,2000). Evl-20 is the Caenorhabditis elegans ortholog of Arl2and loss of function mutants or knockdown in expression viaRNAi yield an elapsed vulva phenotype and show defects in theorganization of embryonic microtubules and spindles (Antoshechkinand Han, 2002; Li et al., 2004b). Arl2 is an essential genein each of these organisms, except for S. cerevisiae. In contrast,Arl3 has not emerged from any of these, or any other, geneticscreens. No phenotypes have been reported for mutants or deletionsof orthologues of Arl3 and no defects were observed after RNAiof arl-3 in C. elegans (Li et al., 2004b).

One potential functional link between the two GTPases may relateto protein folding, specifically the biosynthesis of tubulinheterodimers. Arl2 has been shown to bind the tubulin-specificcochaperone, cofactor D (Bhamidipati et al., 2000). Arl3 wasshown to bind RP2 in a GTP-dependent manner (Bartolini et al.,2002) and RP2 shares homology with cofactor C and can partiallycomplement cofactor C null mutants (cin2^-) in S. cerevisiaeand shares with cofactor C its tubulin GAP activity but nottubulin cochaperone activities (Bartolini et al., 2002). However,Arl3 does not bind cofactor C and there is no evidence thatit can alter the folding or polymerization of tubulin. RP2 islimited to the plasma membrane (Grayson et al., 2002) so isunlikely to be involved in the results described below. A furtherlink between Arl3 and microtubules may be seen from the resultsof Cuvillier et al. (2000), in which they showed that cellsexpressing a predicted dominant activated mutant of Arl3 inLeishmania ([Q70L]Arl3) were immobile and had shortened flagella.Recent comparative genomics searches identified Arl3 as a candidategene/protein linked to ciliary and basal body biogenesis andfunction, in part because it is specifically lost in a numberof species lacking cilia (Avidor-Reiss et al., 2004; Li et al.,2004a) and Arl3 was found in the flagellar proteome of the greenalga, Chlamydomonas (Pazour et al., 2005). Thus, both Arl2 andArl3 have been very highly conserved throughout eukaryotic evolutionand each is implicated in aspects of microtubule function.

A systematic analysis of the locations of these GTPases andtheir effector(s) has not been undertaken previously. Usinga single method of cell fixation and permeabilization, Arl2and Bart have been previously localized to mitochondria, wherethey bind the adenine nucleotide translocase 1 (ANT1; Shareret al., 2002). Later, we found that after fractionation of tissuelysates the majority of Arl2 was cytosolic and bound tightlyin a complex containing cofactor D and the heterotrimeric proteinphosphatase PP2A (Shern et al., 2003).

In studying members of the Arf family it has become clear thatit is important to determine the extent of functional overlapbetween closely related family members as well as to determinethe functions and mechanisms of each GTPases (e.g., see Volpicelli-Daleyet al., 2005). We provide evidence for distinct roles for Arl2and Arl3 in microtubule-dependent processes.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

Antibodies
Affinity-purified rabbit, polyclonal Arl2 (R-86336) and Bart(R-46712) antibodies were prepared as described in Sharer etal. (2002). Antibodies directed toward the "EAGE" epitope of $beta$ -COP were generated as described previously (Pepperkok et al.,1993). Monoclonal ${alpha}$ -tubulin (clone DM1A), ${gamma}$ -tubulin (clone GTU-88),and polyclonal ${gamma}$ -tubulin (T5192) antibodies were purchased fromSigma Chemical Co. (St. Louis, MO). The mouse monoclonals anti-centrin(clone 20H5) and that to GM130 were a gift from Dr. Jeff Salisbury(Rochester, MN) or were purchased from BD Transduction Laboratories(Lexington, KY), respectively.

Polyclonal antisera to Arl3 (R-75448) were raised in rabbitsagainst purified recombinant human Arl3. Characterization ofthis antibody by immunoblotting revealed that <1 ng of purifiedArl3 was detectable by the serum (diluted 1/2000) and that Arl3antibodies did not cross-react with up to 100 ng human Arl2or Arf proteins. The immunoreactivity could be effectively competedby preincubation of 1 µg of purified, recombinant humanArl3 with 3 µl of the serum.

Cell Culture
Chinese hamster ovary (CHO), human cervical carcinoma (HeLa),African Green Monkey kidney (COS-7), rat adrenal pheochromocytoma(PC-12), human neuroglioblastoma (Sf295), mouse embryo fibroblast(NIH3T3), and human embryonic kidney (HEK) cells were grownin Ham's F-12, DMEM, or RPMI 160 media. All media were supplementedwith 10% fetal bovine serum (FBS, Invitrogen, Carlsbad, CA)and 2 mM glutamine and cells were grown at 37°C in the presenceof 5% CO₂.

Transient Transfections and Plasmid Construction
Cells were grown in six-well culture dishes to 50-60% confluence.Plasmids (0.8 µg of pcDNA3 or pcDNA3 carrying indicatedinserts and pEGFP-N1; 4:1 ratio) were cotransfected into thecells using LipofectAMINE and Plus reagents (Invitrogen) accordingto the manufacturer's instructions.

Arl2, Arl3, Bart, and the indicated point mutations were eachcloned into the pcDNA3.1 vector for expression of the nativeprotein in cultured mammalian cells, under control of the CMVpromoter.

Short Interference RNA
Knockdowns of the expression of endogenous Bart, Arl2, or Arl3were carried out as described previously (Hill et al., 2003),using pSUPER-based vectors (Brummelkamp et al., 2002). At leastthree different, sequence-independent constructs were generatedtoward each target RNA and the two constructs that demonstratedthe greatest effectiveness in decreasing cellular levels ofthe target protein were used. Every phenotype described wasfound for each of the sequence-independent constructs for anyone target, as a guard against off-target effects. Target sequenceswere determined with the help of on-line search algorithms atthe Dharmacon (Boulder, CO) and BD Bioscience (San Diego, CA)websites and BLAST searches of the NCBI databases found no otherhuman cDNAs identical to the target sequences.

HeLa cells were plated in six-well dishes to 80-90% confluencethe day before transfection. Cells were cotransfected with 2µg of pSUPER plasmid and 0.2 µg of pEGFP-N1 usingLipofectAMINE and Plus reagents (Invitrogen). The next day,cells were replated at lower cell density. Cells were fixedand prepared for immunofluorescence experiments 2-4 d aftertransfection. Effectiveness and specificity of knockdown ofArl2, Arl3, or Bart was determined by immunoblotting, as previouslydescribed (Sharer et al., 2002).

Immunocytochemistry
Arl2 and Bart have been localized previously to mitochondriaof cells fixed in p-formaldehyde (PFA) and permeabilized withTriton X-100 (Sharer et al., 2002). In this study, three differentmethods of fixation were compared extensively: 1) PHEMO fixationhas been developed to optimally retain and support stainingof microtubules (Mabjeesh et al., 2003), 2) methanol fixationis required for exposure of some epitopes or using some antibodiesand is often required to see proteins at the centrosome, and3) PFA fixation is probably the most common method used forvisualizing cultured cells as the integrity of most cell membranesand organelle morphologies are retained. We used specific antiseradeveloped in our laboratory and directed toward Arl2, Arl3,or Bart to define the cellular location(s) of each protein andthe extent to which they overlap. In every case reported herewe describe specific staining only, which is defined as stainingthat is dependent on the primary antibody, blocked by preincubationof the primary antibody with antigen, and absent in preimmunesera. We also looked at a variety of different cultured celllines from different species as different organelles are bettervisualized in the different lines and to address the generalityof our observations.

Cells were grown on cover slips coated with poly-L-lysine. Differentfixation and permeabilization conditions evaluated in this studyincluded: cold methanol (-20°C) for 10 min, 2 or 4% (onlywhen staining cilia) PFA in phosphate-buffered saline (PBS)for 15 min at room temperature, followed by 0.05% saponin or0.2% Triton X-100 (only when staining cilia) in PBS. For optimalretention of microtubules we also used PHEMO fixation (3.7%PFA, 0.05% glutaraldehyde, 0.5% Triton X-100 in 68 mM PIPES,25 mM HEPES, 15 mM EGTA, 3 mM MgCl₂, 10% dimethylsulfoxide,pH 6.8) for 10 min at room temperature, as described in Mabjeeshet al. (2003). Incubation with primary antibodies was carriedout in PBS containing 5% goat sera and 1% BSA, at 4°C overnight.Secondary antibodies were incubated in the same buffer for 1h at room temperature. Cells were examined using an OlympusBX60 microscope (Melville, NY) and images were taken (100x objective)using a Qimaging RETIGA 1300R camera. Alternatively, confocalimages were taken (63x objective) using a Zeiss LSM 510 confocalmicroscope (Thornwood, NY) with 488- and 543-nm laser excitation.Images were processed with Photoshop 6.0 (Adobe, San Jose, CA).

Only staining that was competed by preincubation of the antibodywith purified recombinant antigen was considered specific andonly specific staining is reported here. Centrosomal stainingwas found to be typically very strong and localized such thatcompetition did not always completely block centrosomal stainingbut in each case was clearly and strongly diminished by preincubationof the antibody with purified recombinant Arl2 (3 µg/ml)or Bart (1 µg/ml). Specificity of the antisera and stainingpatterns were further confirmed by testing of preimmune sera,which failed to detect the signals reported herein.

Effects of taxol were assessed at concentrations ranging between0.003 and 1 µM, added 5 h after transfections with plasmids.Cells were fixed with PHEMO and processed for ${alpha}$ -tubulin staining24 h after transfection, as described above.

For microtubule regrowth experiments, cells were treated withnocodazole (15 µg/ml) for 2 h, and then fresh drug-freemedium was added and recovery was allowed to proceed for 2-15min (CHO cells) or 5-30 min (HeLa cells), before processingas indicated.

Brefeldin A (5 µg/ml) treatments were for 0, 2, 5, 10,15, and 30 min before fixing with PFA and processing for immunofluorescenceanalysis.

Centrosome Purification
Centrosomes were isolated using a modification of the methodof Hsu and White (1998). Exponentially growing HeLa cells wereincubated with cytochalasin D (1 µg/ml) and nocodazole(0.2 µM) at 37°C for 1 h. Cells were successivelywashed with ice-cold 1x PBS, 8% sucrose in 0.1x PBS, and 8%sucrose in water. Cells were then incubated with shaking at4°C for 10 min in lysis buffer (1 mM HEPES, pH 7.2, 0.5%Nonidet P-40, 0.5 mM MgCl₂, 0.1% 2-mercaptoethanol, 50 mM sodiumfluoride and proteinase inhibitors). The insolubles were removedby centrifugation at 2500 x g for 8 min and the supernatantwas filtered through 40-µm nylon mesh. HEPES was adjustedto 10 mM and DNase I was added to 2 U/ml. After 30 min, lysateswere underlain with 60% sucrose solution (60% wt/wt sucrosein 10 mM PIPES, pH 7.2, 0.1% Triton X-100, and 0.1% 2-mercaptoethanol).Tubes were spun at 25,000 x g for 30 min to sediment centrosomesinto the sucrose cushion. The bottom layer was collected, loadedonto a discontinuous sucrose gradient (0.5 ml of 70%, 0.3 ml50%, and 0.3 ml 40% sucrose solution) and spun at 120,000 xg for 1 h. Fractions (0.2 ml each) were collected from the top,diluted in 2 ml of 10 mM PIPES, pH 7.2, and sedimented by centrifugationat 25,000 x g for 30 min. Supernatant was removed and pelletprotein was resuspended and denatured in SDS sample buffer.

Flow Cytometric Analysis
Twenty-four hours after transfection with empty vector or thosedirecting expression of Arl2 or [Q70L]Arl2, cells were trypsinized,washed in PBS, and resuspended in PBS containing saponin (0.3%),propidium iodide (10 µg/ml), and RNase (200 µg/ml)for 20 min at room temperature. Analyses were carried out ona Becton Dickinson FACScan (Mountain View, CA) and the datawere processed with FlowJo software (Tree Star, San Carlos,CA).

Live-Cell Image Acquisition
Cells were imaged using a Perkin Elmer-Cetus Ultraview ERS (Norwalk,CT) confocal mounted on a Zeiss Axiovert 200M microscope. Themicroscope was enclosed in a heating chamber (at 37°C) with5% CO₂ perfused over the plate holder. Cells were plated on35-mm live-cell imaging plates (World Precision Instruments,Sarasota, FL; 500852) and imaged using either a 40x (NA 1.3),63x (NA 1.4) or 100x Plan-Apochromat (NA 1.4). Multiple z-planeswere acquired using a piezo-controlled z-stepper with a z-intervalof $~$ 0.5-1.0 µm. Time-lapse images were taken every 5 minwith 2 x 2 binning and exposure times ranging from 200 to 400ms. For experiments using only GFP-labeled proteins, the fluorophorewas excited using the 488-nm line of an Ar ion laser. For time-lapsesequence where dual labels were used (histone H2B-GFP; BD PharMingen,San Diego, CA; and mCherry-tubulin; the gift of Roger Tsien,UCSD; Shaner et al., 2004), the fluorophores were sequentiallyexcited with the 488 and 568 laser lines and emission signalswere separated using an electronically controlled emission discriminationfilter with the appropriate filter sets.

Image Analysis
To analyze cell cycle timing, time-lapse images were reviewedusing the Perkin Elmer-Cetus Ultraview software. The lengthof prometaphase/metaphase was determined as the time from chromosomecondensation until the onset of anaphase (i.e., chromosome segregation).

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

Arl2, Arl3, and Bart Are Centrosomal Proteins
We observed staining of centrosomes with antisera specific forArl2, Arl3, or Bart, after methanol fixation of cultured mammaliancells. Each of these antisera yielded strong staining of theone or two puncta that colocalized with markers of centrosomes,including ${gamma}$ -tubulin, centrin, or ninein. The staining of Arl2(Figure 1A) and Bart (Figure 1C) appeared slightly larger inarea than that of ${gamma}$ -tubulin so is thought to represent stainingof the pericentriolar matrix (PCM). In contrast, Arl3 stainingwas limited to a smaller area that overlapped better with thatof ${gamma}$ -tubulin (Figure 1B and inset).

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Figure 1. Arl2, Arl3, and Bart are centrosomal proteins. (A) CHO cells were labeled with antibodies specific to Arl2 or ${gamma}$ -tubulin after methanol fixation, as described in Material and Methods. Cells in different phases of the cell cycle are shown. Centrosomal staining of Arl3 is visualized in the merged images. Noncentrosomal Arl3 staining is also evident, in the form of puncta that can be as large as the centrosome (visualized by ${gamma}$ -tubulin staining). Insets are magnified views of the centrosomal staining. (B) The presence of Arl2 at centrosomes, visualized by costaining with antibodies to centrin, does not depend on microtubules as staining is unchanged after treatment of cells with nocodazole (15 µg/ml for 2 h). (C) Arl3 staining at centrosomes is shown, after staining methanol fixed NIH3T3 cells, as described in Material and Methods. Staining of Arl3 at centrosomes is shown in the absence (top panels) and presence (bottom panels) of nocodazole treatment, as described in B. (D) CHO cells were prepared as described in A and labeled with Bart and ${gamma}$ -tubulin antibodies.Bar under each panel, 10 µm.

Arl2 staining at centrosomes was most obvious in CHO cells (Figure 1A),likely due to the larger size of their centrosomes. Centrosomesvary in size between cell lines and the amount of noncentrosomalstaining, seen as punctate staining that did not colocalizewith centrosomal markers, also varied with the cell type andantibody. The highest noncentrosomal punctate staining was typicallyseen with Arl2 staining (see Figure 1A). Arl2 or Bart stainingat centrosomes was evident in a wide range of cell lines (includingCHO, NIH3T3, HEK, Sf295, and HeLa cells), whereas centrosomalArl3 staining was very often difficult to resolve from thatat Golgi membranes (see below) after methanol fixation. Centrosomalstaining of Arl3 was clearest in NIH3T3 cells (Figure 1B). Ineach case the specific staining at centrosomes was absent inpreimmune sera and secondary antibodies, competible with antigen,and optimal after methanol fixation.

Because some proteins dissociate from the centrosome at specificpoints in the cell cycle, we asked if there was any cell cycledependence to the centrosomal staining of Arl2, Arl3, or Bart.Cells at different points in the cycle were identified by thelocation and number of centrosomes and the morphology and locationof DNA (Hoechst staining). Arl2 (Figure 1A), Arl3, and Bart(unpublished data) were found at centrosomes at all parts ofthe cell cycle. Each of these three proteins localizes to centrosomesin a microtubule-dependent manner as staining was unalteredby treatment of cells with nocodazole (Figure 1B). Thus, eachof the three proteins under investigation was found to be acentrosome-associated protein throughout the cell cycle.

Highly enriched preparations of centrosomes were generated bythe method of Hsu and White (1998) and analyzed for the presenceof Arl2, Arl3, and Bart. Purification of centrosomes from HeLacells was monitored by immunoblotting for the enrichment in ${gamma}$ -tubulin and we found that Arl2, Arl3, and Bart each copurifiedin sucrose gradients with centrosomes (Figure 2). In contrast,soluble proteins (Arf3 was examined as a control) were completelyabsent from these fractions (unpublished data). We concludethat Arl2, Arl3, and Bart are present in centrosomes of a widevariety of cultured mammalian cells and at all times of thecell cycle.

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Figure 2. Arl2, Arl3, and Bart copurify with ${gamma}$ -tubulin in centrosomes from HeLa cells. Centrosomes were enriched from HeLa cells ( $~$ 3 x 10⁷ cells) using a modification of the method of Hsu and White (1998

), as described in Material and Methods. Equal volumes of fractions from the sucrose velocity sedimentation gradient were immunoblotted with antisera to ${gamma}$ -tubulin, to locate centrosomes, and Arl2, Arl3, or Bart. Leftmost lane shows the whole cell lysate (WCL; 5 µg protein).

Arl3 Is Also Present on the Mitotic Spindle
Arl3 was also found on two other microtubule-rich structures:the mitotic spindle and midbodies. Arl3 staining was similarto that of acetylated ${alpha}$ -tubulin in mitotic HeLa cells and wasobserved throughout the spindle, particularly in metaphase andanaphase (Figure 3A). Staining appeared on the spindle itselfduring metaphase and could be seen to concentrate at the midzoneduring anaphase. This staining is reminiscent of staining reportedpreviously for some other spindle proteins, e.g., CHO1/MKLP1(Matuliene and Kuriyama, 2002

) that move to the midzone laterin mitosis. In contrast, neither the Arl2 nor the Bart antiserastained the spindle under these conditions.

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Figure 3. Arl3 is found on microtubule-dense structures and Golgi membranes. (A) HeLa cells at different points of the cell cycle were fixed using PHEMO conditions and stained with Arl3 and ${alpha}$ -tubulin antibodies. The presence of Arl3 on the mitotic spindle (top panels), the midzone (second panels), and in midbodies (two bottom panels) is clear from the extensive overlap with ${alpha}$ -tubulin staining. Nuclear staining of Arl3 is also evident in the bottom panels. (B) Staining of Bart at midbodies is shown in methanol-fixed HeLa cells (top panels) and COS-7 cells (bottom panels), and compared with that of ${alpha}$ -tubulin (middle panels). Note that Bart is in the midbody matrix in HeLa cells but radiating down the midbody in COS-7 cells. (C) The colocalization of Arl3 and GM130 at Golgi membranes is shown in Sf295 cells after double labeling of PFA-fixed cells. (D) The binding of Arl3 to Golgi membranes is insensitive to the addition of brefeldin A. Cells were treated with (+) or without (-) brefeldin A (BFA; 5 µg/ml) for 5 min before fixation with PFA and stained for Arl3 or $beta$ -COP, a subunit of the brefeldin A-sensitive COPI coatomer complex. $beta$ -COP has dissociated from the cis-Golgi under these conditions but Arl3 remains at the Golgi. (E) Arl3 is present in the primary cilium of NIH3T3 cells, after fixing with 4% PFA. Primary antibodies were the Arl3 polyclonal and acetylated ${alpha}$ -tubulin mouse monoclonal (6-11 B-1). Bars, 10 µm.

During interphase the density of microtubules is such that itis difficult to determine if the puncta visualized with Arl2,Arl3, or Bart antisera are associated with microtubules butthere was no evidence that such puncta followed a linear track,consistent with decoration of microtubules, as seen in the spindlestaining with Arl3 antibodies. Thus, we tentatively concludethat none of the three proteins studied are bound to interphasemicrotubules.

Midbodies are formed after collapse of the mitotic spindle andcan be visualized in cultured cells by staining with ${alpha}$ - or $beta$ -tubulinantibodies and were optimally visualized in our studies withPHEMO fixation conditions, as seen in Figure 3, A and B. Arl3antisera stained the length of the midbody but staining wasexcluded from the midbody matrix (also referred to as the Flemingbody; Figure 3A, bottom panels). Thus, Arl3 staining of thespindle and the midbody was very similar to that of ${alpha}$ - or $beta$ -tubulinand despite the lack of staining at the midbody matrix we cannotconclude that the protein is absent from this region of themidbody.

Bart staining was absent from the spindle but was found in themidbody (Figure 3B). The presence of Bart in the midbody matrixsuggests either that it becomes recruited to that site duringcytokinesis or that it could be present in the midzone, butour antibodies failed to detect it there. Staining of Bart waslimited to the midbody matrix in HeLa (Figure 3B, top panels).In contrast, Bart staining of COS-7 cells showed staining ofmidbodies that appeared strongest at the contact point of midbodywith matrix and extended partially down the length of the midbodymicrotubule bundles (Figure 3B, bottom panels). We saw no evidencethat Arl2 was present on spindles or any part of midbodies inany of the cell lines examined.

Arl3 Is Also Present on Golgi Membranes and in the Nucleus
Using conditions that better retain intracellular membranes(2% PFA fixation and permeabilization with 0.05% saponin), weobserved specific staining with Arl3 antibodies of cytoplasmic,perinuclear material. This was identified as Golgi by its extensivecolocalization with the marker of Golgi, GM130 (Figure 3C).In contrast, Arl3 staining showed no such overlap with markersof other compartments (unpublished data), including those forthe ER (protein disulfide isomerase), recycling endosomes (transferrinreceptors), or the trans-Golgi network (TGN38 or syntaxin 6).Neither Arl2 nor Bart was seen on any of these organelles ofthe secretory or endocytic pathways.

Reversible association at the Golgi and TGN is a feature ofArf proteins (Arf1-5 but not Arf6) and Arl1 (Cavenagh et al.,1996; Lu et al., 2001; Van Valkenburgh et al., 2001). The fungalmetabolite brefeldin A is a specific and reversible inhibitorof many Arf guanine nucleotide exchange factors (GEFs) and causesthe rapid dissociation of Arfs, Arl1, and associated proteinsfrom Golgi (Donaldson et al., 1992; Boman and Nilsson, 2003;Styers and Faundez, 2003). To test if the binding of Arl3 toGolgi membranes is brefeldin A-sensitive we treated cells withthe drug under conditions that lead to the rapid release ofArfs and associated proteins at 37°C (5 µg/ml). Asseen in Figure 3D, even 10 min after addition of brefeldin Athe Arl3 remained bound at the Golgi, whereas the Arf-dependentcoat protein COP-I (visualized with antibodies to the $beta$ -COP subunit)was released in this experiment within 2 min. Thus, Arl3 bindingto Golgi membranes is insensitive to brefeldin A. The hypothesisthat Arl3 plays a functional role at the Golgi was also supportedby the observation that this organelle became fragmented ina high percentage of cells depleted of Arl3 (see below and Figure 4, B and C).Roles for Arl3 at Golgi were not pursued further in this study.

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Figure 4. Phenotypes associated with the depletion of cellular Arl3. Two sequence-independent siRNA constructs were found to effectively deplete HeLa cells of Arl3 or Arl2 and resulting phenotypes are shown in cells 3 d after transfection. In all bar graphs control (empty vector) cells are shown with filled bars and Arl3 siRNA transfected cells are shown with the open bars. (A) Knockdowns in the levels of total cell Arl3 (left) or Arl2 (right) after transfection of HeLa cells with two sequence-independent siRNA constructs in the pSUPER vector, as described under Material and Methods. Immunoblots are shown of total cell lysates (15 µg/lane) in control (lane 1), and each of the two siRNA-transfected cells (siRNA 1 and 2) for each target. $beta$ -tubulin was included as a loading control. Under these conditions, we routinely obtain 50-70% transfection efficiencies. (B) HeLa cells were transfected with empty vector (top panels) or Arl3 siRNA 1 (bottom panels) and were fixed with PHEMO and stained with ${alpha}$ -tubulin, GM130, or acetylated ${alpha}$ -tubulin (6-11 B-1) antibodies. Representative cells displaying increases in cell length, binucleated cells, vesiculated Golgi, and increased acetylated tubulin staining are shown. Bar, 30 µm. (C) Golgi fragmentation was monitored by staining PHEMO-fixed cells with GM130, as a marker of the Golgi. Results shown are the average of four independent experiments with a total of >175 cells counted in each case. Error bars, 1 SD between experiments. (D) The average length of cells was determined by measuring the long axis of random cells in the population, 3 d after transfections. Controls were transfected with pSUPER carrying no insert. The results from two different experiments are shown, with 93 and 61 cells counted in total from control and Arl3 siRNA cells, respectively. (E) The apparent increase in acetylated tubulin staining in cells depleted for Arl3 was confirmed by immunoblotting with acetylated tubulin (6-11 B-1, top lanes) and ${alpha}$ -tubulin (bottom lanes) antibodies of 20 µg total cell protein in control (left) versus Arl3 siRNA cells (right). (F) The percentage of cells that were binucleated was determined by counting bisbenzamide stained cells. Results shown are averages from three independent experiments with a total of 210 and 240 cells counted for control and Arl3 siRNA, respectively. (G) The percentages of cells with a midbody, visualized by staining PHEMO-fixed cells with ${alpha}$ -tubulin antibody, were determined. The percentages of cells with midbodies are shown from three independent experiments, with a total n > 200 cells for each condition. Error bars, 1 SD between experiments. (H) The length of time of prometaphase/metaphase was determined in control (n = 13) or Arl3 siRNA (n = 10) cells as the time between chromosome condensation and chromosome segregation by counting frames in time-lapse movies of HeLa cells that coexpressed cherry- ${alpha}$ -tubulin and histone-GFP, as described in Material and Methods and shown in Figure 5. Each of these phenotypes described for Arl3 siRNA was observed with each siRNA constructs but quantitation was only performed with one.

In interphase cells Arl3 staining was also observed in the nucleusof each of the cell lines examined (e.g., see Figure 3E), afterPHEMO fixation. Staining was excluded from circular regionsin the nucleus that are presumably nucleoli. Nuclear stainingwas also evident with Arl2 antibodies (unpublished data), particularlyin CHO and HeLa cells, using 2% PFA and saponin and was weakerand more variable after PHEMO fixation. Nuclear staining withBart antisera was also observed after methanol fixation thoughthis was often quite weak in intensity. This nuclear stainingis likely to be specific as it was competed by preincubationof the primary antibody with purified Bart and was also observedin CHO cells expressing Bart tagged at the C-terminus with thehis6 tag, followed by PHEMO fixation and visualization withantibodies to the his6 tag. Nuclear staining was not observedwith secondary antibody alone or with any of our preimmune sera.Thus, we conclude that all three of the proteins under studycan access the nucleoplasm.

Each of the cellular locations described above for Arl2, Arl3,or Bart were defined by staining of fixed cells with specificantisera. Controls in every case included the lack of such stainingwith preimmune sera, competition of the specific staining byantigen, and lack of specific staining by secondary antibody,and in the case of Arl2 we have prepared affinity-purified antibodiesthat gave the same profiles as serum. We believe these dataare sufficient to conclude that the locations described arespecific to the endogenous proteins under study. Initial characterizationssuggest that the expression of GFP- or epitope-tagged Arl2 orArl3 results in localizations that differ from endogenous proteins.It is not clear if this is the result of overexpression or theepitope tag (or both) but changes at termini of members of theArf family of GTPases are known to alter protein-protein interactionsand functions.

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Figure 5. Depletion of Arl3 results in early or late failure in cytokinesis. HeLa cells were triply cotransfected with empty vector (control; top panels) or plasmids directing knockdown of Arl3 (middle and bottom panels) and expression of cherry- ${alpha}$ -tubulin and GFP-histone and time-lapse images were collected as described in Material and Methods. Frames were captured at the indicated time after metaphase began (hours:minutes). The middle panels show a cell with a late failure in cytokinesis as a midbody bridge can be clearly seen at 2:15 but the cells later fused and formed a single, binucleated cell by 3:35. The bottom lowest panels show a cell that underwent an early failure in cytokinesis. Bars in the leftmost panels, 5 µm.

Arl3 Is Required for Cytokinesis
Proteins that bind to the mitotic spindle, move to the midzone,and are still bound to microtubules in the midbody are oftenassociated with roles in mitosis or cytokinesis. To test thishypothesis we used transient expression of short interferenceRNAs (siRNAs) to deplete cellular Arl3. Knockdown of Arl2 orArl3 in HeLa cells was achieved by transfection of HeLa cellswith pSUPER-based plasmids that direct the expression of shorthairpin RNAs and resulted in decreased Arl2 or Arl3 proteinon days 2-4 after transfection (Figure 4A), as previously describedfor Arfs (Volpicelli-Daley et al., 2005

). The siRNAs were designedwith the assistance of algorithms provided by Dharmacon andBD Biosciences and four sequence-independent targets withinthe open reading frame of Arl2 or Arl3 were constructed andtested. The two yielding the strongest reductions in proteinlevels of each target were used in these studies. Only phenotypesthat were found for each of these constructs are reported, asan important control against off-target effects of the siRNAs.Our protocol does not include a selection step and typicallyresults in 50-70% transfection efficiency in HeLa cells. Asmentioned above, $~$ 50% of cells depleted for Arl3 were also foundto display fragmented Golgi.

Reducing the levels of cellular Arl3 resulted in the cells becomingdramatically elongated, as viewed in fixed cells and quantifiedby determination of the length of the long axis of cells inculture 3 d after transfection with the siRNA plasmid (Figure 4B,bottom panels). The average length of the long axis of cellsincreased by >50% in cells depleted of Arl3 (Figure 4D).

When these cells were stained for ${alpha}$ - or $beta$ -tubulin to monitor microtubulesit was clear that the elongated cells contained extensive microtubulesaligned with the long axis of the cells (Figure 4B, bottom panels).Long aligned microtubules are found in a number of cellularstructures, many of which are very stable and contain relativelyhigh concentrations of acetylated tubulin. When cells knockeddown for Arl3 were stained with a monoclonal antibody (611-B1)specific to acetylated tubulin, we saw increased staining inPHEMO-fixed cells (Figure 4B, rightmost panels). This increasein acetylated tubulin was confirmed by immunoblot analysis oftotal cell lysates from control and Arl3 siRNA HeLa cells (Figure 4E).Because the presence in cells of acetylated tubulin is correlatedwith more stable microtubules (often seen in cilia, flagella,and mitotic spindles), it was possible that the microtubules,or a subpopulation of them, in the elongated cells were alsomore stable and this contributed to the change in cell morphology.

Because of this link between acetylated tubulin and Arl3 levelsand comparative genomic screens had implied a role for Arl3in cilia, we specifically looked for Arl3 in cilia. We foundstrong staining of the primary cilium of NIH3T3 cells with Arl3antisera that matched that of acetylated tubulin (Figure 3E).

Another feature of cells deficient in Arl3 was a large increase(>6-fold) in the percentage of binucleated cells (Figure 4, B and F).The binucleated cells were adherent and often elongated butotherwise normal in appearance. The DNA in each nucleus wasdecondensed and distinct nuclei were apparent so a defect incytokinesis was suggested by these observations. Because midbodiesare residual cytoplasmic bridges that connect daughter cellsat the end of cytokinesis, a decrease in midbodies would beexpected from cells defective in cytokinesis. Consistent withthis hypothesis, we also observed that Arl3 depleted cells displayeda dramatic decrease (>10-fold) in the percentage of cellshaving a midbody (Figure 4G).

Binucleated cells and lack of midbodies are indicative of cytokinesisfailure. To begin to learn where such a defect in cytokinesismay lie, we collected time-lapse recordings of live cell imagesusing fluorescence microscopy to try to capture cells as theyunderwent cytokinesis. HeLa cells were triply transfected withcherry- ${alpha}$ -tubulin to visualize microtubules (Shaner et al., 2004),Arl3-siRNA (to deplete Arl3), and histone-GFP (to visualizechromatin). In 16 of 16 time-lapse sequences of control cellstransfected with labeled tubulin and histone and the empty siRNAvector, we saw cells round up to divide and form a cleavagefurrow that extends through the cell to generate the two daughtercells, which quickly flatten out as separate cells after completionof cytokinesis (see Movie 1 in Supplementary Material). Midbodiescan be seen to persist for some time after cell separation,as they are rich in tubulin and stain brightly with the cherry- ${alpha}$ -tubulin.

In contrast, every time-lapse sequence captured of Arl3 knockdowncells showed a failure in cytokinesis. In 5 of 14 time-lapsesequences we observed cells round up, in preparation for celldivision and then begin to form a cleavage furrow, seen as aninpocketing on each side of the cell. But before the cleavagefurrow extended very far, it disappeared and the cell flattenedout as a binucleated cell, with the two nuclei visible fromthe histone-GFP or simply by phase contrast microscopy (seeMovie 2 in Supplementary Material). We have never observed anabortive cell division of this kind in our control cultures.This failure in cytokinesis was not limited to the early portionof cytokinesis as we also found nine of the 14 cells imagedby time lapse had separated to the point of having only themidbody bridge still connecting daughter cells, when suddenlythe two cells fused into a binucleated cell (see Movie 3 inSupplementary Material). The early and late cytokinesis failuresare also shown in Figure 5, as a series of panels taken fromthe movies, at different times after the onset of metaphase.

The data collected in these movies were also used to determinethe average length of time that cells spent in parts of thecell cycle. We measured prometaphase/metaphase by determiningthe length of time between the initiation of chromosome condensationto the onset of anaphase. Metaphase was delayed from an averageof just over 40 min in controls to greater than 140 min in Arl3siRNA cells (Figure 4H). These data suggest that Arl3 is requiredfor cell, but not nuclear, division and the lack of Arl3 slowsmitosis and can ablate cytokinesis.

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Figure 6. Expression of [Q70L]Arl2 causes the loss of microtubules and an M phase arrest. CHO cells were cotransfected with empty vector (control) or the pcDNA3-based plasmid directing expression of [Q70L]Arl2 and a second plasmid expressing EGFP to mark transfected cells. The effects on microtubules, cell cycle, and centrosomes were determined 18 h after transfection, as described in Material and Methods. (A) Control (top panels) or [Q70L]Arl2 expressing cells (bottom panels) were fixed with PHEMO and stained with antibodies to ${alpha}$ -tubulin, to visualize microtubules. GFP-expressing cells are shown in the second panels. Note that transfected cells expressing [Q70L]Arl2 are markedly decreased in their content of microtubules. (B) The changes in microtubule content of transfected cells was quantified by visual inspection and assessed as "normal" microtubule staining, "reduced staining," or "complete loss" of staining. Effects in control (empty vector) cells or those expressing wild-type Arl2 or [Q70L]Arl2, are shown. Data were averaged from three independent experiments, each consisting of counting 100 cells per condition. Error bars, 1 SD between experiments. (C) Cell cycle analyses were performed by flow cytometry on CHO cells 24 h after transfection with empty vector (pcDNA3.1), or vectors directing expression of wild-type Arl2 or [Q70L]Arl2. The percentages of cells in the population at different parts of the cell cycle are shown. This experiment was repeated twice, with similar results. (D) Fragmentation of centrosomes was observed after expression of [Q70L]Arl2. Control or [Q70L]Arl2-expressing CHO cells were fixed with methanol and stained for ninein and bisbenzamide. The fragmented centrosome in one cell is marked with arrowheads. Bars, 30 µm. (E) CHO cells were transfected with empty vector or plasmids directing expression of wild type or [Q70L]Arl2 (left panel or wild type or [Q71L]Arl3 (right panel) and 18 h later cells were collected and analyzed for Arl content by immunoblot. The endogenous proteins can be seen in each case in the control lanes and the exogenously expressed proteins are overexposed to allow visualization and comparison to the endogenous proteins. Note that the Arls are increased several fold relative to the endogenous proteins and that the overexpression of the wild-type proteins was at least as high as those of the dominant activating mutants.

In contrast, though the extent of depletion of Arl2 was similarto that of Arl3 (see Figure 4A), no phenotypes were found tobe associated with the loss of Arl2. Specifically, no changeswere observed in Arl2-depleted cells in the percentage of binucleatedcells, the percentage of cells displaying midbodies, stainingof interphase or mitotic microtubules, staining or abundanceof acetylated tubulin, or failures in cytokinesis. It is possiblethat more effective knockdowns of Arl2 levels may produce effects,including potentially some comparable to those seen with depletionof Arl3. But with the differences in location between Arl2 andArl3 and comparable knockdowns in protein levels we concludethat Arl2 and Arl3 are involved in distinct cellular processes.

Expression of [Q70L]Arl2 Results in the Loss of Microtubules and a G2/M Arrest
We also asked if an increase in the activity of Arl2 or Arl3would reveal phenotypes that may be indicative of functions.The oncogenic mutation of Q61L in Ras is a dominant activatingmutation, as a result of the decreased ability of Ras GAPs tostimulate the hydrolysis of bound GTP, resulting in increasedlevels of Ras-GTP in cells (Sweet et al., 1984; Feig and Cooper,1988; Takai et al., 2001). This glutamine is absolutely conservedin signaling GTP-binding proteins and assists in the coordinationof the catalytic water molecule that is required for hydrolysisof the gamma phosphate of the bound GTP. The homologous mutationin a wide array of regulatory GTPases, including Arfs (Q71L)and Arl1 (Q71L), is also a dominant activating mutation (Zhanget al., 1994; Kahn et al., 1995). The homologous mutations inArl2 and Arl3 are Q70L and Q71L, respectively.

Expression of [Q70L]Arl2 resulted in the dramatic reductionor near complete loss of microtubule staining (Figure 6A). Wequantified this effect by cotransfecting cells with plasmidsdirecting expression of GFP, as a marker for transfection, and[Q70L]Arl2 and scored GFP-positive cells for ${alpha}$ - or $beta$ -tubulin staining,to visualize microtubules. Because microtubules can be verydense and some variability exists normally between cells, weused visual inspection to determine if the level of microtubulesin cells appeared normal, reduced, or nearly completely absent.CHO cells expressing [Q70L]Arl2 were found to have dramaticallyreduced levels of microtubules 24 h after transfection (Figure 6B).Only 24% of transfected cells displayed microtubule stainingthat was normal in appearance. This effect was also observedin HeLa cells (unpublished data). We saw no evidence of suchreduced microtubule staining in control cultures, or cells overexpressingArl2, Arl3, or [Q71L]Arl3 (unpublished data).

Cell cycle analysis by flow cytometry revealed that cells expressing[Q70L]Arl2 were arrested at the G2/M phase of the cell cycle(Figure 6C). This effect was readily apparent, even though underthese conditions we typically observed only 50-70% transfectionfrequencies in these cells. In contrast, cells overexpressingwild-type Arl2 showed no changes in the percentages of cellsin different phases of the cell cycle (Figure 6C). Further analysis,using fluorescence imaging, revealed DNA condensation but nomovement of DNA toward a metaphase plate. Such a phenotype isconsistent with a mitotic arrest resulting from the loss ofthe microtubule-based mitotic spindle.

Taxol Treatment of Cells Prevents the Loss of Microtubules
Microtubules are highly dynamic structures so the decrease inthe levels of microtubules in cells could result from eitheran increase in the rate of destruction or a decrease in theirrate of polymerization. Microtubule dynamics can be alteredby a variety of drugs; including those, like taxol, that stabilizethem or those, like nocodazole, that destabilize them. We askedfirst if taxol stabilization could prevent the loss of microtubulescaused by expression of [Q70L]Arl2. Two different protocolswere used in these studies. In the first, CHO cells were transfectedand 5 h later taxol was added at different concentrations (0.003-1µM) and cells were then assessed for microtubule staining24 h after transfection (see Materials and Methods). At lowconcentrations of taxol (3-30 nM) we saw no effect of the drugon preventing the loss of microtubules (see Figure 7). However,at higher concentrations (100 nM and above) we found that taxolprevented the loss of microtubules in cells expressing [Q70L]Arl2in a dose-dependent manner (Figure 7).

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Figure 7. High concentrations of taxol prevent the loss of microtubules seen upon expression of [Q70L]Arl2. CHO cells were cotransfected with plasmids directing expression of [Q70L]Arl2 and EGFP, and 5 h later were treated with different concentrations of taxol (3 nM-1 µM). Cells were fixed with PHEMO and processed for ${alpha}$ -tubulin staining 24 h after transfection. The persistence of microtubule staining was evident at the higher concentrations (>30 µM) of taxol when cells were stained for ${alpha}$ -tubulin and the results were quantified. The results of three independent experiments were averaged; each experiment consisted of counting 80-100 cells. Error bars, 1 SD between experiments.

Using an alternate protocol, taxol was added only during thelast 2 h, 22 h after initiation of [Q70L]Arl2 expression. Underthese conditions even the highest concentration of taxol tested(1 µM) was ineffective at promoting the retention of microtubulesin transfected cells (unpublished data). It appears that oncethe microtubules are lost in cells expressing [Q70L]Arl2, theremay be fewer or no microtubules for the taxol to act on. Thus,an effect of [Q70L]Arl2 on microtubule growth appears more likelythan an effect on microtubule destruction.

Expression of [Q70L]Arl2 Compromises the Ability of Cells to Polymerize Tubulin
CHO cells were treated with the microtubule-destabilizing drugnocodazole (15 µg/ml) for 2 h, at which point no discerniblemicrotubules were seen in any cells. The drug was then removedand the ability of cells expressing [Q70L]Arl2 to recover theirmicrotubules was compared with controls. Growth of new microtubulesunder these conditions is nucleated radially from centrosomesand so appears as a steadily enlarging aster at early time points.The expression of [Q70L]Arl2 was found to clearly compromisethe ability to grow new microtubules, as seen in Figure 8. Thelength of time after washout of nocodazole was varied between2 and 15 min but cells expressing [Q70L]Arl2 failed to nucleatemicrotubule growth at any of these times. If the [Q70L]Arl2prevents the growth of new microtubules then over time cellswould exhibit reduced or no microtubules, as has been observed.We conclude that the primary defect in cells expressing [Q70L]Arl2is in their ability to polymerize tubulin and form new microtubulesat centrosomes.

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Figure 8. Expression of [Q70L]Arl2 prevents microtubule regrowth. Control and [Q70L]Arl2-expressing CHO cells were treated with nocodazole (15 µg/ml) for 2 h. After the drug was removed, cells were incubated for varying times before fixation in PHEMO and stained for ${alpha}$ -tubulin to visualize nascent microtubule asters and EGFP fluorescence was used to identify transfected cells. (A) Regrowth of microtubule can be visualized as asters in these images, taken 5 min after removal of the drug, in control cells (top panel) and in untransfected cells (bottom panel). Cells expressing [Q70L]Arl2, identified by coexpression with GFP, were devoid of asters (bottom panels). (B) This effect was quantified by counting asters in control ( ${blacksquare}$ ) and [Q70L]Arl2-expressing ( ${square}$ ) cells at 2 (left set of bars) or 5 min (right) after removal of nocodazole. Bar, 20 µm.

[Q70L]Arl2 Causes Fragmentation of Centrosomes
We also examined whether the localization of Arl2 and Bart atcentrosomes was affected by changes in microtubule organization.Microtubules were disrupted by treatment of CHO cells with nocodazole(15 µg/ml) for 2 h before cells were fixed with methanoland doubly labeled and processed for Arl2, Bart, and ${gamma}$ -tubulin,centrin or ninein staining. Staining of Arl2 or Bart (Figure 1D)was retained at centrosomes in nocodazole-treated cells, demonstratingthat Arl2 and Bart localization to the centrosome is independentof microtubules over the time course of these experiments. Wenoted that Arl2 staining at centrosomes was more intense andsharper in nocodazole-treated cells, compared with untreatedcells, though we lack an explanation for this observation.

In contrast to untransfected cells, those expressing [Q70L]Arl2often had three or more ninein-positive puncta (Figure 6D),and in some cases no ninein-positive puncta could be seen. Inthose cells with multiple ninein-positive puncta, the size ofthe puncta were clearly decreased, suggesting that centrosomeswere fragmented in response to the expression of [Q70L]Arl2.When cells were scored for microtubule staining (Figure 6B;as normal, partially lost or completely lost) and cell countswere obtained for ${gamma}$ -tubulin, Bart, and ninein staining, the resultswere essentially identical (unpublished data). This suggestsa strong correlation exists between the loss of microtubulestaining and fragmentation of centrosomes. Because nocodazoletreatment and loss of microtubules that accompanied it had nosuch impact on the integrity of centrosomes, we conclude that[Q70L]Arl2 has an effect on centrosomes that is in additionto its effect on microtubules.

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

We examined the cellular locations of Arl2 and Arl3 in a numberof different cell lines. Our data support the general modelthat Arl2 and Arl3 exist in a pool in cytosol from which theGTPases are recruited to several different locations. This isconsistent with current models for other members of the Arffamily of regulatory GTPases, particularly the Arfs themselves,which are known to have >12 different effectors in multiplecellular locations. We also altered the cellular activitiesof Arl2 and Arl3 to assist in the identification of functionalroles for these GTPases. We propose that Arl2 acts in the regulationof the assembly of microtubules and most likely does so at centrosomes.In contrast, the locations of Arl3 and phenotypes resultingfrom depletion of Arl3 are consistent with it playing a rolein cytokinesis that is also predicted to be linked to its actionsat centrosomes. Thus, Arl2 and Arl3 are each localized in partto centrosomes but we believe they have distinct functions,though each is closely tied to microtubule-based functions.

The earlier genetic data strongly linked Arl2 function to thatof microtubule integrity and in microtubule-dependent processes,including cell division and cellularization during early embryonicdevelopment (Hoyt et al., 1990; McElver et al., 2000; Radcliffeet al., 2000; Antoshechkin and Han, 2002). Bhamidipati et al.(2000) provided the initial evidence for Arl2-cofactor D bindingand proposed a role for Arl2 modulating tubulin destructionmediated by cofactor D. We discovered that expression of thedominant activating Arl2 mutant, [Q70L]Arl2, causes the lossof microtubules in HeLa cells and that cells expressing thismutant are often unable to polymerize microtubules after nocodazolewashout. Thus, we propose that Arl2 plays a more direct rolein the regulation of tubulin polymerization.

Initial tests of mechanism point to the assembly of microtubulesas the likely site of action of Arl2 because after washout ofnocodazole microtubule asters did not form in cells expressing[Q70L]Arl2. Cofactor D binds Arl2-GDP and not Arl2-GTP so isvery unlikely to be the mediator of [Q70L]Arl2 effects on microtubules.Cellular control of tubulin polymerization is complex, and Arl2is not required for in vitro tubulin polymerization so a regulatoryand not obligatory role is envisioned. Homologous mutationsto [Q70L]Arl2 in other GTPases produce elevated levels of theactivated GTPase, resulting in increased binding and often increasedaffinity for effectors and GTPase activating proteins (GAPs),but lacking the ability to hydrolyze the bound GTP. Thus, [Q70L]Arl2may prevent tubulin polymerization at centrosomes by bindingand inhibiting or sequestering an essential component in thatprocess. Identification of the target of [Q70L]Arl2 will likelyprovide insight into the regulation of microtubule growth.

It is the lack of a proper spindle that we believe explainsthe mitotic arrest in cells expressing [Q70L]Arl2. The roleof centrosomes as the microtubule organizing center in cellsmakes them likely to be the site of [Q70L]Arl2 action. Consistentwith this prediction, we found Arl2 to be localized to the centrosomesof several different cell types by staining with affinity-purifiedArl2 antibodies and also to cofractionate with ${gamma}$ -tubulin andcentrosomes by cell fractionation. Arl2 is bound to centrosomesat all parts of the cell cycle and so is available to participatein the growth and regulation of both interphase microtubulesand the mitotic spindle. The observation that taxol is onlyactive in stabilizing microtubules in cells expressing [Q70L]Arl2at concentrations above 100 nM, also consistent with the GTPaseacting at centrosomes as taxol preferentially affects the plusends of microtubules at lower concentrations. In addition, Arl2may play a second role in the maintenance of centrosome integrityas fragmentation was observed in cells depleted of microtubulesas a result of the expression of [Q70L]Arl2, but not in cellslacking microtubules as a result of nocodazole treatment.

At this point we do not understand the functional significanceof Arl2 in mitochondria (Sharer et al., 2002), of Arl2 or Arl3in the nucleus, or of Arl3 at the Golgi. Tubulin has been proposedfor many years to be present in the nucleus (Menko and Tan,1980; Walss-Bass et al., 2003) though its functional role thereis still uncertain. Arl3 has been reported to bind the nuclearenvelope after exposure of HeLa cells to nocodazole (Graysonet al., 2002) but the relationship of that observation to ourlocalization of Arl3 to the nucleoplasm is not clear. Despitethe limits of our current understanding of the functional significanceof these different cellular locations it is likely that we willneed to understand them before the full nature of these GTPasescan be appreciated.

We also provide evidence that Arl3 is at centrosomes and isrequired for cytokinesis. The observations that cells depletedfor Arl3 fail to complete cytokinesis, become binucleated andincreasingly elongated, and display a delay in metaphase couldconceivably be linked to effects of Arl3 on microtubules, andperhaps also at centrosomes. The formation of cilia is linkedto the cessation of cell cycling and there is growing evidencefor the existence of specific signaling pathways that integratethe cell cycle and cilia outgrowth (Quarmby and Parker, 2005).Evidence supporting a link between cellular and flagellar growthhas been described in the protozoan parasite, Leishmania (Cuvillieret al., 2000) in that expression of dominant activating or inactivatingmutants of the Arl3 ortholog resulted in slowed growth ratesand immobile cells due to defective flagella or cell death andG0 arrest, respectively. We speculate that Arl3 is a componentin the signal pathway between cilia and the cell cycle machinery.The presence of Arl3 in cilia, centrosomes, and midbodies isalso consistent with the hypothesis that the signal involvedmay be part of the centrosomal repositioning that controls therelease of microtubules required for completion of cytokinesis(Piel et al., 2001). Correlative evidence in support of thishypothesis was found in that staining of Arl3 was strikinglysimilar to that of acetylated tubulin in interphase cells, spindles,cilia, and midbodies. Acetylated tubulin is correlated withhighly stable microtubules. When Arl3 is depleted in HeLa cells,we saw an increase in acetylated tubulin staining and in acetylatedtubulin in immunoblots. Thus, Arl3 activity may be requiredfor the destabilization of microtubules at different times orplaces and may be involved in the disassembly of the midbodythat is required to complete cytokinesis.

The presence of Arl3 in NIH 3T3 cilia is supported by data fromtwo other approaches. Analysis of the proteome of flagella fromChlamydomonas reinhardtii identified the ortholog of Arl3 inthat organelle (Pazour et al., 2005). And comparative genomicscreens have identified Arl3 as a gene lost in nonciliated cellsand containing characteristics specific to genes involved incilia function or formation (Avidor-Reiss et al., 2004; Li etal., 2004a). The growth of flagella must be well coordinatedwith the cell cycle and the delay in metaphase seen in Arl3-depletedcells may reflect the actions of a cell cycle checkpoint. Weinterpret these observations as supporting our hypothesis thatArl3 is involved in signaling between cilia and cell cycle machinery.

We also found Arl3 on Golgi membranes and this association wasinsensitive to brefeldin A, the inhibitor of some Arf GEFs.The observation that knockdown in Arl3 caused the fragmentationof the Golgi is consistent with a role for Arl3 in maintenanceof the Golgi but could also reflect the need for microtubulesto maintain Golgi integrity in cultured cells. Additional experimentationwill be required to determine the role(s) for Arl3 at the Golgi.The proposed role for the Golgi as a microtubule-organizingcenter (Chabin-Brion et al., 2001) should also be consideredin future studies of Arl3 at Golgi membranes. There is alsoa growing body of evidence supporting the conclusion that Golgi-derivedvesicles are required during cytokinesis, perhaps supplyingthe membranes being added between daughter cells (Skop et al.,2001; Altan-Bonnet et al., 2003; Albertson et al., 2005). Thedefect in cytokinesis that accompanies depletion of Arl3 couldtherefore result from the loss of Arl3 activity at the Golgior indirectly as a result of the change in Golgi morphology.The required role for Arl3 in cytokinesis could be mediatedby either or both of these mechanisms and will require additionalstudy.

Bart binds activated (GTP-bound) Arl2 or Arl3 and we note thateverywhere we found Bart in cells we also found either Arl2or Arl3. We found no phenotypes associated with the overexpressionor knockdown of Bart (C. Zhou, Y. Li, and R. A. Kahn, unpublishedobservations) and so tentatively conclude that it is not themediator of effects of Arl2 or Arl3 on microtubules or cytokinesis.This is consistent with the fact that orthologues of Bart havenot been found in lower eukaryotes as we expect that those effectorswill be highly conserved proteins.

In summary, we describe overlapping and distinctive cellularlocations of Arl2, Arl3, and Bart in cultured mammalian cellsand provide evidence for the roles of Arl2 in microtubule polymerizationand for Arl3 in cytokinesis and cilia signaling. Roles for otherArls in microtubule-dependent processes have also begun to emerge.The same comparative genomic searches for cilia-related genesthat identified Arl3 also pulled out Arl6 (Avidor-Reiss et al.,2004; Li et al., 2004a). Arl6 was also identified as BBS3 (Chianget al., 2004; Fan et al., 2004), one of eight loci causativefor Bardet-Biedl syndrome (BBS), a human disorder characterizedby obesity, retinopathy, polydactyly, renal and cardiac malformations,and learning disorders. Cilia, or more precisely defects incilia, are thought to underlie BBS defects (Pan et al., 2005)and Arl6-GFP has been localized to cilia in C. elegans (Fanet al., 2004). Arl8 was shown to bind tubulin and localize tothe spindle midzone and cause defects in chromosome segregationupon depletion in cells (Okai et al., 2004).¹ Thus, the regulationof microtubule-dependent processes is emerging as a second majorrole for members of the Arf family, along with the roles forArfs and Arl1 in membrane traffic.

ACKNOWLEDGMENTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

We gratefully acknowledge the gift of the mCherry- ${alpha}$ -tubulin fromRoger Tsien, UCSD, and for helpful discussions and criticalreading of the manuscript by Win Sale and Jeff Salisbury. Weare also indebted for the technical assistance of members ofthe Winship Cancer Institute's Imaging Core Facility. This workwas supported by a grant from the National Institute of GeneralMedical Sciences (GM68029).

Footnotes

This article was published online ahead of print in MBC in Press(http://www.molbiolcell.org/cgi/doi/10.1091/mbc.E05-10-0929)on March 8, 2006.

The online version of this article contains supplemental materialat MBC Online (http://www.molbiolcell.org).

¹ The human proteins named Gie1 and Gie2 in the work of Okai etal. are identical to Arl8B and Arl8A, respectively, names thathave recently been approved by the Human Genome NomenclatureCommittee (Kahn et al., 2006).

Address correspondence to: Richard A. Kahn (rkahn{at}emory.edu).

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGMENTS
REFERENCES

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