The Association of the Arabidopsis Actin-Related Protein2/3 Complex with Cell Membranes Is Linked to Its Assembly Status But Not Its Activation

doi:10.1104/pp.109.143859

The Association of the Arabidopsis Actin-Related Protein2/3 Complex with Cell Membranes Is Linked to Its Assembly Status But Not Its Activation¹^,[W]^,[OA]

Simeon O. Kotchoni, Taya Zakharova, Eileen L. Mallery, Jie Le, Salah El-Din El-Assal and Daniel B. Szymanski^*

Department of Agronomy (S.O.K., T.Z., E.L.M., D.B.S.) and Department of Biological Sciences (D.B.S.), Purdue University, West Lafayette, Indiana 47907–2054; Institute of Botany, Chinese Academy of Sciences, Beijing 100093, China (J.L.); and Department of Genetics, Faculty of Agriculture, Cairo University, Giza 12613, Egypt (S.E.-D.E.-A.)

ABSTRACT

TOP
ABSTRACT
RESULTS
DISCUSSION
MATERIALS AND METHODS
LITERATURE CITED

In growing plant cells, the combined activities of the cytoskeleton,endomembrane, and cell wall biosynthetic systems organize thecytoplasm and define the architecture and growth propertiesof the cell. These biosynthetic machineries efficiently synthesize,deliver, and recycle the raw materials that support cell expansion.The precise roles of the actin cytoskeleton in these processesare unclear. Certainly, bundles of actin filaments positionorganelles and are a substrate for long-distance intracellulartransport, but the functional linkages between dynamic actinfilament arrays and the cell growth machinery are poorly understood.The Arabidopsis (Arabidopsis thaliana) "distorted group" mutantshave defined protein complexes that appear to generate and convertsmall GTPase signals into an Actin-Related Protein2/3 (ARP2/3)-dependentactin filament nucleation response. However, direct biochemicalknowledge about Arabidopsis ARP2/3 and its cellular distributionis lacking. In this paper, we provide biochemical evidence fora plant ARP2/3. The plant complex utilizes a conserved assemblymechanism. ARPC4 is the most critical core subunit that controlsthe assembly and steady-state levels of the complex. ARP2/3in other systems is believed to be mostly a soluble complexthat is locally recruited and activated. Unexpectedly, we findthat Arabidopsis ARP2/3 interacts strongly with cell membranes.Membrane binding is linked to complex assembly status and notto the extent to which it is activated. Mutant analyses implicateARP2 as an important subunit for membrane association.

In plant cells, the actin cytoskeleton forms an intricate networkof polymers that organizes the cytoplasm and defines the long-distanceintracellular trafficking patterns of the cell. The actin networkis critical not only for tip-growing cells (for review, seeCole and Fowler, 2006

; Lovy-Wheeler et al., 2007

) but also duringthe coordinated cell expansion that occurs in cells that utilizea diffuse growth mechanism (for review, see Wasteneys and Galway,2003

; Smith and Oppenheimer, 2005

). For example, the polarizeddiffuse growth of leaf trichomes is highly sensitized to actincytoskeleton disruption (Mathur et al., 1999

; Szymanski et al.,1999

), and a recent analysis of Arabidopsis (Arabidopsis thaliana)ACTIN mutants revealed widespread cell swelling and isotropicexpansion in numerous cell types in the root and shoot (Kandasamyet al., 2009

). The actin network is dynamic. The array reorganizesduring cell morphogenesis (Braun et al., 1999

; Szymanski etal., 1999

) and in response to endogenous (Lemichez et al., 2001

) and external (Hardham et al., 2007

) cues. A major researchgoal is to better understand not only how plant cells convertG-actin subunits to particular actin filament arrays but alsohow the actin network interacts with the cellular growth machineryduring cell expansion.

This is a difficult problem to solve, because in expanding vacuolatedcells the actin array adopts numerous configurations and consistsof dense meshworks of cortical actin filaments and bundles (Baluskaet al., 2000), thick actin bundles that penetrate the centralvacuole (Higaki et al., 2006), and meshworks of filaments andbundles that surround the nucleus and chloroplasts (Kandasamyand Meagher, 1999; Collings et al., 2000). The spatial relationshipsbetween these actin networks and localized cell expansion arenot obvious. Certainly, the plasma membrane-cell wall interfaceis a critical location for the regulated delivery and fusionof vesicles containing cell wall polysaccharides. Frequent reportsof localized domains of enriched cortical actin signal at regionsof presumed localized cell expansion have led to the widelyheld view that the cortical actin array creates local tracksfor vesicle-mediated secretion (for review, see Smith and Oppenheimer,2005; Hussey et al., 2006). In one study, the dynamics of actinfilaments were analyzed in living hypocotyl epidermal cellsthat utilize a diffuse growth mechanism (Staiger et al., 2009). In this case, individual actin filaments are very unstableand randomly oriented; therefore, the precise relationshipsbetween cortical F-actin, vesicle delivery, and cell shape changeremain obscure. The best known function for the actin cytoskeletonis that of a track for myosin-dependent vesicle and organelletrafficking (Shimmen, 2007). The actin bundle network mediatesthe transport of cargo between endomembrane compartments (Geldneret al., 2001; Kim et al., 2005) and the long-distance actomyosintransport of a variety of organelles, including the Golgi (Nebenfuhret al., 1999; Peremyslov et al., 2008; Prokhnevsky et al., 2008). Generation of distributed (Gutierrez et al., 2009; Timmerset al., 2009) and localized (Wightman and Turner, 2008) actinbundle networks appears to define early steps in the traffickingof Golgi-localized cellulose synthase complexes to the sitesof primary and secondary wall synthesis, respectively.

Plant cells employ diverse collections of G-actin-binding proteins,actin filament nucleators, and actin-bundling and cross-linkingproteins to generate and remodel the F-actin network (for review,see Staiger and Blanchoin, 2006). One actin filament nucleator,termed the Actin-Related Protein2/3 (ARP2/3) complex, controlsnumerous aspects of plant morphogenesis and development. Thevertebrate complex consists of the actin-related proteins ARP2and ARP3 and five other unrelated proteins termed ARPC1 to ARPC5,in order of decreasing mass. ARP2/3 in isolation is inactive,but in the presence of proteins termed nucleation-promotingfactors such as WAVE/SCAR (for WASP family Verprolin homologous/Suppressorof cAMP Repressor), ARP2/3 is converted into an efficient actinfilament-nucleating machine (for review, see Higgs and Pollard,2001; Welch and Mullins, 2002). In mammalian cells, ARP2/3 activitiesare linked to membrane dynamics. Keratocytes that crawl persistentlyon a solid substrate appear to use ARP2/3-generated dendriticactin filament networks at the leading edge to either driveor consolidate plasma membrane protrusion (Pollard and Borisy,2003; Ji et al., 2008). In many vertebrate cell types, ARP2/3has a strong punctate intracellular localization (Welch et al.,1997; Strasser et al., 2004), which could reflect hypothesizedactivities at the Golgi (Stamnes, 2002) or late endosomal (Fuciniet al., 2002; Holtta-Vuori et al., 2005) compartment.

Genetic studies in plants reveal nonessential but widespreadfunctions for ARP2/3. In the moss Physcomitrella patens, theARPC4 and ARPC1 subunit genes are critical during tip growthof protonemal filaments (Harries et al., 2005; Perroud and Quatrano,2006). In Arabidopsis, loss of either ARP2/3 subunit gene ormutations in WAVE complex genes that positively regulate ARP2/3cause complicated syndromes, including the loss of polarizeddiffuse growth throughout the shoot epidermis, defective cell-celladhesion, and decreased hypocotyl elongation (for review, seeSzymanski, 2005). Altered responses to exogenous Suc (Li etal., 2004; Zhang et al., 2008) and reduced root elongation (Dyachoket al., 2008) are also reported for wave and arp2/3 strains.In higher plants, the involvement of ARP2/3 in tip growth androot hair development is more subtle. In Lotus japonicus, mutationof NAP1 and PIR1, known positive regulators of ARP2/3 (Basuet al., 2004; Deeks et al., 2004; El-Assal et al., 2004a), causesincompletely penetrant root hair phenotypes, but in the presenceof symbiotic bacteria, the mutants have defective infectionthreads and reduced root nodule formation. Arabidopsis arp2/3mutants do not have obvious tip growth defects in pollen tubesor root hairs, but in the presence of GFP:TALIN (Mathur et al.,2003b) and in double mutant combinations with the actin-bindingprotein CAP1 (Deeks et al., 2007), the effects of ARP2/3 onroot hair growth are unmasked.

In Arabidopsis, the genetics of the positive regulation of ARP2/3are well characterized and appear to occur solely through anotherheteromeric complex termed WAVE (Eden et al., 2002; for review,see Szymanski, 2005). The putative WAVE/SCAR complex containsfive subunits, one of which is the ARP2/3 activator SCAR. PlantSCARs contain conserved N-terminal and C-terminal domains thatmediate interactions with other WAVE complex proteins and ARP2/3activation, respectively (Frank et al., 2004; Basu et al., 2005). In nonplant systems, the regulatory relationships betweenWAVE and ARP2/3 appear to vary between cell types and species(for review, see Bompard and Caron, 2004; Stradal and Scita,2006). However, in Arabidopsis, double mutant analyses indicatethat WAVE is the sole pathway for ARP2/3 activation and thatall subunits positively regulate ARP2/3 (Deeks et al., 2004;Basu et al., 2005; Djakovic et al., 2006). SCAR quadruple mutantsare indistinguishable from arp2/3 null plants (Zhang et al.,2008). In moss, BRICK1 and ARP2/3 mutants have similar phenotypes,suggesting conserved regulatory relationships between WAVE andARP2/3 in the plant kingdom (Harries et al., 2005; Perroud andQuatrano, 2006, 2008).

Despite extensive molecular genetic knowledge about the ARP2/3pathway and the strong actin cytoskeleton and growth phenotypesof arp2/3 plants, there are few direct data on the existenceof the plant complex and its cellular function. There are reportsof ARP2/3 localization based on the behavior of individual subunits(Le et al., 2003). In some cases, the results are weakened bythe unknown specificity of heterologous ARP2/3 antibodies (VanGestel et al., 2003; Fiserova et al., 2006). A specific antibodywas raised against Silvetia ARP2 (Hable and Kropf, 2005). Indeveloping zygotes, rhizhoid emergence is an early and actin-dependentdevelopmental event, and at this stage a broad subcortical coneof ARP2 signal extends from the nuclear envelope toward therhizhoid apex (Hable and Kropf, 2005). Double labeling experimentsdetected considerable overlap between ARP2 and actin, but surprisingly,there was a broad cortical domain of putative organelle-associateddistal ARP2 that did not overlap with actin. In tip-growingP. patens chloronema cells, ARPC4 also appears to be membraneassociated and localizes to a broad subcortical apical zone(Perroud and Quatrano, 2006). For these localization and geneticstudies that rely on individual ARP2/3 subunits, it is importantto prove that a plant ARP2/3 complex exists to test for an associationof the complex with endomembrane compartments.

In this paper, we provide several lines of evidence for an evolutionarilyconserved pathway for ARP2/3 complex assembly in plant cells.These studies are based in part on genetic and biochemical analysesof the putative ARP2/3 subunit gene ARPC4. We found that disruptionof the ARPC4 gene caused catastrophic disassembly of the complexand an array of phenotypes that were indistinguishable fromknown arp2/3 mutants. Chromatography experiments clearly revealedthat functional hemagglutinin (HA)-tagged ARPC4 and endogenousARP3 subunits assemble fully into ARP2/3 complexes. Surprisingly,much of the cellular pool of the plant ARP2/3 complex is membraneassociated. An analysis of an extensive collection of wave andarp2/3 mutants allowed us to conclude that the normal associationwith membranes depended on the presence of ARP2 and the assemblystatus of the complex but not on the existence of an activepool of ARP2/3 in the cell.

RESULTS

TOP
ABSTRACT
RESULTS
DISCUSSION
MATERIALS AND METHODS
LITERATURE CITED

Molecular Characterization of ARPC4

In all known ARP2/3 complexes, ARPC4 is a core subunit thatseeds complex assembly (Winter et al., 1999; Gournier et al.,2001). However, in our screens and in a comprehensive mappingstudy of distorted mutants, there was no locus that mapped tothe region of ARPC4 (Schwab et al., 2003). To test the involvementof Arabidopsis ARPC4 in the WAVE-ARP2/3 pathway, we initiateda reverse genetic analysis of the gene using the Salk collectionof Arabidopsis T-DNA knockout lines (Alonso et al., 2003). ARPC4was originally described as a protein fusion to a kinesin-relatedprotein (Mathur et al., 2003a). Subsequently, an ARPC4 cDNAsequence very similar to those of the yeast and human homologswas deduced based on the designed oligonucleotide primer sequencesand reverse transcription (RT)-PCR amplification products (Liet al., 2003). However, a 5' end sequence from a full-lengthARPC4 DNA clone (GenBank accession no. CB258042) predicted adifferent sequence at the N terminus based on the presence ofan intron separating the start codon and the second amino acid.We confirmed the accuracy of this alternative gene model, shownin Figure 1A , by testing an array of oligonucleotides fortheir ability to amplify the 5' end of ARPC4 mRNA in RT-PCRexperiments. Primers C4RT-P4 and C4RT-P5 (Supplemental TableS1) targeting exon 2 amplified a cDNA molecule, while C4RT-P6(Supplemental Table S1) targeting intron 2 failed to generatean amplification product. DNA sequencing of a cloned ARPC4 cDNAidentified a single open reading frame that encodes a polypeptideof 20 kD that is approximately 65% identical to yeast and humanARPC4.

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Figure 1. Physical map of the ARPC4 gene and characterization of the arpc4 T-DNA insertion alleles. A, The positions of exons (numbered vertical rectangles) and introns (thick lines) are represented. The start and stop codons are indicated, and the 5' and 3' untranslated regions are labeled with open rectangles. The locations of the arpc4-t1 and arpc4-t2 T-DNA insertions are shown using inverted black triangles. The names and locations of primers used for RT-PCR experiments are also indicated. Bar = 0. 5 kb. B, The T-DNA insertions cause premature transcriptional termination. Transcription of the ARPC4 exons upstream (top panel; using primers 3F and 6R) and downstream (middle panel; using primers 8F and 9R) from the T-DNA was monitored. The quality of the RNA was assayed using primers to detect glyceraldehyde 3-phosphate dehydrogenase subunit C (GAPC; bottom panel). NC is a "no-template" control for the potential contamination of reagents with ARPC4 cDNA. DNA size standards are shown to the left.

If ARPC4 encodes an important ARP2/3 subunit, then mutationof the gene should cause the syndrome of phenotypes displayedby other known distorted mutants. The insertion line SALK_073297(arpc4-t1) harbors a T-DNA insertion in the sixth intron ofARPC4. The location of the T-DNA was confirmed using the T-DNA-specificoligonucleotide primer LB1 and the ARPC4-specific primer SALK_073297-R(Supplemental Table S1). Lines that were homozygous for thearpc4-t1 allele displayed a typical distorted trichome phenotype(Fig. 2B ). Like all other known distorted mutants, arpc4-t1was recessive, and heterozygous plants gave rise to progenythat segregated very close to the expected Mendelian ratio of3:1 wild type:mutant. To confirm that the distorted trichomephenotype was caused by a mutation of ARPC4, we used a secondindependent T-DNA allele (SALK_052687) named arpc4-t2. The locationof the arpc4-t2 T-DNA in the seventh intron of the gene wasconfirmed by PCR using the primers LB1 and SALK_052687-F (SupplementalTable S1). The arpc4-t2 mutation was also recessive. Complementationtests demonstrated that arpc4-t1 and arpc4-t2 were alleles ofthe same gene, because when the two mutants were crossed, 100%(n = 16) of the F1 progeny had the distorted phenotype.

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Figure 2. Epidermal cell shape and cell-cell adhesion defects of arpc4 plants. A to D, Upper surface of developing leaves, showing young trichomes at the onset of the mutant phenotype during the transition to stage 4. A, Wild type. B, arpc4. C and D, Mature trichomes on wild-type (C) and arpc4 (D) leaves. E and F, Upper surface of cotyledon pavement cells at 12 d after germination. E, Wild type. F, arpc4. G and H, Cell-cell adhesion defects in etiolated hypocotyl. G, Wild type. H, arpc4. Bars = 50 µm (A, B, E, and F), 10 µm (C and D), and 100 µm (G and H). Numbers in A and B indicate the trichome developmental stages (Szymanski et al., 1998

). Arrowheads indicate stomata. Arrows indicate gaps between adjacent pavement cells. The black arrow in H indicates cell adhesion defects on the arpc4 hypocotyl.

The RNA from each genotype was intact, because glyceraldehyde3-phosphate dehydrogenase subunit C transcripts were easilydetected (Fig. 1B, lanes 2–4). The PCR reagents were freefrom contamination, because in the absence of cDNA templatethere was no amplification signal (Fig. 1B, lane 1), and therewas no detectable contamination of the RNA with genomic DNA,because higher molecular mass PCR products containing intronswere not detected (Fig. 1B, lanes 2–4, top panel). Botharpc4 alleles caused premature transcriptional termination,because mRNA containing exons 3 to 6 was detected but the exonsdownstream from the T-DNA were not (Fig. 1B). Both arpc4 allelesare predicted to be null, because they cause equal phenotypesand these truncated transcripts do not encode the C-terminalamino acids that are required for critical interaction withthe other core subunit, ARPC2 (Robinson et al., 2001

; El-Assalet al., 2004b

). Therefore, the genetic analysis of two independentarpc4 alleles proves that disruption of ARPC4 causes the distortedtrichome phenotype.

We examined the phenotypes of the arpc4 alleles in more detailand compared them with the strong ARP2/3 subunit mutants arp3/dis1(Le et al., 2003) and arpc2/dis2 (El-Assal et al., 2004b). Insegregating populations, arpc4-t1 and arpc4-t2 plants displayedcompletely penetrant and equally severe effects on trichomemorphogenesis. Following branch initiation (stage 3), wild-typetrichomes transition to a growth phase in which the initiatedtrichome branches elongate with a blunt tip morphology (stage4; Fig. 2A; see Fig. 1 in Szymanski et al., 1998). During stage5, the branch tip acquires a pointed morphology (Fig. 2A), andmost cell expansion occurs during this phase (Szymanski et al.,1999). All of the leaf trichomes on arpc4 plants, like otherdistorted mutants, displayed a loss of polarized growth at thetransition to stage 4 and the cells twisted and swelled in anunpredictable manner (Fig. 2, B and D). Compared with the wildtype (Fig. 2C), mature arpc4 trichomes (Fig. 2D) also have agreatly decreased trichome branch length (Table I ), but arpc4did not differ from arpc2/dis2 and arp3/dis1.

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Table I. Comparisons of the growth and morphogenesis phenotypes of arpc4 with the wild type and known arp2/3 mutants

Values shown are means ± SD. Asterisks indicate significant differences from the wild type using Student's t test (P < 0.05).

The distorted group genes are expressed throughout the plant(Basu et al., 2005

; Zhang et al., 2008

), the corresponding mutantshave a complex array of growth and developmental phenotypes(Le et al., 2003

; Mathur et al., 2003a

, 2003b

), and we foundthat arpc4 plants share them all. For example, dark-grown arpc4plants have a reduced hypocotyl length (Table I). Like otherarp2/3 and wave mutants (Li et al., 2003

; Brembu et al., 2004

), arpc4 pavement cells had a slightly more simple shape comparedwith the wild type, and cell-to-cell adhesion is affected inboth cotyledons (Fig. 2F; Table I) and dark-grown hypocotyls(Fig. 2H). Analyses of the actin phenotypes of distorted trichomes,using either live cell probes or whole mounts of fixed samples,identify a defect in the generation or maintenance of alignedactin bundles in the core cytoplasm of developing branches (Szymanskiet al., 1999

; Le et al., 2003

; Deeks et al., 2004

; Basu et al.,2005

; Djakovic et al., 2006

). The core bundle organization defectsin stage 4 trichomes correlate with the severity of cell morphologydefects and are likely to be the most relevant. The frequentlyobserved reduction in the quantity of core actin filaments isobserved only in stage 5 cells (Le et al., 2003

, 2004; Zhanget al., 2005

), which is well after the onset of the mutant phenotype.These later stage cytoskeletal defects may reflect an indirecteffect of aberrant vacuole positioning or cell morphology. Similarto previous reports (Zhang et al., 2008

), we detected alignedcore actin filament bundles in nearly all stage 4 wild-typetrichomes (19 of 22 branches; Fig. 3, A and B ). However, inarpc4 stage 4 trichomes, only nine of 28 stage 4 branches hadcore actin bundles that were aligned with the cell axis andterminated near the branch apex (Fig. 3, C and D). Based onthe identical phenotypes of arpc4 and known wave and arp2/3mutants, we conclude that ARPC4 functions within the WAVE-ARP2/3pathway of actin-based morphogenesis.

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Figure 3. The arpc4-t1 mutant causes trichome actin cytoskeleton defects that are indistinguishable from other arp2/3 mutants. A, Maximum projection of confocal image stacks of fixed wild-type trichomes probed with phalloidin. Arrows show trichome branch 1 in two different stage 4 cells. B, Mid planes of wild-type trichome branch 1 from the cells in A. C, Maximum projection of confocal image stacks of arpc4-t1 trichomes, with arrows showing trichome branches 1 and 2. D, Mid planes of arpc4-t1 trichome branches 1 and 2. Stars in A and B indicate a subsection of a mature (stage 6) branch from an adjacent trichome. Bars = 10 µm.

Biochemical Evidence for an Arabidopsis ARP2/3 Complex

In plants, biochemical evidence for the existence of a plantARP2/3 complex and its distribution in cells is lacking. Therefore,it was important to develop tools that would allow us to testfor the presence of a complex. We tagged the C terminus of ARPC4with a triple HA, because this region of the protein is unorderedand extends outward from the other ARP2/3 subunits (Robinsonet al., 2001). We drove ARPC4 expression using its endogenouspromoter by cloning ARPC4 and the intergenic sequences betweenthe start codon- and stop codon-flanking genes AT4G14145 andAT4G14150, respectively. To assess the functionality of ARPC4:HA,we used Agrobacterium tumefaciens-mediated transformation tointroduce the transgene into arpc4 plants (Clough and Bent,1998). ARPC4:HA effectively rescued the mutant phenotype, providingfurther confirmation of the correct identification of ARPC4.An example of a representative ARPC4:HA arpc4-transformed plantis shown in Figure 4B . Transformed line ARPC4:HA-2 had a singleT-DNA insert based on a 3:1 segregation of the dominant selectablemarker gene and an approximately 3:1 segregation of wild-type(31 plants) to distorted (11 plants) phenotypes. From this segregatingpopulation, we generated a stock that was homozygous for theARPC4:HA transgene and displayed stable rescue activity overmultiple generations. We next confirmed that ARPC4:HA retainedthe epitope tag by probing western blots with a monoclonal anti-HAantibody. The antibody specifically detected an HA-tagged versionof TWISTED DWARF1 (HA-TWD1; Geisler et al., 2003; Fig. 4C, lane1). Western blotting of ARPC4:HA arpc4 extracts detected a singleband with a molecular mass of approximately 24 kD, which isvery close to what was expected for ARPC4:HA (Fig. 4C, lane2).

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Figure 4. The epitope-tagged version of ARPC4 expressed with its native promoter rescues the arpc4 phenotype and assembles into an ARP2/3 complex. A, Distorted trichome phenotype of the arpc4-t2 mutant. B, The distorted trichome phenotype in the arpc4-t2 mutant is rescued by ARPC4:HA gene expression driven by its native promoter. C, The HA tag is retained and the ARPC4 protein is detected at the expected size (lane 2). Total, unfractionated HA-TWD1 sample was used as the positive control (lane 1). D, ARPC4-HA protein is a subunit of the ARP2/3 protein complex, the size of which is indistinguishable from the budding yeast ARP2/3. Plant protein microsomes containing ARP2/3 were solubilized with 4% cholate and analyzed by SEC. Column fractions from arpc4-t2 ARPC4:HA rescue line (top panel) and yeast (bottom panel) extracts were probed with anti-HA antibody. The estimated mass of the ARP2/3 complex is labeled above the western-blot panels. At, Arabidopsis thaliana; Sc, Saccharomyces cerevisiae.

Although the ARPC4:HA rescue experiments demonstrated clearlythe activity of the fusion protein, we wanted to test for thepresence of high molecular mass ARP2/3 complexes containingARPC4:HA. To address this question, we used analytical size-exclusionchromatography (SEC) to approximate the mass of ARPC4:HA-containingcomplexes. Surprisingly, in our initial cell fractionation assays,we found that Arabidopsis ARP2/3 associated strongly with themembrane fraction (see below). Therefore, the complexes analyzedby SEC were solubilized from a crude microsome fraction (see"Materials and Methods"). Based on its elution profile, theARPC4:HA complex was estimated to be approximately 310 kD (Fig. 4D, top panel). To compare Arabidopsis ARP2/3 with a known ARP2/3complex, we analyzed crude extracts from a Saccharomyces cerevisiaestrain expressing an epitope-tagged version of ARPC3 (ARC18-HA;a gift from David Drubin). Yeast ARP2/3 complex had a mobilitythat was nearly identical to that observed for the plant complex(Fig. 4D, bottom panel). Importantly, we failed to detect ARPC4:HAin chromatography fractions that would contain the monomeric(24-kD) form (Fig. 4D). These biochemical and transgenic rescuedata indicated that ARPC4:HA assembled into a functional ARP2/3complex and indicate that the properties of ARPC4:HA accuratelyreflected the properties of ARP2/3 complexes. Thus far, we havenot been able to detect SCAR-dependent ARP2/3 actin filamentnucleation activity in the cholate-solubilized extracts.

To further test for the assembly of ARPC4:HA into an ARP2/3complex, we analyzed its ability to associate with the putativeARP2/3 complex protein ARP3 in a coimmunoprecipitation (coIP)assay. During the process of screening more than a dozen ARP2/3antibodies that were either heterologous or that we generatedagainst Arabidopsis subunit proteins, we identified a specificantibody that recognized endogenous ARP3. In western-blot experiments,the antibody most strongly recognized a single protein thatwas preferentially localized in the crude microsome fraction(Fig. 5A , lane 3). The detected protein corresponds to ARP3,because there was no similar signal detected from extracts fromarp3/dis1 null plants (Fig. 5A, lanes 2 and 4). In clarifiedextracts prepared from ARPC4:HA arpc4 plants, we found thatendogenous ARP3 and ARPC4-HA associated with each other (SupplementalFig. S1, top panel, lane 3). The association was specific, becauseno ARPC4:HA was detected when preimmune serum was used in thecoIP assay (Supplemental Fig. S1, lane 2). The coIP and SECdata combined with the identical phenotypes of arpc4 mutantsand all other ARP2/3 subunit mutants strongly suggest that ARPC4and other ARP2/3 subunits assemble into a conserved ARP2/3 complex.

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Figure 5. The endogenous ARP2/3 complex is moderately abundant compared with actin. A, The anti-ARP3 antibody is specific and most prominently detects a single protein at the expected mass for ARP3 (Col-0; lane 3). No corresponding band is present when protein extracts from arp3 (dis1) are probed under identical conditions. An antibody against PEPC was used to probe the same filters and demonstrate similar loading between genotypes. P, Pellet; S, soluble. B, The abundance of endogenous ARP3 (see band intensity indicated as a star in the standard curve) as a percentage of total protein was quantified using purified ARP3 inclusion bodies, which was the source of the original antigen, as a standard (see "Materials and Methods"). Western-blot signals were quantified by densitometry using ImageQuant 5.2 software analyzer. C, ACTIN content was also measured as described above. Vertebrate actin was used as a standard. r² is the correlation coefficient showing how well the standard curve data points fit the line. A.U., Arbitrary unit.

Endogenous ARP2/3 Is Moderately Abundant and Membrane Associated

We used the ARPC4:HA arpc4 line to examine the distributionof ARPC4 in crude plant cell extracts that were subjected todifferential centrifugation. We expected most of the proteinto reside in the soluble fraction, because established ARP2/3purification protocols from a variety of organisms typicallyuse this fraction as the source of material (Machesky et al.,1994; Winter et al., 1999; Robinson et al., 2001). However,the common occurrence of punctate, putatively membrane-associatedARP2/3 signal in a variety of motile cell types suggests thatvertebrate ARP2/3 has the potential to associate with organelles(Strasser et al., 2004; Shao et al., 2006).

Surprisingly, after homogenization of shoots at 16 to 20 d aftergermination and filtration of cell debris, we consistently foundthat most of the ARPC4:HA signal arose from membrane fractions(Fig. 6 ). The 1,000g pellet fraction containing chloroplasts,nuclei, residual cell debris, and starch grains contained onlya small fraction of the total pool of ARP2/3. The vast majorityof ARP2/3 was in the higher speed pellet fractions containingcrude microsomal membranes (Fig. 6A, lanes 2 and 3). Based ondensitometry of immunoblot signal from two independent experiments,only approximately 10% of the protein was present in the solublefraction after high-speed centrifugation (Fig. 6A, lane 4).The subcellular distribution of endogenous ARP3 was indistinguishablefrom ARPC4:HA and was also highly enriched in the membrane fractions(Fig. 6A, middle panel, lanes 2 and 3). Phosphoenolpyruvatecarboxylase (PEPC) was used as a control to monitor the statusof a soluble protein, and as expected, PEPC accumulated in thesoluble fraction (Fig. 6A, bottom panel, lane 4).

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Figure 6. The ARP2/3 protein complex is peripherally associated with membrane fractions. A, Plant protein extracts were centrifuged sequentially at different speeds: 1,000g (P1; lane 1), 10,000g (P10; lane 2), and 200,000g to generate final pellet (P200; lane 3) and soluble cytosolic (S200; lane 4) fractions. In each case, the cell fractions were loaded by equal proportion. The fractions from arpc4-t2 ARPC4:HA and wild-type plants were probed with anti-HA (top panel) and anti-ARP3 (middle panel) antibodies, respectively. PEPC, an abundantly soluble protein (bottom panel), was used as an internal control to monitor the soluble protein fractions. B, ARP2/3 is a peripheral membrane complex. Microsomal pellets were resuspended in MIB alone (control; lane 1) or with MIB supplemented with increasing NaCl concentrations (lanes 2 and 3), 5 M urea (lane 4), 1% Triton (lane 5), and the actin filament-depolymerizing drug latrunculin B (LatB; lane 6). After incubation for 30 min under the different conditions, the soluble and membrane-associated fractions were separated by ultracentrifugation and pellets were probed with anti-HA (top panel), anti-ARP3 (middle panel), and anti-KNOLLE to detect the integral membrane syntaxin (bottom panel).

We were also able to measure the abundance of the endogenousARP3. As expected, we found that ARP3 signal arose exclusivelyfrom a molecular mass complex that was indistinguishable insize compared with the complex detected by probing for ARPC4:HA(Fig. 4D). At present, there is no information on the abundanceof the plant ARP2/3. We used recombinant His-tagged ARP3 asa standard and conducted quantitative western-blot analysisof total cell extracts prepared from shoots at 16 to 20 d aftergermination. From these experiments, we estimated that ARP3was 0.05% of the total protein (Fig. 5B). As a standard forcomparison, we probed total Arabidopsis extracts with a maize(Zea mays) actin antibody (Gibbon et al., 1999

). The maize antibodyefficiently recognizes Arabidopsis, maize, and vertebrate actin(Chaudry et al., 2007

). Actin was approximately five times moreabundant and constituted 0.23% of the total protein (Fig. 5C).The measured concentration for actin in total shoot extractswas similar to a previously reported value of 0.36% for Arabidopsisrosette leaves (Chaudry et al., 2007

). Our data indicate thatin cell extracts, ARP2/3 is relatively abundant and that theapproximately 5:1 molar ratio of actin to ARP2/3 is lower thanthe actin-ARP2/3 ratios that have been reported in other species(Pollard et al., 2000

). The question of ARP2/3 concentrationin the cytosol and in different cell types remains unanswered.Taken together, these data indicate that the Arabidopsis ARP2/3is a moderately abundant heteromeric complex and that a majorityof the protein pool is membrane associated.

To our knowledge, the partitioning of ARP2/3 into soluble andmicrosomal fractions has not been rigorously tested in othersystems. In one example, an accounting of ARP2/3 during itspurification from Acanthomoeba indicates that the complex ismostly soluble (Kelleher et al., 1995; Wu and Pollard, 2005).Therefore, we examined in more detail the nature of plant ARP2/3association with microsomes. ARP2/3 subunits were not partitionedinto the microsomal fraction due to nonspecific trapping, becausein arpc4, ARP3 is completely solubilized (Fig. 7A , lanes 7and 8) compared with the marker protein, PEPC (Fig. 7A, bottompanel). We also wanted to rule out the possibility that ARP2/3was sedimented as part of an aggregated F-actin network. Theinability of 1% Triton to solubilize HA-tagged and endogenousARP2/3 (Fig. 6B, lane 5) is consistent with the idea that thecomplex is part of a cytoskeleton-associated fraction (Abe andDavies, 1995), but many membrane-associated proteins, includingthe syntaxin KNOLLE (Fig. 6B), are not solubilized by 1% Triton.Using fluorescence microscopy, we failed to observe any remnantsof F-actin after incubation of the microsome fraction with theF-actin-binding probes Alexa 488-phalloidin and rhodamine-phalloidin.Under the same imaging conditions, individual actin filamentspolymerized in vitro were easily detected (Basu et al., 2005). Furthermore, treatment of crude microsomes with high concentrationsof the actin-depolymerizing drug latrunculin B had no effecton the association of ARP2/3 with membranes (Fig. 6B, lane 6).Instead, microsomal ARP2/3 had properties of a peripheral membrane-associatedprotein. For example, it could be partially removed from themembrane fraction after incubation with 2 M NaCl and was completelydissociated from membranes by 5 M urea (Fig. 6B, lanes 3 and4). The integral membrane syntaxin KNOLLE contains a singlemembrane-spanning segment (Lauber et al., 1997), and neither2 M salt treatment nor 5 M urea released it from membranes (Fig. 6B, bottom panel). These results suggest that most of thecellular pool of Arabidopsis ARP2/3 exists as a peripheral membranecomplex and that the localization to the membrane fraction doesnot require F-actin.

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Figure 7. The association of plant ARP2/3 with membranes is linked to its assembly and not to the presence of an active pool. A, Cell extracts from the wild type (Col-0) and the indicated genetic mutant backgrounds were separated into crude microsomal membranes (pellet; P) and soluble fractions (soluble; S) by ultracentrifugation. For these experiments, the proportion of soluble to membrane protein that was loaded on SDS-PAGE gels was approximately 1:20. Western blots were probed with anti-ARP3 (top panel) and anti-PEPC (bottom panel) antibodies. B, Microsomal protein from the wild type (Col-0) and the indicated mutant backgrounds was solubilized in 4% cholate and subjected to SEC. Column fractions were TCA precipitated, separated by SDS-PAGE, and blotted with anti-ARP3 antibody.

Assembly-Dependent Association of ARP2/3 with Membranes

If ARP2/3 is membrane associated, then it is possible that eitherthe assembly of the complex or its activity controls membranebinding. We used a collection of arp2/3 and wave subunit mutantsto distinguish these possibilities. Cell extracts from wild-typeand mutant cells were prepared, and soluble and crude microsomefractions were isolated by a single high-speed centrifugationstep. The solubility of ARP2/3 was monitored by probing solubleand microsome protein fractions with the anti-ARP3 antibody.This experiment was repeated at least two times for each genotype,and the results were very consistent. A representative dataset is shown in Figure 7. As expected for wild-type extracts,ARP2/3 was clearly partitioned into the membrane fraction (Fig. 7A, lanes 1 and 2). Interestingly, each of the arp2/3 subunitnull lines that were examined had a reduced membrane associationof ARP3 (Fig. 7A, lanes 3–10). The effect was specific,because PEPC, an irrelevant marker protein with no known linkageto the actin cytoskeleton, was not affected in the arp2/3 lines(Fig. 7A, bottom panel).

To understand the mechanism by which ARP2/3 associates withthe cell membranes, we hypothesized that the membrane associationof ARP2/3 was linked to its activation by the WAVE complex.To test this hypothesis, we analyzed the membrane distributionof ARP2/3 in the sra1 background. Loss of the putative WAVEcomplex protein SRA1 causes a strongly distorted phenotype (Basuet al., 2004; Saedler et al., 2004). SRA1 is an evolutionarilyconserved target for Rho family small GTPase signals that maymediate SCAR-dependent activation of ARP2/3 (Eden et al., 2002; Basu et al., 2004, 2008; Steffen et al., 2004). Given thatsra1 does not affect the stability of other WAVE/SCAR complexproteins such as NAP1 or SCAR2 (Le et al., 2006), it was notsurprising that ARP2/3 was present at normal levels and fullyassembled in this background (Fig. 7). Importantly, in sra1plants, we failed to detect any decrease in the membrane associationof ARP2/3 (Fig. 7A, lanes 11 and 12). As an additional testfor the membrane association of fully assembled inactive complexes,we analyzed both the microsome association and assembly statusof the complex in arp2-1/wrm1-1 (G151D). The arp2-1 complexwas fully membrane associated (Fig. 7A, lanes 13 and 14) anddisplayed a mobility on the SEC column that was indistinguishablefrom that of the wild-type complex (Fig. 7B). Collectively,the sra1 and arp2-1 data indicated clearly that membrane associationwas not linked to the ability of the complex to be activated.

We next hypothesized that the assembly status of the complexmay be the key to membrane association. Therefore, we analyzedthe microsomal association of the complex in different mutantbackgrounds lacking individual subunits. ARPC4 is the most criticalsubunit for the assembly of vertebrate and S. cerevisiae ARP2/3(Mullins et al., 1997; Winter et al., 1999; Gournier et al.,2001). Consistent with its structural importance, loss of ArabidopsisARPC4 from cells had the most severe defects in the assemblyof ARP3-containing complexes (Fig. 7B). Interestingly, in arpc4,we failed to detect membrane-associated ARP2/3, even thoughthe membrane fraction was overloaded 20-fold compared with thesoluble fraction. In the arpc4 background, the overall levelof ARP3 was reduced compared with other genotypes (Fig. 7A,lanes 7 and 8). From this, it was apparent that ARP3 was notsufficient for membrane association; however, the reason fora reduced level of ARP3 in arpc4 is not obvious. In Acanthamoebaand Schizosaccharomyces pombe, ARP2/3 subunits are present atnearly equal stoichiometries (Kelleher et al., 1995; Wu andPollard, 2005). It is possible that the instability of freeARP2/3 subunits and/or subsets of partially assembled complexesmaintain equal subunit stoichiometries in the cell, and thereduced level of ARP3 in arpc4 reflects the extreme defectsin complex assembly. ARPC2 is a known core subunit of the complexthat forms a dimer with ARPC4 (Winter et al., 1999; Gournieret al., 2001). Genetic analyses in Arabidopsis suggest thatthe ARPC2-ARPC4 interaction is also important for ARP2/3 function(El-Assal et al., 2004b). Consistent with the behavior of yeastand human complex assembly, we found that removal of ARPC2 causeda severe shift of ARP3 toward lower molecular mass that wasmatched only by removal of ARPC4 (Fig. 7B). Combined with previousyeast two-hybrid data (El-Assal et al., 2004b), our data supporta conserved model for ARP2/3 assembly in plants in which theARPC2-ARPC4 dimer forms a seed around which the other subunitsassemble. The greatly increased solubility of ARP3 complexesin the arpc2 background is also consistent with the importanceof complex assembly for membrane association (Fig. 7A, lanes5 and 6).

Upon examination of additional ARP2/3 mutants, it quickly becameclear that membrane association did not simply correlate withthe sizes of ARP3-containing complexes. Removal of ARP2 hada subtle effect on the size of the complex (Fig. 7B), yet ARP3-containingcomplexes were mislocalized to the soluble fraction to a similarextent compared with arpc2 (Fig. 7A, lanes 3 and 4). Given thatthe resolution of our SEC column is approximately 70 kD, thebarely detectable shift was consistent with the selective lossof the 44-kD ARP2 subunit. Again, the effects of removal ofARP2 on complex assembly mirrors what has been observed in otherspecies. For example, for both the yeast (Winter et al., 1999; Nolen and Pollard, 2008) and human (Gournier et al., 2001)ARP2/3, loss of the ARP2 subunit does not affect the assemblyof any of the other subunits. Recently, mutant ARP2/3 from S.pombe lacking only ARP2 has been purified and crystallized,and removal of ARP2 has very subtle effects on the structureof the complex. However, the partial complex does not respondto nucleation-promoting factors and lacks significant actinfilament nucleation activity (Nolen and Pollard, 2008). Giventhe subtle effect of arp2-t1 null on complex assembly and itsrelatively strong effect on membrane association, coupled withthe fully membrane-associated status of the arp2-1-containingcomplex, our data suggest that the ARP2 subunit promotes membraneassociation. In the case of arpc5, we consistently detecteda more mild shift of ARP2/3 to the soluble fraction comparedwith the other mutants (Fig. 7A, lanes 9 and 10). Despite amolecular mass of only 15 kD for ARPC5, SEC analysis of thecomplex in the arpc5 background showed a broader distributiontoward a lower molecular mass (Fig. 7B). This suggests thatremoval of ARPC5 affects another subunit of the complex in Arabidopsis.

DISCUSSION

TOP
ABSTRACT
RESULTS
DISCUSSION
MATERIALS AND METHODS
LITERATURE CITED

Understanding the pathways leading to actin filament nucleationand the function of dynamic actin arrays are long-standing goalsin plant cell biology. WAVE-ARP2/3 is implicated as one nucleationpathway that has been adopted throughout the plant kingdom toregulate polarized growth (Frank and Smith, 2002; Le et al.,2003; Li et al., 2003, 2004; Mathur et al., 2003a, 2003b; Harrieset al., 2005), Suc signaling (Li et al., 2004; Zhang et al.,2008), and root nodulation (Yokota et al., 2009). In Arabidopsis,progress has been made in characterizing the regulation of ARP2/3:heteromeric complexes function in series to generate (SPIKE1)and translate (WAVE) activating Rho of plants small GTPase signalsinto an actin-based (ARP2/3) growth response (Basu et al., 2004, 2008). A key missing element of this pathway, and in the fieldof plant ARP2/3 in general, is biochemical proof of the complexand an understanding of its subcellular distribution. In thispaper, we provide genetic, biochemical, and cell biologicalevidence for the existence of plant ARP2/3. Interestingly, wefind that a large fraction of the ARP2/3 pool associates stronglywith cell membranes. Membrane binding is linked to the assemblyand subunit composition of the complex and not its presumedactin filament nucleation activity in the cell. These unexpectedresults suggest that the substrate for WAVE complex signalingis an organelle-associated pool of inactive ARP2/3.

These discoveries grew out of molecular genetic analyses ofArabidopsis ARPC4. In yeast and vertebrates, ARPC4 is a coresubunit of the complex, and gene disruption experiments in Physcomitrellapoint to its importance during tip growth (Perroud and Quatrano,2006). Our genetic analyses demonstrate that Arabidopsis ARPC4is a bona fide distorted group gene and that its in vivo functionis to regulate cell morphogenesis within the well-characterizedWAVE-ARP2/3 pathway. This conclusion is based on the identicalphenotypes of two independent arpc4 alleles and the abilityof ARPC4:HA to rescue arpc4 phenotypes (Fig. 4B). The identicalphenotypes of arpc4 plants and the four other known arp2/3 mutants(Le et al., 2003; Li et al., 2003; Mathur et al., 2003a, 2003b; El-Assal et al., 2004b) strongly suggest that ARPC4 is partof an ARP2/3 complex. ARPC4 shares a high degree of amino acididentity with its vertebrate orthologs and also retains a conservedinteraction with ARPC2 (El-Assal et al., 2004b). Our abilityto coimmunoprecipitate ARPC4:HA and ARP3 (Supplemental Fig.S1) and the strong effects of arpc4 on ARP2/3 assembly and stability(Fig. 7) also prove that ARPC4 is an ARP2/3 subunit.

The availability of an epitope-tagged ARPC4 subunit and a specificARP3 antibody allowed us to test directly for an ARP2/3 complexand to determine how complex assembly is linked to its subcellulardistribution. The results obtained with ARPC4:HA and endogenousARP3 are equally valid, because both probes monitor the behaviorof an ARP2/3 complex and not free subunits. First, SEC experimentsshowed clearly that ARPC4:HA and endogenous ARP3 are presentin high molecular mass complexes that have a mobility that isindistinguishable from yeast ARP2/3 (Fig. 4D). Importantly,we failed to detect a significant pool of monomeric ARPC4:HAor ARP3. In addition, we found that ARPC4:HA and endogenousARP3 had indistinguishable distributions in cell fractionationexperiments (Fig. 6A). The dependence of ARP3 membrane association(Fig. 7A) and complex assembly (Fig. 7B) on several other ARP2/3subunits provided strong proof that we are following the behaviorof a bona fide plant ARP2/3 complex.

Given the highly conserved and functionally interchangeableproperties of Arabidopsis, yeast, and human ARP2/3 subunits(Le et al., 2003; Mathur et al., 2003b), it is not surprisingthat the complex is detected (Fig. 4D) and that it shares acommon mechanism for assembly with the yeast and human complexes(Fig. 7B). However, we did not expect to find that a large poolof ARP2/3 associated with cell membranes (Fig. 6). To our knowledge,a large microsomal pool of ARP2/3 has not been previously reported.However, either direct or indirect associations of ARP2/3 withmembranes are expected given the wide variety of organelle-basedfunctions for the complex in eukaryotic cells (Eitzen et al.,2002; Fucini et al., 2002; Fehrenbacher et al., 2005; Kaksonenet al., 2005), and the often-observed punctate ARP2/3 localizationin mammalian cells reflects a cellular pool of membrane-associatedARP2/3 (Welch et al., 1997; Strasser et al., 2004; Shao et al.,2006). Microsomal ARP2/3 has been reported in plants using avariety of heterologous antibodies (Van Gestel et al., 2003;Fiserova et al., 2006), but the data are conflicting and theextent of membrane association depended on which ARP2/3 subunitantibody was used.

We determined conclusively that both the ARPC4-HA (Fig. 4C)and ARP3 detection was specific (Fig. 5A), but we wanted torule out the trivial explanation that the association of ArabidopsisARP2/3 with microsomes was due to denaturation of the complexor nonspecific trapping of the complex within F-actin networks.Nonspecific trapping cannot explain its strong association withmembranes, because only a small fraction of the soluble proteinPEPC was membrane associated. The complete solubilization ofARP3 in the arpc4 background also argues against a trappingartifact (Fig. 7A, lane 7). The membrane-associated complexis not a denatured aggregate, because the solubilized ARP2/3is cleanly resolved using SEC (Figs. 4D and 7B) and its migrationon the column is sensitive to the loss of individual ARP2/3subunits (Fig. 7B). Furthermore, the microsomal localizationis not caused by an association with actin filament networks,because the crude microsomes have no detectable phalloidin bindingand high concentrations of the F-actin-depolymerizing drug latrunculinB had no effect on the association of ARP2/3 with microsomes(Fig. 6B, lane 6). In addition, association of the complex withmembranes does not involve ARP2/3-generated actin filaments,because ARP2/3 has a normal membrane association in arp2-1 andsra1 extracts that contain inactive, fully assembled ARP2/3(Fig. 7).

Instead, we propose that the membrane association of plant ARP2/3reflects the activity of individual subunits within the complexand that membrane binding may have an in vivo relevance. Forexample, we find that, compared with the other arp2/3 mutants,the membrane association of ARP2/3 is least affected in thearpc5 background (Fig. 7A, lanes 9 and 10). The arpc5 line hasa weaker phenotype compared with all other ARP2/3 subunit mutants(Djakovic et al., 2006). In humans, ARPC5 is a peripheral ARP2/3subunit, and its removal yields a subcomplex with significantresidual nucleation activity (Gournier et al., 2001). Our SECdata are consistent with results obtained for human ARP2/3 assembly,in which ARPC5 recruits ARPC1 into the complex (Gournier etal., 2001). If the reduced mobility of mutant ARP2/3 in arpc5predominantly reflects the loss of ARPC1 as well, our data suggestthat neither ARPC5 nor ARPC1 is essential for efficient membraneassociation. Because thresholds of ARP2/3 activity define thephenotypic severity in Arabidopsis distorted mutants (Zhanget al., 2008), arpc5 cells may contain partial complexes thatretain significant residual membrane-binding and actin filamentnucleation activity. The other arp2/3 subunits likely fall toofar below the activity threshold to generate a leaky phenotype.

The availability of a collection of WAVE and ARP2/3 subunitmutants allowed us to dissect the mechanisms of membrane association.ARP2/3 partitioning into a microsomal fraction is not linkedto its ability to be activated. For example, in the sra1 background,the putative WAVE complex protein NAP1 and the activator SCARare present (Le et al., 2006), but WAVE does not positivelyregulate ARP2/3 (Basu et al., 2004). We confirm here that insra1, it is the activity of ARP2/3 that is affected, ratherthan its assembly (Fig. 7). Despite its inactive status in sra1,the association of ARP2/3 with microsomes in this mutant backgroundis indistinguishable from the wild type (Fig. 7A, lanes 11 and12). Likewise, in the arp2-1 (G151D) background, it is the activityand not the assembly of the complex that is clearly affected(Fig. 7), and the mutant complex localizes normally to the microsomalfraction.

Instead, we find that the association of ARP2/3 with membranescorrelates with the assembly status and subunit compositionof the complex. Interestingly, Arabidopsis ARPC4, like its yeastand human orthologs (Winter et al., 1999; Gournier et al., 2001), is the most critical subunit for complex assembly. In arpc4,partial complexes are found solely in the soluble fraction (Fig. 7). We propose that the complete shift of ARP3 to the solublefraction in arpc4 (Fig. 7A, lanes 7 and 8) is caused by catastrophicdisassembly of the complex and the failure of ARP3 to associatewith other subunits that recruit it to a membrane surface. Theincreased solubility of ARP3 and the severe decrease in themass of the complex in arpc2 can also be understood in the contextof defective complex assembly (Fig. 7, A, lanes 5 and 6, andB). Assembly defects correlate with ARPC2's known function asan ARPC4-binding partner (El-Assal et al., 2004b) and a coresubunit for the assembly of yeast and vertebrate ARP2/3 complexes(Winter et al., 1999; Gournier et al., 2001; Robinson et al.,2001).

It is possible that individual ARP2/3 subunits mediate interactionswith membranes. Our data point to the involvement of ARP2. Inarp2 null strains, partial complexes have a small but detectabledecrease in size that is consistent with the selective lossof the ARP2 subunit (Fig. 7B). This result is consistent witha comparative x-ray crystallography study in S. pombe, in whichloss of ARP2 does not affect the recruitment of the other subunitsinto the complex and the lack of ARP2 has subtle effects onthe overall structure of the ARP2-lacking complex (Nolen andPollard, 2008). In the Arabidopsis arp2-t1 background, the complexesare shifted to the soluble fraction to a similar extent comparedwith arpc2 (Fig. 7A, lanes 3 and 4). The strong membrane associationof the arp2 (G151D) point mutant compared with the weak bindingof the arp2-t1 null allele indicates that ARP2 participatesin membrane association, either by direct lipid-binding activityor by interaction with some other membrane-associated proteinthat recruits the complex to an organelle surface. Alternatively,loss of ARP2 may cause general conformational changes in themutant complex that greatly reduce membrane association.

A Cellular Context for the Membrane Association of ARP2/3

The results described above begin to provide some useful cluesabout the regulation of ARP2/3 in plant cells. In tip-growingcells in moss, highly polarized cell types concentrate ARP2/3in broad regions of the apex that support tip growth, and thislocalization likely requires WAVE complex activity (Perroudand Quatrano, 2008). If our Arabidopsis data reflect generalfeatures of ARP2/3 in plants, the results suggest that localizedaccumulation of ARP2/3 may not be due to the local capture andactivation of ARP2/3 from a large soluble pool. Instead, combinationsof actomyosin-based transport of ARP2/3-containing organellesand the lipid-binding specificity of ARP2/3-containing complexesmay regulate localization and could explain the reported punctatelocalization of ARP2/3 on actin bundles (Fiserova et al., 2006; Maisch et al., 2009). The membrane association of ARP2/3 mayhave advantages. In large cells, especially highly vacuolatedplant cells, diffusion of soluble ARP2/3 may not be an effectivesolution to distribute and locally activate the complex.

Positive regulation of ARP2/3 by SCAR and the SPIKE1-WAVE pathwaypresents an additional layer of complexity (Basu et al., 2005, 2008). It will be important to clearly identify the organellesand subcellular locations that contain active pools of ARP2/3in plant cells. Probes for WAVE complex proteins may be usefulin this regard (Dyachok et al., 2008). Although the microsomeassociation of ARP2/3 is somehow linked to its assembly status,it does not equate to an active pool. Our crude estimates indicatethat actin and ARP2/3 are at an approximately 5:1 molar ratioin plant extracts (Fig. 5, B and C). Yet, arp2/3 null mutantshave very subtle F-actin phenotypes and no obvious effect onthe total amount of F-actin in the cell (Mathur et al., 1999; Szymanski et al., 1999; Le et al., 2003). A simple explanationmay be that only a small fraction of the total ARP2/3 pool isactive at a given moment and particular subsets of ARP2/3-dependentcortical and/or organelle-associated actin filaments are criticalduring morphogenesis. Perhaps a latent, distributed pool ofARP2/3 is important to the cell, and the function of SPIKE1and the WAVE complex is to regulate the location, timing, andextent of activation. It remains to be determined if ARP2/3cycles between membrane compartments and how such an activitymight impact so many aspects of plant morphogenesis.

MATERIALS AND METHODS

TOP
ABSTRACT
RESULTS
DISCUSSION
MATERIALS AND METHODS
LITERATURE CITED

Plant Strains, Growth Conditions, and Mutant Characterization

The SALK T-DNA insertion lines for Arabidopsis (Arabidopsisthaliana) ARPC4, AT4G14147 (arpc4-t1, SALK_073297; arpc4-t2,SALK_52687), were obtained from the Arabidopsis Biological ResourceCenter. Both were backcrossed to the wild type two times priorto their use. The arpc2/dis2-1 (El-Assal et al., 2004b), arp3/dis1-1(Le et al., 2003), arp2/wrm1-t1 (Le et al., 2003), arp2/wrm1-1(Mathur et al., 2003a), arpc5/crk-1 (Mathur et al., 2003b),and sra1/pir-3 (Basu et al., 2004) alleles have been previouslydescribed. For all experiments, the Columbia (Col-0) backgroundwas used as the wild type. The soil-grown plants were plantedin SunGro Redi-earth plug and seedling mix series growth medium(SunGro Horticulture) that was overlaid on an equal volume ofvermiculite under continuous illumination (110 mmol photonsm^–2 s^–1) at 24°C. The trichome morphometry datawere collected using soil-grown plants. Aseptically grown plantswere seeded on half-strength Murashige and Skoog plates with1% Suc under continuous illumination (110 mmol photons m^–2s^–1) at 22°C. Dark-grown plants were grown asepticallyand wrapped with three layers of aluminum foil. T-DNA insertionsin the ARPC4 gene were confirmed by PCR using primer pair sequencesas described in Supplemental Table S1. To analyze the expressionof the ARPC4 gene in mutant backgrounds, total RNA was extractedfrom the homozygous T-DNA insertion mutants by TRIzol reagent(Molecular Research Center) and then reversed transcribed asdescribed previously (Zhang et al., 2008). Thereafter, the cDNAwas used as the template for PCR using ARPC4 cDNA-specific primers(Supplemental Table S1).

Generation of the ARPC4:HA Rescue Construct

To generate the arpc4-t1 rescue line, an ARPC4 genomic fragmentwas first engineered to contain a unique NotI site prior tothe stop codon. The upstream gene fragment was amplified usingPfu Turbo using the primers C4F1 and C4R1 (Supplemental TableS1) and cloned into the vector pCRTOPOII (Invitrogen) to yieldpARPC4A. The downstream fragment was amplified using the primersC4F2 and C4R2 (Supplemental Table S1) and cloned into the vectorpCRTOPOII to yield pARPC4B. The sequences of both fragmentswere confirmed by sequencing. The NotI-EcoRI fragment of pARC4Bwas cloned into pARPC4A, and the modified ARPC4 locus with theintroduced NotI site was cloned into pCB302m vector as a SacII/EcoRIfragment. The resulting ARPC4 genomic clone was then engineeredto contain a triple HA epitope tag at the extreme C terminus,yielding the plasmid pCB302m-ARPC4:HA, by cloning a triple HA-encodingEagI fragment into the NotI site of this plasmid to yield pCB202-ARPC4-HA.The plasmid was used to transform arpc4-t1 plants using thefloral dip method (Clough and Bent, 1998).

Microsome Preparation and Analysis of Membrane Association

The microsomal protein fraction was isolated by Polytron homogenizationof 2 g of seedlings (20 d after germination) in 10 mL of microsomeisolation buffer [MIB; 20 mM HEPES/KOH, pH 7.2, 50 mM KOAc,2 mM Mg(OAc)₂, 250 mM sorbitol, 1 mM EDTA, 1 mM EGTA, 1 mM dithiothreitol,1 mM phenylmethylsulfonyl fluoride, and 1% (v/v) protease inhibitors;Kang et al., 2001]. The homogenate was filtered through a prewetteddouble layer of Miracloth and centrifuged at 4°C for 30min as described in the figure legends. Measurements of thefraction of endogenous and HA-tagged ARP2/3 that was solubleversus membrane associated were done by western-blot analysisof equal proportions of the cell fractions that were generatedby differential centrifugation. In the experiments that testedfor peripheral membrane association and the effects of arp2/3mutants on the solubility of the complex, the filtered celllysate was ultracentrifuged (200,000g, 4°C, 1 h) to generatesupernatant and pellet fractions. The resulting pellet was suspendedin 10 mM Tris-HCl/KOH, pH 7.5, 150 mM NaCl, 1 mM EDTA, 10% (v/v)glycerol, 1 mM phenylmethylsulfonyl fluoride, and 1% (v/v) proteaseinhibitors. For the experiments that assayed the effects ofloss of ARP2/3 subunits on membrane association, the membranefraction was overloaded approximately 20-fold compared withthe soluble fraction.

SDS-PAGE, Antibodies, and Immunoblotting

For immunoblotting, the proteins were separated by SDS-PAGEand transferred to a nitrocellulose membrane (Schleicher &Schuell) in 38.6 mM Gly, 48 mM Tris, 1.3 mM SDS, and 20% (v/v)ethanol. Immunoblots were incubated in 3% (w/v) milk in TBS-T(50 mM Tris, pH 7.5, 150 mM NaCl, and 0.01% [v/v] Tween 20).For anti-HA blots, Tween 20 was not included. Primary antibodies,anti-ARP3, anti-HA (monoclonal HA.11), anti-ACTIN (a kind giftfrom Chris Staiger), and anti-PEPC (Rockland Immunochemicals;1:1,000 dilution) were added and incubated overnight at 4°C.The primary antibodies were detected with horseradish peroxidase-conjugatedgoat anti-rabbit antibodies (1:50,000 dilution; Pierce). Anti-ARP3antibody was raised in rabbits using full-length His-taggedArabidopsis ARP3 expressed in Escherichia coli as the antigen(Harlan Bioproducts for Science).

CoIP

For coIP, the 20,000g pellet fraction was resuspended at a finalprotein concentration of 1 mg mL^–1 in 20 mM HEPES/KOH,pH 7.2, 1 mM EDTA, and 1 mM dithiothreitol and solubilized with4% cholate (Sigma-Aldrich) for 30 min at room temperature. Theextract was clarified by ultracentrifugation (200,000g, 4°C,30 min). The solubilized and clarified extract (300 µg)was added to 200 µL of coIP buffer (20 mM HEPES/KOH, pH7.2, 150 mM NaCl, 1% Nonidet P-40, and 0.1% SDS) containing15 µg of anti-ARP3 or preimmune serum bound to proteinA beads (Pierce). The reactions were rocked at 4°C for 16h, and the protein A beads were washed using immunoprecipitationwash buffer (20 mM HEPES/KOH, pH 7.2, 150 mM NaCl, 1% NonidetP-40, and 0.1% SDS) six times and probed with anti-HA antibody.

Quantification of Endogenous Actin and ARP3 Protein Content

To estimate the amount of actin and ARP3 protein in Arabidopsiscell extracts, known amounts of ARP3 inclusion body and vertebrateG-actin were run via SDS-PAGE along with plant protein extract,blotted with anti-ARP3 and anti-ACTIN antibody, respectively,and quantified by densitometry using ImageQuant 5.2. The purifiedvertebrate actin standard was quantified by UV light absorbance.The ARP3 inclusion body standard was quantified by densitometryreadings of Coomassie Brilliant Blue-stained SDS-PAGE gels containingARP3 inclusion body bands compared with dilutions of known amountsof vertebrate actin and bovine serum albumin standards run onthe same gel. Nearly identical results for ARP3 inclusion bodyconcentration were obtained in both cases. The linear regressionanalysis from western-blot data of the actin and ARP3 standardswas used to estimate the protein content of actin and ARP3 inplant extracts.

F-Actin Localization

F-actin localization and quantification were done accordingto Le et al. (2003). Images were collected using an MRC Bio-RadRadiance 2100 confocal microscope with a Nikon 60x PlanApo (numericalaperture 1.2) water-immersion objective. The images were processedand analyzed using Metamorph (Universal Imaging) or ImageJ (http://rsb.info.nih.gov/ij) software. Criteria to score brancheswith aligned bundles have been described previously (Basu etal., 2005; Zhang et al., 2008); such branches were defined asthose branches that contained more than three bundles that terminatedwithin 3 µm of the branch apex and that were aligned clearlywith the long axis of the branch.

SEC

For SEC, microsomal fractions from the wild type and differentdistorted mutant backgrounds were solubilized in 4% cholateand separated on a Sephadex 200HR 10/300 column (GE Healthcare)as described previously (Basu et al., 2008). Briefly, 200-µLcolumn fractions were collected, TCA precipitated in the presenceof 0.01% deoxycholate, and analyzed by western blotting usinganti-ARP3 or anti-HA antibodies. For the size distribution ofARPC4:HA-containing complexes, SEC employed extracts that wereisolated from arpc4-t1 ARPC4:HA-rescued plants. Endogenous ARP3-containingcomplexes were analyzed using extracts from wild-type and mutantplants as described above. Yeast ARP2/3 was isolated from thestrain DDY2920, a kind gift from David Drubin. In this strain,the ARPC3/ARC18 subunit is tagged with an HA epitope. Yeastcells were lysed using glass beads in MIB, and the cytosolicfraction was analyzed using SEC as described above.

Supplemental Data

The following materials are available in the online versionof this article.

Supplemental Figure S1. ARPC4-HA and ARP3 proteinsare associatedwith each other in vivo.

Supplemental TableS1. Sequences of oligonucleotide primersused in this work.

ACKNOWLEDGMENTS

We are grateful to David Drubin for the kind gift of an ARPC3:HA-taggedyeast strain and to Chris Staiger for his gift of the actinantibody. Thanks also to the Purdue Cytoskeleton Group for helpfulinput during the execution of this project.

Received July 7, 2009; accepted September 28, 2009; published October 2, 2009.

FOOTNOTES

¹ This work was supported by the National Science Foundation (grantnos. IPB 0110817IBN and MCB 0640872IBN to D.B.S.).

The author responsible for distribution of materials integralto the findings presented in this article in accordance withthe policy described in the Instructions for Authors (www.plantphysiol.org)is: Daniel B. Szymanski (dszyman{at}purdue.edu).

^[W] The online version of this article contains Web-only data.

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^{^*} Corresponding author; e-mail dszyman{at}purdue.edu.

LITERATURE CITED

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ABSTRACT
RESULTS
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MATERIALS AND METHODS
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