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First published online 31 January 2007
doi: 10.1242/dev.02792
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1 University of Köln, Botanical Institute III, Gyrhofstr. 15, 50931
Köln, Germany.
2 The Integrative Cell Biology Laboratory, School of Biological and Biomedical
Sciences, University of Durham, South Road, Durham DH1 3LE, UK.
3 School of Biosciences, Division of Molecular Cell Biology, University of
Birmingham, Birmingham B15 2TT, UK.
Author for correspondence (e-mail:
martin.huelskamp{at}uni-koeln.de)
Accepted 19 December 2006
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SUMMARY |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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Key words: ARP2-ARP3, Actin, SCAR/WAVE, Trichomes, Arabidopsis
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INTRODUCTION |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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;
Smith, 2003). Recently it was
shown that one of the key regulators of actin organisation, the ARP2-ARP3
complex, is required for higher plant development
(El-Assal et al., 2004b;
Le et al., 2003;
Li et al., 2003;
Mathur et al., 2003a;
Mathur et al., 2003b;
Saedler et al., 2004a). In
animals and yeast this complex consists of seven subunits, two subunits that
are related to actin (ARP2, ARP3) and five additional components (ARPC1-C5)
(Machesky and Gould, 1999).
The activated ARP2-ARP3 complex binds to existing actin filaments and
initiates the formation of new filaments
(Amann and Pollard, 2001;
Blanchoin et al., 2000). This
in turn creates a dynamic branched network of filamentous actin that is
thought to drive the formation of local membrane protrusions. Consistent with
this, the ARP2-ARP3 complex and its regulators are localised to mammalian
lamellipodia (Machesky, 1997)
and other actin-driven cell extensions. Recent work has revealed in some
detail the role of the ARP2-ARP3 complex in early endocytotic events in yeast,
where cortical actin patches generated by ARP2-ARP3 complex activity guide
endocytotic internalisation (Kaksonen et
al., 2003). The ARP2-ARP3 complex is required for related
processes in animals and protists (Insall
et al., 2001; Merrifield et
al., 2004), and is also utilised in some instances for organelle
motility (Chang et al.,
2003).
In plants, mutant phenotypes have been described for mutations in ARP2,
ARP3, ARPC2 and ARPC5. Consistent with a function of the
ARP2-ARP3 complex in generating new branched actin networks, all four mutants
display F-actin organisational phenotypes
(Mathur et al., 1999;
Schwab et al., 2003;
Szymanski et al., 1999). The
four mutants belong to a class of eight trichome mutants that has been
collectively called the `distorted' group due to their uncoordinated trichome
cell expansion phenotype (Hulskamp et al.,
1994). A more detailed phenotypic analysis of the arp2
mutants revealed defects in additional cell types. Elongating hypocotyl cells
tear out of the epidermal cell layer and may bend outwards when rapid cell
expansion is triggered by dark growth conditions
(El-Assal et al., 2004b;
Le et al., 2003;
Mathur et al., 2003a;
Mathur et al., 2003b;
Saedler et al., 2004a).
Normally, pavement cells form many lobes that tightly interlock to form a
continuous leaf epidermal surface. ARP2-ARP3 complex mutations and
mutations of ARP2-ARP3 complex regulators affect the development of leaf
epidermal lobes by reducing the ability of lobes to intercalate and adhere
(Basu et al., 2004;
El-Assal et al., 2004a;
Frank et al., 2003;
Le et al., 2003;
Li et al., 2004;
Mathur et al., 2003a;
Mathur et al., 2003b;
Saedler et al., 2004a;
Zimmermann et al., 2004).
Tip-growing root-hair cells show reduced or wavy growth in arp2 and
arpc5 mutants when root hairs are challenged to elongate rapidly
(Li et al., 2003;
Mathur et al., 2003b).
In the absence of ARP2-ARP3 complex activity, plants grow fairly normally
and complete their life cycle, indicating that the ARP2-ARP3 complex has
special regulatory functions in some cell types rather than an essential role
in all actin-related processes. This raises the question of how the activity
of the ARP2-ARP3 complex is regulated. Recent reports indicate that a
regulatory pathway similar to that known in animals is also operating in
plants. In animals and Dictyostelium, the SCAR/WAVE (suppressor of
cAMP receptor from Dictyostelium/Wiskott-Aldrich syndrome
protein-family verprolin-homologous protein) complex regulates ARP2-ARP3
complex activity (Machesky and Insall,
1998; Machesky et al.,
1999). The small GTPase RAC1 binds to the pentameric
SRA1-NAP1-ABI-SCAR-HSPC300 complex and either triggers the dissociation of the
SRA1-NAP1-ABI complex from the SCAR-HSPC300 subcomplex
(Eden et al., 2002) or
activates the complete complex (Innocenti
et al., 2004). The SCAR subunit in turn binds and activates the
ARP2-ARP3 complex.
Two of the eight Arabidopsis `distorted' genes encode SRA1 and
NAP1. The corresponding mutants show an aberrant actin phenotype and affect
the same cell types as the arp2-arp3 complex mutants except for the
root hairs, indicating that they regulate most aspects of the ARP2-ARP3
complex function (Basu et al.,
2004; Brembu et al.,
2004; Deeks et al.,
2004; El-Assal et al.,
2004a; Saedler et al.,
2004b; Zimmermann et al.,
2004). Recently it was shown that HSPC300 is conserved in plants
(as BRICK1, BRK1), and the analysis of the corresponding maize and
Arabidopsis mutants also revealed a distorted phenotype and an
involvement in the regulation of actin
(Djakovic et al., 2006;
Frank and Smith, 2002;
Le et al., 2006). Least is
known about the direct activators of the Arabidopsis ARP2-ARP3
complex, the AtSCAR proteins. Five putative SCAR homologues are present in
Arabidopsis (Brembu et al.,
2004; Frank et al.,
2004). They all share a SCAR homology domain (SHD) and in
addition, four of them share a VCA (verprolin homology-central-acidic) domain.
Frank and co-workers showed that ZmSCAR1, AtSCAR3 and AtSCAR4 can activate the
ARP2-ARP3 complex in vitro and that AtSCAR1 and AtSCAR3 bind to the
Arabidopsis HSPC300 homologue. Thus, the biochemical evidence
indicates that SCAR homologues act in the ARP2-ARP3 activation pathway.
Recently two publications reported that mutations in the AtSCAR2 gene
result in a similar range of phenotypes to arp2-arp3 complex mutants
(Basu et al., 2005;
Zhang et al., 2005a). Also the
regulation of the multimeric SRA1-NAP1-ABI-SCAR-HSPC300 complex might be
conserved as Arabidopsis PIR121 interacts with ROP2
(Basu et al., 2004). ROP2 is
one of 11 small Rac-like GTPases found in plants. ROPs form a unique class and
have therefore been termed `Rho proteins of
Plants' (Vernoud et al.,
2003; Yang, 2002;
Zheng and Yang, 2000).
In this study we analyse the role of the five Arabidopsis SCAR
homologues in ARP2-ARP3 complex-dependent actin regulation. Only
atscar2 mutants but none of the other four atscar mutants
show `distorted'-related phenotypes. Our double-mutant analysis revealed that
AtSCAR4 and AtSCAR2 act redundantly. The detailed analysis
of protein-protein interactions by two-hybrid analysis revealed a complex
interaction network including not only interactions already known from other
species but also new ones. Supported by Bimolecular Fluorescence
Complementation (BiFC) analyses of protein interactions in vivo
(Walter et al., 2004), we
provide evidence that SPIKE1 interacts with several members of the
Arabidopsis SCAR and ABI protein families, and that AtSCAR2 interacts
directly and specifically with the activated form of ROP7 at the plasma
membrane.
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MATERIALS AND METHODS |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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To confirm the T-DNA insertions in the AtSCAR genes, PCRs on genomic DNA with the following primers were carried out:
AtSCAR1: GK_447E03: 447E03_fw (5'-CCACTGTTGCTCAGACA-TTGAC-3'), 447E03_rev (5'-GTGCTGCTACATCAGAGCTAC-3') and the T-DNA specific primer 8409.
AtSCAR2: SALK_039449: LP_39449 (5'-TATGGCTGGTCTCGTTGGCAT-3'), RP_39449 (5'-CACATTCAAAACACCATGAGCA-3'); SALK_036419: LP_36419 (5'-CCACCATGGAGTCGGAAACAG-3'), RP_36419 (5'-GGCAACGACCATCACGTTCTT-3'); SALK_57481: LP_57481 (5'-TGGAATCCGTTGTTGTAAAGCG-3'), RP_57481 (5'-GGTGTCCCTCCATTCCTCCAC-3'); SALK_36419: LP_36419 (5'-CCACCATGGAGTCGGAAACAG-3'), RP_36419 (5'-GCAACGACCATCACGTTCTT-3'); SALK_124023: LP_124023 (5'-CGGGAGTAGAGAAATTGGCGG-3'), RP_124023 (5'-GCTCTGATGGTGGAGACCCAA-3') and the T-DNA specific primer LBb1.
AtSCAR3: SALK_087926: LP_087926 (5'-GCTGGGAAAAGGATTAGGAGAA-3'), RP_087926 (5'-AAATTTTTGTTGCAAGTTAATTGAT-3'); SALK_630493: LP_630493 (5'-GCAAATGTCTTCCTGGAGTGA-3'), RP_630493 (5'-TGTCTTGACCCAAGGTGTCTG-3') and the T-DNA specific primer LBb1.
AtSCAR4: SALK_616410: LP_616410 (5'-CATGTGATGTCCGTGAATCCT-3'), RP_616410 (5'-CTATGGAATCAATCCCTTGGC-3'); GK_126B09: 126B09_fw (5'-GGCCAGTCTGGTTATCGTGATCG-3'), 126B09_rev (5'-CCAGGATTTGGTCAGCCGCAG-3') and the T-DNA specific primers LBb1 (SALK) and 8409 (GK).
AtSCAR-like: SALK_555413: LP_555413 (5'-GAGCGCTGACTCTATCCGTCT-3'), RP_555413 (5'-CTCTGTTTCATTTCTGCTGCG-3'); SALK_504474: LP_504474 (5'-GTGCTTCACTTTGTTCTTGCG-3'), RP_504474 (5'-GTAGGCTCTGAGTGGCATCCT-3'); GK_411H03: 411H03_fw (5'-CATCAGATTCCCACAGCTCAG-3'), 411H03_rev (5'-GAAGGTGAAGTACATAATGAGCC-3') and the T-DNA specific primer LBb1 (SALK) and 8409 (GK). The PCR products were sequenced and the exact positions of the inserts determined.
Constructs and recombinant DNA
Full-length cDNAs encoding the proteins investigated in this study were
amplified by PCR using primers containing attB1 and attB2 sites for GATEWAY
recombination as described by Invitrogen. PCR products were recombined into
pDONR201 (Invitrogen), and the resulting clones were further transferred to
yeast two-hybrid vectors (pAS-attR and pACT-attR; J.F.U., unpublished), and to
BiFC vectors (pBatTL; J.F.U., unpublished) by GATEWAY recombination
(Invitrogen). Details of the numerous constructs and primers will be provided
on request. The cDNA encoding the N-Terminal 346 amino acids of AtSCAR2, which
contains the SCAR homology domain, was amplified with the primers WAVE4_fw
(see above) and WAVE4_F1_rev (5'-attB2-tcatCCA
CGGACCTCATTGTATGTAG-3'). For protein expression, the C-terminal fragment
of AtSCAR2 encoding the last 153 amino acids containing the VCA domain was
amplified using the primers 384VCAGATF (5'-attB1
TCCCTGATGCTTCAAATGCAGAAACTG-3') and 384VCAGATR
(5'-attB2-GATTTCAAGAATCACTCCAACTATCTG-3'). A C-terminal fragment
encoding the last 236 amino acids of AtSCAR2 containing the VCA domain was
amplified for use in yeast two-hybrid assays using the primers WAVE4_rev
(5'-attB2-tTCAAGAATCACTCCAACTATCTG-3') and WAVE_F2_fw
(5'-attB1-CCTTATCAGGAGTGCATAGAGG-3').
The amplified cDNAs were inserted into pDONR201 or pDONR207 (Invitrogen).
For localisation and rescue experiments, SCAR2 cDNA
(Deeks et al., 2004) was
transferred to GFP vector pMDC43 (Curtis
and Grossniklaus, 2003) to form a GFP-SCAR2 fusion. Functionality
of the GFP-SCAR2 fusion protein was proven by rescue of the scar2
mutant. Rescued plants were verified by testing homozygosity of the
scar2 mutant alleles and the presence of the rescue construct.
Analysis of gene expression
Total RNA was isolated by using TRI reagent (Molecular Research Centre)
from the following tissues of wild-type Arabidopsis plants:
seedlings, roots, rosette leaves, cauline leaves, stems and inflorescence. RNA
was treated with DNaseI (MBI). First strand cDNA was then synthesised with the
RevertAid H-Minus First Strand cDNA Synthesis Kit (MBI).
A total of 33 cycles of PCR were performed with the indicated primers. Different dilutions of cDNA preparations were amplified with actin-specific primers to yield equal amounts of cDNA for each tissue. The normalised dilutions were then used for amplification with AtSCAR/WAVE-specific primers. The following primers were used for expression analysis: wave1-fw (5'-TTCGGAAATAAGTAGTGGCACTCATAG-3'); wave1-rev (5'-CCTCTTGCTTTCTCGGATACCTTCTG-3'); wave2-fw (5'-TGGTCGGGAGATTGTGGGAG-3'); wave2-rev (5'-TCCTTTCTGCGGAAACCACTAG-3'); wave3-fw (5'-CCACAGGACGCATATGAGGG-3') wave3-rev (5'-GGCCAATCCGTCTTCCAGACA-3'); wave4-fw (5'-ACCAGCCACCATGGAGTCGGAAAC-3') wave4-rev (5'-CCTTTCTTCCATCATTGCCTCCCT-3') wave5-fw (5'-CCTATATAGCCCCTCAGAAGACCTACTTGTGC-3') wave5-rev (5'-GCATCTTTCAGAGACGGGCATGAGAT-3').
cDNA isolated from each of the atscar and atscar-like mutants was treated in the same manner. The normalisation of cDNA was done by performing PCR with elongation factor 1-specific primers. The equally concentrated dilutions of cDNA were used to carry out the expression analysis of AtSCAR and AtSCAR-LIKE in each of the mutant alleles. The following primers were used to amplify a fragment 3' of the T-DNA insertion (42 cycles):
AtSCAR1: fw (5'-CAGAAGCTGGAGACTTCTTGC-3'), rev (5'-GAGAGACTCGAGATCATGTGTCGCTATCGCTCCATG-3').
AtSCAR2: fw (5'-ACCAGTGAGGCTGACAATTATGTGGACG-3'), rev (5'-AAACTTCCATCCCCACCCCAGCTG-3').
AtSCAR3: fw (5'-GCATGGTGACTTCTGCTCC-3'), rev (5'-GAGAGACTCGAGATTACGTATCACTCCATGTATCGC-3').
AtSCAR4: fw (5'-GAGCCTCAGGTTGATCACC-3'), rev (5'-GAGAGAGCGGCCGCACTCACTCGCTCCAGCTATCTG-3').
AtSCAR-LIKE: fw (5'-CCTATATAGCCCCTCAGAAGACCTACTTGTGC-3'), rev (5'-GCATCTTTCAGAGACGGGCATGAGAT-3').
Protein expression
The AtSCAR2 VCA domain was transferred using LR enzyme mix into GST fusion
vector pGEX-4T-1 (Amersham) containing the gateway cassette (Invitrogen). This
plasmid was transformed into Escherichia coli BL21 DE3 pLysS Rosetta
2 expression cells (Novagen). Cells were induced with IPTG at a final
concentration of 1 mM at 37°C for 3 hours. GST-tagged protein was
recovered using glutathione sepharose 4B (Amersham) and dialysed against
G-buffer. After buffer exchange the protein was snap-frozen in liquid nitrogen
and stored at -80°C.
Actin polymerisation assays
Polymerisation assays were performed using 4 mM actin in G-buffer (2 mM
Tris-HCl pH 8, 0.5 mM DTT, 0.2 mM CaCl2, 0.2 mM ATP, 0.02 %
NaN3) with 10 % of monomers pyrenelated. Bovine ARP2-ARP3 was
supplied by Cytoskeleton (Denver, CO, USA), and handled according to the
manufacturer's instructions. Polymerisation was induced by the addition of
10x KME (500 mM KCl, 10 mM MgSO4, 10 mM EGTA, 100 mM
Imidazole pH 6.5). Pyrene fluorescence was monitored using a PTI
spectrofluorimeter equipped with a rotating multi-sample turret. For a general
description of this method, see Mullins and Machesky
(Mullins and Machesky,
2000).
Particle bombardment
Particle bombardment was carried out using a helium Helios gene gun
(BIO-RAD, Hercules, CA, USA). Microcarriers of 1.0 µm diameter were
prepared for DNA coating by washing several times with 70% ethanol and
resuspending in a 50% v/v glycerol solution. The microcarriers were then
coated with 1 mg of plasmid per 0.5 mg of gold (equivalent to one cartridge)
as described by Kemp et al. (Kemp et al.,
2001). Helium at a pressure of 150 psi was used for microcarrier
acceleration. The bombarded cells were then placed at 22°C in an
illuminated growth chamber and analysed after 24 hours.
Cell culture, protoplasting and transfection
Arabidopsis cell suspension culture (Columbia ecotype; grown in MS
medium supplemented with 0.5 mg/L NAA and 0.1 mg/L KIN) was maintained as
described previously (Mathur and Koncz,
1998a). Protoplast isolation and polyethylene glycol-mediated
transfection was performed according to Mathur and Koncz
(Mathur and Koncz, 1998b). The
transfected cells were incubated at 23°C for 16 hours in the dark before
microscopic observation.
Yeast transformation and yeast two-hybrid assays
Yeast strains AH109 (Halladay and
Craig, 1996) and Y187 (Harper
et al., 1993), were maintained in standard yeast full media or
selective dropout media (Clontech) using standard conditions. Transformation
of plasmids into yeast was done according to the LiAc transformation method
(Gietz et al., 1995).
Interaction of hybrid proteins was tested by crossing singly transformed cells
or by co-transformation of yeast cells with subsequent plating onto synthetic
dropout medium lacking leucine and tryptophan and onto synthetic dropout
medium lacking leucine, tryptophan and histidine supplemented with 3-20 mM
3-aminotriazole (3-AT) (Sigma-Aldrich, Munich, Germany). Recombinant hybrid
proteins were tested for self-activation and nonspecific protein-binding
properties. The adequate 3-AT concentrations suppressing unspecific reporter
activation were determined individually for every bait construct.
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RESULTS |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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In a previous study it was shown that AtSCAR2 is normally only
expressed in cotyledons, siliques and rosette leaves but not in flower buds or
roots (Frank et al., 2004). In
our hands, AtSCAR2 expression was found in all tissues analysed
including the root, the cotyledons, the stem, the rosette leaves, the cauline
leaves and the inflorescence (Fig.
1B). In addition the expression profiles of the other
Arabidopsis SCAR homologues were different to that previously
published (Fig. 1B). In
particular, we found that all Arabidopsis SCAR homologues are
expressed in roots. In addition we showed that AtSCAR1 transcript is
specifically absent in seedlings and that AtSCAR-LIKE is absent in
the stem.
Phenotypic analysis of atscar and atscar-like mutants
In order to test whether the four AtSCAR genes and
AtSCAR-LIKE gene are involved in ARP2-ARP3 complex-dependent cell
morphogenesis, we analysed cell types known to be affected in
arp2-arp3 complex mutants including trichomes, epidermal pavement
cells, root hairs and hypocotyls cells.
All three atscar2 alleles analysed in this study exhibited a weak
distorted phenotype reminiscent of arp2-arp3 complex mutant
trichomes. Branches of atscar2 trichomes are often twisted and
variable in length (Fig. 2A-F).
The effect on branch formation was studied using the criteria developed in
Zhang and co-workers (Zhang et al.,
2005b). The branch positioning defect was quantified by measuring
the distance between the first and the second branch point of 100 trichomes of
ten leaves in each mutant line. Also, the relative arrangement of
atscar2 branches was affected
(Fig. 2D,E,F) in a manner
similar to arp2-arp3 complex mutants
(Basu et al., 2005). In
wild-type trichomes, the second branch is found on average 11 µm above the
first branching point. In the three alleles of atscar2 analysed in
more detail, SALK-039449 (scar2-1), SALK-036419 (scar2-2)
and SALK-124023 (scar2-3), the branch point was found 34, 33 and 31
µm above the first branching point. Using the Student's t test we
confirmed that the interbranch zone lengths of the three mutants are
significantly different from wild type (P=0.0001, t=9.27).
This indicates that the relative positions of branch points are affected in
atscar2 mutants. The distance between the two branch points in the
mutant lines of the other three AtSCAR genes and AtSCAR-LIKE
was not significantly different from wild type
(Fig. 2Q).
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;
Frank et al., 2003;
Li et al., 2003;
Mathur et al., 2003a;
Mathur et al., 2003b;
Saedler et al., 2004a;
Saedler et al., 2004b) or
cell-cell adherence following lobe intercalation
(Basu et al., 2004;
El-Assal et al., 2004b;
Le et al., 2003).
Surprisingly, the atscar2 mutants showed well-developed epidermal
lobes. In order to detect a mild lobing phenotype we quantified the lobe
formation by calculating the complexity of 100 individual pavement cells on
ten mature rosette leaves per mutant line using the formula: complexity=
(perimeter)2/(4xpxarea). Compared with wild-type plants
(complexity=2.4) none of the mutant lines of the four AtSCAR genes
and AtSCAR-LIKE showed a significant difference concerning the
pavement cell complexity. In arp2-arp3 complex mutants the hypocotyl
epidermal cells also show morphogenetic defects when grown in the dark. During
etiolation, hypocotyl cell elongation is drastically increased and represents
a challenging mode of growth for some cytoskeletal mutants. As shown in
Fig. 2G-I, the dark-grown
atscar2 lines occasionally exhibit severe cell expansion and
adherence defects such that in some instances cells tear out of the epidermal
tissue layer and bend away from the surface. This phenotype was absent in the
other atscar and atscar-like mutants. Root hair growth was
normal in all atscar and atscar-like mutants.
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;
Deeks et al., 2004;
El-Assal et al., 2004a;
Li et al., 2004;
Zimmermann et al., 2004). The
analysis of the cellular phenotype revealed that the elongation of the petiole
is due to increased cell elongation of petiole cells. In wild-type petioles
the epidermal cells are, on average, 0.82 mm long. The average length in
homozygous SALK-039449 (scar2-1) and SALK-124023 (scar2-3)
lines is 1.67 mm and 2.1 mm, respectively. This twofold increase in average
cell length indicates that the ARP2-ARP3 pathway counteracts cell elongation
in these cells. The petioles in the other atscar and
atscar-like mutants were normal.
Double-mutant analysis of the Arabidopsis SCAR genes
One explanation for the finding that atscar2 mutants show a weak
phenotype and that the other atscar mutants show no obvious phenotype
is a redundancy of gene function between members of the AtSCAR
family. We tested this possibility by creating various double mutants. A
striking enhancement of the atscar2 phenotype was found when
atscar2 mutants were combined with atscar4 alleles. Both
atscar2; atscar4 double mutants and mutants homozygous for
atscar2 and heterozygous for atscar4 showed an equally
severe phenotype indistinguishable from strong `distorted' mutants
(Fig. 2M-P). This indicates
that in an atscar2 mutant background the reduction of
AtSCAR4 gene dosage leads to a severe phenotype reflecting a
redundant action between the two genes. All other double-mutant combinations
tested, including atscar1; atscar3, atscar1; atscar5, atscar3; atscar4,
atscar2; atscar-like showed no obvious actin-related phenotype.
AtSCAR2 VCA activates the ARP2-ARP3 complex
The similarity between aspects of the atscar2 phenotype to
arp2-arp3 complex mutants would suggest that AtSCAR2 activates the
Arabidopsis ARP2-ARP3 complex. Rabbit muscle skeletal G-actin (10%
pyrenelated) at a concentration of 4 mM was polymerised in the presence of
bovine ARP2-ARP3 (500 nM) and either AtSCAR2 GST-VCA (160 nM) or GST only. In
animals, the VCA domain brings together actin monomers and the
actin-nucleating ARP2-ARP3 complex and consists of three homology domains (V,
which binds to an actin monomer; C, cofilin homology domain; A, acidic region
that associates with the ARP2-ARP3 complex)
(Stradal et al., 2004).
Fig. 3 shows that ARP2-ARP3
activity is stimulated by AtSCAR2 GST-VCA, whereas AtSCAR2 GST-VCA alone does
not accelerate polymerization. Consequently AtSCAR2 has the potential to act
as an activator of the ARP2-ARP3 complex in vivo.
AtSCAR2:GFP is localised to the cytoplasm
Epidermal lobe phenotypes exhibited by mutant subunits of the ARP2-ARP3
complex and by mutant arp2-arp3 complex regulators suggest that
ARP2-ARP3 complex activity affects the development of pavement cell lobes and
the subsequent intercalation of lobes between neighbouring epidermal cells.
Mutations of the maize HSPC300 homologue BRICK1 and
Arabidopsis ARP2 and ARP3 are associated with the loss or
mis-localisation of F-actin structures within epidermal lobes
(Frank et al., 2003;
Li et al., 2003). The AtSCAR2
protein fused to GFP was created and proven to be functional by demonstrating
that it can rescue the atscar2 mutant phenotype. As we could not
detect fluorescence in these lines, we expressed AtSCAR2-GFP in single
epidermal pavement cells transiently by particle bombardment. AtSCAR2-GFP
localises to the cytoplasm of initiating cell lobes without any preference to
particular cell regions (Fig.
4). Occasionally we found apparent concentrations in lobes, but
this was always colocalised with co-transformed cytoplasmic RFP.
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Protein-protein interactions within the SCAR/WAVE complex
The array of yeast two-hybrid analyses revealed partnering selectivity
between the members of SCAR/WAVE and ABI proteins
(Fig. 6,
Table 1). Interaction with all
four ABI proteins was found in the case of AtSCAR3 only. AtSCAR2 interacts
with ABI1, 2 and 4, AtSCAR1 and AtSCAR-LIKE interact with ABI 1 and 2, whereas
no interaction between AtSCAR4 and any ABI protein could be found. Several
combinations were selected for confirmation in BiFC assays
(Table 1). Interactions between
these proteins were always found in the cytoplasm without preference to the
plasma membrane or the cytoskeleton.
Furthermore, the five SCAR homologues from A. thaliana differ in their ability to interact with the HSPC300 homologue BRICK1. Interaction could be detected between HSPC300/BRICK1 and AtSCAR1, 2 and 3, respectively, whereas AtSCAR4 and AtSCAR-LIKE were not able to activate reporter gene expression in yeast (Fig. 6, Table 1). Both examples tested in BiFC were found to interact in the cytoplasm.
We found that BRICK1 homodimerises, and physically interacts with all four
ABI proteins. HSPC300/BRICK1 homodimerisation
(Fig. 5G,H) and the interaction
between HSPC300/BRICK1 and ABI4 have been confirmed in planta by BiFC
(Table 1). A physical
interaction between HSPC300/BRICK1 and ABI proteins indicates potential
cooperativity in a ternary complex formed by HSPC300/BRICK1, ABI and AtSCAR
proteins, equivalent to the interactions within the animal complex suggested
by the work of Gautreau et al. (Gautreau
et al., 2004). We further found that NAP1 also homodimerises and
interacts with two ABI proteins (ABI 1 and 2) and with SRA1
(Fig. 6,
Table 1). NAP1 might therefore
act as an adaptor protein recruiting SRA1 to the SCAR/WAVE complex in a manner
similar to that reported for the mammalian NAP1 protein
(Gautreau et al., 2004).
Interactions within the ARP2-ARP3 complex and between the SCAR/WAVE complex and components of the ARP2-ARP3 complex
Several anchoring possibilities link subunits of the SCAR/WAVE complex with
the ARP2-ARP3 complex. In accordance with published data, the ARP2-ARP3
subunits ARPC3 and ARP3 seem to be central in this respect. We identified
interactions between both ARP3 and ARPC3 and AtSCAR3, HSPC300/BRICK1 and ABI1
and 2. ABI4 interacted only with ARP3. Furthermore, AtSCAR1 and AtSCAR2 have
been found to interact with ARPC3. AtSCAR4, AtSCAR-LIKE and ABI3 did not bind
to components of the ARP2-ARP3 complex
(Fig. 6,
Table 1). That AtSCAR4 shows no
interactions with components of the ARP2-ARP3 complex is surprising as it has
been shown that the C-terminus can activate the bovine ARP2-ARP3 complex
(Frank et al., 2004). Whether
this finding is due to our particular experimental setup or whether this
reflects that the rest of the AtSCAR4 protein can regulate the binding to the
ARP2-ARP3 complex remains to be determined. Interactions of AtSCAR1 and
AtSCAR2 with ARPC3, and interactions between HSPC300/BRICK1 and ARP3 and
ARPC3, respectively, have been confirmed by BiFC in planta.
We also assessed the interactions between components of the ARP2-ARP3
complex. Based on the two-hybrid system, ARPC4 functions as an integral
component as it interacts with ARPC1, ARPC2, ARPC3 and ARPC5. Two of these
interactions have exemplarily been confirmed in planta
(Fig. 6,
Table 1). Similar protein
interactions have been detected by yeast two-hybrid analyses in the human
ARP2-ARP3 complex (Zhao et al.,
2001). Our data indicate additionally direct contact between ARP2
and ARP3. With the exception of a physical interaction of ARPC4 and ARPC5, our
data fit with the inter-subunit contacts revealed by the 3D structure of the
bovine complex (Robinson et al.,
2001), indicating a structural conservation from mammals to
plants.
Upstream regulators of the SCAR/WAVE complex
Our protein interaction network reveals a novel interesting link between
AtSCAR proteins and ROP GTPases. For the yeast two-hybrid assays we used
either the unmodified full-length ROP cDNAs or single point mutations leading
to the constitutively active (CA) form or, for the ROP7 protein, the dominant
negative (DN) form. The constitutively active form carries the amino acid
exchange Glycine 15 to Valine (ROP7CA), Glycine 17 to Valine (ROP2CA,
ROP11CA), Glycine 27 to Valine (ROP8CA), and the dominant negative form the
Threonine 20 to Asparagine exchange (ROP7DN).
The unmodified ROP5 interacted with AtSCAR1, AtSCAR2 and AtSCAR4; ROP7 interacted in both the wild type and the constitutively active form with AtSCAR2 but did not interact with AtSCAR2 in the dominant negative form; ROP8 interacted in both forms with AtSCAR2 and AtSCAR3, whereas only the unmodified form interacted with AtSCAR1, and constitutively active ROP11 interacted with AtSCAR1, AtSCAR2 and AtSCAR4 (Fig. 6, Table 1). These findings are very interesting because, to our knowledge, no interactions between SCARs and small Rho-like GTPases have been reported previously.
The constitutively active and the dominant negative forms of ROP7 interacted differentially with AtSCAR2 indicating that AtSCAR2 might be a downstream effector of ROP7. Because this question cannot be unambiguously answered with the yeast two-hybrid system, we applied the BiFC technology to investigate the interactions between ROP GTPases and AtSCAR proteins in planta. Upon co-expression of either wild-type ROP7 or the constitutively active form with AtSCAR2 in onion cells and Arabidopsis protoplasts, respectively, we observed a strong fluorescence signal localised to the plasma membrane (Fig. 5A-C,E). In contrast, co-expression of the dominant negative form of ROP7 and AtSCAR2 did not result in any detectable yellow fluorescence (Fig. 5D). ROP GTPases cycle between the predominant inactive GDP-bound state in the cytoplasm and a membrane-associated active GTP-bound state. Transiently expressed wild-type ROP7 protein should mainly exist in the inactive form in the cytoplasm with a fraction of activated protein at the plasma membrane. The fact that in both the wild type and the constitutively active form we observe the reconstituted fluorescence signal only at the cell periphery indicates that AtSCAR2 interacts specifically with the activated form of ROP7, which is associated with the plasma membrane. Similarly we could detect a BiFC signal specifically at the plasma membrane upon co-expression of ROP2 and ROP8 with AtSCAR2.
|
). We also tested this combination with two different
vector systems with both possible bait and prey combinations and with the full
length ROPs as well as with ROPs that carry a C-terminal deletion typically
used in yeast two-hybrid systems to avoid artefacts due to mislocalisation. In
our hands, however, none of the tested ROPs including ROP2, ROP 5, ROP7, ROP8
and ROP11 showed interaction with SRA1.
In order to further assess the upstream regulation of the AtSCAR proteins
and AtSCAR-LIKE we included the SPIKE1 protein in our analysis. Because of its
sequence similarity to DOCK180 it has been speculated that SPIKE1 is a
potential upstream regulator of ROPs (Qiu
et al., 2002). We found interactions of SPIKE1 with wild-type
forms of ROP2, ROP5 and ROP8, and with the constitutively active form of
ROP11. This could support the proposed role of SPIKE1 as a ROP-GEF, but so
far, we have not been able to confirm these yeast two-hybrid results with BiFC
(Table 1).
Another interesting finding from our systematic protein interaction analyses is a direct interaction between SPIKE1 and all four ABI proteins and four of five AtSCAR proteins. Interactions with ABI1 and with AtSCAR2, respectively, have been confirmed by BiFC (Fig. 5F, Table 1). This finding suggests SPIKE1 is a novel integral component of the Arabidopsis SCAR/WAVE complex.
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DISCUSSION |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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). Our
data show that no mutant in any other AtSCAR isoform can alone produce a
`distorted' phenotype, but a reduction in the gene dosage of AtSCAR4 in an
atscar2 background is sufficient to produce a phenotype with
increased severity that mimics the arp2-arp3 complex mutants. This
shows that AtSCAR proteins are indeed essential for the function of ARP2-ARP3
complex activation and do not rely upon a parallel genetic pathway to achieve
full activation.
Genetic confirmation of the essential role of plant SCAR homologues in
ARP2-ARP3 complex activation highlights the importance of understanding how
plant SCAR proteins physically interact with their SCAR/WAVE complex and
ARP2-ARP3 complex partners. The current data from animal systems suggest that
the SCAR/WAVE complex assembles in a linear series of inter-subunit
interactions such that SRA1 binds to NAP1, NAP1 to ABI, ABI to SCAR, and SCAR
and ABI bind to HSPC300/BRICK1. Upon activation, the VCA/WA domain of
SCAR/WAVE is thought to contact the ARP2-ARP3 complex principally through the
ARPC3 subunit (Machesky and Insall,
1998) to stimulate the ARP2-ARP3 complex, although this model is
constantly evolving to incorporate new insights into ARP2-ARP3 complex
structural biology. In plants key interactions have been verified using a
small number of ABI and SCAR isoforms (Basu
et al., 2005; Frank et al.,
2004) tested in one-to-one interaction assays that have confirmed
a minimal number of associations that match the animal model for complex
assembly. Our alternative approach has created a yeast two-hybrid interaction
matrix that tests the majority of possible interactions between complex
components and putative regulators. Confirmation of interactions in planta
using the BiFC system has identified a number of novel protein associations
not predicted by the animal model.
Genetic and biochemical experiments have identified Arabidopsis
SCAR2 as a potential activator of the ARP2-ARP3 complex in plants (this work)
(Basu et al., 2005;
Zhang et al., 2005b). Four
plant homologues of the five components of the SCAR regulatory complex have
now been associated with phenotypes that either resemble arp2-arp3
complex mutant alleles (Basu et al.,
2004; Brembu et al.,
2004; El-Assal et al.,
2004a; Saedler et al.,
2004b; Zimmermann et al.,
2004) or are correlated with disruption of the F-actin
cytoskeleton (Frank and Smith,
2002).
Of these components SCAR is the most essential for ARP2-ARP3 regulation; as
the conserved SCAR VCA domain makes physical contact with and activates the
ARP2-ARP3 complex via an acidic domain and amphipathic helix
(Marchand et al., 2001;
Pan et al., 2004;
Panchal et al., 2003).
Consequently, SCAR alone can activate the ARP2-ARP3 complex in vitro
(Eden et al., 2002;
Machesky et al., 1999).
Associating plant SCAR with ARP2-ARP3 regulation is therefore central to understanding the role of NAP1, PIR121, HSPC300 and ABI homologues in plants.
|
), but data testing alternative ARP2-ARP3- and
SCAR/WAVE-complex binding partners were not presented. Our alternative
systematic approach revealed two surprising results. First, we identified a
specific interaction between AtSCAR3 and ARPC2, which to our knowledge has not
been reported to interact with SCAR proteins in other systems. Second,
Arabidopsis HSPC300/BRICK1 and a subset of ABI proteins bind directly
to components of the ARP2-ARP3 complex. The HSPC300/BRICK1-ARPC3 interaction,
the HSPC300/BRICK1-ARP3 interaction and the AtSCAR3-ARPC2 interaction were
successfully verified in planta by BiFC. The identification of these
interactions in the two independent systems suggests that the regulation of
the plant ARP2-ARP3 complex by the SCAR/WAVE complex might involve novel
binding configurations not previously identified in animal or fungal model
species. Plant SCAR proteins dwarf their animal counterparts due to the
presence of large plant-specific central domains that vastly increase the
distance between the SHD N-terminus and VCA/WA C-terminus. These extra domains
could potentially provide novel ARP2-ARP3 complex binding sites, or permit the
flexibility required for other SCAR/WAVE complex subunits to contact the
ARP2-ARP3 complex directly.
Interactions between the subunits of the putative plant SCAR/WAVE complex
In mammals, the SCAR/WAVE protein family comprises three members, and there
are two ABI isoforms, ABI1 and ABI2. So far, no differences in interaction
specificities have been found. Investigation of the interactions among these
two protein families revealed that all SCAR/WAVE proteins can interact with
ABI1 (Stovold et al., 2005).
These findings suggest that the regulation of different SCAR/WAVE isoforms is
likely at the level of tissue expression or is based upon different affinities
to the binding partner, or relies upon additional regulatory components or
post-translational modifications (Stovold
et al., 2005). Similarly, association of all three members of the
mammalian SCAR/WAVE protein family with HSPC300/BRICK1 has been proven
(Eden et al., 2002;
Gautreau et al., 2004;
Stovold et al., 2005). The
Arabidopsis SCAR and ABI proteins, by contrast, show specific
interaction patterns such that they each bind only to a subset of the
potential interaction partners. This results in a complex interaction network.
In addition to identifying isoform-specific interactions during SCAR/WAVE
complex assembly our analysis provides confirmatory evidence for a direct
physical interaction between HSPC300/BRICK1 and ABI proteins. For the bovine
SCAR/WAVE complex this interaction was predicted by Gautreau and co-workers,
as HSPC300/BRICK1 bound to the SRA1-NAP1-ABI complex in the absence of
SCAR/WAVE; however, despite being inferred, direct interaction between ABI and
HSPC300/BRICK1 was not detected (Gautreau
et al., 2004).
Regulation of the plant SCAR/WAVE complex
In mammals, the pentameric SRA1-NAP1-ABI-HSPC300/BRICK1-SCAR complex is
activated by small Rho-like GTPases, which in turn are regulated by various
upstream regulators including GEFs. Similar to the mammalian SRA1 protein,
Arabidopsis SRA1 is considered a downstream effector of small
Rho-like GTPases in plants because an interaction was found with the activated
form of ROP2 (Basu et al.,
2004). We could not identify an interaction between
Arabidopsis SRA1 and any of the ROP proteins in our yeast two-hybrid
assays, which may be due to different experimental setups. In our experiments
we found, however, interactions between several ROPs and different subsets of
the AtSCAR proteins. This raises the possibility that some plant ROPs can
regulate AtSCAR activity through direct interactions (see below).
The activity of Rho-like GTPases in animals and yeast is regulated by
exchange factors (GEFs). Plant ROP control by GEF proteins was only recently
demonstrated (Berken et al.,
2005). Arabidopsis SPIKE1 protein is considered to act as
a GEF because it contains the DOCK domain found in a class of unconventional
guanine nucleotide exchange factors that stimulate the GTPase activity of Rho
family proteins in animals (Qiu et al.,
2002). As the spike1 phenotype shares some aspects of
arp2-arp3 complex mutant phenotypes, SPIKE1 is a good candidate
regulator of ROP activity in the context of cell morphogenesis. Our yeast
two-hybrid data support this concept as SPIKE1 showed interactions with three
ROP proteins. These results, however, have to be treated with caution as we
could not confirm them in the BiFC system. However, the surprising finding
that SPIKE1 interacts with all four ABI proteins and four of five SCAR
proteins, and that examples of both interactions can be confirmed by BiFC,
raises the interesting possibility that SPIKE1 might act as an integral part
of the plant SCAR/WAVE complex. The physical coupling of a ROP GEF to the
SCAR/WAVE complex could establish an intriguing signalling feedback loop where
the SCAR/WAVE complex ROP effector could influence the status of its own
activation through SPIKE1 GEF activity. Alternatively, a close association of
the SPIKE1 GEF might be required to regulate small GTPases involved in
plant-specific SCAR/WAVE complex interactions (see below).
A potential WASP-like pathway in plants?
In mammalian cells WASP (in contrast to SCAR/WAVE) contains a CRIB domain
and consequently has been shown to be a direct effector of the small GTPase
Cdc42. With the SRA1-Kette(NAP1)-ABI complex also regulating WASP function
(Bogdan et al., 2004;
Bogdan and Klambt, 2003;
Bogdan et al., 2005), there are
two effector proteins for small GTPases (SRA1-Rac1 and WASP-Cdc42) in the
regulatory system. To date, no family of ARP2-ARP3 activators other than SCAR
have been identified in plants by bioinformatics or experimentally.
Surprisingly, our protein-protein interaction data suggest that Arabidopsis SCAR proteins are directly-associated downstream effectors of ROPs. Both yeast two-hybrid data and BiFC demonstrate that AtSCAR2 interacts with ROP7 wild type and constitutive active forms but not the ROP7 dominant negative form. Interaction of AtSCAR2 with active ROP8 was also shown in both systems. Moreover the specific localisation of the ROP interactions at the plasma membrane supports the idea that ROPs can directly recruit SCAR proteins to the cell periphery. These data suggest that in plants, similar to the WASP complex, there might be two entry points for ROP-GTPase regulation. The significance of our finding remains to be determined, as an activating role similar to Cdc42 regulation of WASP seems unlikely as plant SCAR/WAVE proteins appear to be constitutively active and therefore not dependent on the release of an auto-inhibitory domain. Alternatively, active ROP proteins might provide an additional anchor to the plasma membrane for the large plant SCAR proteins. The plant-specific domains of AtSCAR proteins could contain small GTPase binding sites and require further investigation. It is interesting to note that AtSCAR2 is both the most `promiscuous' ROP-binding AtSCAR isoform and is also the AtSCAR isoform shown to play the most prominent role during plant development.
Conclusion
Our data show that AtSCAR2 is an essential AtSCAR isoform required for
plant development, and in our assays AtSCAR2 has the ability to interact
directly with active small GTPases. Further analysis is required to identify
the biological role for this phenomenon, but it should be noted that our
systematic approach has identified novel interactions that behave in a more
robust manner than some of the perceived `canonical' interactions based upon
the animal model of the SCAR/WAVE complex. Genetic analysis of the functional
role of each SCAR/WAVE complex member is hindered by the potential functional
redundancy between SCAR, ABI and ROP isoforms. Detailed complementation
experiments using sophisticated mutant backgrounds combined with technically
challenging in vitro reconstitution experiments will eventually be capable of
testing the configuration of whole complexes, and be capable of assessing the
role of each interaction in plant ARP2-ARP3 complex activation.
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ACKNOWLEDGMENTS |
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Footnotes |
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REFERENCES |
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TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES |
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