Arabidopsis GNARLED encodes a NAP125 homolog that positively regulates ARP2/3

In migrating cells, the actin filament nucleation activity of ARP2/3 is an essential component of dynamic cell shape change and motility. In response to signals from the small GTPase Rac1, alterations in the composition and/or subcellular localization of the WAVE complex lead to ARP2/3 activation. The human WAVE complex subunit, WAVE1/SCAR1, was first identified in Dictyostelium and is a direct ARP2/3 activator. In the absence of an intact WAVE complex, SCAR/WAVE protein is destabilized. Although the composition of the five-subunit WAVE complex is well characterized, the means by which individual subunits and fully assembled WAVE complexes regulate ARP2/3 in vivo are unclear. The molecular genetics of trichome distortion in Arabidopsis is a powerful system to understand how signaling pathways and ARP2/3 control multicellular development. In this paper we prove that the GNARLED gene encodes a homolog of the WAVE subunit NAP125. Despite the moderate level of amino acid identity between Arabidopsis and human NAP125, both homologs were functionally interchangeable in vivo and interacted physically with the putative Arabidopsis WAVE subunit ATSRA1. gnarled trichomes had nearly identical cell shape and actin cytoskeleton phenotypes when compared to ARP2/3 subunit mutants, suggesting that GRL positively regulates ARP2/3.     

The <Emphasis Type="Italic">Arabidopsis</Emphasis><Emphasis Type="Italic">KLUNKER</Emphasis> gene controls cell shape changes and encodes the AtSRA1 homolog

The analysis of a group of seven trichome mutants in Arabidopsis, which all show distorted trichomes along with severe actin defects has revealed insight into the role of the actin cytoskeleton in cell shape control. Four of the corresponding genes encode components of a protein complex, the ARP2/3 complex that stimulates the production of fine actin at active growth sites. In this study, we show that another member of the distorted group, KLUNKER (KLK), encodes the AtSRA1 homolog of Arabidopsis and that klk mutants show a similar range of cell shape defects to those of arp2/3 mutants. In animals, SRA1 regulates the activity of the ARP2/3-regulating WAVE-HSPC300 complex in a Rho-dependent manner. Our findings provide evidence that a Rho/ARP2/3 regulation pathway exists in plants.     

Interchangeable functions of Arabidopsis PIROGI and the human WAVE complex subunit SRA1 during leaf epidermal development

The WAVE complex is an essential regulator of actin-related protein (ARP) 2/3-dependent actin filament nucleation and cell shape change in migrating cells. Although the composition of the WAVE complex is well characterized, the cellular mechanisms that control its activity and localization are not well known. The 'distorted group' defines a set of Arabidopsis genes that are required to remodel the actin cytoskeleton and maintain the polarized elongation of branched, hair-like cells termed trichomes. Several loci within this group encode homologs of ARP2/3 subunits. In addition to trichome distortion, ARP2/3 subunit mutants have reduced shoot fresh weight and widespread defects in epidermal cell-cell adhesion. The precise cellular function of plant ARP2/3, and the means by which it is regulated, is not known. In this paper, we report that the 'distorted group' gene PIROGI encodes a homolog of the WAVE complex subunit SRA1. The similar cell shape and actin phenotypes of pir and ARP2/3 complex subunit mutants suggest that PIROGI positively regulates ARP2/3. PIROGI directly interacts with the small GTPase ATROP2 with isoform specificity and with selectivity for active forms of the protein. PIROGI shares only 30% amino acid identity with its human homolog. However, both WAVE subunit homologs are functionally interchangeable and display identical physical interactions with RHO family GTPases and the Arabidopsis homolog of the WAVE complex subunit NAP125. These results demonstrate the utility of the 'distorted group' mutants to study ARP2/3 complex functions from signaling input to cell shape output.     

A role for ABIL3 in plant cell morphogenesis

Actin nucleation facilitated by the ARP2/3 complex plays a central role in plant cell shape development. The molecular characterization of the distorted class of trichome mutants has recently revealed the SCAR/WAVE complex as an essential upstream activator of ARP2/3 function in plants. The SCAR/WAVE complex is conserved from animals to plants and, generally, is composed of the five subunits SCAR/WAVE, PIR121, NAP125, BRICK and ABI. In plants, four of the five subunits have been shown to participate in trichome and pavement morphogenesis. Plant ABI‐like proteins (ABIL), however, which constitute a small four‐member protein family in Arabidopsis thaliana, have not been characterized functionally, so far. Here we demonstrate that microRNA knock‐down of the ABIL3 gene leads to a distorted trichome phenotype reminiscent of ARP2/3 mutant phenotypes and consistent with a crucial role of the ABIL3 protein in an ARP2/3‐activating SCAR/WAVE complex. In contrast to ARP2/3 mutants, however, the ABIL3 knock‐down stimulated cell elongation in the root, indicating distinct functions of the ABIL3 protein in different tissues. Furthermore, we provide evidence that ABIL3 associates with microtubules in vivo, opening up the intriguing possibility that ABI‐like proteins have a function in linking SCAR/WAVE‐dependent actin nucleation with organization of the microtubule cytoskeleton.     

IRREGULAR TRICHOME BRANCH1 in Arabidopsis encodes a plant homolog of the actin-related protein2/3 complex activator Scar/WAVE that regulates actin and microtubule organization

The dynamic actin cytoskeleton is important for a myriad of cellular functions, including intracellular transport, cell division, and cell shape. An important regulator of actin polymerization is the actin-related protein2/3 (Arp2/3) complex, which nucleates the polymerization of new actin filaments. In animals, Scar/WAVE family members activate Arp2/3 complex-dependent actin nucleation through interactions with Abi1, Nap1, PIR121, and HSCP300. Mutations in the Arabidopsis thaliana genes encoding homologs of Arp2/3 complex subunits PIR121 and NAP1 all show distorted trichomes as well as additional epidermal cell expansion defects, suggesting that a Scar/WAVE homolog functions in association with PIR121 and NAP1 to activate the Arp2/3 complex in Arabidopsis. In a screen for trichome branching defects, we isolated a mutant that showed irregularities in trichome branch positioning and expansion. We named this gene IRREGULAR TRICHOME BRANCH1 (ITB1). Positional cloning of the ITB1 gene showed that it encodes SCAR2, an Arabidopsis protein related to Scar/WAVE. Here, we show that itb1 mutants display cell expansion defects similar to those reported for the distorted class of trichome mutants, including disruption of actin and microtubule organization. In addition, we show that the scar homology domain (SHD) of ITB1/SCAR2 is necessary and sufficient for in vitro binding to Arabidopsis BRK1, the plant homolog of HSPC300. Overexpression of the SHD in transgenic plants causes a dominant negative phenotype. Our results extend the evidence that the Scar/WAVE pathway of Arp2/3 complex regulation exists in plants and plays an important role in regulating cell expansion.     

NAPP and PIRP encode subunits of a putative wave regulatory protein complex involved in plant cell morphogenesis

The ARP2/3 complex is an important regulator of actin nucleation and branching in eukaryotic organisms. All seven subunits of the ARP2/3 complex have been identified in Arabidopsis thaliana, and mutation of at least three of the subunits results in defects in epidermal cell expansion, including distorted trichomes. However, the mechanisms regulating the activity of the ARP2/3 complex in plants are largely unknown. In mammalian cells, WAVE and WASP proteins are involved in activation of the ARP2/3 complex. WAVE1 activity is regulated by a protein complex containing NAP1/HEM/KETTE/GEX-3 and PIR121/Sra-1/CYFIP/GEX-2. Here, we show that the WAVE1 regulatory protein complex is partly conserved in plants. We have identified Arabidopsis genes encoding homologs of NAP1 (NAPP), PIR121 (PIRP), and HSPC300 (BRK1). T-DNA inactivation of NAPP and PIRP results in distorted trichomes, similar to ARP2/3 complex mutants. The napp-1 mutant is allelic to the distorted mutant gnarled. The actin cytoskeleton in napp-1 and pirp-1 mutants shows orientation defects and increased bundling compared with wild-type plants. The results presented show that activity of the ARP2/3 complex in plants is regulated through an evolutionarily conserved mechanism.     

The role of Arabidopsis SCAR genes in ARP2-ARP3-dependent cell morphogenesis

The actin-nucleating ARP2-ARP3 complex controls cell shape in plants in many different cell types. Its activity is controlled by a multimeric complex containing BRK1 (also known as HSPC300), NAP1, SRA1, ABI and SCAR/WAVE. In this study, we focus on the function of the five putative SCAR homologues in Arabidopsis and we provide biochemical evidence that AtSCAR2 can activate the ARP2-ARP3 complex in vitro. Among the single mutants, mutations in only AtSCAR2 result in a subtle or weak phenotype similar to ARP2, ARP3 and other ;distorted' mutants. Double-mutant analysis revealed a redundancy with AtSCAR4. Systematic application of the yeast two-hybrid system and Bimolecular Fluorescence Complementation (BiFC) revealed a complex protein-interaction network between the ARP2-ARP3 complex and its genetically defined regulators. In addition to protein interactions known in other systems, we identified several new interactions, suggesting that SPIKE1 may be an integral component of the SCAR/WAVE complex and that SCAR proteins in plants might act as direct effectors of ROP GTPases.     

BRICK1/HSPC300 functions with SCAR and the ARP2/3 complex to regulate epidermal cell shape in Arabidopsis

The Arp2/3 complex, a highly conserved nucleator of F-actin polymerization, is essential for a variety of eukaryotic cellular processes, including epidermal cell morphogenesis in Arabidopsis thaliana. Efficient nucleation of actin filaments by the Arp2/3 complex requires the presence of an activator such as a member of the Scar/WAVE family. In mammalian cells, a multiprotein complex consisting of WAVE, PIR121/Sra-1, Nap1, Abi-2 and HSPC300 mediates responsiveness of WAVE to upstream regulators such as Rac. Essential roles in WAVE complex assembly or function have been demonstrated for PIR121/Sra-1, Nap1 and Abi-2, but the significance of HSPC300 in this complex is unclear. Plant homologs of all mammalian WAVE complex components have been identified, including HSPC300, the mammalian homolog of maize BRICK1 (BRK1). We show that, like mutations disrupting the Arabidopsis homologs of PIR121/Sra-1, Nap1 and Scar/WAVE, mutations in the Arabidopsis BRK1 gene result in trichome and pavement cell morphology defects (and associated alterations in the F-actin cytoskeleton of expanding cells) similar to those caused by mutations disrupting the ARP2/3 complex itself. Analysis of double mutants provides genetic evidence that BRK1 functions in a pathway with the ARP2/3 complex. BRK1 is required for accumulation of SCAR1 protein in vivo, potentially explaining the apparently essential role of BRK1 in ARP2/3 complex function.     

Arabidopsis NAP and PIR regulate actin-based cell morphogenesis and multiple developmental processes

The actin cytoskeleton mediates cellular processes through the dynamic regulation of the time, location, and extent of actin polymerization. Actin polymerization is controlled by several types of evolutionarily conserved proteins, including those comprising the ARP2/3 complex. In animal cells ARP2/3 activity is regulated by WAVE complexes that contain WAVE/SCAR proteins, PIR121, Nap125, and other proteins. The activity of the WAVE complex is regulated by Rho-GTPase-mediated signaling that leads to ARP2/3 activation by WAVE/SCAR proteins. We describe in this report Arabidopsis (Arabidopsis thaliana) genes encoding Nap and PIR proteins. Light-grown Atnap-1 and Atpir-1 mutant plants displayed altered leaf, inflorescence, silique, and seed set phenotypes. Dark-grown Atnap-1 and Atpir-1 seedlings also exhibited longer roots, enhanced skotomorphogenesis and Glc responses, and shorter thicker hypocotyls than those of wild type, showing that AtNAP and AtPIR participate in a variety of growth and developmental processes. Mutations in AtNAP and AtPIR caused cell morphology defects in cotyledon pavement cells and trichomes seen in mutants in ARP2/3 subunits and in plants expressing constitutively active Rop2 GTPase. The patterns and levels of actin polymerization observed in Atnap-1 and Atpir-1 mutant trichome cells and epidermal pavement cell morphology is consistent with Arabidopsis NAP and PIR proteins forming a WAVE complex that activates ARP2/3 activity. The multiple growth and developmental phenotypes of Atnap and Atpir mutants reveals these proteins are also required for a wider variety of cellular functions in addition to regulating trichome cell growth.     

The ARP2/3 complex: giving plant cells a leading edge

The seven-subunit ARP2/3 complex is an efficient modulator of the actin cytoskeleton with well-recognized roles in amoeboid locomotion and subcellular motility of organelles and microbes. The recent identification of different subunit homologs suggests the existence of a functional ARP2/3 complex in higher plants. Mutations in some of the subunits have revealed a pivotal role for the complex in determining the shape of walled cells and focused attention on the interlinked processes of cortical-actin organization, growth-site selection, organelle motility and actin-microtubule interactions during plant cell morphogenesis. The findings supporting a global conservation of molecular mechanisms for membrane protrusion have been further strengthened by the identification of plant homologs of upstream regulators of the complex such as PIR121, NAP125 and HSPC300. As discussed here, the recent studies suggest that there might be hitherto unappreciated molecular and cell-biological commonalities between protrusion mediated motility of animal cells and polarized, expansion-mediated growth of plant cells.     

Mutations in actin-related proteins 2 and 3 affect cell shape development in Arabidopsis

ACTIN-RELATED PROTEINS 2 and 3 form the major subunits of the ARP2/3 complex, which is known as an important regulator of actin organization in diverse organisms. Here, we report that two genes, WURM and DISTORTED1, which are important for cell shape control in Arabidopsis, encode the plant ARP2 and ARP3 orthologs, respectively. Mutations in these genes result in misdirected expansion of various cell types: trichome expansion is randomized, pavement cells fail to produce lobes, hypocotyl cells curl out of the normal epidermal plane, and root hairs are sinuous. At the subcellular level, cell shape changes are linked to severe filamentous actin aggregation and compromised vacuole fusion. Because all seven subunits of the ARP2/3 complex are present in plants, our data indicate that this complex may play a pivotal role during plant cell morphogenesis.     

Arabidopsis SCARs function interchangeably to meet actin-related protein 2/3 activation thresholds during morphogenesis

During polarized growth and tissue morphogenesis, cells must reorganize their cytoplasm and change shape in response to growth signals. Dynamic polymerization of actin filaments is one cellular component of polarized growth, and the actin-related protein 2/3 (ARP2/3) complex is an important actin filament nucleator in plants. ARP2/3 alone is inactive, and the Arabidopsis thaliana WAVE complex translates Rho-family small GTPase signals into an ARP2/3 activation response. The SCAR subunit of the WAVE complex is the primary activator of ARP2/3, and plant and vertebrate SCARs are encoded by a small gene family. However, it is unclear if SCAR isoforms function interchangeably or if they have unique properties that customize WAVE complex functions. We used the Arabidopsis distorted group mutants and an integrated analysis of SCAR gene and protein functions to address this question directly. Genetic results indicate that each of the four SCARs functions in the context of the WAVE-ARP2/3 pathway and together they define the lone mechanism for ARP2/3 activation. Genetic interactions among the scar mutants and transgene complementation studies show that the activators function interchangeably to meet the threshold for ARP2/3 activation in the cell. Interestingly, double, triple, and quadruple mutant analyses indicate that individual SCAR genes vary in their relative importance depending on the cell type, tissue, or organ that is analyzed. Differences among SCARs in mRNA levels and the biochemical efficiency of ARP2/3 activation may explain the functional contributions of individual genes.     

DISTORTED3/SCAR2 is a putative arabidopsis WAVE complex subunit that activates the Arp2/3 complex and is required for epidermal morphogenesis

In a plant cell, a subset of actin filaments function as a scaffold that positions the endomembrane system and acts as a substrate on which organelle motility occurs. Other actin filament arrays appear to be more dynamic and reorganize in response to growth signals and external cues. The distorted group of trichome morphology mutants provides powerful genetic tools to study the control of actin filament nucleation in the context of morphogenesis. In this article, we report that DISTORTED3 (DIS3) encodes a plant-specific SCAR/WAVE homolog. Null alleles of DIS3, like those of other Arabidopsis thaliana WAVE and Actin-Related Protein (ARP) 2/3 subunit genes, cause trichome distortion, defects in cell-cell adhesion, and reduced hypocotyl growth in etiolated seedlings. DIS3 efficiently activates the actin filament nucleation and branching activity of vertebrate Arp2/3 and functions within a WAVE-ARP2/3 pathway in vivo. DIS3 may assemble into a WAVE complex via a physical interaction with a highly diverged Arabidopsis Abi-1-like bridging protein. These results demonstrate the utility of the Arabidopsis trichome system to understand how the WAVE and ARP2/3 complexes translate signaling inputs into a coordinated morphogenetic response.     

CYFIP dependent actin remodeling controls specific aspects of Drosophila eye morphogenesis

Cell rearrangements shape organs and organisms using molecular pathways and cellular processes that are still poorly understood. Here we investigate the role of the Actin cytoskeleton in the formation of the Drosophila compound eye, which requires extensive remodeling and coordination between different cell types. We show that CYFIP/Sra-1, a member of the WAVE/SCAR complex and regulator of Actin remodeling, controls specific aspects of eye architecture: rhabdomere extension, rhabdomere terminal web organization, adherens junctions, retina depth and basement membrane integrity. We demonstrate that some phenotypes manifest independently, due to defects in different cell types. Mutations in WAVE/SCAR and in ARP2/3 complex subunits but not in WASP, another major regulator of Actin nucleation, phenocopy CYFIP defects. Thus, the CYFIP-SCAR-ARP2/3 pathway orchestrates specific tissue remodeling processes.     

拟南芥AtJ3通过核质转运调控植物质膜H~+-ATPase活性与ABA响应

拟南芥AtJ3(Arabidopsis thaliana Dna J homolog 3)为一蛋白分子伴侣,在植物体内可通过与PKS5(SOS2-like protein kinase 5)蛋白激酶形成复合物来抑制PKS5的活性;同时AtJ3-PKS5复合物可对质膜上H~+-ATPase质子转运活性进行正向调节,并参与对外源ABA的响应。为揭示AtJ3-PKS5复合物参与质膜H~+-ATPase活性调节及对外源ABA响应中的作用,本研究以拟南芥AtJ3、PKS5不同突变体为材料,在盐及ABA共同处理下对AtJ3-PKS5复合物的功能及作用机制进行了探讨。结果显示,在2种因素共同处理下,AtJ3-PKS5复合物可同时对处理因素进行响应。即AtJ3-PKS5复合物可对质膜上H~+-ATPase质子转运活性进行调节,并使细胞内p H值发生变化,同时还可诱导ABI5下游ABA响应基因的表达;外源ABA可引起AtJ3从细胞核向细胞质的转运,从而增强了AtJ3对H~+-ATPase活性的调节。说明AtJ3-PKS5复合物在对H~+-ATPase活性调节及对外源ABA响应的交互代谢途径中起着关键调节子的作用。     

Catching the WAVEs of Plant Actin Regulation

Plants, as all other eukaryotic organisms, depend on a dynamic actin cytoskeleton for proper function and development. Actin dynamics is a complex process, regulated by a number of actin-binding proteins and large multiprotein complexes like ARP2/3 and WAVE. The ARP2/3 complex is recognized as a nucleator of actin filaments, and it generates a highly branched network of interlaced microfilaments. Results from multiple organisms show that ARP2/3 activity is regulated through multiple pathways. Recent results from plants point to a signaling pathway leading from the small GTPase RAC/ROP through a protein complex containing the ARP2/3-activating protein WAVE. This signaling pathway appears to be evolutionarily conserved. Support for this regulatory mechanism comes from studies of mutations in genes encoding subunits of the putative ARP2/3 complex and the WAVE complex in Arabidopsis. Several such mutants have defects of actin filament organization, leading to a conspicuous “distorted” trichome phenotype. Multiple growth and developmental phenotypes reported for napp/gnarled/atnap, pirp/pirogi/atpir, and distorted3 mutants reveal that these WAVE proteins are also required for a wider variety of cellular functions in addition to regulating trichome cell growth. These results have implications for the current view on cell morphogenesis in plants.     

The ARP2/3 complex,acting cooperatively with Class I formins,modulates penetration resistance in Arabidopsis against powdery mildew invasion

The actin cytoskeleton regulates an array of diverse cellular activities that support the establishment of plant–microbe interactions and plays a critical role in the execution of plant immunity. However, molecular and cellular mechanisms regulating the assembly and rearrangement of actin filaments (AFs) at plant–pathogen interaction sites remain largely elusive. Here, using live-cell imaging, we show that one of the earliest cellular responses in Arabidopsis thaliana upon powdery mildew attack is the formation of patch-like AF structures beneath fungal invasion sites. The AFs constituting actin patches undergo rapid turnover, which is regulated by the actin-related protein (ARP)2/3 complex and its activator, the WAVE/SCAR regulatory complex (W/SRC). The focal accumulation of phosphatidylinositol-4,5-bisphosphate at fungal penetration sites appears to be a crucial upstream modulator of the W/SRC–ARP2/3 pathway-mediated actin patch formation. Knockout of W/SRC–ARP2/3 pathway subunits partially compromised penetration resistance with impaired endocytic recycling of the defense-associated t-SNARE protein PEN1 and its deposition into apoplastic papillae. Simultaneously knocking out ARP3 and knocking down the Class I formin (AtFH1) abolished actin patch formation, severely impaired the deposition of cell wall appositions, and promoted powdery mildew entry into host cells. Our results demonstrate that the ARP2/3 complex and formins, two actin-nucleating systems, act cooperatively and contribute to Arabidopsis penetration resistance to fungal invasion.

ARP2/3 complex, acting cooperatively with Class I formins, modulates actin patch formation beneath fungal penetration sites, contributing to the penetration resistance of Arabidopsis against powdery mildew invasion.     

SCAR mediates light-induced root elongation in Arabidopsis through photoreceptors and proteasomes

The ARP2/3 complex, a highly conserved nucleator of F-actin, and its activator, the SCAR complex, are essential for growth in plants and animals. In this article, we present a pathway through which roots of Arabidopsis thaliana directly perceive light to promote their elongation. The ARP2/3-SCAR complex and the maintenance of longitudinally aligned F-actin arrays are crucial components of this pathway. The involvement of the ARP2/3-SCAR complex in light-regulated root growth is supported by our finding that mutants of the SCAR complex subunit BRK1/HSPC300, or other individual subunits of the ARP2/3-SCAR complex, showed a dramatic inhibition of root elongation in the light, which mirrored reduced growth of wild-type roots in the dark. SCAR1 degradation in dark-grown wild-type roots by constitutive photomorphogenic 1 (COP1) E3 ligase and 26S proteasome accompanied the loss of longitudinal F-actin and reduced root growth. Light perceived by the root photoreceptors, cryptochrome and phytochrome, suppressed COP1-mediated SCAR1 degradation. Taken together, our data provide a biochemical explanation for light-induced promotion of root elongation by the ARP2/3-SCAR complex.     

Arabidopsis ZDP DNA 3′‐phosphatase and ARP endonuclease function in 8‐oxoG repair initiated by FPG and OGG1 DNA glycosylases

Oxidation of guanine in DNA generates 7,8‐dihydro‐8‐oxoguanine (8‐oxoG), an ubiquitous lesion with mutagenic properties. 8‐oxoG is primarily removed by DNA glycosylases distributed in two families, typified by bacterial Fpg proteins and eukaryotic Ogg1 proteins. Interestingly, plants possess both Fpg and Ogg1 homologs but their relative contributions to 8‐oxoG repair remain uncertain. In this work we used Arabidopsis cell‐free extracts to monitor 8‐oxoG repair in wild‐type and mutant plants. We found that both FPG and OGG1 catalyze excision of 8‐oxoG in Arabidopsis cell extracts by a DNA glycosylase/lyase mechanism, and generate repair intermediates with blocked 3′‐termini. An increase in oxidative damage is detected in both nuclear and mitochondrial DNA from double fpg ogg1 mutants, but not in single mutants, which suggests that a single deficiency in one of these DNA glycosylases may be compensated by the other. We also found that the DNA 3′‐phosphatase ZDP (zinc finger DNA 3′‐phosphoesterase) and the AP(apurinic/apyirmidinic) endonuclease ARP(apurinic endonuclease redox protein) are required in the 8‐oxoG repair pathway to process the 3′‐blocking ends generated by FPG and OGG1. Furthermore, deficiencies in ZDP and/or ARP decrease germination ability after seed deteriorating conditions. Altogether, our results suggest that Arabidopsis cells use both FPG and OGG1 to repair 8‐oxoG in a pathway that requires ZDP and ARP in downstream steps.