Constitutively activated barley ROPs modulate epidermal cell size, defense reactions and interactions with fungal leaf pathogens

RHO-like monomeric G-proteins of plants (ROPs, also called RACs), are involved in plant development and interaction with the environment. The barley (Hordeum vulgare) ROP protein HvRACB has been shown to be required for entry of the biotrophic powdery mildew fungus Blumeria graminis f.sp. hordei (Bgh) into living host cells. To get a deeper insight into evolutionarily conserved functions of ROPs in cell polarity and pathogen responses, we stably expressed constitutively activated (CA) mutant variants of different barley ROPs (HvRACB, HvRAC1, HvRAC3) in barley. CA HvROPs induced epidermal cell expansion and/or abolished polarity in tip growing root hairs. All three CA HvROPs enhanced susceptibility of barley to penetration by Bgh whereas only CA HvRAC1 supported whole cell H₂O₂ production in non-penetrated cells. Despite increasing penetration by Bgh, CA HvRAC1 promoted callose deposition at sites of fungal attack and resistance to penetration by Magnaporthe oryzae. The data show an involvement of ROPs in polar growth processes of the monocot barley and in responses to fungal pathogens with different life style.     

Barley ROP binding kinase1 is involved in microtubule organization and in basal penetration resistance to the barley powdery mildew fungus

Certain plant receptor-like cytoplasmic kinases were reported to interact with small monomeric G-proteins of the RHO of plant (ROP; also called RAC) family in planta and to be activated by this interaction in vitro. We identified a barley (Hordeum vulgare) partial cDNA of a ROP binding protein kinase (HvRBK1) in yeast (Saccharomyces cerevisiae) two-hybrid screenings with barley HvROP bait proteins. Protein interaction of the constitutively activated (CA) barley HvROPs CA HvRACB and CA HvRAC1 with full-length HvRBK1 was verified in yeast and in planta. Green fluorescent protein-tagged HvRBK1 appears in the cytoplasm and nucleoplasm, but CA HvRACB or CA HvRAC1 can recruit green fluorescent protein-HvRBK1 to the cell periphery. Barley HvRBK1 is an active kinase in vitro, and activity is enhanced by CA HvRACB or GTP-loaded HvRAC1. Hence, HvRBK1 might act downstream of active HvROPs. Transient-induced gene silencing of barley HvRBK1 supported penetration by the parasitic fungus Blumeria graminis f. sp. hordei, suggesting a function of the protein in basal disease resistance. Transient knockdown of HvRBK1 also influenced the stability of cortical microtubules in barley epidermal cells. Hence, HvRBK1 might function in basal resistance to powdery mildew by influencing microtubule organization.     

Plant small monomeric G-proteins (RAC/ROPs) of barley are common elements of susceptibility to fungal leaf pathogens,cell expansion and stomata development

Small monomeric RAC/ROP GTPases act as molecular switches in signal transduction processes of plant development and stress responses. They emerged as crucial players in plant-pathogen interactions either by supporting susceptibility or resistance. In a recent publication, we showed that constitutively activated (CA) mutants of different barley (Hordeum vulgare) RAC/ROPs regulate susceptibility to barley fungal leaf pathogens of different life style in a contrasting way. This illustrates the distinctive signalling roles of RAC/ROPs for different plant-pathogen combinations. We also reported the involvement of RAC/ROPs in plant epidermis development in a monocotyledonous plant. Here we further discuss a failure of CA HvRAC/ROP-expressing barley to normally develop stomata.Key words: Hordeum vulgare, G-proteins, RAC, ROP, cell expansion, stomata, transpirationMembers of the RHO family of small G-proteins in plants (RAC/ROPs) regulate signal transduction processes at the plasma membrane.¹ They act as multifunctional signalling switches in plant development and a variety of stress responses. RAC/ROP GTPases play regulatory roles in polar growth and cell morphogenesis in several cell systems including pollen tubes, developing root hairs and leaf pavement cells.²In a recent publication,³ we showed that constitutively activated (CA) mutants of different barley (Hordeum vulgare) RAC/ROPs support susceptibility to the barley powdery mildew fungus Blumeria graminis f.sp. hordei (Bgh). CA HvRAC1 supported susceptibility to biotrophic Bgh but resistance to hemibiotrophic Magnaporthe oryzae in barley at the penetration level in both cases. Additionally, CA HvRAC1 supported local callose deposition at sites of attack from Bgh and a secondary H₂O₂ burst in whole non-penetrated epidermal cells. This supports a regulatory function of RAC/ROPs in plant defence¹ and the potential corruption of defence pathways in susceptibility to Bgh. Because the rice ortholog of HvRAC1, OsRAC1, can regulate an H₂O₂ burst via activation of the plasma membrane NADPH oxidase OsRBOHB,⁴ one can speculate that the secondary H₂O₂ burst in CA HvRAC1 barley could also be caused by over-activation of an NADPH oxidase. However, CA HvRAC1 barley was also more susceptible to fungal penetration, and penetrated cells did not show an H₂O₂ burst. Hence, CA HvRAC1 did not contribute to penetration resistance, and the H₂O₂ burst might have been suppressed by Bgh after successful penetration. Interestingly, Bgh secretes a catalase during interaction with the plant.⁵The involvement of RAC/ROPs in plant development has been widely studied in the dicots Arabidopsis and tobacco. In Arabidopsis, CA AtRAC/ROPs disturb root hair tip growth and epidermal cell morphogenesis.^6,7 We showed similar developmental aberrations as a result of CA HvRAC/ROP expression in monocotyledonous barley. Root hair polarity disruption and enhanced leaf epidermal cell expansion was observed in CA HvRAC/ROP expressing barley. Here, we further report on reduced or abnormal development of stomata as an effect of CA HvRAC/ROP expression.In barley, stomata and short epidermal cells alternate in a row of leaf epidermal cells (Fig. 1A). The number of stomata number was significantly reduced in three CA HvRAC/ROP (CA HvRACB, CAHvRAC3, CA HvRAC1) expressing barley genotypes when compared to azygous controls (barley siblings that lost the transgene due to segregation) (Fig. 1E). In part, this could be explained by enhanced length of epidermal cells intercalated between stomata (Fig. 1B). The presence of longer epidermal cells in all CA HvRAC/ROP-barleys further supports that RAC/ROPs are operating in epidermal cell expansion.³Open in a separate windowFigure 1Stomatal abnormalities observed in CA HvROPexpressing transgenic barley leaves. (A) Wild type leaf adaxial epidermis with alternating stomata complexes (arrows) and short epidermal cells (asterisk). (B) Presence of more than one short epidermal cell in between two stomata. Arrows point the stomata. Double headed arrows highlight intercalated cells with enhanced cell length (C) Two stomata lacking an intercalated short epidermal cell. (D) Stoma failed to develop and left an abnormal blank cell. (E) Average number of stomata present in 5 cm of a stomatal row in transgenic plants expressing distinct CA barley CA HvRAC/ROPs. For all samples, stomatal rows present on either side of the mid rib were counted in the leaf upper epidermis. Fully expanded leaves of 3-weeks-old barley plants were used for counting stomata. Error bars show 95% confidence intervals. Repetition of the experiment led to similar results. Scale bars = 50 µm.Previously, we carried out porometry experiments to measure stomata conductivity in CA HvRACB expressing barley leaves.⁸ The CA HvRACB leaves showed up to 50% less transpiration than azygous controls without any treatment. Additionally, CA HvRACB leaves were less responsive to abscisic acid (ABA) and subsequently they could not effectively reduce transpiration when treated with ABA or when cut-off from water supply.⁸ Our data on numbers of stomata per leaf segment could now explain the lower rates of transpiration in non-stressed CA HvRACB barley when compared to wild type.Apart from the stomata number, developmental abnormalities were observed in the arrangement of epidermal cells. Generally, the shape of epidermal cells was less regular in CA HvRAC/ROP barley.³ We also observed the presence of more than one short epidermal cell in between two stomata (Fig. 1B) or two stomata lacking an intercalated short epidermal cell (Fig. 1C), or stomata failed to develop, which ended up in an abnormally short epidermal cell (Fig. 1D). Although such abnormalities were also rarely observed in wild type plants, all three CA HvRAC/ROP-barley leaves exhibited a clearly higher frequency of abnormalities in a given length of a stomata row. Together, CA HvRAC/ROPs had an effect on both the number and development of stomata. These observations suggest that RAC/ROPs are not only operating in cell expansion but also in barley cell differentiation for stomata development.     

Barley RIC171 interacts with RACB in planta and supports entry of the powdery mildew fungus

RHO-like GTPases of plants (ROPs, also called RACs) are involved in plant development and interaction with the environment. The barley ROP protein RACB is involved in susceptibility to the fungal pathogen Blumeria graminis f.sp. hordei ( Bgh ) . By screening barley sequence databases for potential protein interactors of plant RHO-like proteins, we identified a ROP-interactive CRIB (CDC42/RAC interactive binding) motif containing protein of 171 amino acids (RIC171). The protein interacted with constitutively activated RACB in a targeted yeast two-hybrid assay. By use of split yellow fluorescing protein fusions, we demonstrated that RIC171 interacts with constitutively activated (CA) RACB-G15V but not with dominant negative RACB-T20N in planta . Transient overexpression of RIC171, similar to overexpression of CA RACB-G15V, rendered epidermal cells more susceptible to penetration by Bgh . In contrast, expression of a 46-amino-acid RIC171-CRIB peptide, which was sufficient to interact with CA RACB-G15V, had a dominant negative effect and reduced susceptibility to Bgh . A red fluorescing DsRED–RIC171 fusion protein colocalized with green fluorescing GFP–RACB-G15V at the cell periphery. Coexpression with CA RACB-G15V but not with RACB-T20N increased peripheral localization of DsRED–RIC171. Additionally, DsRED–RIC171 accumulated at sites of fungal attack, suggesting enhanced ROP activity at sites of attempted fungal penetration.     

A barley SKP1‐like protein controls abundance of the susceptibility factor RACB and influences the interaction of barley with the barley powdery mildew fungus

In an increasing number of plant–microbe interactions, it has become evident that the abundance of immunity‐related proteins is controlled by the ubiquitin–26S proteasome system. In the interaction of barley with the biotrophic barley powdery mildew fungus Blumeria graminis f.sp. hordei (Bgh), the RAC/ROP [RAT SARCOMA‐related C3 botulinum toxin substrate/RAT SARCOMA HOMOLOGUE (RHO) of plants] guanosine triphosphatase (GTPase) HvRACB supports the fungus in a compatible interaction. By contrast, barley HvRBK1, a ROP‐binding receptor‐like cytoplasmic kinase that interacts with and can be activated by constitutively activated HvRACB, limits fungal infection success. We have identified a barley type II S‐phase kinase 1‐associated (SKP1)‐like protein (HvSKP1‐like) as a molecular interactor of HvRBK1. SKP1 proteins are subunits of the SKP1‐cullin 1‐F‐box (SCF)–E3 ubiquitin ligase complex that acts in the specific recognition and ubiquitination of protein substrates for subsequent proteasomal degradation. Transient induced gene silencing of either HvSKP1‐like or HvRBK1 increased protein abundance of constitutively activated HvRACB in barley epidermal cells, whereas abundance of dominant negative RACB only weakly increased. In addition, silencing of HvSKP1‐like enhanced the susceptibility of barley to haustorium establishment by Bgh. In summary, our results suggest that HvSKP1‐like, together with HvRBK1, controls the abundance of HvRACB and, at the same time, modulates the outcome of the barley–Bgh interaction. A possible feedback mechanism from RAC/ROP‐activated HvRBK1 on the susceptibility factor HvRACB is discussed.     

The receptor-like MLO protein and the RAC/ROP family G-protein RACB modulate actin reorganization in barley attacked by the biotrophic powdery mildew fungus Blumeria graminis f.sp. hordei

Cytoskeleton remodelling is a crucial process in determining the polarity of dividing and growing plant cells, as well as during interactions with the environment. Nothing is currently known about the proteins, which regulate actin remodelling during interactions with invading pathogens. The biotrophic powdery mildew fungus Blumeria graminis f.sp. hordei (Bgh) invades susceptible barley (Hordeum vulgare L.) by penetrating epidermal cells, which remain intact during fungal development. In contrast, resistant host plants prevent infection by inhibiting penetration through apoplastic mechanisms, which require focusing defence reactions on the site of attack. We stained actin filaments in a susceptible Mlo-genotype and a near-isogenic race-non-specifically resistant barley mlo5-mutant genotype using fluorescence-labelled phalloidin after chemical fixation. This revealed that the actin cytoskeleton is differentially reorganized in susceptible and resistant hosts challenged by Bgh. Actin filaments were polarized towards the sites of attempted penetration in the resistant host, whereas when susceptible hosts were penetrated, a more subtle reorganization took place around fungal haustoria. Strong actin filament focusing towards sites of fungal attack was closely associated with successful prevention of penetration. Actin focusing was less frequent and seemingly delayed in susceptible wild-type barley expressing the susceptibility factor MLO. Additionally, single cell overexpression of a constitutively activated RAC/ROP G-protein, CA RACB, another potential host susceptibility factor and hypothetical actin cytoskeleton regulator, partly inhibited actin reorganization when under attack from Bgh, whereas knockdown of RACB promoted actin focusing. We conclude that RACB and, potentially, MLO are host proteins involved in the modulation of actin reorganization and cell polarity in the interaction of barley with Bgh.     

RAC/ROP GTPases: 'hubs' for signal integration and diversification in plants

RAC/ROP GTPases are a family of plant-specific signaling molecules solely representing the Ras and Rho family of Ras-related G proteins in plants. RAC/ROPs potentially interact with cell surface-associated signal perception apparatus for a broad range of extracellular stimuli, including hormones, pathogen elicitors and abiotic stress, and mediate diverse cellular pathways in response to these signals. They are also known to interact with multiple effectors, affecting cellular and biochemical systems that regulate actin dynamics, reactive oxygen species production, proteolysis, and gene expression. RAC/ROPs are, thus, ideally suited as integrators for multiple signals and as coordinators of diverse cellular pathways to control growth, differentiation, development and defense responses. Recent findings that suggest how RAC/ROP signaling activity is regulated and how functional specificity can be achieved are discussed here.     

A novel ROP/RAC GTPase effector integrates plant cell form and pattern formation

ROPs/RACs are the only known signaling Ras superfamily small GTPases in plants. As such they have been suggested to function as central regulators of diverse signaling cascades. The ROP/RAC signaling networks are largely unknown, however, because only few of their effector proteins have been identified. In a paper that was published in the June 5, 2007 issue of Current Biology we described the identification of a novel ROP/RAC effector designated ICR1 (Interactor of Constitutive active ROPs 1). We demonstrated that ICR1 functions as a scaffold that interacts with diverse but specific group of proteins including SEC3 subunit of the exocyst vesicle tethering complex. ICR1-SEC3 complexes can interact with ROPs in vivo and are thereby recruited to the plasma membrane. ICR1 knockdown or silencing leads to cell deformation and loss of the root stem cells population, and ectopic expression of ICR1 phenocopies activated ROPs/RACs. ICR1 presents a new paradigm in ROP/RAC signaling and integrates mechanisms regulating cell form and pattern formation at the whole plant level.Key words: Rho, auxin, root development, vesicle trafficking, RAC, ROP, polarity, Arabidopsis, exocyst     

ROPs:植物细胞内多种信号通路的分子开关

植物RHO相关蛋白GTPases(RHO-related GTPases of plants, ROPs)是广泛存在于植物中的一类信号转导G蛋白(又称GTP结合蛋白),其通过结合GDP或GTP在非活性和活性状态间进行切换,进而在细胞极性控制、形态发育、激素水平调控、逆境反应等诸多植物生命活动的信号转导过程中扮演重要的分子开关角色。本文对ROP蛋白的结构域及基于蛋白质结构分类进行了介绍,并对拟南芥、玉米、水稻和大麦中的ROP家族蛋白质进行了系统进化分析。分析结果表明,这些植物中的ROP蛋白根据蛋白质结构域组成可分为Ⅰ类(typeⅠ)和Ⅱ类(typeⅡ)两种类型,而根据蛋白质序列的保守性可将其在植物中的ROP蛋白划分为4个进化枝。本综述不但对ROP蛋白作为分子开关在细胞内调控各种信号通路的机制进行了叙述,还对ROP在花粉管、根毛及植物表皮铺盖细胞极性发育,以及其他抗逆反应中的具体作用和机制及研究进展进行了阐述。本文还对ROP蛋白在ABA、IAA、BR等植物激素信号传导过程中的调控作用及研究进展进行了阐述。本文对植物ROP蛋白研究过程中尚未解决的问题,例如不同的ROP蛋白在同一个信号通路中的作用为何如此不同,以及ROP是如何协调不同的信号通路以共同调控一个植物发育或者生理过程等问题进行了总结,并在此基础上对未来的研究方向进行了展望。     

A class III peroxidase specifically expressed in pathogen-attacked barley epidermis contributes to basal resistance

Higher plants possess large multigene families encoding secreted class III peroxidase (Prx) proteins. In barley, two Prx cDNAs encoding HvPrx07 and HvPrx08 have been isolated and characterized to some extent with respect to a resistance-mediating function upon attack by the powdery-mildew fungus Blumeria graminis f.sp. hordei ( Bgh ). Here we present evidence for the tissue-specific accumulation of a new Prx mRNA, HvPrx40 , in Bgh -attacked epidermis of barley ( Hordeum vulgare ). The encoded protein is predicted to be secreted into the apoplastic space of epidermal cells due to the absence of a C-terminal extension, which distinguishes it from other Prx proteins reported to accumulate in leaf epidermis. Transient overexpression of HvPrx40 enhanced the resistance of wheat ( Triticum aestivum ) and barley against Blumeria graminis f.sp. tritici (wheat powdery mildew) and Bgh , respectively. These findings were complemented by transient-induced gene silencing showing hypersusceptibility of barley leaf epidermal cells to Bgh . The local accumulation of oxidized 3,3-diaminobenzidine that reflects H₂O₂ production at sites of attempted fungal penetration was not reduced in HvPrx40 -silenced cells, suggesting a role of this peroxidase other than the production of reactive oxygen species.