保卫细胞中的微丝骨架

微丝骨架存在于多种植物的保卫细胞中,周质微丝骨架的排列和结构是动态的。越来越多的证据表明保卫细胞中的微丝骨架可作为信号调节物,对气孔的启闭运动起着重要的调控作用。本文综述了保卫细胞微丝骨架的标记方法、结构,以及其在气孔运动中的功能和作用机制的最新研究进展。     

微丝骨架和活性氧在调节气孔运动中的作用及机制

气孔运动调节植物的光合作用和蒸腾作用,对植物的生长发育和干旱等非生物胁迫的响应都起到重要的作用。保卫细胞能够通过感知胞内和胞外多种信号调节气孔开度,因此,保卫细胞已经成为植物细胞信号转导研究中广泛应用的细胞模型。该文对保卫细胞中微丝骨架和活性氧对气孔运动的调节作用、微丝骨架在调节细胞壁与质膜间联系中的作用进行了综述,最后分析了微丝骨架通过ROS(reactive oxygen species)调节保卫细胞壁–质膜联系参与气孔运动调控的可能机制。     

拟南芥保卫细胞微丝骨架的解聚可能参与了细胞外钙调素诱导的气孔关闭

细胞外钙调素(CaM)在植物的许多生理活动中都执行着重要功能, 但它对气孔运动的作用及其调控机制, 人们了解的很少. 以模式植物拟南芥为材料, 研究了细胞外CaM在保卫细胞壁上的存在及其对气孔运动的调控机制. 结果表明, 拟南芥保卫细胞壁中存在有分子量为17 kD的CaM, 并应用W7-琼脂糖和CaM抗血清初步证明了保卫细胞壁中存在的CaM可能具有促进气孔关闭和抑制气孔开放的作用. 在应用外源CaM诱导气孔关闭的实验中, 保卫细胞微丝骨架由长而呈辐射状分布的聚合态逐步解聚, 气孔开度也随着降低. 药理学实验结果表明, 保卫细胞微丝骨架的解聚能明显地促进外源CaM诱导的气孔关闭, 而微丝骨架的聚合则抑制这一过程. 研究结果还表明, 外源CaM能诱导保卫细胞[Ca²⁺]_cyt升高; 当使用Ca²⁺螯合剂EGTA时, 外源CaM诱导的[Ca²⁺]_cyt升高和气孔关闭运动均受到抑制. 为此推测细胞外CaM可能是通过诱导保卫细胞[Ca²⁺]_cyt升高, 导致微丝骨架的解聚, 进而促进气孔的关闭运动.     

蚕豆水孔蛋白可能参与微丝骨架对气孔运动的调节

水孔蛋白的抑制剂HgCl2可明显抑制壳梭孢菌素（FC）和微丝骨架的解聚剂细胞松弛素D（CD）对蚕豆保卫细胞原生质体膨胀的诱导作用,而对微丝骨架的稳定剂鬼笔环肽（phalloidin）的抑制作用影响不明显。这表明水孔蛋白可能介导了FC和微丝骨架对气孔运动的调节。     

气孔蒸腾中保卫细胞原生质的调控作用

气孔运动的机理一般公认为保卫细胞的渗透调节。作者所在研究小组近几年的工作表明：动物神经递质乙酰胆碱参与气孔运动的调节;植物细胞骨架微管、微丝在气孔运动中起重要作用。因面提出保卫细胞原生质在气孔蒸腾中的气孔蒸腾中的作用值得进一步研究。     

拟南芥微丝加帽蛋白β亚基参与壳梭孢素诱导的气孔开放过程

气孔是植物响应外源信号,与环境进行水分和气体交换的门户。由外源信号引起的保卫细胞微丝骨架动态变化在气孔运动中发挥重要作用,但是具体的精确调节机制仍不清楚。微丝结合蛋白家族(ABPs) 是微丝动态组装最直接的调控者,它们的作用不容忽视。本文运用反向遗传学,以微丝结合蛋白—加帽蛋白 (CP) β-亚基 (CPB) 突变体cpb-3为实验材料,探究其在壳梭孢素 (FC)诱导气孔开放中的作用。结果发现:离体叶片干燥3 h,cpb-3突变体的叶片失水率为63.45%,明显高于野生型的48.99%。气孔开度测量及激光共聚焦显微镜观察发现,cpb-3突变体的气孔开放程度以及微丝动态重排对FC分子更敏感。气孔开度相比野生型增大了20% (P<0.05),含辐射状微丝排布的保卫细胞数量比例增幅达到58.3%,比对照组高出18.5%。此外,非损伤微测技术记录保卫细胞Ca²⁺、K⁺等跨膜运输动态,FC处理下,cpb-3突变体保卫细胞中Ca²⁺外流速度升至212.86 pmol cm^-2s^-1,野生型仅为68.76 pmol cm^-2s^-1,明显快于野生型。且K⁺内流也有相同表现。综上表明,微丝加帽蛋白CP的β亚基CPB可能通过调节保卫细胞微丝骨架动态重排以及离子流动,在FC诱导的气孔运动中发挥重要的作用。     

GFP-mTn融合蛋白对蓝猪耳生活细胞微丝骨架的标记

用农杆菌介导法将嵌合基因GFP-mTn(mTn是微丝结合蛋白Talin的微丝结合域,可以显示活体细胞中微丝的结构)导入蓝猪耳。经激光共聚焦显微镜观察了转基因植株的各种不同组织中融合蛋白的表达和分布情况。在叶片的表皮细胞、保卫细胞、根部的皮层细胞中有融合蛋白的不同程度表达。但仅在保卫细胞中微丝标记状况良好,显示基因表达的组织特异性。经光诱导处于开放态的气孔的保卫细胞微丝呈网状结构,在细胞内无规则分布;经黑暗诱导处于关闭态的气孔保卫细胞中微丝束沿保卫细胞纵轴排列,呈卷曲状分布,并观察到螺旋和环状的微丝结构。在转基因植株的其他部位,例如茎表皮细胞、根毛细胞和花粉粒中,未检测到目的基因的表达。本研究获得的转基因植株为研究气孔运动过程中微丝动态变化提供了有用的材料。     

GFP-mTn融合蛋白对蓝猪耳生活细胞微丝骨架的标记

用农杆菌介导法将嵌合基因GFP-mTn(mTn是微丝结合蛋白Talin的微丝结合域,可以显示活体细胞中微丝的结构)导入蓝猪耳.经激光共聚焦显微镜观察了转基因植株的各种不同组织中融合蛋白的表达和分布情况.在叶片的表皮细胞、保卫细胞、根部的皮层细胞中有融合蛋白的不同程度表达.但仅在保卫细胞中微丝标记状况良好,显示基因表达的组织特异性.经光诱导处于开放态的气孔的保卫细胞微丝呈网状结构,在细胞内无规则分布;经黑暗诱导处于关闭态的气孔保卫细胞中微丝束沿保卫细胞纵轴排列,呈卷曲状分布,并观察到螺旋和环状的微丝结构.在转基因植株的其他部位,例如茎表皮细胞、根毛细胞和花粉粒中,未检测到目的基因的表达.本研究获得的转基因植株为研究气孔运动过程中微丝动态变化提供了有用的材料.     

WASP与微丝骨架研究进展

细胞骨架是细胞内由蛋白质万分组成的网架状结构,在细胞多种生命活动中起重要作用威奥综合征蛋白（WASP）家族为近年来发现的参与细胞信号传递和微丝骨架运动的中介蛋白,在促进细胞信号传递与微丝骨架运动而诱使细胞变形,趋化,形成伪足状突起结构中起到至关重要的作用。本文主要综述WASP近年来的研究进展及在介导T细胞信号级联及微丝骨架运动中的作用。     

保卫细胞碳代谢与气孔运动

作为气孔运动渗透调节的代谢基础 ,气孔保卫细胞的碳代谢有特殊的调控机理。本文介绍了气孔保卫细胞中参与碳代谢的主要酶的特性及调控特点 ,特别是保卫细胞叶绿体中催化苹果酸形成的PEP羧化酶 ,其磷酸化和去磷酸化参与了保卫细胞信号传递。保卫细胞碳代谢调控在气孔运动调节中的作用 ,并讨论了保卫细胞碳代谢与能量代谢的关系     

Actin filaments of guard cells are reorganized in response to light and abscisic acid.

We recently showed that treatment with actin antagonists perturbed stomatal behavior in Commelina communis L. leaf epidermis and therefore suggested that dynamic changes in actin are necessary for signal responses in guard cells (M. Kim, P.K. Hepler, S.O. Eun, K.-S. Ha, Y. Lee [1995] Plant Physiol 109: 1077-1084). Here we show that actin filaments of guard cells, visualized by immunofluorescence microscopy, change their distribution in response to physiological stimuli. When stomata were open under white-light illumination, actin filaments were localized in the cortex of guard cells, arranged in a pattern that radiates from the stomatal pore. In marked contrast, for guard cells of stomata closed by darkness or by abscisic acid, the actin organization was characterized by short fragments randomly oriented and diffusely labeled along the pore site. Upon abscisic acid treatment, the radial pattern of actin arrays in the illuminated guard cells began to disintegrate within a few minutes and was completely disintegrated in the majority of labeled guard cells by 60 min. Unlike actin filaments, microtubules of guard cells retained an unaltered organization under all conditions tested. These results further support the involvement of actin filaments in signal transduction pathways of guard cells.     

Abscisic acid-induced actin reorganization in guard cells of dayflower is mediated by cytosolic calcium levels and by protein kinase and protein phosphatase activities

In guard cells of open stomata under daylight, long actin filaments are arranged at the cortex, radiating out from the stomatal pore. Abscisic acid (ABA), a signal for stomatal closure, induces rapid depolymerization of cortical actin filaments and the slower formation of a new type of actin that is randomly oriented throughout the cell. This change in actin organization has been suggested to be important in signaling pathways involved in stomatal closing movement, since actin antagonists interfere with normal stomatal closing responses to ABA. Here we present evidence that the actin changes induced by ABA in guard cells of dayflower (Commelina communis) are mediated by cytosolic calcium levels and by protein phosphatase and protein kinase activities. Treatment of guard cells with CaCl2 induced changes in actin organization similar to those induced by ABA. Removal of extracellular calcium with EGTA inhibited ABA-induced actin changes. These results suggest that Ca2+ acts as a signal mediator in actin reorganization during guard cell response to ABA. A protein kinase inhibitor, staurosporine, inhibited actin reorganization in guard cells treated with ABA or CaCl2, and also increased the population of cells with long radial cortical actin filaments in untreated control cells. A protein phosphatase inhibitor, calyculin A, induced fragmentation of actin filaments in ABA- or CaCl2-treated cells and in control cells, and inhibited the formation of randomly oriented long actin filaments induced by ABA or CaCl2. These results suggest that protein kinase(s) and phosphatase(s) participate in actin remodeling in guard cells during ABA-induced stomatal closure.     

Cortical actin filaments in guard cells respond differently to abscisic acid in wild-type and abi1-1 mutant Arabidopsis

Cortical actin filaments in guard cells of Commelina communis L. show signal-specific organization during stomatal movements [S.-O. Eun and Y. Lee (1997) Plant Physiol 115: 1491–1498; S.-O. Eun and Y. Lee (2000) Planta 210: 1014–1017]. To study the roles of actin in signal transduction, it is advantageous to use Arabidopsis thaliana (L.) Heynh., an excellent model plant with numerous well-characterized mutants. Using an immunolocalization technique, we found that actin deployments in guard cells of A. thaliana were basically identical to those in C. communis: actin proteins were assembled into radial filaments under illumination, and were disassembled by ABA. In addition, we examined actin organization in an ABA-insensitive mutant (abi1-1) to test the involvement of protein phosphatase 2C (PP2C) in the control of actin structure. A clear difference was observed after ABA treatment, namely, neither stomatal closing nor depolymerization of actin filaments was observed in guard cells of the mutant. Our results indicate that PP2C participates in ABA-induced actin changes in guard cells. Received: 23 June 2000 / Accepted: 20 October 2000     

Immuno-reactant to RhoA antibody co-localizes with cortical actin filaments in guard cells of open stomata inCommelina communis L.

Stomatal regulation is essential for the growth of land plants. Pairs of guard cells that delineate the stomata perceive stimuli and respond to acquire the optimum aperture. The actin cytoskeleton participates in signaling pathways of the guard cell (Kim et al., 1995; Eun and Lee, 1997; Hwang et al., 1997). To identify the upstream molecules that regulate actin dynamics in plant cells, we immunoblotted proteins extracted from leaves ofCommelina commuais L. with the RhoA antibody, and identified one band of 26KD from the epidermis. Using immunofluorescence microscopy, we examined the subcellular distribution of the immuno-reactant(s) in guard cells. When stomata were open under light, the organization of the immuno-reactant(s) resembled the radial arrangement of cortical actin filaments of guard cells. Double-labeling of the guard cells, using the RhoA and actin antibodies as primary antibodies, showed that the immuno-reactant(s) of the RhoA antibody and actin filaments co-localized in the cortex of illuminated guard cells. However, the pattern was not found in guard cells when stomata were closed under darkness or by ABA, conditions under which cortical actin proteins are disassembled in guard cells. From these observations, we can suggest the possible presence of a RhoA-like protein and its involvement in the organization of the actin cytoskeleton in guard cells.     

Stomatal opening by fusicoccin is accompanied by depolymerization of actin filaments in guard cells

Actin in guard cells is assembled in a radial pattern when stomata are induced to open under light, but the filaments are disassembled when stomata are closed under darkness or by abscisic acid (S.-O. Eun and Y. Lee, 1997, Plant Physiol. 115: 1491–1498). To test if signals that open stomata commonly generate the polymerized form of actin in guard cells, leaves of Commelina communis L. were treated with a potent stomatal opening agent, fusicoccin, and the actin organization examined by immunolocalization techniques. When stomata were induced to open by fusicoccin, hardly any of the filamentous form of actin was detected; instead, the actin resembled that present in guard cells that had been treated with an antagonist to actin filaments, cytochalasin D, and showed a sharp contrast to the long filaments developed in illuminated guard cells. Furthermore, treatment of illuminated leaves with fusicoccin disintegrated actin filaments that had already been formed in the guard cells. Preincubation of leaves with phalloidin, which interferes with fusicoccin-induced actin depolymerization, delayed fusicoccin-induced opening during the early phase. These observations suggest that the prevention of actin filament formation and/or depolymerization of actin filaments may accelerate the stomatal opening process in response to fusicoccin. Received: 1 October 1999 / Accepted: 29 November 1999     

Array and distribution of actin filaments in guard cells contribute to the determination of stomatal aperture

Actin filaments in guard cells and their dynamics function in regulating stomatal movement. In this study, the array and distribution of actin filaments in guard cells during stomatal movement were studied with two vital labeling, microinjection of alexa-phalloidin in Vicia faba and expression of GFP-mTn in tobacco. We found that the random array of actin filaments in the most of the closed stomata changed to a ring-like array after stomatal open. And actin filaments, which were throughout the cytoplasm of guard cells of closed stomata (even distribution), were mainly found in the cortical cytoplasm in the case of open stomata (cortical distribution). These results revealed that the random array and even distribution of actin filaments in guard cells may be required for keeping the closed stomata; similarly, the ring-like array and cortical distribution of actin filaments function in sustaining open stomata. Furthermore, we found that actin depolymerization, the trait of moving stomata, facilitates the transformation of actin array and distribution with stomatal movement. So, the depolymerization of actin filaments was favorable for the changes of actin array and distribution in guard cells and thus facilitated stomatal movement.     

Stochastic dynamics of actin filaments in guard cells regulating chloroplast localization during stomatal movement

Actin filaments and chloroplasts in guard cells play roles in stomatal function. However, detailed actin dynamics vary, and the roles that they play in chloroplast localization during stomatal movement remain to be determined. We examined the dynamics of actin filaments and chloroplast localization in transgenic tobacco expressing green fluorescent protein (GFP)-mouse talin in guard cells by time-lapse imaging. Actin filaments showed sliding, bundling and branching dynamics in moving guard cells. During stomatal movement, long filaments can be severed into small fragments, which can form longer filaments by end-joining activities. With chloroplast movement, actin filaments near chloroplasts showed severing and elongation activity in guard cells during stomatal movement. Cytochalasin B treatment abolished elongation, bundling and branching activities of actin filaments in guard cells, and these changes of actin filaments, and as a result, more chloroplasts were localized at the centre of guard cells. However, chloroplast turning to avoid high light, and sliding of actin fragments near the chloroplast, was unaffected following cytochalasin B treatment in guard cells. We suggest that the sliding dynamics of actin may play roles in chloroplast turning in guard cells. Our results indicate that the stochastic dynamics of actin filaments in guard cells regulate chloroplast localization during stomatal movement.     

Dynamics of vacuoles and actin filaments in guard cells and their roles in stomatal movement

Vacuoles and actin filaments are important cytoarchitectures involved in guard cell function. The changes in the morphology and number of vacuoles and the regulation of ion channel activity in tonoplast of guard cells are essential for stomatal movement. A number of studies have investigated the regulation of ion channels in animal and plant cells; however, little is known about the regulating mechanism for vacuolar dynamics in stomatal movement. Actin filaments of guard cells are remodelling with the changes in the stomatal aperture; however, the dynamic functions of actin filaments in stomatal movement remain elusive. In this paper, we summarize the recent developments in the understanding of the dynamics of actin filaments and vacuoles of guard cells during stomatal movement. All relevant studies suggest that actin filaments might be involved in stomatal movement by regulating vacuolar dynamics and the ion channels in tonoplast. The future study could be focused on the linker protein mediating the interaction between actin filaments and tonoplast, which will provide insights into the interactive function of actin and vacuole in stomatal movement regulation.