气孔功能的结构基础

近年来,国际上十分关注气孔动动的调控机理,在保卫细胞内外的信息传递和转导途径的研究方面取得重要进展。保卫细胞的特殊结构和气孔功能密切相关,对保卫细胞壁特性、质膜上的各种结合蛋白、质膜和液泡膜上的离子通道的研究,以及对细胞骨架和气孔运动的关系的探索为阐明气孔运动的机理提供了更多的依据。     

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。     

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。     

H+参与茉莉酸调控蚕豆气孔运动的信号转导

以BCECF-AM为pH的荧光探针,结合激光共聚焦扫描显微技术,研究H 可能参与茉莉酸(JA)调控气孔运动信号转导途径的结果表明,0.1~100μmol·L~(-1)浓度的(-)JA可诱导蚕豆气孔关闭,在引起气孔孔径改变之前,(-)JA能引起蚕豆保卫细胞胞质的碱化;而(±)JA可诱导气孔适当开放,它未引起蚕豆保卫细胞胞质中pH的明显改变。药理学实验证明,质膜上质子泵的抑制剂矾酸钠能减弱(-)JA诱导气孔关闭的作用;而质膜上质子泵的激活剂壳梭孢菌素(fusicoccin)基本上未改变(±)JA的作用趋势。(-)JA和(±)JA刺激保卫细胞胞质Ca2 变化则表现出不同趋势。说明不同异构体形式的JA在调节气孔运动中的作用和信号转导途径有所不同。     

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     

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。     

蚕豆保卫细胞质膜水通道蛋白的鉴定及其在气孔运动中的作用

水通道或水通道蛋白是水分运动的主要通道。以RD2 8cDNA和RD2 8抗体为探针证明了蚕豆 (ViciafabaL .)保卫细胞中存在水通道蛋白 ,并以气孔运动为指标 ,结合抗体和抑制剂处理证明水通道蛋白是水分运动的主要通道。研究表明编码质膜水通道蛋白的RD2 8转录体在叶片保卫细胞、叶肉细胞和维管束中高表达 ,尤以保卫细胞中最多 ;荧光免疫染色和Confocal显微镜观察表明 ,RD2 8抗体反应主要位于保卫细胞质膜。进一步采用RD2 8抗体和水通道蛋白抑制剂———HgCl2 (2 5 μmol L) 处理可抑制壳梭孢素 (FC)、光照诱导的气孔开放和原生质体体积膨胀以及ABA诱导的气孔关闭 ,但这种抑制作用可以被水通道抑制剂的逆转剂 β_巯基乙醇 (ME)逆转。表明蚕豆保卫细胞中存在水通道蛋白并参与蚕豆保卫细胞的运动过程。     

蚕豆保卫细胞质膜水通道蛋白的鉴定及其在气孔运动中的作用

水通道或水通道蛋白是水分运动的主要通道.以RD28 cDNA和RD28抗体为探针证明了蚕豆(Vicia fabaL.)保卫细胞中存在水通道蛋白,并以气孔运动为指标,结合抗体和抑制剂处理证明水通道蛋白是水分运动的主要通道.研究表明编码质膜水通道蛋白的RD28转录体在叶片保卫细胞、叶肉细胞和维管束中高表达,尤以保卫细胞中最多;荧光免疫染色和Confocal显微镜观察表明,RD28抗体反应主要位于保卫细胞质膜.进一步采用RD28抗体和水通道蛋白抑制剂--HgCl2 (25μmol/L)处理可抑制壳梭孢素(FC)、光照诱导的气孔开放和原生质体体积膨胀以及ABA诱导的气孔关闭,但这种抑制作用可以被水通道抑制剂的逆转剂β-巯基乙醇(ME)逆转.表明蚕豆保卫细胞中存在水通道蛋白并参与蚕豆保卫细胞的运动过程.     

蚕豆下表皮细胞外钙调素的存在及其对气孔运动的调节

细胞外钙调素可能作为多肽第一信使,调节细胞增殖、花粉萌发、特定基因表达等生理过程.气孔能灵敏地对外界刺激作出反应,快速开闭.本文用免疫电镜和免疫荧光显微镜技术证明保卫细胞及其它表皮细胞胞外都存在钙调素.外源纯化钙调素能促进气孔关闭、抑制气孔开放,最适浓度为10-8mol/L;不能透过质膜的大分子钙调素拮抗剂W7-agarose和钙调素抗血清都能抑制气孔关闭、促进开放,说明保卫细胞的内源胞外钙调素确实能促进气孔关闭、抑制开放,而且只能在细胞外起作用.推测在自然情况下,保卫细胞内源胞外钙调素可能作为胞外第一信使和其它信号分子一起调节气孔的开关运动,而且可能在环境刺激与细胞响应之间起重要作用.     

蚕豆下表皮细胞外钙调素的存在及其对气孔运动的调节

细胞外钙调素可能作为多肽第一信使,调节细胞增殖,花粉萌发,特定基因表达等生理过程,气孔能灵敏地对外界刺激作出反应,快速开闭,本文用免疫电镜和免疫荧光显微镜技术证明保卫细胞及其它表皮细胞胞外都存在钙调素;外源纯化钙调素能促进气孔关闭,抑制气孔开放,最适浓度为10^-8mol/L;不能透过质膜的大分子钙调素拮抗剂W—-agarose和钙调素抗血清都能抑制气孔关闭,促进开放,说明保卫细胞的内源胞外钙调素确实能促进气孔关闭,抑制开放。而且只能在细胞外起作用,推测在自然情况下,保卫细胞内源胞外钙调素可能作为胞外第一信使和其它信号分子一起调节气孔的开关运动,而且可能在环境刺激与细胞响应之间起重要作用。     

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.     

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.     

Functional Epidermal Cells are Necessary for Abscisic Acid Effects on Guard Cells

Experimental results are presented which show that abscisicacid (ABA) causes stomatal closure only if the stomatal complexis adjacent to live epidermal cells. It is further shown thatABA acts by affecting solute fluxes into and out of epidermaland guard cells. Live epidermal cells function as recipientsfor solutes and thereby assist their movement out of the guardcells. ABA-mediated solute leakage from guard cells alone doesnot suffice to cause stomatal closure within one hour.     

STOMATAL MECHANICS

A model of stomatal movement due to changes in turgor is presented which systematically illustrates the role of certain anatomical features. During the expansion of paired guard cells, there are two physical constraints that cause the guard cells to bend and thus open the stomatal pore. The radial orientation of the micellae is shown to be the crucial feature which directly transmits the movement of the dorsal wall of the polar and central section to the stomatal slit. Furthermore, it is necessary that either the overall length of the entire stomatal apparatus or length of the common wall between the polar segments of the guard cells be constrained during the expansion of the guard cells. The model also shows that asymmetrically thickened guard cell walls are not necessary to cause bending of the guard cell. The ideas set forth in our model are consistent with the opening movements of both elliptical and grass-type stomata.     

The nitrate transporter AtNRT1.1 (CHL1) functions in stomatal opening and contributes to drought susceptibility in Arabidopsis

The movement of guard cells in stomatal complexes controls water loss and CO(2) uptake in plants. Examination of the dual-affinity nitrate transporter gene AtNRT1.1 (CHL1) revealed that it is expressed and functions in Arabidopsis guard cells. CHL1 promoter-beta-glucuronidase and CHL1 promoter-green fluorescent protein constructs showed strong expression in guard cells, and immunolocalization experiments with anti-CHL1 antibody confirmed these results. To assess CHL1 function, chl1 mutant plants grown in the presence of nitrate were examined. Compared with wild-type plants, chl1 mutants had reduced stomatal opening and reduced transpiration rates in the light or when deprived of CO(2) in the dark. These effects result in enhanced drought tolerance in chl1 mutants. At the cellular level, chl1 mutants showed reduced nitrate accumulation in guard cells during stomatal opening and failed to show nitrate-induced depolarization of guard cells. In wild-type guard cells, nitrate induced depolarization, and nitrate concentrations increased threefold during stomatal opening. These results identify an anion transporter that functions in stomatal opening and demonstrate that CHL1 supports stomatal function in the presence of nitrate.