叶际微生物诱发气孔免疫的机制及其应用前景北大核心CSCD

植物叶际微生物通过自身代谢活动影响植物功能的正常运行。而植物则可感应叶际微生物的存在,在诱发气孔免疫关闭以抵御病原菌入侵的同时,也降低了植物蒸腾作用,提高了其水分利用效率。对气孔免疫相关理论的研究有利于开发新型生物抗蒸腾剂,并对开发节水农业新技术具有重要意义。该文综述了叶际微生物与植物间的互作关系、气孔免疫及其免疫机制等方面的研究进展,并探讨了相关机制在节水农业方面的应用前景和重点研究方向。     

叶际微生物诱发气孔免疫的机制及其应用前景

植物叶际微生物通过自身代谢活动影响植物功能的正常运行。而植物则可感应叶际微生物的存在,在诱发气孔免疫关闭以抵御病原菌入侵的同时,也降低了植物蒸腾作用,提高了其水分利用效率。对气孔免疫相关理论的研究有利于开发新型生物抗蒸腾剂,并对开发节水农业新技术具有重要意义。该文综述了叶际微生物与植物间的互作关系、气孔免疫及其免疫机制等方面的研究进展,并探讨了相关机制在节水农业方面的应用前景和重点研究方向。     

植物气孔运动调节的新进展

综述了植物气孔的发生和气孔运动的调节机制,并对高表达pepc水稻气孔调节机理和高光效特性的关系作了简要的分析,最后对植物气孔运动的调节机制研究做了展望。     

不同生境条件下蕨类和被子植物的气孔形态特征及其对光强变化的响应

气孔是植物与大气环境进行气体交换的重要通道, 在调控植物碳水平衡方面发挥着重要作用。为探讨生境和植物类型对气孔形态特征的影响以及气孔对光强变化的响应格局在不同植物间和不同生境条件下的变异, 选取开阔生境和林下生境的5种蕨类植物和4种被子植物, 测定了它们的气孔形态特征和气孔导度对光强变化的响应。此外, 还收集了8篇文献中开阔和林下生境的45种蕨类植物和70种被子植物的气孔密度和气孔长度数据, 以增大样本量从而更好地探讨不同生境条件下蕨类和被子植物气孔密度及长度的变异格局, 并通过分析生境和植物类型对气孔形态特征的影响来推测生境和植物类型对气孔响应行为的可能影响。实验结果表明, 与林下植物相比, 开阔环境下的植物气孔密度更大, 气孔长度更小, 气孔对光强降低的响应更敏感; 但植物类型对气孔形态特征的影响以及对气孔响应光强的敏感程度的影响均不显著。对文献数据的分析表明, 生境和植物类型对气孔形态特征均有显著影响。考虑到气孔响应快慢与气孔形态特征密切相关, 与蕨类植物相比, 被子植物小而密的气孔可能为其更快地响应环境变化提供了基础。研究表明生境和植物类型对气孔响应行为均有显著影响。     

Stomatal characteristics of ferns and angiosperms and their responses to changing light intensity at different habitats

气孔是植物与大气环境进行气体交换的重要通道, 在调控植物碳水平衡方面发挥着重要作用。为探讨生境和植物类型对气孔形态特征的影响以及气孔对光强变化的响应格局在不同植物间和不同生境条件下的变异, 选取开阔生境和林下生境的5种蕨类植物和4种被子植物, 测定了它们的气孔形态特征和气孔导度对光强变化的响应。此外, 还收集了8篇文献中开阔和林下生境的45种蕨类植物和70种被子植物的气孔密度和气孔长度数据, 以增大样本量从而更好地探讨不同生境条件下蕨类和被子植物气孔密度及长度的变异格局, 并通过分析生境和植物类型对气孔形态特征的影响来推测生境和植物类型对气孔响应行为的可能影响。实验结果表明, 与林下植物相比, 开阔环境下的植物气孔密度更大, 气孔长度更小, 气孔对光强降低的响应更敏感; 但植物类型对气孔形态特征的影响以及对气孔响应光强的敏感程度的影响均不显著。对文献数据的分析表明, 生境和植物类型对气孔形态特征均有显著影响。考虑到气孔响应快慢与气孔形态特征密切相关, 与蕨类植物相比, 被子植物小而密的气孔可能为其更快地响应环境变化提供了基础。研究表明生境和植物类型对气孔响应行为均有显著影响。     

青藏高原和内蒙古高原典型草地植物叶片肾型和哑铃型气孔器气孔特征及其与环境的关系

该研究利用植物制片技术,以中国青藏高原和内蒙古高原典型草地常见种或优势种植物的叶片为研究对象,通过比较分析叶片哑铃型气孔器和肾型气孔器的特征及其与环境因子的关系,揭示植物叶片两类气孔器对环境因子的响应策略。结果表明:(1)叶片哑铃型气孔器气孔指标的变异系数小于肾型气孔器。(2)叶片哑铃型气孔器气孔指标与环境气候指标的关系弱于肾型气孔器。(3)叶片哑铃型气孔器气孔特征与环境关系在叶片上下表面之间存在显著差异,而肾型气孔器气孔特征与环境因子的关系在叶片上下表面之间无显著差异。(4)叶片哑铃型气孔器的气孔特征与降水关系密切,而肾型气孔器气孔特征与温度关系密切。(5)同一种气孔器的气孔特征在两个地区(青藏高原和内蒙古高原)间存在显著差异。研究认为,肾型气孔器和哑铃型气孔器的气孔特征及其与环境之间的关系存在差异,在分析气孔特征时有必要将肾形与哑铃形保卫细胞形成的气孔器加以区分,该研究结果有助于进一步理解中国草地植物叶气孔特征对气候变化的响应与适应策略。     

干旱下植物气孔运动的调控

概述了植物气孔对大气干旱和土壤干旱的反应,认为植物气孔对大气干旱的反应并不是一种反馈机制;并就干旱条件下植物气孔运动的水力学和化学信号调控机制进行了简要论述,认为虽然化学信号调控干旱下气孔运动更为广泛,但ABA不是唯一的化学信号,水分关系影响了信号的产生、运转和气孔对信号的敏感性,干旱条件下水力学和化学信号共同调控着植物的气孔运动。     

青藏高原草地双子叶植物叶片的气孔特征研究

利用光学显微镜对青藏高原29种草地双子叶植物叶片的气孔形态与数量特征进行观察及差异显著性分析,为揭示青藏高原草地双子叶植物对高原环境的适应机制及探索气孔作为辅助分类的依据奠定理论基础。结果表明:(1)青藏高原草地双子叶植物大多数种类在叶片上、下表皮均分布有气孔,气孔随机排列,气孔器多为无规则型。(2)气孔长度(SL)较小,上、下表皮的气孔平均长度分别为26.20μm与25.56μm,且气孔密度(SD)与气孔指数(SI)相对较大。(3)不同科、属、种间叶片上、下表皮的SL、SD、SI差异均极显著。(4)叶片上、下表皮的6个气孔数量特征之间具有显著相关关系。(5)上表皮的SL、SD与不同科、属、种间显著相关,下表皮除SI与物种间相关不显著外,其他指标与科、属、种间显著相关。研究认为,青藏高原草地双子叶植物独特的气孔形态与数量特征是对高寒极端环境长期适应的结果,且气孔数量特征对植物辅助分类具有重要价值。     

干旱胁迫对植物气孔特性影响研究进展

综述干旱胁迫对植物叶片气孔特性的影响,从气孔大小、气孔密度、气孔导度等方面概括植物气孔对干旱胁迫的响应,分析植物气孔特性与其抗旱性的关系,并对气孔特性的研究方向进行展望。     

褪黑素调节烟草丁香假单胞菌抗性的功能研究

为分析褪黑素(N-乙酰-5-甲氧基色胺)在植物先天免疫中的功能及调控机理,研究以病原菌丁香假单胞杆菌(Pseudomonas syringae pv.tomato DC3000,Pst DC3000)—烟草互作系统为模型,检测了病原菌侵染对烟草褪黑素相关基因表达的影响,并探讨了褪黑素对植物叶片病原菌生长以及气孔开度和活性氧自由基(reactive oxygen species,ROS)含量的影响以及调控机理。结果表明:(1)Pst DC3000处理提高了烟草褪黑素合成(NtSNAT1)和受体(NtPMTR1)基因表达,且外源褪黑素处理降低了叶片中的病原菌含量。(2)与野生型植物相比,过表达大豆GmSNAT1基因显著提高了转基因烟草中内源褪黑素含量和NtPMTR1的表达,且转基因烟草叶片中的Pst DC3000菌落数显著下降。(3)外源褪黑素和细菌鞭毛蛋白多肽flg22处理诱导了野生型和转基因烟草保卫细胞中ROS产生和气孔关闭,且转基因植物对褪黑素和flg22诱导的气孔关闭和ROS产生比野生型烟草更加敏感。综上所述,研究表明褪黑素可能通过受体NtPMTR1介导的信号途径促进保卫细胞ROS产生,诱导气孔关闭,从而降低病原菌Pst DC3000的入侵。     

斑驳气孔特点及形成机理

气孔是植物叶片内外气体交换的场所。斑驳气孔在形态结构、动态变化、光合气体交换机制等方面都与常见的普通气孔不同,是植物体响应环境变化而形戍的特殊气孔形式。本文介绍了斑驳气孔的特点及其形成机理。     

近一世纪黄土高原区植物气孔密度变化规律

以黄土高原地区 4种典型 C3植物辽东栎 (Quercus liaotungensis)、虎榛子 (Ostryopsis davidiana)、酸枣 (Zizyphus jujubavar.spinosa)和狼牙刺 (Sophora viciifolia)植物腊叶样品标本为材料 ,利用数码图像显微镜处理系统 ,研究了从 2 0世纪 30年代至 2 0 0 2年中不同年代植物气孔密度的变化情况。结果表明 ,在近百年中 ,4种植物气孔密度随环境变化的演变规律不同 ,辽东栎气孔密度升高率为 1.31% ,几乎没有变化 ,虎榛子气孔密度降低率为 9.79% ,下降也不十分明显 ,而酸枣和狼牙刺的气孔密度降低率分别为 32 .35 %、4 6 .85 % ,下降非常明显。 4种植物气孔密度变化率比较 :狼牙刺 >酸枣 >虎榛子 >辽东栎。说明不同植物对气候环境因子的敏感性不同 ,具有不同的适应环境变化的策略 ,环境变化对气孔密度的影响 ,其效应因植物种类而异     

白刺叶片气孔特征对人工模拟降雨的响应

以荒漠生态系统典型植物白刺(Nitraria tangutorum Bobr)叶片为研究对象,利用数码图像显微镜处理系统,研究了不同人工模拟增雨处理下的白刺叶片气孔密度及形态特征的变化情况。结果表明,荒漠植物固有特征决定了白刺叶片下表皮气孔密度大于上表皮,上表皮、下表皮气孔密度对增雨响应差异不显著(P0.05)。增雨处理上表皮、下表皮气孔密度与对照差异显著(P0.05)。相同增雨季节,50%处理下叶片气孔密度高于100%处理;不同增雨季节,气孔密度对生长季后期增雨响应更明显。白刺叶表皮气孔分布遵循"一细胞间隔(one cell spacing rule)"法则。增雨后叶片上表皮和下表皮气孔长度、宽度均有不同程度的增加,气孔形态特征对100%处理的响应较50%处理更为明显,且生长季后期增雨对叶片气孔形态特征的影响更大。     

Leaf anatomy of Caltha dioneaefolia Hooker (Ranunculaceae) – is this species carnivorous?

The leaf of C. dioneaefolia is composed of two pairs of lobes, each pair resembling a trap of the carnivorous plant Dionaea. The anatomy of the leaf was studied to examine the possibility that this species, like Dionaea , is carnivorous. Neither glandular structures, nor trigger hairs could be found, and it was concluded that C. dioneaefolia is non-carnivorous. The leaf of C. dioneaefolia is dorsiventral. The inner surface of each leaf lobe is covered with a thick cuticle with numerous anomocytic stomata. The stomata seem to be functional, not occluded. The outer surface of each leaf lobe is covered with a thin cuticle and has no stomata. The mesophyll is of the conjugate type, with papillae both in the pallisade and in the spongy mesophyll cells. The conductive system is developed to only a limited extent.     

豚鼠卵巢囊淋巴孔的发现及卵巢囊超微结构研究

本实验通过扫描电镜等方法研究豚鼠卵巢囊及卵巢囊淋巴孔的结构,并探讨了卵巢囊及其淋巴孔的种属差异.实验结果首次报道豚鼠卵巢囊内、外层上皮均存在淋巴孔;豚鼠卵巢囊结构在输卵管走行、囊闭合程度及囊表面超微结构等方面与金仓鼠存在差异.结果提示豚鼠卵巢囊内、外层淋巴孔是沟通卵巢囊腔、卵巢囊淋巴系及腹膜腔的形态基础,可能是三者间物质转运的重要途径.卵巢囊淋巴孔可能影响物种的繁殖并参与囊腔内局部免疫反应.卵巢囊结构和发育程度与对应的输卵管伞端等结构及其他生殖特点相适应,研究结果丰富了生殖形态学和比较解剖学资料.     

The role of cytoskeleton in stomata functioning

The main question in this review is of whether and how the cytoskeleton of guard cells is involved in stomata movements. The main function of stomata is the regulation of the rate of gas exchange between the plant environment and underlying plant tissues. As a result of special morphology and anatomy GCs form the stomatal pore. It can open or close in a controlled manner via internal or external signal-induced changes in GCs turgor pressure, volume and shape. The mechanism of stomata movement is a complex process. A network of actin microfilaments and microtubules, dynamic polymers collectively known as the cytoskeleton forms protein fibril systems in GCs. CT elements are dynamic structures, interconnected to different cell structures. The organization of CT during morphogenesis of stomata is very important in establishing the size and shape of GCs. It is well documented that AFs and MTs are involved in stomata movements and can modify the ability of GCs to respond to environmental and hormonal stimuli. Data gathered clearly suggest that the organization of CT elements is not a direct effect of stomata movements. Several investigation procedures for study of the CT role in stomata functioning, including GCs treatment with anti-CT drugs (disrupters or stabilizers), have been analyzed and discussed in this review but the question of what role AFs and MTs play in stomata movements and how they work still remains open. The availability of new CT visualization techniques and the usage of mutants to study this problem is a good perspective for further research.     

Ultrastructure of stomatal development in early-divergent angiosperms reveals contrasting patterning and pre-patterning

Background and Aims

Angiosperm stomata consistently possess a pair of guard cells, but differ between taxa in the patterning and developmental origin of neighbour cells. Developmental studies of phylogenetically pivotal taxa are essential as comparative yardsticks for understanding the evolution of stomatal development.

Methods

We present a novel ultrastructural study of developing stomata in leaves of Amborella (Amborellales), Nymphaea and Cabomba (Nymphaeales), and Austrobaileya and Schisandra (Austrobaileyales), representing the three earliest-divergent lineages of extant angiosperms (the ANITA-grade).

Key Results

Alternative developmental pathways occur in early-divergent angiosperms, resulting partly from differences in pre-patterning and partly from the presence or absence of highly polarized (asymmetric) mitoses in the stomatal cell lineage. Amplifying divisions are absent from ANITA-grade taxa, indicating that ostensible similarities with the stomatal patterning of Arabidopsis are superficial. In Amborella, ‘squared’ pre-patterning occurs in intercostal regions, with groups of four protodermal cells typically arranged in a rectangle; most guard-mother cells are formed by asymmetric division of a precursor cell (the mesoperigenous condition) and are typically triangular or trapezoidal. In contrast, water-lily stomata are always perigenous (lacking asymmetric divisions). Austrobaileya has occasional ‘giant’ stomata.

Conclusions

Similar mature stomatal phenotypes can result from contrasting morphogenetic factors, although the results suggest that paracytic stomata are invariably the product of at least one asymmetric division. Loss of asymmetric divisions in stomatal development could be a significant factor in land plant evolution, with implications for the diversity of key structural and physiological pathways.     

Stomatal behaviour and leaf water potential of chilled and water-stressed Solanum melongena, as influenced by growth history

Abstract Leaf diffusion resistance and leaf water potential of intact Solanum melongena plants were measured during a period of chilling at 6 °C. Two pretreatments, consisting of a period of water stress or a foliar spraying of abscisic acid (ABA), were imposed upon the plants prior to chilling. The control plants did not receive a pretreatment. In addition to intact plant studies, stomatal responses to water loss and exogenous abscisic acid were investigated using excised leaves, and the influence of the pretreatment observed. Chilled, control plants wilted slowly and maintained open stomata despite a decline in leaf water potential to –2.2 MPa after 2 d of chilling. In contrast plants that had been water stressed or had been sprayed with abscisic acid, prior to chilling, did not wilt and maintained a higher leaf water potential and a greater leaf diffusion resistance. In plants that had not received a pretreatment, abscisic acid caused stomatal closure at 35 °C, but at 6°C it did not influence stomatal aperture. The two pretreatments greatly increased stomatal sensitivity to both exogenous ABA and water stress, at both temperatures. Stomatal response to water loss from excised leaves was greatly reduced at 6°C. These results are discussed in relation to low temperature effects on stomata and the influence of preconditioning upon plant water relations.     

Growth and stomata development of Arabidopsis hypocotyls are controlled by gibberellins and modulated by ethylene and auxins

The plant hormones gibberellin (GA), ethylene and auxin can promote hypocotyl elongation of Arabidopsis seedlings grown in the light on a low nutrient medium (LNM). In this study, we used hypocotyl elongation as a system to investigate interactions between GA and ethylene or auxin and analysed their influence on the development of stomata in the hypocotyl. When applied together, GA and ethylene or auxin exerted a synergistic effect on hypocotyl elongation. Stimulated cell elongation is the main cause of hypocotyl elongation. Furthermore, hypocotyls treated with GA plus either ethylene or auxin show an increased endoreduplication. In addition, a small but significant increase in cell number was observed in the cortical cell files of hypocotyls treated with ethylene and GA together. However, studies with transgenic seedlings expressing CycB1::uidA genes revealed that cell division in the hypocotyl occurs only in the epidermis and mainly to form stomata, a process strictly regulated by hormones. Stomata formation in the hypocotyl is induced by the treatment with either GA or ethylene. The effect of GA could be strongly enhanced by the simultaneous addition of ethylene or auxin to the growth medium. Gibberellin is the main signal inducing stomata formation in the hypocotyl. In addition, this signal regulates hypocotyl elongation and is modulated by ethylene and auxin. The implication of these three hormones in relation to cell division and stomata formation is discussed.