热胁迫下不结球白菜和甘蓝叶片组织结构的变化

利用显微及扫描电镜方法,研究不结球白菜及甘蓝的耐热品种和感热品种种在高温（３８－３９℃）胁迫下,叶片表皮和组织结构的差异。结果如下：耐热品种叶片下表皮比感热品种气孔频度高,气孔体积小且开张度小。耐热品种部分气孔呈关闭状态,而感热品种气孔基本上呈开放状态。显微结构观察到耐热品种叶肉组织细胞排列紧密,叶脉的维管束发达,特别是木质部的导管数量多且孔径大。而感热品种相比于耐热品种叶肉细胞排列疏松,维管束相     

水分胁迫对小麦叶片光合作用的影响及其与抗旱性的关系

在水分胁迫初期,两个小麦品种叶片光合速率,气孔导度和细胞间隙CO_2浓度降低,气孔限制值增加,光合速率的降低主要是气孔因素的限制。中度到严重水分胁迫使叶片光合速率、气孔导度和气孔限制值降低,细胞间隙CO_2浓度明显增加,且叶圆片放氧能力,叶绿体Hill反应、叶绿素荧光强度和表观量子产额降低,此时光合速率的降低主要是叶肉细胞光合活性的下降引起的。抗旱性弱的郑引一号叶肉细胞光合活性比抗旱性强的丰抗13更容易受到水分胁迫的影响。     

芭蕉芋叶片结构特征及其与抗旱性的关系

运用石蜡切片法和指甲油印迹法,对3个芭蕉芋品种的叶片解剖结构——叶片厚度、叶肉厚度、上表皮厚度、下表皮厚度、气孔密度、气孔长度及宽度、长细胞长度及宽度、短细胞长度及宽度等10项相关指标进行测定,分析芭蕉芋抗旱性与叶片结构之间的关系。结果表明:(1)芭蕉芋的表皮结构与抗旱性有一定的关系,表现为抗旱性强的品种气孔密度大,且长、短细胞体积小、排列紧密。(2)芭蕉芋叶片、叶肉、上下表皮厚度与抗旱性关系在不同品种间差异不显著。(3)芭蕉芋叶肉及上、下表皮占叶片横切面的比例与抗旱性存在显著相关关系。(4)芭蕉芋叶片保水能力与叶肉比例呈极显著负相关关系,与上表皮比例呈极显著正相关关系。     

热胁迫下萝卜不同耐热性品种细胞组织结构比较

利用显微及扫描电镜方法,研究热胁迫下萝卜不同耐热性品种外部形态,叶片及叶柄组织细胞结构的差异,耐热性品种比感热性品种叶表皮气孔密度大,体积小和开度小,部分呈关闭状态,叶片厚,叶肉细胞排列紧密,叶肉细胞很少出现质壁分离;耐热品种叶柄内维管束总面积是感热性品种的１．５倍以上,具发达的形成层及厚壁组织。     

高羊茅叶片表皮蜡质含量与其抗旱性的关系

以14个高羊茅品种为试验材料,在田间试验中对干旱高温胁迫下的叶片表皮蜡质含量、净光合速率、蒸腾速率、气孔导度、胞间CO2浓度等生理指标测定分析。结果表明,干热胁迫下高羊茅品种间的叶片表皮蜡质含量和水分利用效率均存在极显著差异(P<0.01);叶片蜡质含量与综合抗旱性和水分利用效率的等级相关系数分别为0.78(P<0.01)和0.68(P<0.01);蜡质含量越高的品种,其叶片气孔导度和胞间CO2浓度越低,水分利用效率越高,但所有品种的水分利用效率绝对值都较低。研究发现,在干热胁迫时,高羊茅叶片表皮蜡质可通过对气孔导度的调节来减少气孔蒸腾,提高水分利用效率,最终提高其抗旱性;表皮蜡质含量可以作为高羊茅品种抗旱性鉴定的一个新指标。     

小麦叶片光合作用与其渗透调节能力的关系

在缓慢干旱条件下,小麦叶片渗透调节能力在一定范围内随胁迫程度的加剧而增加,而在快速干旱下,渗透调节能力丧失。小麦叶片通过渗透调节使光合速率和气孔导度对水分胁迫的敏感性降低,叶片维持较高的电子传递能力、RuBP羧化酶活性和叶绿体光合能量转换系统活性,并推迟了小麦叶片光合速率受气孔因素限制向叶肉细胞光合活性限制转变的时间。     

土壤水分胁迫与遮荫对生姜生长特性的影响

水分胁迫使生姜叶片叶绿素含量降低,叶片气孔密度及气孔面积减小,根系活力下降。根系伤流量减少,在相同土壤水分条件下,遮光使叶片叶绿素含量增加。气孔密度减小,叶片上表皮气孔变大,而下表皮气孔变小。根系活力增强,水分胁迫显著影响生姜的生长与产量,但不同水分条件下,光强对生姜生长与产量的影响不同,正常供水条件下,生姜在自然光照条件下生长较好,产量较高;水分胁迫条件下,生姜在遮荫条件下生长较好,产量较高。     

水分胁迫下蚕豆（Vicia faba L．）气孔关闭与叶片细胞中ABA区隔化与再分配的关系

应用胶体金免疫电镜定位技术研究水分胁迫下叶片ＡＢＡ的再分配。表明：水分胁迫初期蚕豆叶肉细胞中ＡＢＡ的量与对照相比无明显变化,但水分胁迫可导致表皮细胞质外体ＡＢＡ含量明显增加;保卫细胞在水分胁迫前即含有大量ＡＢＡ;ＡＢＡ主要分布在叶绿体和细胞核,细胞的腹壁及相邻外壁和内壁也有大量ＡＢＡ存在,但背壁ＡＢＡ的量很少;气孔完全开放时背壁ＡＢＡ含量更少,当水分胁迫导致气孔关闭时,保卫细胞背壁ＡＢＡ含量大增,说明气孔运动与保卫细胞中ＡＢＡ的区隔化与再分配密切相关。     

高产小麦旗叶细胞结构与产量关系的研究

本文旨在揭示小麦旗叶结构与产量的关系.通过时四个品种小麦旗叶进行离析、显微观察、拍照、数据统计,并计算出叶肉细胞环数的期望,分别作了同产量的相关分析和回归分析.结果表明,气孔密度、气孔面积、表皮细胞面积、叶肉细胞环数的期望同产量呈正相关关系,并建立了同产量的回归方程.     

水分胁迫下小麦叶肉细胞超微结构变化与抗旱性的关系

本文用电子显微镜观察研究了抗旱性不同的6个小麦品种在不同程度水分胁迫下叶肉细胞超微结构的变化。结果表明:轻度水分胁迫(-0.5MPa)对参试的6个小麦品种叶肉细胞超微结构几乎没有影响。中度(-1.0MPa)和严重(-1.5MPa)水分胁迫下的叶肉细胞超微结构发生了程度不同的变化,且这种变化与品种抗旱性相一致。抗旱性愈弱的品种,对水分胁迫反应愈敏感。但表现在叶肉细胞结构上的变化过程基本一致。胁迫导致叶肉细胞质壁分离,液泡膜破裂。叶绿体变成球形挤入细胞中央,类囊体肿胀。线粒体基质变稀,脊减少。最终叶绿体、线粒体解体。其它细胞器消失,细胞中出现大量的小泡。     

兴安落叶松针叶解剖结构变化及其光合能力对气候变化的适应性

叶片易受环境因子影响,其形态解剖结构特征不但与叶片的生理功能密切相关,而且反映树木对环境变化的响应和适应。叶片结构的改变势必会改变树木的生理功能。同一树种长期生长在异质环境条件下,经过自然选择和适应,会在形态和生理特性等方面产生变异,形成特定的地理种群。另外,母体所经受的环境胁迫也会影响到其子代的生长、发育和生理等特征。因此,了解植物叶片形态结构对环境变化的响应与适应是探索植物对环境变化的响应适应机制的基础。兴安落叶松(Larix gmelinii Rupr.)是我国北方森林的优势树种,主要分布在我国东北地区,但日益加剧的气候变化可能会改变其现有的分布区。为了区分叶片对气候变化的可塑性和适应性,本研究采用同质园法比较测定了6个不同气候条件下的兴安落叶松种源的32年生树木的针叶解剖结构和光合生理相关因子,利用石蜡切片方法分析了针叶的解剖结构特征、光合能力（Pmax-a）、水分利用效率（WUE）之间的关系及其对气候变化的适应性。结果表明：表皮细胞厚度、叶肉细胞厚度、传输组织厚度、维管束厚度、内皮层厚度以及叶片总厚度均存在显著的种源间差异（P < 0.05）。叶肉细胞厚度与Pmax-a、气孔导度和WUE之间均存在显著的正相关关系（P < 0.05）。叶肉细胞厚度、表皮细胞厚度、叶片总厚度以及叶肉细胞厚度和表皮细胞厚度在叶片总厚度中所占比例均与种源地的干燥度指数（即年蒸发量与年降水量之比）呈正线性关系。这些结果说明：不同种源兴安落叶松针叶解剖结构因对种源原地气候条件的长期适应而产生显著的差异,从而引起其针叶光合作用、水分利用等生理功能发生相应的变化,从而有利于该树种在气候变化的情景下得以生存和繁衍。     

喜树各器官解剖学及其喜树碱含量测定的研究

运用植物解剖学方法研究了喜树各器官的结构,对喜树不同器官中喜树碱含量进行了HPLC法测定。结果表明:(1)喜树根尖纵切面的结构由根冠、分生区、伸长区和根毛区4个部分组成。根和茎的初生结构都由表皮、皮层和维管柱3部分组成;在根和茎初生结构的皮层和髓部具有被锇酸染成黑色的嗜锇细胞;在次生生长中,根的木栓形成层起源于中柱鞘,茎的木栓形成层起源于皮层细胞;随着次生维管组织的增加,茎的中央形成髓腔。(2)叶片由表皮、叶肉和叶脉组成,叶肉细胞中分布有嗜锇细胞;光学显微镜和扫描电子显微镜观察显示,喜树叶的上表皮没有气孔器分布;下表皮气孔器的保卫细胞呈肾形,没有副卫细胞,被几个表皮细胞不规则的围绕,属于无规则型;在上下表皮均分布着单细胞非腺毛和2种类型的腺毛,其中下表皮的分布相对稠密;上表皮腺毛呈球形,下表皮腺毛大部分为长卵形,其中间杂着一些球形腺毛;观察发现,越幼嫩的叶中,分布的腺毛和非腺毛越多。(3)喜树不同器官中喜树碱含量以幼叶和种子中较高,木质部中较低,髓中含量最少;随着叶的发育成熟,叶中喜树碱的含量逐渐降低,且同一叶的不同部位,喜树碱含量也有差异;喜树幼苗发育过程中喜树碱含量也在不断变化。     

Stomatal Response to Light of Solanum pennellii, Lycopersicon esculentum, and a Graft-induced Chimera

To learn how species differences in stomatal behavior are regulated, the response of epidermal and leaf diffusive resistance to light was investigated in Lycopersicon esculentum Mill., Solanum pennellii Corr., and a periclinal chimera having an S. pennellii epidermis and an L. esculentum mesophyll that was produced from a graft of the two species. S. pennellii has about 23% fewer stomata per square millimeter than does L. esculentum, and the two species have contrasting stomatal sensitivities to light. The abaxial stomata of L. esculentum open in dimmer light and to a greater extent than the adaxial stomata. The abaxial and adaxial stomata of S. pennellii respond similarly to light incident on the adaxial epidermis and are less open at all quantum flux densities than comparable stomata of L. esculentum. The patterns of response to light of the abaxial and adaxial stomata of the chimera were practically identical to those of L. esculentum, and quite unlike those of S. pennellii. Thus, the pattern of stomatal light response in the chimera was regulated by the L. esculentum mesophyll. The reduction in stomatal frequency of the chimera, which was regulated by the epidermis of S. pennellii, contributed to the 40% difference in leaf diffusive resistance between the plants in moderate light.     

Stomatal Movements, Frequencies, and Resistances in Two Maize Varieties Differing in Photosynthetic Capacity

The Stomatal characteristics of two maize varieties previouslyfound to differ in rates of net photosynthesis were examinedin a controlled environment. Measurements with a ventilateddiffusion porometer showed that one variety exhibited a pronouncedand the other a weak periodicity in stomatal resistance of theadaxial epidermis. At equal illumination the stomatal resistanceof the adaxial epidermis decreased from upper to lower leaves,while the resistance of the abaxial epidermis changed in theopposite manner. Stomata on the adaxial and abaxial surfacesof maize leaves exhibited random not compensatory, movementsin a constant environment. The variety with the lesser stomatalfrequency and higher total leaf resistance to water loss hadnevertheless faster net photosynthesis than the variety withthe greater stomatal frequency, demonstrating the importanceof the so-called mesophyll resistance.     

Effects of Simulated Acid Rain on Anatomy of Primary Leaves of Phaseolus Vulgaris

Ten-days-old bean plants (Phaseolus vulgaris L., cv. Cheren Starozagorski) were treated with simulated acid rain (pH 2.4, 2.2, 2.0 and 1.8). Anatomical changes in the primary leaves were studied 3, 48 and 168 h after a single treatment. This treatment induced: 1) change in the shape of palisade cells, contraction of their contact surfaces and expansion of spongy cells (pH 1.8, 3 h after treatment); 2) reduction of symplast connections among palisade cells and of apoplast in the spongy mesophyll (pH 1.8, 48 h after treatment); 3) destruction of adaxial epidermis and portions of palisade mesophyll, plasmolysis of spongy cells (pH 1.8, 168 h after treatment); 4) full destruction of mesophyll (pH 2.4, 2.2, 2.0 and 1.8, 168 h after treatment). The structure of abaxial epidermis was more stable than that of the adaxial one. With respect to anatomical parameters the studied species could be considered as comparatively resistant to acid rain.     

Assessment of leaf micromorphology after full desiccation of resurrection plants

Resurrection plants are unique among higher plants because of their ability to withstand long periods of dehydration without damages. In this study, leaf epidermis and palisade mesophyll of three resurrection species, Haberlea rodopensis, Ramonda serbica and Ramonda myconi, grown under full desiccation and benign conditions, were analyzed by differential interference contrast microscopy. Detailed investigation of adaxial and abaxial leaf surfaces revealed species-specific differences in the size and number of epidermal cells and stomatal density. The applied full desiccation did not cause any significant deviations of these parameters from the controls. There were no changes in the size and number of mesophyll cells as well. Analysis of stomatal patterning displayed essentially hypostomatic leaves, having stomata mainly abaxially positioned. The most significant change detected in the leaves of dehydration-treated plants was the increased formation of adaxially positioned trichomes. This increase was very high in R. myconi, where the adaxial leaf surface was fully covered by trichomes. Despite the existence of small species-specific differences, the results showed uniform desiccation-related responses of the studied resurrection species. The quantified leaf epidermal and mesophyll features are discussed with respect to their possible contribution to the desiccation tolerance of resurrection species.     

水分对药用兰科植物白及生理和形态结构的影响

通过水分控制实验,研究不同土壤水分条件对白及(Bletilla striata(Thunb.ex A.Murray)Rchb.f.)光合作用、叶片解剖结构、生物量和多糖含量的影响。结果表明,低水分处理不仅使白及的最大光合速率、气孔导度、光反应中心Ⅱ活性及叶绿素含量等参数降低;也使叶肉层变薄、上表皮增厚、生物量和多糖含量下降。气孔导度降低是白及在低水分条件下光合能力下降的主要原因。低水分条件可引起白及光合碳同化能力下降,导致生物量和多糖积累减少,进而影响白及的产量和品质。     

豆蔻属(姜科)植物叶的比较解剖学研究

采用石蜡切片法对豆蔻属12个种的叶片横切面结构进行比较解剖学研究。结果显示:豆蔻属植物叶片表皮层由1层表皮细胞组成,在无下皮层的种中,近轴面的表皮细胞通常体积较大,而在有下皮层的种中,表皮层通常较薄,细胞壁增厚;下皮层的结构具有多样性;叶肉中栅栏组织通常1~2层,海绵组织2~6层细胞,常含丹宁,所观察的大部分种含有方晶或砂晶;中脉韧皮部极端维管束形态多样,维管束系统II通常缺失,未发现同时具有4个系统的种。此外,对叶缘的形态特点进行了概括性描述,并结合前人的研究资料讨论了叶解剖结构的系统学意义。     

Protection by the epidermis of photosynthesis against UV-C radiation estimated by chorophyll a fluorescence

The epidermis of Argenteum mutant of Pisum sativum L. and Vicia faba L. was shown to be effective in protecting mesophyll photosynthesis from UV-C irradiation (peak 254 nm; 1.5 W m⁻²). These plants were chosen because it is easy to peel the epidermis from both sides of the leaf in Argenteum and the abaxial side in Vicia . Chlorophyll a fluorescence induction was decreased to the same extent by UV-C radiation in both leaf sides when the epidermis was removed. The fluorescence from the leaf with the epidermis inact was not affected. With irradiation of leaves with higher intensity (3.4 W m⁻²) of UV-C, the variable fluorescence was decreased by UV-C impinging on the abaxial side, but not the adaxial side in either of the plant species. A methanol extract from the mutant Pisum epidermis had a high absorbance in the UV region, and the absorbance was more than two-fold larger in adaxial epidermis than in abaxial epidermis. These results indicate that the epidermal layer, which contains substances that have high UV absorbance, protects mesophyll photosynthesis against UV radiation.     

安徽贝母属植物叶片的比较解剖学研究

在光学显微镜下,对安徽省贝母属(Fritillaria L.)8种1变种,其中包括安徽贝母(F. anhuiensis)和宁国贝母(F. ningguoensis)各两个居群的植物叶片进行了解剖结构观察,结果发现：叶肉细胞均含有淀粉粒,近上表皮的叶肉细胞多为方形或圆柱状,较大,排列较紧密,近下表皮的叶肉细胞形状不规则,多有分枝,细胞间隙大;叶均无表皮毛等附属物,除铜陵黄花贝母(F. monantha var. tonglingensis)的下表皮细胞类似平行四边形外,其它种叶表皮细胞表面观为长方形或长条形,细胞长轴与叶脉平行,垂周壁为平直、浅波状或深波状;气孔器为Allium型,仅分布于下表皮,椭圆形,长轴与叶脉平行,单个随机分布,部分种保卫细胞两极有“T”形加厚。叶表皮细胞的形状,垂周壁式样,气孔器的类型等特征较为稳定,可以为贝母属内种的划分及系统演化关系的探讨提供实验证据。