龙牙花不同花器官的表皮形态

花的光合作用与气孔密度密切相关, 但关于在花生长过程中气孔密度如何改变尚未见报道。以龙牙花(Erythrina corallodendron)花为实验材料, 将花的生长期分为6个阶段, 采用光学显微镜对不同阶段的花萼、旗瓣、翼瓣、龙骨瓣、雌蕊托、子房、花柱、花丝和花药表皮的形态特征、表皮细胞密度、气孔密度、保卫细胞长度及宽度进行研究, 并对其光合作用的能力进行测定。结果发现: 除了翼瓣和花丝表皮以外, 气孔均分布在花朵的其它器官表皮上, 如花萼、旗瓣、龙骨瓣、雌蕊托、子房、花柱和花药。气孔复合体主要有无规则型、平列型以及辐射型, 但不同花器官存在的气孔类型具有差异。在花萼、旗瓣、龙骨瓣、翼瓣以及花丝生长过程中表皮细胞密度逐步下降, 表明其生长主要由表皮细胞扩大引起;大部分花器官如花萼、旗瓣、龙骨瓣、雌蕊托和子房表皮的气孔密度在其生长中后期趋于稳定, 然而其保卫细胞长度和宽度的变化规律具有多样性。旗瓣不进行光合作用。     

多花黄精叶表皮的发育

通过光学显微镜和电子扫描显微镜,对多花黄精(P olyg ona tum cy rtonem a)不同发育时期的叶表皮细胞及其气孔器进行了研究。结果表明:(1)多花黄精叶片的上下表皮细胞的发育方式基本一致,都是表皮细胞进行伸长生长和加宽生长,且伸长生长速度大于加宽生长速度。(2)气孔器的发育方式有两种:由表皮细胞进行不均等分裂所形成的两个细胞之中较小的一个发育而来;直接由表皮细胞发育而来。(3)在叶片发育过程中,气孔器指数是由低到高;在叶片展开第1天达到最高值,随后逐渐降低并趋于稳定。     

燕山山脉野生欧李群体叶表皮微形态特征研究

利用扫描电子显微镜对同一生境条件下自然生长的燕山山脉野生欧李实生群体（含嫁接类型）叶片表面微形态特征进行观测。结果表明：欧李叶表皮细胞形态存在两种类型,一类是上下表皮细胞向下凹陷相互连接形成蜂窝状,另一类是上下表皮细胞向上隆起近圆形,且上表皮细胞均具条纹状的角质层;叶片上表皮仅有表皮毛而无气孔分布,叶片下表皮仅有气孔分布;气孔突出于表皮细胞,属无规则型,气孔平均长度8.22±1.30 μm,宽度2.55±0.65 μm,大小21.64±8.60μm²,密度836.23±197.16 个/mm²;欧李群体中不同株系间、叶表皮细胞形态不同类别间气孔特征变异程度较大,可作为欧李优异种质选育和抗干旱胁迫研究的指标之一。     

鸢尾属（Iris）植物叶片表皮微形态特征的研究

对12种鸢尾叶片的表皮特征进行了观察和研究,结果表明野鸢尾、单花鸢尾、北陵鸢尾3种鸢尾各自的上下表皮细胞的形状及气孔密度等有明显区别,而其余9种鸢尾叶片各自上下表皮形态均无明显差异。12种鸢尾的气孔类型均属于横列型,且气孔均是随机分布,气孔保卫细胞的长轴与叶脉平行,叶脉处无气孔分布。不同种鸢尾之间叶片表皮特征具有显著差异,可为鸢尾属植物的分类提供依据。     

24种鳞毛蕨科植物叶表皮形态特征的研究

该研究利用光学显微镜对鳞毛蕨科24种植物的叶表皮形态特征进行观察。结果表明:(1)24种鳞毛蕨科植物的上表皮细胞形状为长条形或不规则形,垂周壁为深波状或浅波状,下表皮细胞均为无规则形,垂周壁均为深波状;上表皮细胞长宽比在1.5~5.7之间,下表皮细胞长宽比在2.2~3.9之间。(2)在24种鳞毛蕨科植物中共观察到8种气孔器类型,分别为不等细胞型、无规则四细胞型、极细胞型、腋下细胞型、横列型、无规则型、聚腋下细胞型和聚合极细胞型,每种植物具有2~8种气孔器类型,气孔均为下生型,多为椭圆形;气孔的长宽比在1.2~1.8之间,气孔密度在17.4~86.0个/mm~2之间,气孔指数为8.60%~37.4%。(3)通过对24种鳞毛蕨科植物的观察可将其上表皮细胞形状、垂周壁形状、上表皮细胞长宽比、主要气孔器类型及衍生类型等作为叶表皮形态特征的分类依据。(4)根据叶表皮形态特征可将24种鳞毛蕨科植物分为2类:即耳蕨类和鳞毛蕨类。该研究在一定程度上支持秦仁昌分类系统对鳞毛蕨科的划分,为鳞毛蕨科植物的系统分类及演化研究提供基础资料。     

酸枣叶表皮微形态对不同生态环境的适应特征

以生长于烟台—石家庄—宁夏—新疆不同生境形成的自然梯度干旱环境中的酸枣(Ziziphus jujuba var.spinosas)为材料,应用扫描电镜和能谱分析研究酸枣叶表皮微形态对不同自然梯度干旱环境的适应特征。结果表明:酸枣叶片的上、下表皮都有表皮毛着生且在叶脉处分布浓密;叶片表层覆盖有较厚的角质层和蜡质并形成突起,其主要成分为C、O、Ca三种元素;叶片表面气孔数量平均40个/视野且按一定规律分布。不同生境中酸枣叶片表面都分布有大量的晶体,且晶体的形态和组成成分表现出一定的生态适应特征。晶体的形状多样,有正六棱体、长六棱体、不规则片状、正方体、棒状晶体或针状,晶体的分布方式有单晶和簇晶。从烟台到新疆随干旱梯度的加剧,酸枣叶片表皮毛逐渐增多,气孔数量减少,气孔腔下陷明显,有助于植株减少蒸腾保水抗旱;晶体的体积逐渐变小,数量增多,密度增大,提升了叶片硬度及抗旱性;酸枣叶片晶体的主要成分为C、O、Ca三种元素,且随生境干旱加剧,C元素的含量逐渐增加,O和Ca元素含量依次减少,此外宁夏的晶体中还含有Si元素,进一步提升了叶片的机械性能。酸枣叶表皮微形态中表皮毛、角质层与蜡质、气孔、晶体等在形态结构、生物功能和组成成分上特异性的变化是其长期生存于不同梯度干旱生境的生态适应特征。     

15种铁角蕨科植物叶表皮形态特征的研究

利用光学显微镜对铁角蕨科15种植物的叶表皮形态特征进行观察。研究结果表明：（1）15种铁角蕨科植物的叶上、下表皮细胞形状为不规则型,垂周壁为深波状、波状或浅波状;上表皮细胞长宽比1.3~2.6,下表皮细胞长宽比1.3~4.1;（2）在15种铁角蕨科植物中共观察到7种气孔器类型,分别为腋下细胞型、不等细胞型、无规则四细胞型、无规则型、极细胞型、聚合极细胞型和聚腋下细胞型,每种植物具有2~5种气孔器类型,气孔均为下生型,多为椭圆形;气孔的长宽比1.12~2.81,气孔密度16.4~105.1个·mm^-2,气孔指数为5.7%~21.1%;（3）铁角蕨科植物叶表皮形态特征中的上表皮细胞形状、垂周壁形状、上表皮细胞长宽比、主要气孔器类型及衍生类型等具有一定的属内稳定性,可作为铁角蕨科属间分类的依据之一;（4）该研究在一定程度上支持秦仁昌和吴兆洪对铁角蕨科的划分以及铁角蕨属内分组和组内分系,并为铁角蕨科植物的分类鉴定及系统演化研究提供基础资料。     

鸡蛋花(夹竹桃科)花表皮气孔的初步研究

对鸡蛋花花表皮的气孔进行初步研究,结果发现:花冠裂片的上表皮没有气孔的分布;花冠裂片的下表皮则有气孔的分布。当花冠裂片长度1.5cm时,气孔密度最大,且极显著地高于花冠裂片长度为2.0、2.5、3.5cm和4.0cm时的气孔密度。长度为3.0cm的花冠裂片的气孔指数最大,与花冠裂片长度为1.0、2.0、3.5cm和4.0cm时的气孔指数的差异均达极显著水平。在花冠筒长度为0.3cm和0.4cm时,没发现气孔;当花冠筒生长到0.5cm时开始出现气孔。花冠筒长度为0.6cm时,气孔密度最大,且极显著地高于其它长度花冠筒的气孔密度。花冠筒长为0.6、1.1cm和1.3cm时的气孔指数均极显著地大于长度为0.5cm花冠筒的气孔指数。花冠裂片和花冠筒下表皮的普通表皮细胞都呈不规则的多边形,保卫细胞呈半月形。     

合意非洲铁羽片表皮及气孔器的发育研究

用光学显微镜和扫描电镜对合意非洲铁羽片表皮及气孔器的发育过程进行观察研究。结果显示,(1)在羽片发育过程中表皮细胞变化不明显,主要是细胞伸长和壁增厚的过程;表皮的角质层连续出现。(2)气孔器发育可大致分3个阶段:保卫细胞母细胞阶段、幼保卫细胞阶段和成熟保卫细胞阶段;气孔器发育方式为单唇型或周源型;成熟气孔器属单环型。(3)在羽片发育过程中,气孔密度起初很低,后急剧升高并达到峰值,之后逐渐下降并趋于稳定。(4)有早熟气孔器。(5)羽片表皮发育成熟的方式是由基部向顶部逐步推进。     

委陵菜属锥状花柱组植物叶表皮微形态特征的研究

利用光学显微镜和扫描电子显微镜,观察了新疆委陵菜属（Potentilla L.）锥状花柱组（Sect.Conostylae(Wolf)Yü et Li）15种委陵菜植物叶表皮的微形态特征。对其叶表皮毛的类型、表皮细胞的形状及大小、气孔器的分布、气孔器类型、气孔形状、气孔大小、气孔密度、气孔指数、气孔外拱盖形态及其纹饰等指标进行分析：有几种植物叶的上表皮无气孔,而下表皮均有气孔器的分布,形状为长椭圆形、椭圆形、宽椭圆形和近圆形;气孔器的类型多为短平列四细胞型、无规则四细胞型、无规则型、围绕型和辐射型;表皮毛的类型为针状毛、带状柔毛和腺毛;表皮细胞分为不规则形和多边形;表皮毛特征、叶片表皮细胞的形状、垂周壁式样、气孔器的形状类型、气孔密度指数及蜡质纹饰等存在差异,可作为亚属间及种间分类的依据。     

Crystal structures of Erythrina cristagalli lectin with bound N-linked oligosaccharide and lactose

Erythrina cristagalli lectin (ECL) is a galactose-specific legume lectin. Although its biological function in the legume is unknown, ECL exhibits hemagglutinating activity in vitro and is mitogenic for T lymphocytes. In addition, it has been recently shown that ECL forms a novel conjugate when coupled to a catalytically active derivative of the type A neurotoxin from Clostridium botulinum, thus providing a therapeutic potential. ECL is biologically active as a dimer in which each protomer contains a functional carbohydrate-combining site. The crystal structure of native ECL was recently reported in complex with lactose and 2'-fucosyllactose. ECL protomers adopt the legume lectin fold but form non-canonical dimers via the handshake motif as was previously observed for Erythrina corallodendron lectin. Here we report the crystal structures of native and recombinant forms of the lectin in three new crystal forms, both unliganded and in complex with lactose. For the first time, the detailed structure of the glycosylated hexasaccharide for native ECL has been elucidated. The structure also shows that in the crystal lattice the glycosylation site and the carbohydrate binding site are involved in intermolecular contacts through water-mediated interactions.     

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。     

植物气孔对大气CO2浓度和温度升高的反应——基于在CO2浓度和温度梯度中生长的10种植物的观测

许多研究表明 ,大气 CO2 浓度 ([CO2 ])的升高会导致植物气孔密度 (Stom atal Density,SD)和气孔指数 (Stom atal Index,SI)降低。这一关系成为推测地质历史时期大气 [CO2 ]变化的重要古生物指标之一。但是 ,[CO2 ]不是唯一影响 SD和 SI的环境因素。研究利用温度梯度和温度 [CO2 ]梯度技术 ,以 7种美国中西部地区弃耕地常见草本植物和 3种美国东部落叶阔叶林优势木本植物为材料 ,其中草本包含豆科、非豆科 C3和 C4 功能型 ,就它们的 SD,SI,表皮细胞密度 (Epidermal Cell Density,ECD)和气孔孔径长度 (Stomatal Aperture L ength,APL)对 [CO2 ]和温度升高的反应进行了研究。结果表明 ,沿 [CO2 ]梯度 ,所研究物种的 SD比 SI反应敏感 ,SD显示出与 [CO2 ]正相关、负相关和无显著相关性 ,SI显示出与 [CO2 ]正相关和无显著相关性 ;沿温度梯度 ,所研究物种的 SI比 SD反应敏感 ,SI显示出与温度正相关、负相关和无显著相关性 ,SD显示出与温度正相关和无显著相关性。 ECD和 APL对 [CO2 ]和温度梯度也有不同的响应。这说明 ,除 [CO2 ]外 ,温度也对 SD,SI,ECD和 APL有显著的影响。所以在用气孔特征重建地质历史时期 [CO2 ]的变化趋势时 ,除准确建立气孔参数与 [CO2 ]关系外 ,还应考虑大气温度对这一关系的影响     

Genome size is a strong predictor of cell size and stomatal density in angiosperms

Across eukaryotes phenotypic correlations with genome size are thought to scale from genome size effects on cell size. However, for plants the genome/cell size link has only been thoroughly documented within ploidy series and small subsets of herbaceous species. Here, the first large-scale comparative analysis is made of the relationship between genome size and cell size across 101 species of angiosperms of varying growth forms. Guard cell length and epidermal cell area were used as two metrics of cell size and, in addition, stomatal density was measured. There was a significant positive relationship between genome size and both guard cell length and epidermal cell area and a negative relationship with stomatal density. Independent contrast analyses revealed that these traits are undergoing correlated evolution with genome size. However, the relationship was growth form dependent (nonsignificant results within trees/shrubs), although trees had the smallest genome/cell sizes and the highest stomatal density. These results confirm the generality of the genome size/cell size relationship. The results also suggest that changes in genome size, with concomitant influences on stomatal size and density, may influence physiology, and perhaps play an important genetic role in determining the ecological and life-history strategy of a species.     

Epidermal conductance, stomatal density and stomatal size among genotypes of Sorghum bicolor (L.) Moench

Abstract. The ability of a plant to survive severe water deficits depends on its ability to restrict water loss through the leaf epidermis after stomata attain minimum aperture. At this stage, the rate of water loss is regulated by the epidermal conductance (g_c). Low g_c would be a useful selection criterion to identify genotypes with enhanced survival capability. Consequently, variation in g_c among Sorghum bicolor (L.) Moench genotypes was evaluated. Since there is little conclusive evidence linking g _c with leaf waxiness, alternative hypotheses relating g _c to stomatal trails were also examined. Epidermal conductance varied from 6.3 to 17.6mmol m⁻² s⁻¹ among sorghum genotypes. It was unrelated to stomatal pore length which varied with genotype and to pore depth which was similar for all genotypes measured. However, g _c, increased with increasing stomatal density. This indicates that stomatal density plays a direct role in water loss even at very low conductances. The association of low stomatal density with low g _c is consistent with the hypothesis that at the smallest stomata aperture, water loss from the epidermis above guard cell teichodes becomes a significant source of leaf water loss. Since low g _c is directly related to crop survival under severe water deficits, it is recommended that genotypes with low g _c. be selected using the selection criterion of stomatal density.     

长春花叶片发育过程中气孔密度和气孔指数的动态变化

对长春花叶片近轴面和远轴面上的气孔密度和气孔指数在不同发育阶段的动态变化进行了研究.结果表明:在各个发育阶段,近轴面上的气孔以叶脉两侧居多,远轴面上的气孔则在整个叶片上均匀分布.将一个枝条上的10对真叶按发育顺序界定为10个发育阶段,即从枝条的顶端到基部,分别将第10、第9、第8……第1节位的叶片定义为第1、第2、第3...     

Isoflavonoids from the roots of Erythrina poeppigiana

Five isoflavonoids, 7,4′-dihydroxy-2′-methoxy-8-(γ,γ-dimethylallyl)isoflav-3-ene, 4′-hydroxy-2′-methoxy-6″,6″-dimethylpyran[2″,3″:7,8]isoflav-3-ene, 5,7,4′-trihydroxy-2′-methoxy-5′-(γ,γ-dimethylallyl)isoflavanone, 5,4′-dihydroxy-7,2′-dimethoxy-5′-(γ,γ-dimethylallyl)isoflavanone and 3,9-dihydroxy-4-(γ,γ-dimethylallyl)pterocarpene as well as six known compounds were isolated from the roots of Erythrina poeppigiana. Their structures were established on the basis of spectroscopic evidence.     

Terminology and classification of stomata and stomatal development—a critical survey

The literature on terminology of stomata and stomatal development is reviewed and the terminology rationalized. The classification of developmental types and of the developing cells should not be combined with the morphological classification of mature stomatal complexes. The cells involved in the development should be distinguished on the basis of their origin and position in the developing stomatal complex, and not on the basis of their future form and appearance. It is unsound to distinguish any kind of cell only on the basis of a presumed future division by which it is replaced by its two daughter cells. Development of stomata begins with the formation of a stomatal meristemoid by an unequal division of a protodermal cell. A meristemoid may divide unequally to produce a new meristemoid and a mesogene cell. Stomatal meristemoids eventually function as guard-cell mother-cells. The adjective perigene is restricted to those cells that have arisen by divisions of protodermal cells surrounding the future stoma. The undivided cells surrounding protodermal cells should be termed agene cells, and not neighbouring cells, a term which should be restricted to morphological terminology.