根源信号参与调控气孔行为的机制及其农业节水意义

在土壤干旱情况下,根源信号一方面向植物地上部分的长距离传输,为地上部分提供了土壤水分获取能力的测度,另一方面调控气孔开度,抑制蒸腾作用并提高植物的水分利用效率．文中综述了根源信号参与调控植物水分利用的生理机制和理论模型,指出该模型与根系吸水模型、气孔导度模型耦合,能够更好地反映植物叶片对土壤干旱以及大气干旱的响应、评述了在根源信号参与调控植物水分关系的基础上发展的调亏灌溉(RDI)、部分根系干旱(PRD)和控制性交替灌溉(CAI)等有效灌溉手段,有助于合理配置根系层供水量,通过根土相互作用和信号物质的传输,降低蒸腾和提高水分利用效率、另外,根源信号在调控根系生长发育、延缓地上部分生长以调节根冠比例,优化资源分配以利于生殖生长等方面均有所为,为全面提高农田水分利用效率提供节水生理基础。     

蜡梅科植物的叶表皮特征及其在分类上的意义

用扫描电镜和光学显微镜观察了蜡梅科3属5种植物成熟叶片远轴面的表皮特征,认为这些表皮细胞特征和气孔器特征在分类上有比较重要的意义。蜡梅属、夏蜡梅属和美国蜡梅属植物的叶表皮毛均为单细胞毛、非腺毛,上、下表皮细胞均为多边形,垂周壁呈深波状,气孔器均为平列型．这三个属的亲缘关系密切,应该归属于同一个大类群－蜡梅科。这为蜡梅属、夏蜡梅属、美国蜡梅属的分类提供了有用的性状特征。这三个属气孔器的演化趋势为：气孔器在保卫细胞的两极无"T"型加厚到有"T"型加厚,气孔器由单层外拱盖到双层外拱盖．     

The genetic basis of tongue rolling

Tongue rolling is widely used in elementary biology education to illustrate simple genetics despite doubts about its validity. A survey was carried out to determine the extent to which apparent non-rollers can learn to roll their tongues and to discover what advantage the ability to roll the tongue or not might confer and thus offer an explanation for this apparent polymorphism.     

凹唇姜属(Boesenbergia O.Kuntze)和山柰属(Kaempferia L.)(姜科)叶的解剖学

通过凹唇姜属（Boesenbergia curtisii,B.Prainana,B.rotunda和B.plicata)和山柰属（Kaempferia pulchra,D.galanga.K.gilbertii,K.rotunda,K.parviflora和K.angustifolia)种间叶解剖学变化的研究,寻找能用于鉴别种的解剖学特征,结果显示变化表现在气孔的类型,中脉的结构,叶缘和叶柄横切面轮廓,叶片的远 轴面或近轴面下皮层和毛状体的出现或缺如,研究表明这些特征的联合对已研究的种的鉴别是有用的。     

Short-term and long-term effects of plant water deficits on stomatal response to humidity in Corylus avellana L.

Short-term (hours) changes in plant water status were induced in hazel (Corylus avellana L.) by changing the evaporative demand on a major portion of the shoot while maintaining a branch in a constant environment. Stomatal conductance of leaves on the branch was influenced little by these short-term changes in water status even with changes in leaf water potential as great as 8 bars. Long-term (days) changes in plant water status were imposed by soil drying cycles. Stomatal conductance progessively decreased with increases in long-term water stress. Stomata still responded to humidity with long-term water stress but the range of the conductance response decreased. Threshold responses of stomata to leaf water potential were not observed with either short-term or long-term changes in plant water status even when leaves wilted. It is suggested that concurrent measurements of plant water status may not be sufficient for explaining stomatal and other plant responses to drought.     

地黄属(Rehmannia)和崖白菜属(Triaenophora)植物的叶表皮形态特征

利用扫描电子显微镜对车前科(P lantaginaceae)地黄属(Rehmannia)和崖白菜属(Triaenophora)8种植物成熟叶片的背面进行了观察。地黄属和崖白菜属的气孔都突出于叶表面,气孔类型均为无规则型;毛被有2种类型,即单列多细胞疏柔毛+单列多细胞腺毛和单列多细胞棉毛+单列多细胞腺毛。气孔和毛被在种间无明显的差异,不能作为分种依据,但毛被在属间具有明显的差异,具有一定的属间分类意义。     

植物对大气CO2浓度升高的光合适应机理

光合作用对大气中CO2浓度升高适应的可能原因主要表现在以下几个方面:由于CO2浓度升高,碳水化合物过量积累,光合电子传递链中质体醌与过氧化氢(H2O2)的氧化还原信号对光合作用发生反馈抑制;核酮糖1,5-二磷酸羧化/加氧酶(Rubisco)的含量及其活性下降;气孔状态发生变化.此外,植物体内C/N平衡、生长调节物质和己糖激酶对光合基因表达水平的调控等多个方面会对光合适应产生影响.     

Secondary phenolic products in isolated guard cell,epidermal cell and mesophyll cell protoplasts from pea (Pisum sativum L.) leaves: Distribution and determination

Summary Guard cells and epidermal cells of the abaxial (lower) and adaxial (upper) epidermis ofPisum sativum L., mutant Argenteum, are the predominant sites of flavonoid accumulation within the leaf. This was demonstrated by the use of a new method of simultaneous isolation and separation of intact, highly-purified guard cell and epidermal cell protoplasts from both epidermal layers and of protoplasts from the mesophyll. Isolated guard and epidermal protoplasts retained flavonoid patterns of the parent epidermal tissue; quercetin 3-triglucoside and its p-coumaric acid ester as major constituents, kaempferol 3-triglucoside and its p-coumaric acid ester as minor compounds. Total flavonoid content in the lower epidermis was estimated to be ca. 80 fmol per guard cell protoplast and 500 fmol per epidermal cell protoplast. Protoplasts isolated from the upper epidermis had about 20–30% as much of these flavonoids. Mesophyll protoplasts retained only about 25 fmol total flavonoid per protoplast.By fluorescence microscopy, using the alkaline-induced yellow-green fluorescence characteristics of flavonols, we suggest that these flavonol glycosides are present in cell vacuoles. There was no indication for the presence of flavine-like compounds.Abbreviations uE adaxial (upper) epidermis - IE abaxial (lower) epidermis - GCP guard cell protoplasts - ECP epidermal cell protoplasts - MCP mesophyll cell protoplasts - PP protoplasts - HPLC high performance liquid chromatography - TLC thin layer chromatography - CC column chromatography - HOAc acetic acid