4种作物部分非叶器官气孔频度及其在光合作用中的意义（英文

 通过对小麦（Triticum aestivum L.）、大豆 (Glycine max (L.) Merrill)、 油菜（Brassica napus L.）和玉米（Zea mays L.）等4种作物部分非叶器官(油菜和大豆的豆荚;小麦的外稃和玉米的苞叶)的气孔频度、气孔大小和气孔指数进行了比较研究。结果发现,上述作物非叶器官的气孔频度均较对应叶低;而气孔大小和气孔指数则变化较大。其中油菜和大豆非叶器官气孔的直径通常比对应叶大,小麦和玉米非叶器官的气孔直径则较小;大豆和油菜的非叶器官气孔指数比对应叶小,     

CO2浓度倍增对10种禾本科植物叶片形态结构的影响

在CO_2正常浓度(350μL/L)和倍增(700μL/L)条件下,对小麦(Triticum aestivum L.)、半野生小麦(T.aestivum ssp.tibeticum)、大麦(Hordeum vulgare L.)、野大麦(H.brevisubulatum(Trin.)Link)、水稻(Oryza sativa L.)、野生稻(O.meyeriana subsp.granulata)、谷子(Setaria italica(L.)Beauv)、狗尾草(S.viridis (L.)Beauv)、高粱(Sorghum vulgare Pers.)和玉米(Zea mays L.)等10种禾本科植物幼苗期叶的形态结构进行比较研究。结果表明,在CO_2浓度倍增条件下,除野大麦和玉米外,其它几种禾本科植物的叶片厚度普遍增加;表皮细胞密度下降(野大麦和谷子的远轴面除外)。其中C_3种类的平均气孔密度和气孔指数下降,C_4种类则呈相反趋势。在CO_2浓度倍增条件下,栽培种类表皮细胞密度和维管束鞘细胞中的叶绿体数明显增加,野生种类则呈相反趋势。气孔密度与气孔指数基本呈正相关。     

不同种植模式对作物根系生长、产量及根际土壤微生物数量的影响

采用多年大田试验研究了小麦-大豆(A1)、小麦-甘薯(A2)、玉米(A3)、小麦/玉米/大豆(A4)和小麦/玉米/甘薯(A5)5种种植模式的根际环境变化特征和根系生长特性.结果表明:与A1、A2、A3和A5相比,A4提高了小麦、玉米、大豆在开花期和成熟期的生物量、根系活力和根干质量,提高了各作物根际土壤细菌、真菌和放线菌数量.各种植模式之间,植株生物量和根际微生物数量的变化规律为套作＞单作、大豆茬口＞甘薯茬口、边行＞中行.小麦/玉米/大豆(A4)套作模式通过改善3种作物的根际环境,促进了作物地下部根系生长和地上部生物量的增加,从而实现作物增产.     

不同种植模式对西南坡地水土保持及作物产值的影响

通过3年定位监测试验研究了小麦/玉米/大豆全程免耕全程秸秆覆盖、小麦/玉米/大豆半程免耕半程秸秆覆盖、小麦/玉米/大豆全程翻耕不覆盖秸秆和小麦/玉米/甘薯全程翻耕不覆盖秸秆4种不同种植模式对西南坡地水土保持、土壤肥力及作物产值的影响.结果表明：在水土保持方面,小麦/玉米/大豆全程免耕全程秸秆覆盖模式的3年平均土壤侵蚀量和地表径流量最低,分别为1189 kg·hm^-2和215 m³·hm^-2,显著低于其他处理,比小麦/玉米/甘薯全程翻耕不覆盖秸秆模式分别低10.6%和84.7%.在土壤肥力方面,3种小麦/玉米/大豆模式都能增加土壤有机质、全氮、速效钾和碱解氮含量,以小麦/玉米/大豆全程免耕全程秸秆覆盖模式增加幅度最大,分别增加15.7%、18.2%、55.2%和25.9%,显著高于其他模式,小麦/玉米/大豆半程免耕半程秸秆覆盖模式次之,小麦/玉米/甘薯全程翻耕不覆盖秸秆模式最低.在作物产值方面,以小麦/玉米/大豆全程免耕全程秸秆覆盖模式的3年平均总产值和纯收入最高,分别为18809元·hm^-2和12619元·hm^-2,比其他几个处理分别增加2.2%～20.6%和3.8%～32.9%,总体效益最好.总之,小麦/玉米/大豆模式比传统的小麦/玉米/甘薯模式能更好地保持水土,减少土壤侵蚀量和地表径流量,增加土壤肥力和作物产值.     

作物干旱指标对西北半干旱区春小麦缺水特征的反映

针对作物水分胁迫较为严重的西北半干旱区,应用CI301-PS光合作用仪对春小麦开花到乳熟期间的生理特征和环境因子进行了近1个月的观测, 并研究分析了3种作物干旱指标叶水势、作物水分胁迫指数以及气孔导度随时间变化和对气象因子的响应.发现干旱胁迫增加时,叶片水分减少,作物水分胁迫指数增大,叶水势降低,气孔导度有所减小.因此,气孔下腔的CO2浓度降低,作物净光合速率有所减小,不利于半干旱区小麦生物量的累积;三者相比,叶水势是反应西北半干旱区作物干旱最敏感的指标;受半干旱区逆湿现象的影响,9:00或之后一段时间观测叶水势和气孔导度对小麦等作物缺水状况反映得更客观.     

不同种植模式花椒园昆虫群落的结构及稳定性

对云南昭通市4种不同种植模式花椒园（花椒-玉米-大豆园、花椒-大豆园、花椒-玉米园、花椒园）昆虫群落的组成和结构进行调查,采用群落特征指数和主分量分析法对不同种植模式花椒园昆虫群落特征及其稳定性进行了研究.结果表明：研究区花椒园共发现326种昆虫;与单一种植花椒园相比,间作套种作物花椒园昆虫群落的丰富度指数、多样性指数和均匀度指数均较高,而优势度指数较低;不同种植模式花椒园昆虫群落多样性指数值大小依次为花椒玉米大豆园>花椒大豆园>花椒玉米园>花椒园.花椒、玉米、大豆间作套种系统中昆虫群落的稳定性较好.     

玉米大豆对农林复合系统小气候的光合响应

对黄土区核桃(Juglans regia L.)-(玉米+大豆)、李子(Prunus salicina)-(玉米+大豆)农林复合系统小气候效应的研究表明,在玉米和大豆的花期,农林间作系统与对照地相比可以降低农田地面温度1.7-1.9℃,减低风速55%-67%,提高相对湿度6.9%-8.4%,降低光合有效辐射强度13.9%-24.5%和大气CO2浓度5.3-10.9μmol.mol-1。本研究中,单作大豆叶片光合速率午间变化主要受到非气孔的限制作用。逐步回归分析结果表明,光合有效辐射强度和大气CO2浓度是影响林下作物光合速率的主要环境因子。林下小气候可能是作物避免"午休"现象的主要原因。     

不同作物轮作制度对土壤杂草种子库特征的影响

为明确不同作物轮作制度对杂草种子库特征的影响,比较研究了玉米-小麦(MW)、大豆-小麦(SW)轮作和原水稻-小麦(RW)轮作方式下杂草种子库的特征。结果表明,作物轮作显著影响杂草种子库的密度和种类组成,进行玉米-小麦或大豆-小麦轮作2年后,杂草种子库密度分别比稻麦轮作降低27．16％、44．44％。在原水稻-小麦轮作方式下,种子库中主要杂草为陌上菜、异型莎草、菵草、水苋菜、千金子等。玉米-小麦轮作使种子库中马唐、碎米莎草、飘拂草的相对优势度显著上升,鸭舌草、水苋菜、菵草的相对优势度显著下降。而在大豆-小麦轮作方式下,种子库中通泉草、马唐、鳢肠、飘拂草的相对优势度显著上升。玉米-小麦轮作种子库的物种多样性指数高于大豆-小麦轮作和水稻-小麦轮作。玉米-小麦与大豆-小麦轮作种子库的物种组成相似性较高。作物轮作影响杂草种子库密度和种类组成的机制,可能在于通过轮换种植不同的作物,提供了多样化的选择压,限制了某些对单一种植系统有着良好适应性的杂草种类的生长。     

不同类型作物对干湿交替环境的反应

通过对干湿交替环境下春小麦、马铃薯、大豆和玉米等作物的产量,水分利用效率及光合作用、蒸腾作用、气孔导度等生理变化的研究表明：（１）春小麦和马铃薯在干湿交替环境下可获得与充分供水相当的产量而它们的水分利用效率却显著提高,大豆减产幅度较大,玉米减产严重,其水分利用效率显著低于全湿处理;（２）浇水后各作物的光合速率、蒸腾速率和气孔导度都有所增加,但不同作物增加的幅度不同,就是同一作物各指标的增幅也不同;     

应用热平衡法测定玉米/大豆间作群体内作物的蒸腾量

通过田间试验采用基于热平衡法的茎流计测定玉米/大豆条带间作群体内作物的蒸腾规律.结果表明：间作群体内,玉米和大豆植株的茎流速率在晴天呈单峰曲线,在阴天则呈多峰曲线.植株的茎流受多个环境因子的影响,其中太阳辐射是影响植株茎流最主要的气象因子.玉米和大豆的单株日茎流量与多个气象因子间存在较好的相关关系,达到极显著水平.茎流观测期内（2008年6月1-30日）,间作群体内玉米植株的日均蒸腾量（1.44 mm·d^-1）为大豆（0.79 mm·d^-1）的1.8倍,玉米和大豆植株的蒸腾量分别占间作群体总蒸腾量的64%和36%.考虑到作物的茎直径和叶面积的空间变异,安装一定数量的茎流探头对于准确测定植株茎流是十分必要的.     

Anion-Channel Blockers Inhibit S-Type Anion Channels and Abscisic Acid Responses in Guard Cells

The effects of anion-channel blockers on light-mediated stomatal opening, on the potassium dependence of stomatal opening, on stomatal responses to abscisic acid (ABA), and on current through slow anion channels in the plasma membrane of guard cells were investigated. The anion-channel blockers anthracene-9-carboxylic acid (9-AC) and niflumic acid blocked current through slow anion channels of Vicia faba L. guard cells. Both 9-AC and niflumic acid reversed ABA inhibition of stomatal opening in V. faba L. and Commelina communis L. The anion-channel blocker probenecid also abolished ABA inhibition of stomatal opening in both species. Additional tests of 9-AC effects on stomatal aperture in Commelina revealed that application of this anion-channel blocker allowed wide stomatal opening under low (1 mM) KCI conditions and increased the rate of stomatal opening under both low and high (100 mM) KCI conditions. These results indicate that anion channels can function as a negative regulator of stomatal opening, presumably by allowing anion efflux and depolarization, which prohibits ion up-take in guard cells. Furthermore, 9-AC prevented ABA induction of stomatal closure. A model in which ABA activation of anion channels contributes a rate-limiting mechanism during ABA-induced stomatal closure and inhibition of stomatal opening is discussed.     

Effect of CO2 Concentration Doubling on the Leaf Morphology and Structure of 10 Species in Gramineae

The effects of CO2 concentration on leaf thickness, chloroplast manbers in the bundle sheath cell, epidermal cell density, stomatal density, stomatal index, stomatal size were compared in 10 species in Gramineae: Triticum aestivum L., T. aestivum ssp. tibeticum, Hordeum vulgare L., H. brevisubulatum ( Trin. ) Link, Oryza sativa L., O. meyeriana ssp. granulata, Setaria italica (L.) Beauv, S. viridis (L.) Beauv, Sorghum vulgare Pers., Zea mays L. following their exposure to doubled carbon dioxide (700μL/L) and ambient carbon dioxide concentration (350μL/L). The results indicated that different species of plants might vary in their response to doubled CO2. In general, the leaves became thicker under the elevated CO2 condition. The mean stomatal density of the C3 species was decreased in doubled CO2, whereas the results of C4 species showed an inverse trend. The epidermal cell density and the chloroplast numbers of the bundle sheath cell in the wild plant species were less than those in the control under CO2 enrichment. The stomatal density was positively correlated with the stomatal index. Finally, the general pattern of structural variation under different CO2 concentrations was proposed, and their implication to the research of global change was discussed as well.     

一氧化氮在乙烯诱导蚕豆气孔关闭中的作用

以蚕豆为材料研究了一氧化氮(nitric oxide,NO)和乙烯对气孔运动的影响。结果表明,10μmol/L的NO供体硝普钠(sodium nitroprusside,SNP)以及0.04%的乙烯能明显诱导蚕豆气孔关闭,并且二者共同处理后,能够增强其促进气孔关闭的作用。乙烯合成抑制剂AVG可以减弱NO诱导气孔关闭的程度,NO清除剂c-PTIO和NR抑制剂NaN3也可减弱乙烯诱导气孔关闭的程度,而一氧化氮合酶(nitric oxide synthase,NOS)抑制剂L-NAME对乙烯诱导气孔关闭的作用不明显。推测,在调控蚕豆气孔关闭过程中,NO可能主要通过NR途径参与乙烯调控气孔关闭过程。     

过氧化氢对蚕豆气孔运动和质膜K+通道的影响

不同浓度H2 O2 可使蚕豆 (ViciafabaL .)叶片气孔关闭 ,抑制气孔张开 ,10mmol/L的H2 O2 最有效 ,10 μmol/L的H2 O2 仍明显使气孔关闭。且 10 μmol/L的H2 O2 抑制气孔张开作用能被EGTA所消除 ,表明Ca2 参与低浓度H2 O2 使气孔关闭的过程。 2mmol/L的H2 O2 可使质膜内向K 通道电流明显减小 ,而外向K 通道电流显著增加。因此 ,H2 O2 促进蚕豆气孔关闭主要是通过抑制K 通过保卫细胞质膜内向流入 ,或加强K 外向流出实现的     

Stomatal malfunctioning under low VPD conditions: induced by alterations in stomatal morphology and leaf anatomy or in the ABA signaling?

Exposing plants to low VPD reduces leaf capacity to maintain adequate water status thereafter. To find the impact of VPD on functioning of stomata, stomatal morphology and leaf anatomy, fava bean plants were grown at low (L, 0.23 kPa) or moderate (M, 1.17 kPa) VPDs and some plants that developed their leaves at moderate VPD were then transferred for 4 days to low VPD (M→L). Part of the M→L‐plants were sprayed with ABA (abscisic acid) during exposure to L. L‐plants showed bigger stomata, larger pore area, thinner leaves and less spongy cells compared with M‐plants. Stomatal morphology (except aperture) and leaf anatomy of the M→L‐plants were almost similar to the M‐plants, while their transpiration rate and stomatal conductance were identical to that of L‐plants. The stomatal response to ABA was lost in L‐plants, but also after 1‐day exposure of M‐plants to low VPD. The level of foliar ABA sharply decreased within 1‐day exposure to L, while the level of ABA‐GE (ABA‐glucose ester) was not affected. Spraying ABA during the exposure to L prevented loss of stomatal closing response thereafter. The effect of low VPD was largely depending on exposure time: the stomatal responsiveness to ABA was lost after 1‐day exposure to low VPD, while the responsiveness to desiccation was gradually lost during 4‐day exposure to low VPD. Leaf anatomical and stomatal morphological alterations due to low VPD were not the main cause of loss of stomatal closure response to closing stimuli.     

Ion movements during stomatal opening in darkness after illumination under nitrogen

In Zea mays L., Bryophylum laxiflorum Bak., Gossypium hirsutum L., Helianthus annuus L., Oryza sativa L. and Vigna radiata L., a pre-illumination in nitrogen causes transient stomatal opening upon returning the plant to darkness and normal air. In Zea mays L. hybrid INRA 508, K⁺ and Cl⁻ fluctuations in the stomatal complex during this stomatal opening in darkness were similar to those observed during a light-induced opening in normal air. These results are consistent with a two-phase mechanism for stomatal opening: a light phase that may occur in the absence of oxygen and carbon dioxide, and a dark phase during which oxygen is necessary for ion accumulation and other mechanisms of osmotic adjustment.     

Seasonal changes in stomatal responses of sweet cherry and plum to water status in detached leaves

Seasonal changes in the relationship between stomatal responses and water potential components in detached leaves of sweet cherry ( Prunus avium L. cv. Bigarreau Morreau) and plum ( Prunus domestica L. cv. Queen Victoria) were examined by the simultaneous measurement of stomatal conductance and water relation parameters derived from pressure-volume curves. The water potential threshold for stomatal closure in sweet cherry leaves throughout the season and in plum leaves until mid-July varied nearly in parallel with changes in the osmotic potential at the turgor loss point. From August onward, closing reactions of plum stomata had no relationship to the turgor loss point. Stomata of sweet cherry leaves opened more widely and showed slower reactions to dehydration early in the season than later. Seasonal changes of stomatal conductance and stomatal responses to dehydration in both species seem thus to be influenced by fruit development and ripening.     

微管在气孔运动中的作用

用植物微管专一性解聚剂甲基胺草磷(APM)预处理蚕豆(Vicia faba L.)下表皮,再用诱导气孔运动的因子处理,在显微镜下观察气孔孔径的变化。结果显示,用50mg/L APM预处理开放或关闭状态气孔,虽胞质微管被解聚,但气孔孔径没有发生明显的变化,表明胞质微管与开放或关闭状态气孔的维持无关;而去掉APM后,CaCl_2可在4h内诱导气孔关闭,气孔的运动功能又可恢复。进一步的研究表明,开放气孔经APM预处理60min后,再用ABA、Ca~(2 )及暗处理均不能诱导气孔关闭,表明微管可能参与了ABA、Ca~(2 )及暗诱导的气孔关闭过程;关闭气孔经50mg/L APM预处理后,光诱导气孔开度较不经 APM处理的有明显差异,且随着APM预处理时间和浓度的变化,气孔开放程度亦不同,表明微管也参与了光诱导的气孔开放过程。