NaCl胁迫对菠菜叶片中水分和光合气体交换的影响(简报)

NaCl胁迫下,菠菜幼苗叶片的净光合速率（Pn）、气孔导度（Gs）和蒸腾速率（Tr）下降。短期处理的叶片中CO2浓度（Ci）降低,气孔限制值（Is）升高,水分利用效率（WUE）增大,而长期处理的叶片中Ci升高,Is下降,WUE降低。NaCl短期处理下,菠菜光合降低以气孔限制为主,而在长期处理下光合的非气孔限制因素增大。     

砂仁光合作用的CO2扩散限制与气孔限制分析

 目前常用从气体交换参数计算的胞间CO2浓度（Ci）来计算气孔限制值（Ls）,但由于胁迫情况下计算的Ci偏高常导致结果不准确。该文引入扩散限制分析概念,以砂仁为例介绍了一种不需 Ci的计算扩散限制值（Ld）的新方法。同时通过叶绿素荧光参数间接估算受干旱胁迫植株的Ci（用Ci′表示）计算气孔限制值（Ls′）。采用这3种方法分析了生长在100%和40%土壤相对湿度（RSM）下的砂仁（Amomum villosum）净光合速率的限制因素。结果表明两种水分状况下砂仁午后净光合速率的限制因素不同。100%RSM下,午后砂仁Ls没有升高,说明光合作用气孔限制并未增强;午后其Ld升高表明光合作用的CO2扩散限制增强,这主要是由叶肉阻力相对增大所致。40%RSM下,午后砂仁Ls′升高比Ld升高明显,说明气孔阻力在所有扩散阻力中占主导作用,是限制净光合速率的主要原因;而其 Ls午后并未升高,暗示传统的气孔限制分析会得出非气孔限制的错误结论。Ci′低于Ci,说明干旱胁迫时传统的气体交换方法高估了Ci。上述结果都证明水分胁迫情况下传统方法不可靠,该文介绍的两种新方法比较准确可靠,同时使用两种新方法还可定性推测叶肉阻力的变化方向。     

NaCl对玉米和棉花光合作用与渗调节能力影响的比较（简报）

100mmol.L^-1NaCl胁迫下,玉米植株叶片的含水量降低,棉花的变化不明显,两者的渗透势都下降,但玉米的渗透调节能力下于棉花,受NaCl胁迫的玉米和棉花植株叶片Pn,Tr,gs都降低,前者Ci升高,Ls减小,后者的Ci下降,Ls增大。     

土壤水分对温室盆栽番茄叶片生理特性的影响及光合下降因子动态

以温室盆栽番茄(Lycopersicon esculentum Mill．)为试验材料,研究了土壤水分对叶水势(LWP)、细胞液浓度(CSC)、气孔导度(Gs)、气孔限制值(Ls)和叶片光合特性的影响,以及引起光合下降的因子动态。结果表明,随着土壤水分胁迫程度的增加,净光合速率(Pn)、蒸腾速率(Tr)、LWP明显下降．Gs具有相同的趋势,而CSC显著升高。土壤水分胁迫和高水分处理的Pn与Tr日变化呈双峰曲线,但在适宜土壤水分下为单峰曲线。随着土壤含水量的增加,光合下降的非气孔限制出现的时间具有滞后现象。本文对非气孔限制出现的临界点动态作了进一步的探讨。     

不同光照强度下三角叶滨藜光合作用对盐激胁迫的响应

以溶液培养的三角叶滨藜植株为材料研究了不同光照条件下其叶片光合作用对盐(NaCl)激胁迫的即刻反应及变化规律.结果表明,三角叶滨藜光合作用对盐激胁迫的响应有8 min左右的滞后期.在光照强度为100umol·m-2·-1和100 mmol·L-1浓度NaCl共同作用下,三角叶滨藜叶片净光合速率略有上升;但随NaCl浓度和光照强度进一步增加,其净光合速率呈下降趋势,且光照越强,盐胁迫导致的净光合速率下降幅度越大.同时,弱光下或强光低浓度NaCl胁迫下,盐激胁迫导致的净光合速率下降主要是气孔限制引起的;而强光下,高浓度的NaCl胁迫导致的净光合速率下降在盐激胁迫处理的前30-40 min主要由气孔限制引起.40 min后则主要由非气孔限制引起.可见,不同光照强度和NaCl浓度胁迫下三角叶滨藜叶片光合作用响应规律不同,引起净光合速率下降机制各异.     

NaCl胁迫对两种番茄气孔特征、气体交换参数和生物量的影响

为探讨番茄叶片气孔特征、气体交换参数和生物量对盐胁迫的响应机理,以赛棚和阿拉姆番茄为试材,通过向水培营养液中添加NaCl(0.1 mol·L^-1),在人工气候箱条件下进行为期90 d的NaCl盐胁迫处理.结果表明: NaCl胁迫导致赛棚番茄叶片的气孔密度、气孔宽度、气孔面积和气孔面积指数显著降低,降幅分别为32%、45%、25%、49%,但没有改变阿拉姆番茄叶片的气孔特征参数.同时,NaCl胁迫还导致赛棚和阿拉姆叶片气孔规则分布的空间尺度分别减少30%和43%,且赛棚品种的单个气孔最小邻域距离在盐胁迫下增加20%.另外,赛棚和阿拉姆叶片的净光合速率(P_n)、气孔导度(g_s)和蒸腾速率(T_r)在盐胁迫下均显著下降,通过气孔限制值分析发现,盐胁迫导致赛棚番茄叶片光合速率下降主要是由气孔限制因素引起的,而阿拉姆叶片则以非气孔限制因素为主导作用.盐胁迫还导致赛棚和阿拉姆番茄生物量显著降低,且地下生物量的下降幅度大于地上生物量.综合分析表明,阿拉姆的抗盐能力高于赛棚.     

砷对小麦生长和光合作用特性的影响

研究了水培条件下砷对小麦根系和地上部分生长速率、光合速率(Pn)、气孔导度(Gs)、胞间CO2浓度(Ci)和蒸腾速率(Tr)的影响.结果表明,随着营养液中砷浓度的提高,小麦根长生长量和地上部分生长量较对照减少;鲜重和砷的浓度呈显著负相关.在0～90mg/L 砷处理内,Pn、Gs、Tr都随砷的浓度的提高而降低;Ci呈先降低,后升高的变化.在As≤30 mg/L时Ci逐渐降低,气孔限制值Ls升高,使Pn下降,造成气孔性限制;而As>30 mg/L时,Ci升高,气孔限制值Ls下降,Pn降低,造成了非气孔性限制.叶片水分利用效率WUE和气孔限制值Ls在As≤30 mg/L时变化一致,都有所升高;但是当As>60 mg/L时,小麦趋于死亡,水分利用率降低.叶绿素含量在0～10mg/L As处理内,差异不显著,在较高砷浓度(As>30 mg/L)时叶绿素显著下降.这说明较低浓度的砷不会抑制小麦叶绿素的合成.砷主要是毒害小麦根系生长,造成植株体光合作用的气孔性限制和非气孔性限制出现,最终影响小麦的生长和发育.     

水分胁迫对牛心朴子光合生理特性影响的研究

采用PVC管种植模拟土壤干旱的方法,研究了牛心朴子(Cynanchum komarovii)在水分胁迫下光合速率(Pn)、气孔导度(Gs)、胞间CO2浓度(Ci)、叶绿素荧光的变化规律及不同生育期适应性表现。结果表明：土壤水分胁迫对牛心朴子叶片光合生理的影响与其胁迫时间及其胁迫程度都有关系,胁迫前中期Pn下降的原因主要是气孔限制,而到后期则以非气孔因素限制为主。中度土壤水分胁迫在短期内对牛心朴子叶片光合作用具有促进作用,而且有利于WUE的提高。而重度胁迫对牛心朴子Pn的影响较显著,而且非气孔因素的出现早于中度胁迫的处理。牛心朴子的光合生理对土壤水分胁迫具有一定的适应时期和适应范围。     

NaCl胁迫对大米草光合·蒸腾等生理特性的影响

研究了NaCl胁迫下大米草净光合速率（Pn）、蒸腾速率（Tr）,叶片气孔导度（Gs）、细胞间CO2浓度（Ci）、株高、叶长、叶宽、茎粗、叶绿素含量、气孔限制值和水分利用效率。结果表明：当NaCl浓度高于300mmol／L时,大米草Pn、Tr、Gs、株高、叶长以及叶绿素含量受到显著抑制（P〈0．05）,叶宽及茎粗则无显著性差异。NaCl胁迫下,大米草光合速率的降低是气孔因素和非气孔因素综合导致的结果,Pn、Tr、Gs、株高以及叶绿素含量的降低可作为大米草受NaCl胁迫的症状．而WUE则保持在较高的水平．因此在防治大米草荨延时．排水处理不是最佳选择。     

水分胁迫对短枝型果树光合作用的非气孔限制

水分胁迫使叶片相对含水量降低,气孔阻力增大.水分胁迫光合速率的下降除受气孔因素影响之外,随着胁迫时间的延长和胁迫程度的加剧,水分胁迫导致O-·2累积,H2O2含量增加,从而引发膜脂过氧化,造成膜渗漏,质膜相对膜透性增大,膜脂过氧化产物MDA含量升高,由膜系统破坏而诱发的非气孔因素成为光合速率下降的主要原因.     

热带林下人工种植阳春砂仁的生长与果实产量动态

调查了西双版纳不同海拔热带沟谷雨林和次生林下的阳春砂仁生长和果实产量动态.结果表明,西双版纳热带林下阳春砂仁自身年龄增长、林下光照不足和旱季水分胁迫影响阳春砂仁果实产量.随种植期增加,阳春砂仁果实产量和成熟植株密度降低.当林下光照水平在全日照的35%以下时,阳春砂仁果实产量随林下日照水平变化呈线性增加(P<0.05).沟谷下方阳春砂仁果实产量显著高于上方(P<0.05).海拔600～1000m,由于阳春砂仁的主花期从干热季3～4月推迟到雨季5月,果实产量显著增加.沟谷雨林和次生林下阳春砂仁果实产量差异不显著.因此,在海拔800～1000m沟谷中轮歇地次生林下有计划种植阳春砂仁,代替在沟谷雨林下种植阳春砂仁,既能解决沟谷雨林下光照和当地旱季水分不足对阳春砂仁果实产量的影响,又有利于热带沟谷雨林的保护.     

Photosynthetic responses of the tropical spiny shrub Lycium nodosum (Solanaceae) to drought, soil salinity and saline spray

Water relations and photosynthetic characteristics of plants of Lycium nodosum grown under increasing water deficit (WD), saline spray (SS) or saline irrigation (SI) were studied. Plants of this perennial, deciduous shrub growing in the coastal thorn scrubs of Venezuela show succulent leaves which persist for approx. 1 month after the beginning of the dry season; leaf succulence is higher in populations closer to the sea. These observations suggested that L. nodosum is tolerant both to WD and salinity. In the glasshouse, WD caused a marked decrease in the xylem water potential (psi), leaf osmotic potential (psi(s)) and relative water content (RWC) after 21 d; additionally, photosynthetic rate (A), carboxylation efficiency (CE) and stomatal conductance (gs) decreased by more than 90 %. In contrast, in plants treated for 21 d with a foliar spray with 35 per thousand NaCl or irrigation with a 10 % NaCl solution, psi and RWC remained nearly constant, while psi(s) decreased by 30 %, and A, CE and gs decreased by more than 80 %. An osmotic adjustment of 0.60 (SS) and 0.94 MPa (SI) was measured. Relative stomatal and mesophyll limitations to A increased with both WD and SS, but were not determined for SI-treated plants. No evidence of chronic photoinhibition due to any treatment was observed, since maximum quantum yield of PSII, Fv/Fm, did not change with either drought in the field or water or salinity stress in the glasshouse. Nevertheless, WD and SI treatments caused a decrease in the photochemical (qP) and an increase in the non-photochemical (qN) quenching coefficients relative to controls; qN was unaffected by the SS treatment. The occurrence of co-limitation of A by stomatal and non-stomatal factors in plants of L. nodosum may be associated with the extended leaf duration under water or saline stress. Additionally, osmotic adjustment may partly explain the relative maintenance of A and gs in the SS and SI treatments and the tolerance to salinity of plants of this species in coastal habitats.     

NaCl胁迫对大米草光合·蒸腾等生理特性的影响

研究了NaCl胁迫下大米草净光合速率(Pn)、蒸腾速率(Tr),叶片气孔导度(Gs)、细胞问CO_2浓度(Ci)、株高、叶长、叶宽、茎粗、叶绿素含量、气孔限制值和水分利用效率.结果表明:当NaCl浓度高于300mmol/L时,大米草Pn、Tr、Gs、株高、叶长以及叶绿素含量受到显著抑制(P＜0.05),叶宽及茎粗则无显著性差异.NaCl胁迫下,大米革光合速率的降低是气孔因素和非气孔因素综合导致的结果,Pn、Tr、Gs、株高以及叶绿素含量的降低可作为大米草受NaCl胁迫的症状,而WUE则保持在较高的水平,因此在防治大米草蔓延时,排水处理不是最佳选择.     

Effect of Water Stress on Photosynthesis in Two Mulberry Genotypes with Different drought Tolerance

Three-month-old mulberry (Morus alba L.) cultivars (drought tolerant S13 and drought sensitive S54) were subjected to water stress for 15 d. Water stress decreased the leaf water potential, net photosynthetic rate (PN), and stomatal conductance (gs) in both the cultivars. However, the magnitude of decline was comparatively greater in the sensitive cultivar (S54). Intercellular CO2 concentration (Ci) was unaltered during mild stress, but significantly increased at severe stress in both cultivars. The photosystem 2 activity significantly declined only at a severe stress in both cultivars. The Ci/gs ratio representing the mesophyll efficiency was greater in the tolerant cultivar S13. Involvement of stomatal and/or non-stomatal components in declining PN depended on the severity and duration of stress. However, the degree of non-stomatal limitations was relatively less in the drought tolerant cultivar.     

Stomatal conductance is a key parameter to assess limitations to photosynthesis and growth potential in barley genotypes

Fourteen genotypes of barley were compared for response to salinity by monitoring the parameters gas exchange and chlorophyll fluorescence. We present relationships between stomatal conductance (gs) gas exchange chlorophyll fluorescence parameters and aboveground dry matter (AGDM). We found that genetic variability provided a continuum of data for gs across control and saline conditions. We used this continuum of gs values to test the overall relationships between gs and net photosynthesis (A), leaf internal CO2 concentration (Ci), actual quantum yield of PSII electron transport (PhiPSII), relative electron yield over net CO2 assimilation rate (ETR/A), and AGDM. The relationship between gs and A was highly significant (P < 0.0001) for both control and saline treatments, while correlations between gs and Ci, and Ci and A were significant only under control conditions. Unexpectedly, we found positive correlations between gs and PhiPSII (P < 0.0001) for both conditions. A comparison between relationships of gs and A, and gs and PhiPSII seemed to indicate a possible acclimation to salinity at the chloroplastic level. Finally, the relationships between gs and ETR/A were exceptionally strong for both growing conditions (P < 0.0001) indicating that, as gs values were negatively affected in barley by genetics and salinity as main or interactive effects, there was a progressive increase in photorespiration in barley. Overall, we found that stomatal conductance was a key parameter in the study of barley responses to limiting situations for photosynthesis. We also found a strong relationship between AGDM and gs regardless of growing conditions and genotypes. For breeding evaluations to select barley genotypes for salinity tolerance, it may be possible to replace all measurements of gas exchange and chlorophyll fluorescence by the simple use of a porometer.     

NaCl胁迫下黄连木叶片光合特性及快速叶绿素荧光诱导动力学曲线的变化

以1年生黄连木为试材,设置NaCl浓度分别为0(CK)、0.15%、0.3%、0.45%、0.6%5个处理,利用快速叶绿素荧光诱导动力学曲线分析技术(JIP-test),研究了NaCl胁迫对黄连木叶片光合特性和快速叶绿素荧光诱导动力学参数的影响.结果表明: 随着NaCl浓度的升高, 黄连木叶片中的叶绿素a、叶绿素b和总叶绿素含量逐渐降低,叶绿素a/b比值先升高后下降,类胡萝卜素含量逐渐增加; 叶片的净光合速率(P_n)、气孔导度(g_s)逐渐降低,其中NaCl浓度＜0.3%时,叶片P_n下降主要受气孔限制;当NaCl浓度＞0.3%时, P_n下降主要由非气孔因素限制;单位面积捕获的光能(TR_o/CS_o)、电子传递的量子产额(ET_o/CS_o)、单位面积的反应中心数量(RC/CS_o)、量子产额或能量分配比率(ψ_o和φ_Eo)逐渐降低,而单位面积吸收的光能(ABS/CS_o)、荧光诱导曲线中K点(W_k)和J点(V_j)明显增加,说明盐胁迫对黄连木叶片放氧复合体(OEC)、受体侧和PSⅡ反应中心造成了伤害.当NaCl浓度为0.3%时,PSⅡ最大光化学效率(F_v/F_m)和光化学性能指数(PI_ABS)分别比对照下降 17.7%和36.6%.     

Photosynthetic carbon assimilation and associated metabolism in relation to water deficits in higher plants

Experimental studies on CO2 assimilation of mesophytic C3 plants in relation to relative water content (RWC) are discussed. Decreasing RWC slows the actual rate of photosynthetic CO2 assimilation (A) and decreases the potential rate (Apot). Generally, as RWC falls from c. 100 to c. 75%, the stomatal conductance (gs) decreases, and with it A. However, there are two general types of relation of Apot to RWC, which are called Type 1 and Type 2. Type 1 has two main phases. As RWC decreases from 100 to c. 75%, Apot is unaffected, but decreasing stomatal conductance (gs) results in smaller A, and lower CO2 concentration inside the leaf (Ci) and in the chloroplast (Cc), the latter falling possibly to the compensation point. Down-regulation of electron transport occurs by energy quenching mechanisms, and changes in carbohydrate and nitrogen metabolism are considered acclimatory, caused by low Ci and reversible by elevated CO2. Below 75% RWC, there is metabolic inhibition of Apot, inhibition of A then being partly (but progressively less) reversible by elevated CO2; gs regulates A progressively less, and Ci and CO2 compensation point, Gamma rise. It is suggested that this is the true stress phase, where the decrease in Apot is caused by decreased ATP synthesis and a consequent decreased synthesis of RuBP. In the Type 2 response, Apot decreases progressively at RWC 100 to 75%, with A being progressively less restored to the unstressed value by elevated CO2. Decreased gs leads to a lower Ci and Cc but they probably do not reach compensation point: gs becomes progressively less important and metabolic limitations more important as RWC falls. The primary effect of low RWC on Apot is most probably caused by limited RuBP synthesis, as a result of decreased ATP synthesis, either through inhibition of Coupling Factor activity or amount due to increased ion concentration. Carbohydrate synthesis and accumulation decrease. Type 2 response is considered equivalent to Type 1 at RWC below c. 75%, with Apot inhibited by limited ATP and RuBP synthesis, respiratory metabolism dominates and Ci and Gamma rise. The importance of inhibited ATP synthesis as a primary cause of decreasing Apot is discussed. Factors determining the Type 1 and Type 2 responses are unknown. Electron transport is maintained (but down-regulated) in Types 1 and 2 over a wide range of RWC, and a large reduced/oxidized adenylate ratio results. Metabolic imbalance results in amino acid accumulation and decreased and altered protein synthesis. These conditions profoundly affect cell functions and ultimately cause cell death. Type 1 and 2 responses may reflect differences in gs and in sensitivity of metabolism to decreasing RWC.     

青杨雌雄叶片气孔分布及气体交换的异质性差异

利用网格和二维成图的方法对青杨雌雄叶片各区域的气孔分布及气体交换特性进行了测定.结果表明:1)除气孔密度(SD)外,雌雄植株在气孔长度(SL)、宽度(SW)和比值(SR)方面具有显著差异(P=0.000,P=0.000和P=0.002).雌株的SL和SW分别比雄株的高51.86%和67.06%,而SR则比雄株的低11.46%.从雌株和雄株的叶面分布来看,SD均为叶中>叶尖>叶基,SL均为叶尖>叶中>叶基,SW的最小值同在叶基部,但最大值分别在叶中和叶尖部.雌株的SR表现为叶基>叶尖>叶中,雄株却正好相反.2)在净光合速率(Pn)上雌株明显低于雄株.雌株的Pn叶基最低(Pn值介于2.00～3.00?μmol m-2 s-1),叶尖最高(Pn值介于8.00～9.00?μmol m-2 s-1),总体上表现出沿叶基到叶尖逐渐增大的趋势.雄株的Pn在叶面的分布也有差异,但总体规律不明显.3)从叶面各区间的气体交换来看,雌株的蒸腾速率(Tr)和气孔导度(Gs)变化不大,雄株的Tr和Gs呈现叶尖和叶中部高于叶基部的明显趋势.雌株的胞间CO2浓度(Ci)为叶基>叶中>叶尖,气孔限制值(Ls)与此相反.而雄株的Ci在叶面的变化较大,Ls呈现沿叶尖至叶基方向逐步上升的趋势.上述结果表明,青杨雌雄叶片在气孔分布及气体交换特性上不仅存在显著的性别差异,而且具有明显的叶面区域异质性.