NaCl对光合作用影响的研究进展

对NaCl对光合作用影响的几个重要方面的研究进展进行了综述,包括NaCl对光合作用的影响途径,气孔效应与非气孔效应,NaCl对光能吸收与转换、光合电子传递、光合磺素同化的影响及盐与其他胁迫因子对PSⅡ活性的协同影响等,对今后这些方面研究中的重点内容与趋势进行了评述。     

短期夜间低温胁迫对秋茄幼苗碳氮代谢及其相关酶活性的影响

采用人工控制手段,研究短期夜间低温对秋茄幼苗叶片光合特性、色素含量、抗氧化系统、细胞膜透性以及碳氮代谢相关酶活性的影响。结果表明：(1)低温16 h内,秋茄的净光合速率、气孔导度、气孔限制值均显著降低,而胞间CO2浓度显著增加。(2)低温低于8 h,叶片叶绿素含量、类胡萝卜素含量以及Chl a/Chl b比值均未产生显著变化,而Car/Chl 比值显著增加。低温12、16 h,其叶片光合色素均下降,尤其白天下降幅度更大。(3)低温16 h内叶片可溶性总糖一直增加,而蔗糖含量、蔗糖合成酶(SS)和蔗糖磷酸合成酶(SPS)活性均在低温12 h后下降。(4)低温16 h内叶片可溶性蛋白、游离氨基酸含量以及羧肽酶活性均增加,而低温8 h时叶片内肽酶活性就开始下降。(5)低温16 h内叶片相对电导率、MDA均增加,而叶片POD活性均下降,尤其夜间下降更明显。另外,低温4、16 h能显著降低叶片SOD活性。以上说明,低温16 h时秋茄叶片光合作用的下降主要是因为非气孔导度限制引起,这主要与光合色素下降、抗氧化酶活性降低有关。此外,短期夜间低温通过影响SS、SPS、内肽酶以及羧肽酶活性,从而抑制了秋茄自身的碳氮代谢调控能力。     

NaCl对光合作用影响的研究进展

对ＮａＣｌ对光合作用影响的几个重要方面的研究进展进行了综述，包括ＮａＣｌ对光合作用的影响途径，气孔效应与非气孔效应，ＮａＣｌ对光能吸收与转换、光合电子传递、光合碳素同化的影响及盐与其他胁迫因子对ＰＳＩＩ活性的协同影响等，对今后这些方面研究中的重点内容与趋势进行了评述     

光质对植物光合作用的调控及其机理

光合作用是植物生长发育的基础.光质对植物光合作用的调控主要包括可见光对植物气孔器运动、叶片生长、叶绿体结构、光合色素、D1蛋白及其编码基因和光合碳同化等的调节,以及紫外光对植物光系统Ⅱ的影响.蓝光和红光能促进气孔的开张,而绿光能够逆转这种作用.蓝光有利于叶绿体的发育,红、蓝、绿复合光有利于叶面积的扩展,而红光更有利于光合产物的积累;不同光质对不同植物、不同组织器官叶绿素积累的影响不同.蓝光和远红光可以促进psbA基因转录物质的积累.大多数高等植物和绿藻在橙、红光下光合速率最高,蓝紫光其次,绿光最低.紫外光可以导致光系统Ⅱ的电子传递活性下降.此外,针对光质与光合作用研究领域中存在的问题,对今后的研究方向进行了讨论.     

不同叶龄杂交酸模叶片光合速率及PSⅡ光化学效率诱导对NaCl胁迫的响应

通过气体交换和叶绿素荧光分析方法研究了杂交酸模(Rumex K-1)幼叶、功能叶和衰老叶的光合速率及PSⅡ光化学效率诱导对NaCl胁迫的响应特征。结果表明,老叶的光合作用对盐胁迫最为敏感,幼叶次之,功能叶对盐胁迫的抗性最强。对照植株幼叶、功能叶和老叶的光合诱导速率相差不大,幼叶和功能叶光合诱导后期受气孔限制的影响。盐胁迫后幼叶和功能叶的光合诱导推迟,出现了一个新的光合适应阶段;老叶仍有部分电子传递功能,但已丧失碳同化能力。盐胁迫后气孔导度不再是叶片光合碳同化诱导过程的限制因素,不同叶龄叶片PSⅡ光化学效率启动所需时间远远小于光合速率启动所需时间,盐胁迫对叶片的PSⅡ光化学效率诱导过程几乎没有影响。     

植物光合作用的三维特性研究进展

光合作用是地球上最重要的化学反应。虽然针对植物光合作用已经进行了广泛深入的研究, 但从三维层面探讨植物叶片光合功能及其调节作用的工作较少。叶片结构、光合机构组分、叶片内光能吸收和传递均具有明显的三维特性, 极大影响叶片内CO₂转运、叶肉细胞的电子传递和碳同化, 进而使叶片光合功能及其调控表现出复杂的三维特征。因此, 从三维角度分析叶片光合特性有助于理解光合作用机理, 也能够为提高植物光合作用效率提供理论支持。     

施氮对不同抗旱性冬小麦叶片光合与呼吸的调控

在大田条件下对两个不同抗旱特性的冬小麦品种全生育期叶片光合气体交换参数、光合色素含量和呼吸值及其对氮素水平的响应进行了研究.结果表明,施氮180 kg·hm^-2处理旱地品种叶片气孔导度、总光合色素含量、光合速率较不施氮处理在全生育期分别提高了43.75%、18.54%和49.66%,水地品种分别提高了12.12%、20.88%和29.25%;而旱地品种总呼吸速率降低了4.8%,水地品种降低了4.5%.适量施氮,增强了小麦叶片的气体交换能力,提高了光合色素含量,并降低了呼吸速率,从而提高了小麦叶片光合碳同化能力.小麦品种间光合的差异主要由非气孔因素引起.旱地品种呼吸速率较低,吸收的光能较多地用于光合碳同化作用.不施氮处理叶片光合速率较高的生育时期其呼吸速率也高,而施氮处理叶片光合速率高的生育时期呼吸值较低.施氮增加了光能向光合碳同化方向的分配.施氮对提高冬小麦抗旱能力有积极作用,其机理在于氮素改善了叶片气体交换状况,提高了光合色素含量,并优化了叶片对光能吸收的分配.     

试管苗木薯的光合作用及水分关系特性

引进种试管苗木薯188比本地栽培种面包木薯具有相对高的光合速率、光合产物输出率、光合色素含量、叶片气孔传导性、良好的水分关系参数和较低的乙醇酸氢化酶活性。表明引进种试管苗比本地栽培种对干旱逆境的适应性强,生产性能高。     

冰冻对珊瑚树(Viburnum odoratissimum)叶片光合效率的影响

光合作用的冰冻伤害研究大多利用离体叶片、原生质体,甚至叶绿体类囊体进行人工冰冻预处理,关于室外自然温度下出现的植物光合作用冰冻伤害,特别是冰冻影响光合量子效率的研究报告还很少。虽然光合碳同化受抑是最早可以测到的冰冻伤害征状,但其机理迄今不清楚(Krause等1982,Krause和Klosson1983)。     

高山植物光合机构耐受胁迫的适应机制

植物的光合作用是易受环境影响的重要生理过程之一.高山植物作为生长在特定极端环境(低温/强辐射)下的植物群体,其光合器官在形态结构和生理功能上形成了抵御强辐射和低温胁迫的特殊适应机制.但由于较高的生境异质性,高山植物的光保护适应机制存在较大的差异.光保护适应机制与光合作用密切关联,影响植物的碳同化能力和生物量的形成能力.本文对近年来国内外有关高山植物光合器官叶绿体的形态、超微解剖结构及光合机构光保护适应机理的研究进展进行了综述,并提出了今后高山植物光合作用生理适应性研究的方向.     

光合作用对光和CO2响应模型的研究进展

光合作用对光和CO₂响应模型是研究植物生理和植物生态学的重要工具, 可为植物光合特性对主要环境因子的响应提供科学依据。该文综述了当前光合作用对光和CO₂响应模型的研究进展和存在的问题, 并在此基础上探讨了这些模型的可能发展趋势。光合作用涉及光能的吸收、能量转换、电子传递、ATP合成、CO₂固定等一系列复杂的物理和化学反应过程。光合作用由原初反应、同化力形成和碳同化3个基本过程构成, 任一个过程均可对光合作用速率产生直接的影响。光合作用对光响应模型只涉及光能的转换, 而光合作用的生化模型包含了同化力形成和碳同化这两个基本过程。把光合作用的原初反应, 即把参与光能吸收、传递和转换的捕光色素分子的物理参数(如捕光色素分子数、捕光色素分子光能吸收截面、捕光色素分子处于激发态的平均寿命等)结合到生化模型中, 可能是今后光合作用对光响应机理模型的发展方向。     

降水和温度变化对长白山地区水曲柳幼苗生长和光合参数的影响

以我国温带主要阔叶树种水曲柳幼苗为对象,在长白山自然保护区海拔740 m和1200 m布设两处试验地,分别进行增水30％(+W)、减水30％(-W)和自然降水(CK)处理试验,分析植株生长和叶片光合作用参数、可溶性蛋白和光合色素含量,以及降水和温度变化对水曲柳光合作用的影响.结果表明:温度变化对水曲柳幼苗生长和光合生理指标的影响显著,与海拔1200 m样地相比,海拔740 m样地3个处理水曲柳幼苗的基径、株高、叶片叶绿素含量和可溶性蛋白含量显著增加,胡萝卜素含量降低;叶片净光合速率、气孔导度、蒸腾速率和气孔限制值均显著升高,而胞间CO2浓度和叶片水分利用效率显著降低.水曲柳幼苗光合能力的下降归因于非气孔因素限制.降水变化对水曲柳幼苗生长及光合作用的影响均不显著.     

UV-B辐射增强对芦苇光合生理及叶绿体超微结构的影响

在UV-B辐照增强条件下,研究不同辐照梯度对芦苇光合特性、光合色素含量及叶绿体超微结构的影响. 结果表明: 与自然光照相比,UV-B辐照增强显著降低芦苇叶片净光合速率、气孔导度、蒸腾速率,且随辐照强度增大,降低程度加剧,胞间CO₂浓度升高,光合效率显著降低;与自然光照相比,UV-B辐照增强显著降低芦苇叶片光合色素含量(包括叶绿素a、叶绿素b、总叶绿素和类胡萝卜素),且随辐照强度增大,降低程度加剧;UV-B辐射增强条件下,叶绿体超微结构遭到破坏,表现为叶绿体结构变形,类囊体片层排列稀疏紊乱、膨胀甚至模糊不清,并且UV-B辐射强度越大,损伤越大,高强度UV-B辐射对叶绿体超微结构的影响大于低强度辐射.     

The contribution of photosynthesis to the red light response of stomatal conductance

To determine the contribution of photosynthesis on stomatal conductance, we contrasted the stomatal red light response of wild-type tobacco (Nicotiana tabacum 'W38') with that of plants impaired in photosynthesis by antisense reductions in the content of either cytochrome b(6)f complex (anti-b/f plants) or Rubisco (anti-SSU plants). Both transgenic genotypes showed a lowered content of the antisense target proteins in guard cells as well as in the mesophyll. In the anti-b/f plants, CO(2) assimilation rates were proportional to leaf cytochrome b(6)f content, but there was little effect on stomatal conductance and the rate of stomatal opening. To compare the relationship between photosynthesis and stomatal conductance, wild-type plants and anti-SSU plants were grown at 30 and 300 micromol photon m(-2) s(-1) irradiance (low light and medium light [ML], respectively). Growth in ML increased CO(2) assimilation rates and stomatal conductance in both genotypes. Despite the significantly lower CO(2) assimilation rate in the anti-SSU plants, the differences in stomatal conductance between the genotypes were nonsignificant at either growth irradiance. Irrespective of plant genotype, stomatal density in the two leaf surfaces was 2-fold higher in ML-grown plants than in low-light-grown plants and conductance normalized to stomatal density was unaffected by growth irradiance. We conclude that the red light response of stomatal conductance is independent of the concurrent photosynthetic rate of the guard cells or of that of the underlying mesophyll. Furthermore, we suggest that the correlation of photosynthetic capacity and stomatal conductance observed under different light environments is caused by signals largely independent of photosynthesis.     

Effects of Water Deficits on Carbon Assimilation

This review focuses on the effects of water deficits on photosynthesisand partitioning of assimilates at the leaf level. It is nowestablished that the rate of CO₂ assimilation in the leavesis depressed at moderate water deficits, mostly as a consequenceof stomatal closure. In fact, depending on the species and onthe nature of dehydration, carbon assimilation may diminishto values close to zero without any significant decline in mesophyllphotosynthetic capacity. This remarkable resistance of the photosyntheticapparatus to water deficits became apparent after the measurementof photosynthesis at saturating CO₂ concentrations was madepossible. Whenever light or heat stress are superimposed a declinein mesophyll photosynthesis may occur as a result of a ‘down-regulation’process, which seems to vary among genotypes. A major secondaryeffect of dehydration on photosynthetic carbon metabolism isthe change in partitioning of recently fixed carbon towardssucrose, which occurs in a number of species in parallel tothe increase in starch breakdown. This increase in compoundsof low molecular weight may contribute to an osmotic adjustment.Controlling mechanisms involved in this process deserve furtherinvestigation. Key words: Carbohydrates, carbon partitioning, heat stress, photoinhibition, photosynthetic capacity, stomatal limitation, water deficits     

Photosynthesis and Stomatal Conductance of Potato Clones (Solanum tuberosum L.) : Comparative Differences in Diurnal Patterns, Response to Light Levels, and Assimilation through Upper and Lower Leaf Surfaces

A few potato clones, such as A6948-4, had higher rates of photosynthesis in the field than the Russet Burbank and were able to maintain higher rates not only during mid-day but also in the early morning and late evening hours. In addition, they maintained higher carbon assimilation rates over a range of photosynthetic photon flux density from 400 to 2,000 microeinsteins per square meter per second.

Stomatal conductance increased linearly as irradiance increased from 500 to 2,000 microeinsteins per square meter per second with all four potato clones that were examined. Obviously, comparative measurements of stomatal conductance or diffusive resistance with potato must be taken at a known and constant photosynthetic photon flux density.

The upper (adaxial) leaf surface of some potato clones provided a surprising contribution to total carbon assimilation. Neither stomatal conductance, number of stomata per unit area, total area of the stomatal apparatus, nor chlorophyll content appear to account for differences in carbon assimilation rates among clones.

     

Deficiency of mitochondrial fumarase activity in tomato plants impairs photosynthesis via an effect on stomatal function

Transgenic tomato (Solanum lycopersicum) plants expressing a fragment of a fumarate hydratase (fumarase) gene in the antisense orientation and exhibiting considerable reductions in the mitochondrial activity of this enzyme show impaired photosynthesis. The rate of the tricarboxylic acid cycle was reduced in the transformants relative to the other major pathways of carbohydrate oxidation and the plants were characterized by a restricted rate of dark respiration. However, biochemical analyses revealed relatively little alteration in leaf metabolism as a consequence of reducing the fumarase activity. That said, in comparison to wild-type plants, CO(2) assimilation was reduced by up to 50% under atmospheric conditions and plants were characterized by a reduced biomass on a whole plant basis. Analysis of further photosynthetic parameters revealed that there was little difference in pigment content in the transformants but that the rate of transpiration and stomatal conductance was markedly reduced. Analysis of the response of the rate of photosynthesis to variation in the concentration of CO(2) confirmed that this restriction was due to a deficiency in stomatal function.     

模拟大气硫酸铵污染对香樟幼苗生长及光合特性的影响

通过室内盆栽实验研究了大气颗粒污染物硫酸铵对香樟幼苗生长及光合特性的影响。结果表明,香樟幼苗叶片涂抹硫酸铵处理对植物生长无显著影响;低浓度硫酸铵(2 g·L^-1)提高了叶片叶绿素含量,而高浓度(4 g·L^-1)却降低了叶片叶绿素含量;与对照相比,低浓度处理的香樟叶片净光合速率、气孔导度、胞间二氧化碳浓度与蒸腾速率无显著差异;高浓度处理的香樟叶片净光合速率与蒸腾速率高于对照,而气孔导度与胞间二氧化碳浓度与对照无显著差异。机理分析表明,硫酸铵颗粒物主要通过影响叶片气孔导度来影响植物光合特性。