植物叶片最大羧化速率与叶氮含量关系的变异性

叶片最大羧化速率是表征植物光合能力的关键参数, 受到光照、温度、水分、CO₂浓度、叶片氮含量等多个要素的控制。准确地模拟植物叶片最大羧化速率对环境因子的响应是预测未来植被生产力和碳循环过程的前提。目前大多数陆地碳循环过程模型以Farqhuar光合作用模型为基础模拟植物的光合作用, 关于植物叶片的最大羧化速率与叶氮含量关系的模拟方法却各不相同。该文汇总了1990-2013年国内外植物叶片光合速率观测研究文献中叶片最大羧化速率与叶氮含量的关系式及相关数据, 分析了叶片最大羧化速率与叶氮含量关系随不同植被功能型和时间的变化特征, 以及环境因子变化条件下最大羧化速率与叶氮含量关系的变化特征, 探讨了二者关系变异性的可能原因以及影响因子。结果表明: 1)不同功能型植物叶片的最大羧化速率和叶氮含量的关系存在较大差异, 二者线性关系式的斜率平均值变化范围为16.29-50.25 μmol CO₂·g N^-1·s^-1。落叶植被叶片的最大羧化速率随叶氮含量的变化率和光合氮利用效率一般都高于常绿植被, 其变异主要源于植物的比叶重和叶片内部氮素分配的差异。2)叶片最大羧化速率随叶氮含量的变化存在季节和年际变异。在没有受到水分胁迫的年份中, 叶片最大羧化速率随叶氮含量变化的速率一般在春季或夏季最高, 其季节变异与比叶重和叶氮在Rubisco的分配比例的季节变化有关。受到干旱的影响, 叶片最大羧化速率随叶氮含量的变化率会升高。3)当大气CO₂浓度增加时, 由于叶片中Rubisco含量的降低, 多年生针叶叶片最大羧化速率和叶氮关系斜率值会出现降低; 当供氮水平增加时, 叶片最大羧化速率和叶片氮含量均表现出增加趋势, 二者线性关系的斜率也相应增加。在此基础上, 该文指出在模拟叶片最大羧化速率与叶氮含量的关系时, 应考虑叶片比叶重和叶氮在Rubisco中的分配比例的季节变异、水分胁迫、大气CO₂浓度和供氮水平变化对二者关系的影响。囿于数据的有限性, 今后应进一步加强多因子控制实验研究, 深入探讨叶片最大羧化速率与叶氮含量关系的变异性机理, 并获得更系统的观测数据, 以助生态系统过程模型的改进, 提高模型的模拟精度。     

Variations in the relationship between maximum leaf carboxylation rate and leaf nitrogen concentration

叶片最大羧化速率是表征植物光合能力的关键参数, 受到光照、温度、水分、CO₂浓度、叶片氮含量等多个要素的控制。准确地模拟植物叶片最大羧化速率对环境因子的响应是预测未来植被生产力和碳循环过程的前提。目前大多数陆地碳循环过程模型以Farqhuar光合作用模型为基础模拟植物的光合作用, 关于植物叶片的最大羧化速率与叶氮含量关系的模拟方法却各不相同。该文汇总了1990-2013年国内外植物叶片光合速率观测研究文献中叶片最大羧化速率与叶氮含量的关系式及相关数据, 分析了叶片最大羧化速率与叶氮含量关系随不同植被功能型和时间的变化特征, 以及环境因子变化条件下最大羧化速率与叶氮含量关系的变化特征, 探讨了二者关系变异性的可能原因以及影响因子。结果表明: 1)不同功能型植物叶片的最大羧化速率和叶氮含量的关系存在较大差异, 二者线性关系式的斜率平均值变化范围为16.29-50.25 μmol CO₂·g N^-1·s^-1。落叶植被叶片的最大羧化速率随叶氮含量的变化率和光合氮利用效率一般都高于常绿植被, 其变异主要源于植物的比叶重和叶片内部氮素分配的差异。2)叶片最大羧化速率随叶氮含量的变化存在季节和年际变异。在没有受到水分胁迫的年份中, 叶片最大羧化速率随叶氮含量变化的速率一般在春季或夏季最高, 其季节变异与比叶重和叶氮在Rubisco的分配比例的季节变化有关。受到干旱的影响, 叶片最大羧化速率随叶氮含量的变化率会升高。3)当大气CO₂浓度增加时, 由于叶片中Rubisco含量的降低, 多年生针叶叶片最大羧化速率和叶氮关系斜率值会出现降低; 当供氮水平增加时, 叶片最大羧化速率和叶片氮含量均表现出增加趋势, 二者线性关系的斜率也相应增加。在此基础上, 该文指出在模拟叶片最大羧化速率与叶氮含量的关系时, 应考虑叶片比叶重和叶氮在Rubisco中的分配比例的季节变异、水分胁迫、大气CO₂浓度和供氮水平变化对二者关系的影响。囿于数据的有限性, 今后应进一步加强多因子控制实验研究, 深入探讨叶片最大羧化速率与叶氮含量关系的变异性机理, 并获得更系统的观测数据, 以助生态系统过程模型的改进, 提高模型的模拟精度。     

施氮和大气CO2浓度升高对小麦旗叶光合电子传递和分配的影响

采用开顶式气室盆栽培养小麦,设计2个大气CO₂浓度（正常：400 μmol·mol^-1;高：760 μmol·mol^-1）、2个氮素水平（0和200 mg·kg^-1土）的组合处理,通过测定小麦抽穗期旗叶氮素和叶绿素浓度、光合速率（P_n）-胞间CO₂浓度（C_i）响应曲线及荧光动力学参数,来测算小麦叶片光合电子传递速率等,研究了高大气CO₂浓度下施氮对小麦旗叶光合能量分配的影响.结果表明：与正常大气CO₂浓度相比,高大气CO₂浓度下小麦叶片氮浓度和叶绿素浓度降低,高氮处理的小麦叶片叶绿素a/b升高.施氮后小麦叶片PSⅡ最大光化学效率（F_v/F_m）、PSⅡ反应中心最大量子产额（F_v′/F_m′）、PSⅡ反应中心的开放比例（q_p）和PSⅡ反应中心实际光化学效率（Φ_PSⅡ）在大气CO₂浓度升高后无明显变化,虽然叶片非光化学猝灭系数（NPQ）显著降低,但PSⅡ总电子传递速率（J_F）无明显增加;不施氮处理的F_v′/F_m′、Φ_PSⅡ和NPQ在高大气CO₂浓度下显著降低,尽管F_v/F_m和q_P无明显变化,J_F仍显著下降.施氮后小麦叶片J_F增加,参与光化学反应的非环式电子流传递速率(J_C)明显升高.大气CO₂浓度升高使参与光呼吸的非环式电子流传递速率(J₀)、Rubisco氧化速率（V₀）、光合电子的光呼吸/光化学传递速率比（J₀/J_C）和Rubisco氧化/羧化比（V₀/V_C）降低,但使J_C和Rubisco羧化速率（V_C）增加.因此,高大气CO₂浓度下小麦叶片氮浓度和叶绿素浓度降低,而增施氮素使通过PSⅡ反应中心的电子流速率显著增加,促进了光合电子流向光化学方向的传递,使更多的电子进入Rubisco羧化过程,P_n显著升高.     

大气CO2浓度升高对干旱条件下冬小麦叶片光合适应的影响

大气CO₂浓度升高是全球气候变化的主要特征,但大气CO₂浓度长期升高条件下冬小麦叶片发生光合适应的机制尚不十分清楚。本研究以盆栽冬小麦‘郑麦9023’为试验材料,在人工气候控制室内设置2个CO₂浓度(400和600 μmol·mol^-1)、2个水分条件(田间持水量的80%±5%和55%±5%),测定拔节期和抽穗期的光合特征曲线、叶绿素荧光动力学参数、叶氮含量和收获后的籽粒产量等指标,探讨干旱条件下库源关系改变对叶片光合适应的影响。结果表明: 在小麦拔节期,干旱条件下CO₂浓度升高处理的小麦PSⅡ实际光化学效率没有显著增加,但通过提升最大电子传递速率和电子向光化学方向的传递比例,增强了Rubisco的羧化速率,从而提高了最大净光合速率;在抽穗期,功能叶最大电子传递速率和电子向光化学方向的传递比例虽然较高,但PSⅡ实际光化学转换效率降低,Rubisco羧化速率和丙糖磷酸利用效率下降,以致最大净光合速率降低。干旱条件下,CO₂浓度升高增加了小麦单茎生物量、单穗粒数和穗粒重,降低了不孕小穗数,提高了籽粒产量。土壤干旱条件下,CO₂浓度升高对收获期小麦单茎籽粒产量的促进作用可能主要来自于生长前期的光合产物积累。生长后期光合适应发生的主要原因是功能叶PSⅡ实际光化学转换效率和丙糖磷酸利用效率的降低,而不是最大电子传递速率、光化学方向的电子传递比例和新叶库强的变化。     

Physiological responses of the legume model Medicago truncatula cv. Jemalong to water deficit

In Medicago truncatula Gaertn. cv. Jemalong plants some mechanisms involved in drought resistance were analysed in response to a progressive water deficit imposed by suppression of soil irrigation. Withholding water supply until the soil had reached one-half of its maximum water content had no significant effect on leaf RWC, gas exchanges or chlorophyll fluorescence parameters. Under severe drought conditions, the plants resistance to water shortage involved mainly drought avoidance mechanisms through a decrease in stomatal conductance. The consequent decrease in the internal CO₂ concentration (C_i) should have limited the net CO₂ fixation (A). Since A decreased slightly more than C_i under severe water deficit, non-stomatal limitations of photosynthesis may have also occurred. Analysis of A/C_i curves showed reduced carboxylation efficiency due to limitations in RuBP regeneration and Rubisco activity, confirming the presence of non-stomatal limitations of photosynthesis. Drought tolerance mechanisms involving osmotic adjustment and an increase in cell membrane integrity were also present. Altogether, these mechanisms allowed M. truncatula cv. Jemalong plants to still maintain a quite elevated level of net CO₂ fixation rate under severe water deficit conditions. These results may contribute to identify useful physiological traits for breeding programs concerning drought adaptation in legumes.     

Nitrate additions enhance the photosynthetic sensitivity of a nodulated South African Mediterranean-climate legume (Podalyria calyptrata) to elevated UV-B

Nitrate deposition from anthropogenic activities into nutrient impoverished soils of Mediterranean ecosystems represents a significant income to their N economy, which may potentially increase the sensitivity of those typically UV-B (280–315 nm) resilient plants from these ecosystems with superior photosynthetic rates especially to increases in solar UV-B flux due to ozone depletion. This proposal was examined by exposing nodulated Podalyria calyptrata seedlings for 6-months in nitrate deficient and nitrate replete sand culture to biologically effective UV-B (UV-B_BE) supplements approximating 40 and 77% above clear-sky background (control) at an outdoor site. Leaf photosynthesis and chemical composition of purely symbiotic plants were unaffected by increased UV-B_BE. Conversely, nodulated plants that received nitrate supplements displayed a linear reduction in stomatal conductance (g_S) but non-linear asymptotic reductions in light-saturated net CO₂ assimilation rate (A_sat), apparent carboxylation efficiency (ACE) and nitrogen use efficiency (NUE) with increased UV-B_BE. RuBP regeneration limitations on CO₂ assimilation were not apparent, since A_sat at saturating internal leaf CO₂ concentrations displayed insignificant depressions with increased UV-B_BE. Nor was there any suggestion of diminished light absorption capacity of antenna complexes, or of photosynthetic inhibition due to starch accumulation, since leaf chlorophyll and carotenoid contents and non-structural carbohydrate concentrations were insignificantly altered by increased UV-B_BE. Also, there seemed unlikely photosynthetic inhibition due to reduced allocation of N to Rubisco with increased UV-B_BE in the nitrate-fed plants, since both ACE and A_sat were negatively correlated with leaf N content, much of which probably constituted assimilated nitrate according to the less negative δ¹⁵N values. We suggest that the molecular processes that rendered P. calyptrata plants receiving nitrate supplements more sensitive to photosynthetic inhibition by increased UV-B_BE may be related indirectly to their more active metabolic state, this apparent from their elevated respiratory and photosynthetic rates, rather than to any direct UV-B effects on CO₂ uptake and fixation.     

玉米花生间作和磷肥对间作花生光合特性及产量的影响

揭示玉米(Zea mays)和花生(Arachis hypogaea)间作提高花生对弱光利用能力的光合特点及磷(P)肥效应, 对阐明间作花生适应弱光的光合机理和提高间作花生的产量具有重要意义。该试验于2011-2012年在河南科技大学试验农场分析了间作花生功能叶的叶绿素含量与构成、光响应曲线和CO₂响应曲线特点和荧光参数。结果表明: 与单作花生相比, 施P与不施P条件下玉米和花生间作显著(p < 0.01)提高了花生功能叶的叶绿素b含量, 降低了叶绿素a/b, 显著提高了光系统II最大光化学效率(F_v/F_m)、实际光化学效率(Φ_PSII)、光化学猝灭系数(q_P)、表观量子效率(AQY)和弱光时的光合速率, 显著降低了气孔导度、二磷酸核酮糖羧化酶羧化速率(V_cmax)、电子传递速率(J_max)和磷酸丙糖利用速率(TPU); 与不施P相比, 施P有利于提高间作花生功能叶的叶绿素含量, 显著提高了Φ_PSII、q_P、V_cmax、J_max和TPU, 说明间作花生通过提高功能叶的叶绿素b含量, 改变叶绿素构成, 提高了光系统II的F_v/F_m、Φ_PSII和q_P, 增强了对光能的捕获和转化能力, 提高了对弱光的利用能力, 而并非提高了对CO₂的羧化固定能力; 施P有利于提高间作花生对弱光的利用能力和产量, 土地当量比提高了6.2%-9.3%。     

A review on the FvCB biochemical model of photosynthesis and the measurement of A-Ci curves

The biochemical model of photosynthesis proposed by Farquhar, von Caemmerer and Berry is a CO₂ response model based on photosynthetic processes. It hypothesizes that leaf CO₂ assimilation rate (A) of C₃ plants is decided by the minimum of three biochemical processes: the carboxylation rate supported by ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco), the ribulose-1,5-bisphosphate (RuBP) regeneration rate supported by electron transport and the triose-phosphate (TP) use rate. Fitting leaf CO₂ assimilation rate versus intercellular CO₂ concentration (A-C_i) curves with the modified FvCB model could provide several important biochemical parameters, including maximum Rubisco carboxylation rate, maximum rate of electron transport, TP use rate, day respiration rate and mesophyll conductance. The FvCB model has greatly improved our understanding and prediction of plant photosynthetic physiology and its response to environmental changes. In this review, we firstly described the FvCB model, and analysed the characteristics of this model: segmentation and overparameterization. We reviewed the estimation of biochemical parameters which by fitting A-C_i curves with the FvCB model. The biochemical parameters were estimated previously by segmenting subjectively and fitting each limitation state separately, whereas now by segmenting objectively and fitting all limitation simultaneously. In comparison to the previously conventional ordinary least squares (OLS), terativgorithms (eg. Genetic Algorithm, Simulated Annealing Algorithm) based on the modern computer technology are now in common use. However, to further improve the reliability and the precision of the parameters estimation, more studies about Rubisco kinetics parameters and their temperature dependence are needed. In the end, to obtain efficient photosynthetic data for biochemical parameters estimation, we integrated and modified methods concerning the measurement of A-C_i curves according to current knowledge about FvCB model fitting. We expect this review would advance our understanding and application of the FvCB model and A-C_i curves.     

四川巴郎山齿果酸模叶片氮素及其分配的海拔响应

在卧龙自然保护区, 按海拔梯度选择了齿果酸模(Rumex dentatus)的4个分布地点(2350、2700、3150和3530 m), 对各研究地点的齿果酸模进行了叶片光合、扩散导度、叶片碳稳定同位素组成(δ¹³C)、氮素含量、光合氮利用效率(PNUE)、比叶面积(SLA))等参数的测量, 以期揭示该植物叶片氮素、氮素分配情况及其他生理生态参数随海拔的响应趋势, 进而明确氮素及其分配在齿果酸模响应和适应海拔梯度环境的生物学过程中的作用。结果表明: 随着海拔的升高, 齿果酸模的叶片单位面积氮含量(N_area)随之增加, 进而光合能力随之增加。随着海拔升高而增加的扩散导度也在一定程度上促进了这一趋势, 这可能是落叶草本植物对于高海拔低温所导致的叶寿命缩短的适应结果。沿着海拔梯度, 植物叶片氮素和扩散导度均通过羧化位点与外界CO₂分压比(P_c/P_a)而间接影响叶片δ¹³C值, 且相比之下, 以氮素为基础的羧化能力对于P_c/P_a的作用更大些, 进而导致齿果酸模叶片δ¹³C随海拔增加; 随着海拔的升高, 齿果酸模叶片将更多的氮素用于防御性结构组织的建设, 这也是SLA和PNUE降低的主要原因; 在光合系统内部, 随着海拔的升高, 植物光合组织增加了用于捕光系统氮素的比例, 使得植物可以更好地利用随海拔升高而增强的光照资源, 进而促进了光合能力的增加。可见, 氮素及其在叶片各系统间(尤其是在光合系统与非光合系统间)的分配方式是齿果酸模适应和响应海拔梯度环境的关键。     

水稻田稗草叶片光合作用对开放式空气CO2浓度增高(FACE)的适应

于分蘖、拔节和抽穗3个时期在空气CO₂浓度(380μmol·mol^-1)下测定稻田中稗草叶片的净光合速率(Pn),发现在开放式CO₂浓度增高(FACE)条件下生长的稗草叶片后2个时期的Pn显著低于普通空气中生长的对照,比对照下降约20%,说明FACE条件下稗草叶片光合作用对高CO₂浓度发生了明显的适应.同时,叶片的气孔导度(Gs)和胞间CO₂浓度(Ci)的下降更为明显.与对照相比,叶片可溶性蛋白含量明显降低,拔节期只有对照的62.4%;高CO₂浓度下生长的稗草叶片Rubisco含量也降低,分蘖期和拔节期分别为对照的87%和84%,但其差异未达到显著水平.可以认为,长期生长在高CO₂浓度下的C₄植物稗草叶片光合作用的适应是叶片气孔部分关闭和可溶性蛋白含量下降的结果.     

大气CO2浓度升高对香蕉光合作用及光合碳循环过程中叶氮分配的影响

生长在高CO₂浓度(700±5μl·L^-1)1周的香蕉叶片,其光合速率(Pn,μmol·m^-2·s^-1)为5.14±0.32,较生长在大气CO₂浓度(356±301μl·L^-1)的高22.1%,而生长在较高CO₂浓度下8周,叶片Pn较生长在大气CO₂浓度的低18.1%,表现香蕉叶片对较长期高CO₂浓度的驯化和光合作用抑制.生长在高CO₂浓度的香蕉叶片有较低光下呼吸速率(R_d),而不包括光下呼吸的CO₂补偿点则变幅较小.最大羧化速率(Vcmax)和电子传递速率(J)分别较生长在大气CO₂浓度的低30.5%和14.8%,根据气体交换速率计算的表观量子产率(α,mol CO₂·mol^-1光量子),生长在较高CO₂浓度下8周的叶片为0.014±0.01,而生长在大气CO₂浓度下的为0.025±0.005.较高CO₂浓度下叶片的表观量子产率降低44%.光能转换效率electrons·quanta^-1)亦从0.203降低至0.136.生长在较高CO₂浓度下香蕉叶片的叶氮在Rubicos分配系数(PR)、叶氮在生物力能学组分分配系数(P_B)和叶氮在光捕组分的分配系数(P_L)均较生长在大气CO₂浓度低,表明在高CO₂浓度下较长期生长(8周)的香蕉叶片多个光合过程受抑制,光合活性明显降低.     

开放式空气CO2浓度升高与作物/杂草的竞争关系

CO₂浓度升高对植物的光合作用、呼吸作用和水分利用等生理过程产生直接影响,进而影响植物的生长和繁殖.CO₂浓度升高对于具有C₃光合途径的植物较具C₄光合途径的植物更为有益.由于许多重要的杂草是C₄植物,而许多重要的作物是C₃植物,CO₂浓度升高对杂草/作物的相互关系将有重要影响.本文就全球CO₂浓度升高和气候变化对杂草/作物之间竞争关系影响进行综述,同时针对目前研究现状和可持续农业的需要,提出CO₂浓度升高条件下杂草/作物之间竞争关系及未来农田杂草治理方面理论与实践中有待解决的问题.     

AtERF49在拟南芥应答盐碱胁迫中的作用

盐碱胁迫是造成作物减产的主要逆境因素之一。植物AP2/ERF（APELATA2/ethylene response factors）转录因子在植物生长发育及其响应非生物逆境胁迫过程中发挥重要作用。探究AtERF49在拟南芥中对盐碱胁迫的应答,为深入解析AtERF49参与植物对盐碱胁迫的分子机理奠定基础。选取拟南芥野生型Col-0、过表达AtERF49转基因拟南芥和CRISPR/Cas9突变体erf49为试验材料,用150 mmol/L混合盐碱（摩尔比NaHCO₃∶Na₂CO₃=9∶1）溶液进行处理,使用荧光定量PCR技术对该基因的基本特性、盐碱胁迫及光合响应基因表达模式等进行分析。结果表明,盐碱胁迫处理后,突变体erf49叶片萎蔫并发生白化,而过表达AtERF49植株叶片稍有变黄。此外,在盐碱胁迫条件下,过量表达AtERF49上调盐碱胁迫响应基因（RD29A和RAB18）以及光合响应基因rbcL的表达。拟南芥叶片叶绿素荧光参数测定结果表明,过表达AtERF49植株的光系统Ⅱ实际量子产能Y（Ⅱ）、光化学淬灭系数（qP）显著高于Col-0,光损伤程度（NO）和非光化学淬灭系数（qN）显著低于Col-0,而突变体erf49与之相反。因此,AtERF49通过调控下游盐碱胁迫响应基因的表达以及植物的光合作用效率,改变参与植物对盐碱胁迫的应答。     

日光温室冬季增施CO2对切花红掌光合作用及生长发育的影响

针对切花红掌日光温室冬季生产时CO₂亏缺严重的现象,以不增施CO₂为对照,研究了增施700、1000、1300 μmol·mol^-1浓度CO₂对切花红掌‘火焰’光合特性和生长发育的影响.结果表明: 增施60 d CO₂,红掌叶片的净光合速率、胞间CO₂浓度和水分利用效率均显著提高,且以1000 μmol·mol^-1处理的增幅最大;而气孔导度则较对照显著下降.增施CO₂后,红掌叶片的可溶性糖、淀粉和可溶性蛋白含量均较对照显著增加,佛焰苞大小、色泽、花茎长度等切花品质参数,以及叶片发育质量参数和花茎生长速率均有不同程度的提高,且均以1000 μmol·mol^-1浓度最佳.增施1000 μmol·mol^-1的CO₂可以有效促进日光温室切花红掌的冬季生产.     

日光温室冬季增施CO2对切花红掌光合作用及生长发育的影响

针对切花红掌日光温室冬季生产时CO₂亏缺严重的现象,以不增施CO₂为对照,研究了增施700、1000、1300 μmol·mol^-1浓度CO₂对切花红掌‘火焰’光合特性和生长发育的影响.结果表明: 增施60 d CO₂,红掌叶片的净光合速率、胞间CO₂浓度和水分利用效率均显著提高,且以1000 μmol·mol^-1处理的增幅最大;而气孔导度则较对照显著下降.增施CO₂后,红掌叶片的可溶性糖、淀粉和可溶性蛋白含量均较对照显著增加,佛焰苞大小、色泽、花茎长度等切花品质参数,以及叶片发育质量参数和花茎生长速率均有不同程度的提高,且均以1000 μmol·mol^-1浓度最佳.增施1000 μmol·mol^-1的CO₂可以有效促进日光温室切花红掌的冬季生产.     

Climatic warming changes plant photosynthesis and its temperature dependence in a temperate steppe of northern China

Warming responses of photosynthesis and its temperature dependence in two C₃ grass (Agropyron cristatum, Stipa krylovii), one C₄ grass (Pennisetum centrasiaticum), and two C₃ forb (Artemisia capillaris, Potentilla acaulis) species in a temperate steppe of northern China were investigated in a field experiment. Experimental warming with infrared heater significantly increased daily mean assimilation rate (A) in P. centrasiaticum and A. capillaris by 30 and 43%, respectively, but had no effects on other three species. Seasonal mean A was 13, 15, and 19% higher in the warmed than control plants for P. centrasiaticum, A. capillaries, and S. krylovii, respectively. The mean assimilation rate in A. cristatum and P. acaulis was not impacted by experimental warming. All the five species showed photosynthetic acclimation to temperature. The optimum temperature for photosynthesis (T_opt) and the assimilation rate at T_opt in the five species increased by 0.33–0.78 °C and 4–27%, respectively, under experimental warming. Elevated temperature tended to increase the maximum rate of ribulose-1,5-bisphosphate (RuBP) carboxylation (V_cmax) and the RuBP regeneration capacity (J_max) in the C₃ plants and carboxylation efficiency and the CO₂-saturated photosynthetic rate in the C₄ plant at higher leaf temperature, as well as the optimum temperatures for the four parameters. Our results indicated that photosynthetic responses to warming were species-specific and that most of the species in the temperate steppe of northern China could acclimate to a warmer environment. The changes in the temperature dependence of V_cmax and J_max, as well as the balance of these two processes altered the temperature dependence of photosynthesis under climatic warming.     

Inorganic carbon uptake kinetics of the stream macrophyte Callitriche cophocarpa Sendt.

Photosynthetic carbon uptake of Callitriche cophocarpa Sendt. was examined in plants collected from six Danish streams and in plants grown under variable inorganic carbon conditions in the laboratory. Both field and laboratory plants showed a low affinity for inorganic carbon (CO₂ compensation points ranging from 0.7 to 22 μM, and K_0.5(CO₂) from 51 to 121 μM), consistent with C-3 photosynthesis and use of CO₂ alone. Variation in inorganic carbon uptake characteristics was low in both groups of plants. Only in laboratory-grown plants was a coupling found between carbon uptake and the inorganic carbon regime of the medium. The carbon extraction capacity, expressed as a percentage of the initial amount of dissolved inorganic carbon (DIC) assimilated in PH-drift experiments, increased from −1.4 to 11.8% with declining external carbon availability, and the initial slope of the CO₂ response curve increased from 6.4 to 15.3 g⁻¹ h⁻¹ dm³. The plasticity of the inorganic carbon uptake system of C. cophocarpa was very low compared to the plasticity observed for submerged macrophytes with accessory carbon uptake systems (i.e. HCO₃⁻ use or C-4 photosynthesis), suggesting that the plasticity of the C-3 photosynthetic apparatus as such is restricted. The low carbon affinity of C. cophocarpa indicates that this species depends on CO₂ oversaturation for a sufficient supply of CO₂ for photosynthesis and growth.     

空气CO2增高条件下荔枝叶片光合作用和超氧自由基产率

研究结果表明,生长在77±5PaCO₂分压下30d的荔枝幼树,其光合速率较大气CO₂分压(39.3Pa)下的低23%,光下线粒体呼吸速率和不包含光下呼吸的CO₂补偿点亦略有降低.空气CO₂增高使叶片最大羧化速率(V_cmax)和最大电子传递速率(J_max)降低,表明大气增高CO₂分压下叶片的光系统I(PSI)能量水平较低,叶片超氧自由基产率亦降低39%,叶片感染荔枝霜疫霉病率则从生长在大气CO₂分压下的1.8%增至9.5%.可能较低光合和呼吸代谢诱致较低的超氧自由基产率,而使叶片易受病害侵染.叶片受病害侵染后表现为超氧自由基的激增.在全球大气CO₂分压增高趋势下须加强对荔枝霜疫霉病的控制.     

水稻叶片光合作用对开放式空气CO2浓度增高(FACE)的响应与适应

利用便携式光合气体分析系统(LI-6400),比较测定了高CO₂浓度(FACE,free-airCO₂enrichment)和普通空气CO₂浓度下生长的水稻叶片的净光合速率、水分利用率、表观量子效率和RuBP羧化效率等光合参数.在各自生长CO₂浓度(380vs580μmol·mol^-1)下测定时,高CO₂浓度(580μmol·mol^-1)下生长的水稻叶片的净光合速率、碳同化的表观量子效率和水分利用率明显高于普通空气(380μmol·mol^-1)下生长的水稻叶片.但是,随着FACE处理时间的延长,高CO₂浓度对净光合速率的促进作用逐渐减小.在相同CO₂浓度下测定时,FACE条件下生长的水稻叶片净光合速率和羧化效率明显比普通空气下生长的对照低.尽管高CO₂浓度下生长的水稻叶片的气孔导度明显低于普通空气中生长的水稻叶片,但两者胞间CO₂浓度差异不显著,因此高CO₂浓度下生长的水稻叶片光合下调似乎不是由气孔导度降低造成的.     

褪黑素对盐碱复合胁迫下黄瓜幼苗光合特性和渗透调节物质含量的影响

为明确外源褪黑素(MT)对黄瓜盐碱胁迫的缓解效应,以‘新春四号’黄瓜为试材,采用复合盐碱(NaCl∶Na₂SO₄∶Na₂CO₃∶NaHCO₃=1∶9∶1∶9)模拟胁迫,测定外源根施MT和盐碱胁迫下黄瓜叶片光合特性和渗透调节物质含量。结果表明: 与正常生长黄瓜幼苗相比,在40 mmol·L^-1盐碱胁迫下,外源施加10 μmol·L^-1 MT能够显著增加黄瓜幼苗叶片的叶绿素、可溶性糖和可溶性蛋白质含量,提高净光合速率、气孔导度、蒸腾速率、光系统Ⅱ最大光化学效率、实际光化学效率、表观光合电子传递速率和光化学淬灭系数,而胞间CO₂浓度、非光化学淬灭系数、蔗糖、果糖、淀粉和脯氨酸含量减小了11.1%、13.8%、12.7%、27.5%、1.3%和32.8%,同时,碳同化关键酶核酮糖-1,5-二磷酸羧化/加氧酶、果糖-1,6-二磷酸酯酶活性显著升高,且Rubisco亚基(CsrbcS和CsrbcL)、CsFBA、CsRCA、CsFBPase、CsTK的mRNA水平均下调表达。综上,外源MT能够提高盐碱胁迫下黄瓜幼苗的叶绿素、渗透调节物质含量、光合化学效率和碳同化关键酶活性,增强幼苗光合能力,减轻复合盐碱胁迫对植株的伤害。研究结果可为抗盐碱栽培提供理论依据。