光合作用-蒸腾作用-气孔导度的耦合模型及C_3植物叶片对环境因子的生理响应(英文)

以叶片的气体传输过程为基础,将蒸腾作用包括在以往光合作用气孔导度的耦合模型中,建立了光合作用蒸腾作用气孔导度的耦合模型。该模型可以模拟边界层导度对生理过程的影响。模拟了Ｃ３植物叶片对环境因子,如光照、温度、湿度、边界层导度和ＣＯ２浓度等的生理响应（光合作用、蒸腾作用、气孔导度）以及Ｃｉ和水分利用效率的变化。在环境因子变化于较大范围的情况下,模拟结果符合许多实验结论。     

光合作用—蒸腾作用—气孔导度的耦合模型及C3植物叶片对环境因子的生理 …

以叶片的气体传输过程为基础,将蒸腾作用包括在以往光合作用－气孔导度的耦合模型中,建立了光合作用－蒸腾作用－气孔导度的耦合模型。该模型可以模拟边界层导度对生理过程的影响。模拟了Ｃ３植物叶片对环境因子,如光照、温度、湿度、边界层导度和ＣＯ２浓度等的生理响应（光合作用、蒸腾作用、气孔导度）以及Ｃｉ和水分利用效率的变化。在环境因子变化于较大范围的情况下,模拟结果符合许多实验结论。     

基于FvCB模型的叶片光合生理对环境因子的响应研究进展

为提高叶片光合速率并更好地理解叶片光合生理对环境因子变化的响应机制,FvCB模型(C_3植物光合生化模型)常用于分析不同环境条件下CO_2响应曲线并预测叶片活体内光合系统的内在变化状况。系统介绍了FvCB模型的建立、发展过程和拟合方法等基本理论,综述了该模型在叶片光合生理对光、CO_2、水、温度和N营养等环境因子变化的响应机制中的应用研究。为进一步完善FvCB模型并更好地理解叶片活体内光合系统对环境因子变化的响应机制,未来拟加强以下研究:1)羧化速率与光合电子传递速率之间的联系;2)叶肉导度的具体组分及其对FvCB模型参数估计的影响;3)叶片气孔导度和叶肉导度对环境因子变化的调控机制。     

植物生长和生理生态特点在海拔梯度上的表现

植物生长离不开自然环境,每一种环境中都存在其独有的植物类型。随着世界气候的改变,海拔较高的地区环境发生了一定的变化,致使生长的植物生理生态特征特点发生一定改变。本研究通过对海拔梯度上植物生长与生理生态特点的深入了解,从其环境因子变化、植物生态特点、生理特征等方面展开研究,分析其不同因子的差异对植物相关生理特征的作用,以为相关领域研究提供参考和借鉴。     

植物非结构性贮藏碳水化合物的生理生态学研究进展

非结构性碳水化合物是参与植物生命过程的重要物质。蔗糖不仅是植物体内碳水化合物运输的主要形式,而且可以在基因表达水平上对细胞内的代谢进行调节。果聚糖是植物营养组织碳水化合物的主要暂贮形式;淀粉是植物主要的长期贮藏物质之一。植物体内非结构性碳水化合物的代谢在很大程度上影响着植株的生长发育和对环境因子的响应。综述了植物非结构性贮藏碳水化合物的生理生态学研究进展,着重介绍了蔗糖、果聚糖和淀粉代谢的生理过程及对环境因子(温度和水分)和人为因素的响应机制。     

植物质膜H+-ATPase的研究进展

质膜H -ATPase参与植物细胞的物质跨膜转运、细胞的伸长生长、气孔的开闭以及植物对环境胁迫的响应等生理过程,是植物生命活动的“主宰酶”。其活性调节涉及激素、环境因子等多种因素,可发生在转录、翻译和酶分子等多级水平。因此,在植物生长发育过程中,质膜H -ATPase活性的调节对生理活动起重要作用。本文就植物质膜H -ATPase的结构特征、生理功能、活性变化及其调节机理等的研究进展进行综述,以进一步揭示该酶的生理功能及其调节机理与植物生命活动过程的关系。     

植物蜡质及其与环境的关系

陆生植物的地上部分如叶、茎、花、果实等的表面覆盖着一层蜡质,它是由一系列复杂化合物组成的具有三维微结构的疏水层,在植物生长和发育过程中起着不可或缺的作用,具有很好的生物学功能。作为植物与环境的第一接触面,蜡质对外界环境因子的响应较敏感,当植物受到外界不利环境因子胁迫时,蜡质会改变自身晶体结构形态或化学组分构建防御机制以减少胁迫因子的作用,有效地协调植物与环境的关系。综述了近年来国内外关于植物蜡质的研究进展,在阐述蜡质层结构及其化学组分的基础上,着重介绍植物与环境因子的作用,包括非生物环境因子如水分、温度、光照、环境污染等以及植食性昆虫和病原菌等生物环境因子的作用。研究显示,胁迫环境下植物蜡质化学组分的变化,是由于不利环境因子的作用足以改变蜡质各产物的合成途径,从而影响蜡质产物。植物蜡质利用各种生理、化学机制对胁迫环境因子的适应以及响应,是植物适应各种生境的基础,因此通过对植物蜡质与环境关系的研究为进一步解析植物与环境关系提供证据。     

植物非结构性贮藏碳水化合物的生理生态学研究进展

非结构性碳水化合物是参与植物生命过程的重要物质。蔗糖不仅是植物体内碳水化合物运输的主要形式,而且可以在基因表达水平上对细胞内的代谢进行调节。果聚糖是植物营养组织碳水化合物的主要暂贮形式;淀粉是植物主要的长期贮存物质之一。植物体内非结构性碳水化合物的代谢在很大程度上影响着植株的生长发育和对环境因子的响应。综述了植物非结构性贮藏碳水化合物的生理生态学研究进展,着重介绍了蔗糖,果聚糖和淀粉代谢的生理过程及对环境因子（温度和水分）和人为因素的响应机制。     

植物干旱胁迫响应机制研究进展——从表型到分子

干旱胁迫是抑制植物生长发育的主要限制因子之一,植物为适应干旱的外界环境,会依据自身的习性启动响应机制。从植物外部形态、生理代谢、生化过程、细胞及分子水平的变化阐述了植物对干旱胁迫的响应机制,详细阐述了生理及分子水平的响应机制,并对分子和遗传水平的响应机制和植物抗旱性关系的未来研究方向提出了展望,以期为植物抗逆性及遗传育种研究提供参考。     

城市地表硬化对植物生理生态的影响研究进展

城市地表硬化是城市发展和扩张的主要表征之一,也是影响城市生态环境及植物生理生态的重要原因。在分析城市地表硬化引起植物生态因子变化的基础上,重点综述了地表硬化对植物气体交换、水分平衡、养分循环等生理生态过程的影响,归纳了不同地表硬化性质、气候季节变化、植物类型以及群落结构等因素对地表硬化景观植物生理生态影响的差异。探讨了目前该领域研究中存在的问题,并提出今后研究建议,以期为优化城市生态用地结构,提高城市植物的生态系统服务,改善城市和人居环境提供一定的科学依据。     

土壤水分与冬小麦根、冠功能均衡关系的模拟研究

利用已建立并经充分验证过的根,冠系统模拟模型,研究了不同土壤水分条件下根、冠之间消长关系,给出了不同１ｍ土体贮水量波动情况下根冠比动态变化模拟结果,并提供了有关试验数据作为佐证,其中有些结论为常规试验不易得到的全新认识,有些结果支持并证实了以往有关结论,均为水分对作物生长实施调控提供了重要依据。     

Shoot/root balance of plants: Optimal growth of a system with many vegetative organs

The optimal growth schedule of a plant with two vegetative parts is studied to investigate the balance between shoot and root. An intuitive justification of optimization procedures used in Pontryagin's maximum principle is obtained by defining the marginal values of shoot size, root size, and reproductive activity at various times of the season and deriving their differential equations and terminal conditions. The optimal growth pattern which maximizes the total reproductive activity during the season is composed of the convergence of a plant's shape to a balanced growth path, followed by simultaneous growth of shoot and root (balanced growth), ending with the reproductive growth. Along the balanced growth path, a plant has a root/shoot ratio which maximizes the daily net photosynthesis for a given total biomass. The model also shows a simultaneous stop of shoot and root growth when the reproduction begins, the dependence of root/shoot ratio on age, water and light availability, etc., the convergence of a plant's shape to the balanced growth after pruning or an environmental change.     

Plant biomass partitioning and chemical defense: Response to defoliation and nitrate limitation

Summary Plant growth and allocation to root, shoot and carbon-based leaf chemical defense were measured in response to defoliation and nitrate limitation inHeterotheca subaxillaris. Field and greenhouse experiments demonstrated that, following defoliation, increased allocation to the shoot results in an equal root/shoot ratio between moderately defoliated (9% shoot mass removed) and non-defoliated plants. High defoliation (28% shoot mass or >25% leaf area removed) resulted in greater proportional shoot growth, reducing the root/shot ratio relative to moderate or non-defoliated plants. However, this latter effect was dependent on nutritional status. Despite the change in distribution of biomass, defoliation and nitrate limitation slowed the growth and development ofH. subaxillaris. Chronic defoliation decreased the growth of nitrate-rich plants more than that of nitrate-limited plants. The concentration of leaf mono- and sesqui-terpenes increased with nitrate-limitation and increasing defoliation. Nutrient stress resulting from reduced allocation to root growth with defoliation may explain the greater allocation to carbon-based leaf defenses, as well as the defoliation-related greater growth reduction of nitrate-rich plants.     

A Model of the Partitioning of Growth between the Shoots and Roots of Vegetative Plants

A model of the partitioning of new growth between the shootsand roots of vegetative plants is presented. There are two partitioningfunctions, involving one partitioning parameter, which describethe priorities for new growth in both the shoots and roots.The dynamic responses, to changes in the environment and toshoot defoliation, of shoot and root specific growth rates,shoot: root ratio, and carbon and nitrogen substrate levels,are examined; realistic behaviour is observed. Balanced exponentialgrowth solutions are also examined and it is concluded thatrelationships between some derived plant growth quantities maybe non-unique, thus emphasizing the need for a critical understandingof the underlying physiological processes involved in plantgrowth. Mathematical model, partitioning of assimilates, shoot: root ratio, specific growth rate, carbon and nitrogen substrate levels     

Simulation of Rhythmic Tree Growth under Constant Conditions

The observed rhythmic growth of trees under relatively uniform environmental conditions has been ascribed by some authors to endogenous factors, by others to slight fluctuations of environmental factors. A model for the simulation of rhythmic growth was developed based on the assumption that endogenous rhythms can result from feedback interaction between two potentially continuous processes, like shoot and root growth, if the slower process is rate limiting for the faster one. Rhythmic growth in trees would be the consequence of feedback mechanisms needed for maintaining a constant shoot: root ratio. Period length of the rhythms depends upon the rates of the growth processes involved. Environmental factors modify period length through affecting growth rates. Growth patterns predicted by the model compare well with growth measurements of tropical trees. The transition from intermittent to continuous growth, as observed under certain conditions, can be simulated by varying a single parameter in the model.     

Vegetative phase change in Metrosideros: Shoot and root restriction

Plants of Metrosideros excelsa Sol. ex Gaertn. Scarlet Pimpernel, which had undergone reversal of ontogenetic ageing (rejuvenation) following micropropagation, were subjected to shoot and root restriction treatments over 35 weeks to accelerate vegetative phase change. Shoot restriction was imposed by removal of axillary branches, while control plants were allowed to branch. Root restriction, imposed by growing plants in a range of container sizes, was applied in factorial combination with shoot restriction. Image analysis techniques were used to measure changes in leaf dimensional (roundness, area, length, width, length/width ratio and perimeter) and optical (hue, saturation and lightness) properties which change gradually between juvenile and mature forms of Metrosideros excelsa. Leaves of single-stemmed plants became progressively mature with increasing node position, and developed the downy tomentum on the abaxial surface characteristic of mature leaves. In general, leaves on the branched plants did not become progressively mature with increasing node position. The acceleration in vegetative phase change in single-stemmed plants was not due to a greater number of nodes produced along the main axis, nor because of a greater distance from root to shoot apex. Root restriction reduced root growth in branched plants, and increased shoot/root dry weight ratio in both sets of plants. However, it did not affect shoot growth, nor did it accelerate vegetative phase change.     

A Model of Shoot: Root Partitioning with Optimal Growth

A shoot: root partitioning model is presented, which is a developmentof previous approaches in the area. The model incorporates asa physiologically reasonable apparent ‘goal’ forthe plant, the assumption that the partitioning of growth betweenthe shoot and root maximizes the plant specific growth ratein balanced exponential growth. The analysis is concerned principallywith plant growth being a function of carbon and nitrogen only,although it is indicated how other nutrients, or growth factors,may be incorporated. Plant growth is driven by the environmentalconditions, and partitioning is defined entirely in terms ofthe shoot: root ratio and carbon and nitrogen status of theplant. In its basic form the model requires the definition ofa single plant growth parameter, along with the shoot and rootspecific activities and structural composition. Shoot: root partitioning, specific growth rate, vegetative phase     

不同磷浓度对玉米生长及磷、锌吸收的影响

在不同磷水平(0.1、1.0、5.0、10和100μmol·L^-1P)的水培液中培养玉米苗,测定不同培养时期玉米的生长和玉米植株对P、Zn吸收和利用效率.结果表明,玉米在100μmol·L^-1P的溶液中生长速率最大,而根冠比在0.1μmol·L^-1P的溶液中为最大.随着水培液中P水平的增加,植株对P的吸收速率增加,而利用效率降低;玉米根系含Zn量增加,而冠层含Zn量变化不大,说明增P使Zn在根内富集,Zn向冠层转移速率较小,玉米幼苗根系中P和Zn的浓度呈正相关关系.     

水氮添加条件下高寒草甸主要植物种氮素吸收分配的同位素示踪研究

资源利用方式的分化可以减小物种间对相同资源的竞争,是群落物种多样性维持的主要机制。在全球变化背景下,土壤温度和水分条件的变化可能影响高寒草甸生态系统植物的氮素(N)营养。该实验在经N、水处理3年的高寒草甸开展,通过15NH415NO3的15N稳定性同位素注射,比较高寒草甸主要植物种对N、水处理的响应方式,以及N吸收能力、分配和根冠比特点,研究其营养吸收和资源分配方式的分化。结果发现不同植物种对N、水处理响应差异显著,N吸收能力、根N含量和根冠比等功能性状种间差异显著;回归分析发现植物种N吸收能力和根N含量之间的关系不显著,和根冠比之间呈显著线性负相关。说明高寒草甸生态系统不同植物种间N吸收具有生态位分化,并且存在N营养吸收能力和资源分配策略的权衡。     

Dissecting the effects of nitrate, sucrose and osmotic potential on Arabidopsis root and shoot system growth in laboratory assays

Studying the specific effects of water and nutrients on plant development is difficult because changes in a single component can often trigger multiple response pathways. Such confounding issues are prevalent in commonly used laboratory assays. For example, increasing the nitrate concentration in growth media alters both nitrate availability and osmotic potential. In addition, it was recently shown that a change in the osmotic potential of media alters the plant's ability to take up other nutrients such as sucrose. It can also be difficult to identify the initial target tissue of a particular environmental cue because there are correlated changes in development of many organs. These growth changes may be coordinately regulated, or changes in development of one organ may trigger changes in development of another organ as a secondary effect. All these complexities make analyses of plant responses to environmental factors difficult to interpret. Here, we review the literature on the effects of nitrate, sucrose and water availability on root system growth and discuss the mechanisms underlying these effects. We then present experiments that examine the impact of nitrate, sucrose and water on root and shoot system growth in culture using an approach that holds all variables constant except the one under analysis. We found that while all three factors also alter root system size, changes in sucrose and osmotic potential also altered shoot system size. In contrast, we found that, when osmotic effects are controlled, nitrate specifically inhibits root system growth while having no effect on shoot system growth. This effectively decreases the root : shoot ratio. Alterations in root : shoot ratio have been widely observed in response to nitrogen starvation, where root growth is selectively increased, but the present results suggest that alterations in this ratio can be triggered across a wide spectrum of nitrate concentrations.