稀有植物太行花的保护生物学研究

悬崖代表着一个残遗的、较少受到干扰的古生境，悬崖也是生物多样性的避难所。这个特殊生境中分布种类丰富的稀有植物和特有植物，而这些稀有和特有植物又往往以悬崖为唯一的生境，在长期的演化历史进程中形成彼此相互适应的关系。这种分布在特殊生境中的稀有植物为保护研究提出了新的研究方向和问题。本文以蔷薇科的中国特有植物太行花（Taihangia rupestris Yü et Li）为对象，对这个仅分布在有限的地理范围内悬崖上的稀有物种进行了保护生物学的研究。 利用RAPD分子标记技术对太行花8个居群的遗传多样性和遗传结构进行了检测分析。结果表明太行花居群内维持着较高的遗传多样性水平，未显示遭受过严重遗传瓶颈的迹象。同时，居群间遗传分化显著，与居群间的地理距离相关，聚类分析得到的树系图与太行花种下两个变种（太行花原变种Taihangia rupestris var. rupestris和缘毛太行花Taihangia rupestris var. ciliate Yü et Li）的划分相符。 通过栽培实验，研究了太行花对光照和养分的反应，从生态学角度检测植物对环境因子变化的适应能力。结果表明光照处理显著影响太行花的气体交换参数，且显示出随季节不同而变化的趋势。在8月第一次测量时，光合速率随着光照水平的增加而增加;而在9月底第二次测量时，高光下植株的光合速率反低于中光条件下的植株。光合光反应曲线表明太行花对不同光照水平（高光、中光和低光）均显示出一定的光合适应性。 光照对太行花的生长反应、形态、解剖等指标均具有显著的作用。在收获时，高光下植物形成小而厚的叶片，更快的叶片形成速率足以弥补单叶面积上光合速率的下降，使植株维持最大的总生物量。中光条件下的植株具有更长的叶柄，更大的叶面积，大而薄的叶片，和更大的叶面积比，被认为是对较弱光照环境适应的表现。而光照对叶片的气孔指标（气孔密度、气孔指数和大小）没有作用，养分施加对太行花的影响也甚微。总体来说，太行花显示出对光照变化的生理适应性和形态可塑性，光照和养分这两个环境条件均非影响太行花局限分布的关键因素。 同时，我们采用扫描电镜手段跟踪观察了太行花的花的早期发育过程。太行花早期发育过程中苞片内残留的退化花痕迹表明，太行花的顶生单花其实是有限聚伞花序中其它花芽败育的结果，显示出从花序向单花演化的趋势。同时，雌蕊的发育在早期是正常的，未显示出退化痕迹。 根据以上结果表明，局限分布在特殊生境上的太行花并未显示出生理适应幅度的狭窄性和遗传多样性水平的降低，因此，太行花在长期的进化过程中形成了对特殊生境——悬崖的适应性，遗传衰退和缺乏适应性不是稀有植物太行花局限分布的原因。在对太行花的保护中应进一步加强对其生境的保护，并在进行迁地保护和回归引种时应兼顾不同变种和地理分布的居群，以实现对其遗传完整性的有效保护。

水稻对大气二氧化碳浓度及温度升高的光合适应的研究

基于长期观测资料，众多大气环流模型预测在二十一世纪末大气中二氧化碳浓度将达到700μmolmol'I，地球表面年平均温度也将升高1.5-4.OoC。水稻是亚洲的主要粮食作物，为世界近三分之一的人口提供食物能源。这项工作的目的，是利用人工模拟环境，预测在未来全球气候变化，二氧化碳及温度升高的条件下，水稻的光合生理反应及随之而来的对其产量的影响。本研究是美国环境署( EPA)与国际水稻研究所(IRRI)合作研究项目“Effects of UV-B and Global Climate Change on Rice”的一部分． 在这项研究中，采用了特殊设计并直接建立在水稻田间的开顶式气室（open-top chambers）。在此之前还没有这样大规模的在水稻主产区的此类模拟研究，水稻在气室中渡过了从萌发到收获的整个生长过程。模拟环境条件有三个浓度的二氧化碳（包括现有大气浓度，在此基础上升高200及300 μmolmol-l）和两个温度（即：现有大气温度及升高4度）共六个处理。供试水稻品种四个：IR72，IR65598-112-2，IR65600-42-5-2-BSI-313和N22。在实验中我们发现，水稻品种（如：1R72）单叶光合速率（以二氧化碳气体交换速率计）受二氧化碳浓度促进，在水稻营养生长期，二氧化碳及温度对其光合有协同促进作用．然而，随着花期的到来，在高温条件下，叶片光合能力（photosynthetic capacity）下降，出现光合适应现象（Photosynthetic acclirnation）.水稻群体光合作用同样受到二氧化碳浓度促进，但在后期(Grain fill stage)这种促进作用消失;在高浓度二氧化碳下生长的大多数水稻品种的叶片中有较多的碳水化和物（可溶性糖和淀粉）积累．耐高温品种N22叶片中淀粉积累较少：叶片中氮素含量降低，同时发现Rubisco总活性相应降低，这与NCi曲线所示光合效率降低相吻合;通过叶片叶绿素荧光动力学测定，没有发现光系统光能转化效率的变化;水稻籽粒产量随二氧化碳浓度升高而增加，但温度升高使产量降低12.8-36.8%;不同品种对二氧化碳浓度的反应没有显著差别;在高温条件下，耐高温品生长在高二氧化碳浓度下表现良好。 本文系统地研究了水稻光合作用在二氧化碳及温度条件影响下，对二氧化碳浓度及光强变化的反应曲线，初次对水稻单叶与群体光合对二氧化碳浓度变化的反应做了实验性对比;讨论了温度升高对水稻在高浓度二氧化碳下发生光合适应的影响，对光合适应现象的可能机制做了探讨，并提出对未来大气二氧化碳浓度及温度升高条件下水稻适应品种筛选的可能方向。

Light histories influence the impacts of solar ultraviolet radiation on photosynthesis and growth in a marine diatom, Skeletonema costatum

Phytoplanktonic species acclimated to high light are known to show less photoinhibition. However, little has been documented on how cells grown under indoor conditions for decades without exposure to UV radiation (UVR, 280-400 nm) would respond differently to solar UVR compared to those in situ grown under natural solar radiation. Here, we have shown the comparative photosynthetic and growth responses to solar UVR in an indoor-(IS) and a naturally grown (WS) Skeletonema costatum type. In short-term experiment (<1 day), phi(PSII) and photosynthetic carbon fixation rate were more inhibited by UVR in the IS than in the WS cells. The rate of UVR-induced damages of PSII was faster and their repair was significantly slower in IS than in WS. Even under changing solar radiation simulated for vertical mixing, solar UVR-induced higher inhibition of photosynthetic rate in IS than in WS cells. During long-term (10 days) exposures to solar radiation, the specific growth rate was much lower in IS than WS at the beginning, then increased 3 days later to reach an equivalent level as that of WS. UVR-induced inhibition of photosynthetic carbon fixation in the IS was identical with that of WS at the end of the long-term exposure. The photosynthetic acclimation was not accompanied with increased contents of UV-absorbing compounds, indicating that repair processes for UVR-induced damages must have been accelerated or upgraded. (C) 2008 Elsevier B.V. All rights reserved.

CO2浓度升高对红桦幼苗生理与生长的影响

大气CO2浓度的增加已经成为不可争议的事实。预计本世纪末大气CO2浓度将增加到约700µmol mol-1。森林年光合产量约占陆地生态系统年光合产量的70%。森林树木是一个巨大的生物碳库，约占全球陆地生物碳库的85%。森林树木对CO2的固定潜力是缓解由大气CO2浓度升高引起的未来全球气候变化问题的决定性因子之一。红桦（Betula albosinensis Burk.）是川西亚高山采伐迹地自然或人工恢复的重要树种。本研究以1a红桦幼苗为模式植物，采用人工模拟的方法，研究CO2浓度升高对不同种内竞争强度（种群水平）下红桦幼苗的生理特征、生长、干物质积累及其分配的影响，探讨在种内竞争生长条件下红桦幼苗的“光合适应机理”与生长特征，为西南亚高山森林生产力对未来全球变化的预测提供重要参考。 本研究的主要结果如下： 1）在种内竞争生长条件下红桦幼苗经过CO2浓度升高熏蒸4个月后，叶片出现“光合适应”现象。与对照相比，低种植密度（28株m-2）和高种植密度（84株m-2）条件下的红桦幼苗净光合速率（A）、气孔导度（gs）、蒸腾速率（E）、表观量子产量（AQY）和羧化速率（CE）显著降低，而水分利用效率（WUE）则显著提高。CO2浓度升高处理的红桦幼苗叶片Rubisco活性、单位叶面积N浓度、叶绿素a、叶绿素b和类胡萝卜素浓度都显著降低。但CO2浓度对红桦幼苗的叶绿素a与叶绿素b的比值没有显著影响。CO2浓度升高显著增加红桦幼苗单位叶面积的非结构性碳水化合物（TNC）浓度，结果是红桦幼苗的比叶面积（SLA，cm2 g-1）显著降低。 2）与对照相比，CO2浓度升高处理的红桦幼苗高、基径、单叶面积和侧枝的相对生长速率（R GR）显著提高，尤其在试验处理的早期。CO2浓度升高既增加单株红桦幼苗总叶片数量又增加单叶面积，结果是单株红桦幼苗的总叶面积比对照显著增加。 3）CO2浓度升高处理显著增加红桦幼苗干物质积累（尤其是细根生物量），改变了红桦幼苗生物量的分配格局。与对照相比，CO2浓度升高处理的红桦幼苗叶重比（LWR）、叶面积比（LAR）、叶根重比（Wl/Wr）和源汇重比（leaf weight to non-leaf weight ratio, Wsource/Wsink）显著下降（高种植密度的LWR除外），而根冠比（R/S）则显著增加。在两种种植密度条件下，CO2浓度升高显著增加红桦幼苗根生物量的分配比率，显著降低叶片的生物量分配比率，对主茎、侧枝以及地上生物量的分配比率不变或约有下降。 总之，长期生长在CO2浓度升高条件下的红桦幼苗光合能力下降，并伴随Rubisco活性、叶N浓度、光合色素浓度的显著降低以及TNC浓度的显著增加。支持树木光合速率下降与Rubisco活性、叶N浓度下降以及TNC浓度增加紧密相关的假设。CO2浓度升高处理红桦幼苗的早期相对生长速率大大高于对照，而后期迅速下降，说明红桦幼苗生物量的显著增加主要归功于CO2浓度升高的早期促进作用和叶面积的显著增加。CO2浓度升高显著增加红桦幼苗根系生物量和根冠比，表明红桦幼苗“额外”固定的C向根系转移。 The steady increae of atmospheric CO2 concentration（[CO2]）has been inevitable fact. Models predict that the atmospheric [CO2] will increase to about 700µmol mol-1 at the end of the twenty-first century. As trees constitute a majoor carbon reservoir–85% of total plant carbon is found in forest, and their ability to sequester carbon is a key determinant of future global change problems caused by increases in atmospheric CO2. In addition to the role of forests in the global carbon cycle, inceased growth could be of economic benefit, for example, offsetting deleterious effects of climatic changes. Betula albosinensis (Burk.) usually emerges as the pioneer species in initial stage and as constructive species in later stages of forest community succession of mountain forest area, and also is one of important tree species for afforestation in logged area, in southwesten China. In this experinment, Betula albosinensis seedling (one-year-old) was used as the model plant. B. albosinensis seedlings were grown under two all-day [CO2], ambient (about 350 µmol·mol-1) and elevated [CO2] (about 700 µmol·mol-1), and two planting densities of 28 plants per m2 and 84 plants per m2. The objectives were to characterize birch mature leaf photosynthesis, growth, mass accumulation and allocation responses to long-tern elevated growth [CO2] under the influences of neighbouring plants, and to assess whether elevated [CO2] regulated birch mature leaf photosynthetic capacity, in terms of leaf nitrogen concentration (leaf [N]), activity of ribulose bisphosphate carboxygenase (Rubisco), Rubisco photosynthetic efficiency, and total nonstructural carbohydrates (TNC) concentration, and also to provide a strong reference to predict the productivity of subalpine forests under the future global changes. The results are as follows: 1) B.albosinensis seedlings exposed to elevated [CO2] for 120 days, photosynthetic acclimation phenomena occurred. At two planting densities, leaves of birch seedlings grown under elevated [CO2] had lower net photosynthetic rate (A), stomatal conductance (gs), transpiration (E), apparent quantum yield (AQY) and carboxylated efficiency (CE) and higher water use efficiency (WUE), compared to those of B.albosinensis seedlings grown under ambient [CO2]. Based on the leaf area, leaf [N], Rubisco activity and photosynthetic pigments concentrations of B. albosinensis seedlings grown under elevated [CO2] were significantly lower than those grown under ambient [CO2]. The ratio of chlorophyll a to chlorophyll b concentration was not affected by elevated [CO2]. Under elevated [CO2], the TNC concentration per unit leaf area significantly increased, resulting in significant decrease in specific leaf area. Thus leaf photosynthetic capacity of B. albosinensis seedlings would perform worse under rising atmospheric [CO2] and the influences of neighbouring plants. 2) Under elevated [CO2], the relative growth rate (RGR) of B. albosinensis seedlings height, basal diameter, a leaf area and branch length significantly increased, especially at the initial stage of exposure to elevated [CO2], and a leaf area and leaf numbers per B. albosinensis seedling also significantly increased. Thus the total leaf area per B. albosinensis seedling was significantly increased under elevated [CO2]. 3) As the increase of RGR and total leaf area, biomass of B. albosinensis seedling grown elevated [CO2] was higher, compared to that of B.albosinensis seedlings grown at ambient [CO2]. Elevated [CO2] changed the biomass allocation pattern of B. albosinensis seedling. At two planting densities, B. albosinensis seedlings grown elevated [CO2] had lower leaf weight to total weight ratio (LWR), leaf area to total weight ratio (LAR) and leaf weight to non-leaf weight ratio (Wsource/Wsink), but higher root weight to shoot weight ratio (R/S), compared to those of B.albosinensis seedlings grown at ambient [CO2]. Under elevated [CO2], roots biomass to total biomass ratio was signigicantly increased, leaves biomass to total biomass ratio was significantly decreased. The main stem and branch biomass to total biomass ratio were not affected by elevated [CO2]. In conclusion, our results supported the hypothesis that the decline in photosynthetic capacity of C3 plants will appear after long-term exposure to elevated [CO2], accompanying with the significant decrease in Rubisco activity, leaf N concentration, photosynthetic pigments concentration, and significant increase in total non-structural carbohydrates concentration. Our results also have shown that the increase of biomass of B. albosinensis seedlings should be attributed to initial stimulation on RGR and total leaf area resulted from elevated [CO2]. Under elevated [CO2], the extra carbon sequestered by B.albosinensis seedlings transferred into under-ground part because of increase in root biomass and R/S.