925 resultados para plant functional types
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Several studies have shown that submerged macrophytes provide a refuge for zooplankton against fish predation, whereas the role of emergent and floating-leaved species, which are often dominant in eutrophic turbid lakes, is far less investigated. Zooplankton density in open water and amongst emergent and floating-leaved vegetation was monitored in a small, eutrophic lake (Frederiksborg Slotsso) in Denmark during July-October 2006. Emergent and floating-leaved macrophytes harboured significantly higher densities of pelagic as well as plant-associated zooplankton species, compared to the open water, even during periods where the predation pressure was presumably high (during the recruitment of 0+ fish fry). Zooplankton abundance in open water and among vegetation exhibited low values in July and peaked in August. Bosmina and Ceriodaphnia dominated the zooplankton community in the littoral vegetated areas (up to 4,400 ind/l among Phragmites australis and 11,000 ind/l between Polygonum amphibium stands), whereas the dominant species in the pelagic were Daphnia (up to 67 ind/l) and Cyclops (41 ind/l). The zooplankton density pattern observed was probably a consequence of concomitant modifications in the predation pressure, refuge availability and concentration of cyanobacteria in the lake. It is suggested that emergent and floating-leaved macrophytes may play an important role in enhancing water clarity due to increased grazing pressure by zooplankton migrating into the plant stands. As a consequence, especially in turbid lakes, the ecological role of these functional types of vegetation, and not merely that of submerged macrophyte species, should be taken into consideration.
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Despite striking differences in climate, soils, and evolutionary history among diverse biomes ranging from tropical and temperate forests to alpine tundra and desert, we found similar interspecific relationships among leaf structure and function and plant growth in all biomes. Our results thus demonstrate convergent evolution and global generality in plant functioning, despite the enormous diversity of plant species and biomes. For 280 plant species from two global data sets, we found that potential carbon gain (photosynthesis) and carbon loss (respiration) increase in similar proportion with decreasing leaf life-span, increasing leaf nitrogen concentration, and increasing leaf surface area-to-mass ratio. Productivity of individual plants and of leaves in vegetation canopies also changes in constant proportion to leaf life-span and surface area-to-mass ratio. These global plant functional relationships have significant implications for global scale modeling of vegetation–atmosphere CO2 exchange.
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Patch formation is common in grazed grasslands but the mechanisms involved in the formation and maintenance of patches are not clear. To increase our knowledge on this subject we examined possible reasons for patch formation and the influence of management on changes between patch states in three experiments in native pasture communities in the Crows Nest district, south-east Queensland. In these communities, small-scale patches (tall grassland (dominated by large and medium tussock grasses), short swards (dominated by short tussock grasses and sedges), and lawns (dominated by stoloniferous and/or rhizomatous grasses)) are readily apparent. We hypothesized that the formation of short sward and lawn patches in areas of tall grassland was due to combinations of grazing and soil fertility effects. This was tested in Experiment 1 by applying a factorial combination of defoliation, nutrient application and transplants of short tussock and stoloniferous species to a uniform area of tall grassland. Total species density declined during the experiment, was lower with high nutrient applications, but was not affected by defoliation. There were significant changes in abundance of species that provided support for our hypotheses. With light defoliation and low nutrients, the tall grassland remained dominated by large tussock grasses and contained considerable amounts of forbs. With heavy defoliation, the pastures were dominated by medium tussock grasses and there were significant decreases in forbs and increases in sedges (mainly with low nutrients) and stoloniferous grasses (mainly with high nutrients). Total germinable seed densities and those of most species groups were significantly lower in the heavy defoliation than the light defoliation plots. Total soil seed numbers were not affected by nutrient application but there were fewer seeds of the erect forbs and more sedge seeds in plots with high nutrients. The use of resting from grazing and fire to manage transitions between patches was tested. In Experiment 2, changes in species density and abundance were measured for 5 years in the three patch types with and without grazing. Experiment 3 examined the effects of fire, grazing and resting on short sward patches over 4 years. In Experiment 2, total species density was lower in lawn than short sward or tall grassland patches, and there were more species of erect forbs than other plant groups in all patch types. The lawn patches were originally dominated by Cynodon spp. This dominance continued with grazing but in ungrazed patches the abundance of Cynodon spp. declined and that of forbs increased. In the short sward patches, dominance of short tussock grasses continued with grazing but in ungrazed plots their abundance declined while that of large tussock grasses increased. The tall grassland patches remained dominated by large and medium tussock species. In Experiment 3, fire had no effect on species abundance. On the grazed plots the short tussock grasses remained dominant but where the plots were rested from grazing the small tussock grasses declined and the large tussock grasses increased in abundance. The slow and relatively small changes in these experiments over 4 or 5 years showed how stable the composition of these pastures is, and that rapid changes between patch types are unlikely.
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There is a proliferation of categorization schemes in the scientific literature that have mostly been developed from psychologists’ understanding of the nature of linguistic interactions. This has a led to problems in defining question types used by interviewers. Based on the principle that the overarching purpose of an interview is to elicit information and that questions can function both as actions in their own right and as vehicles for other actions, a Conversational Analysis approach was used to analyse a small number of police interviews. The analysis produced a different categorization of question types and, in particular, the conversational turns fell into two functional types: (i) Topic Initiation Questions and (ii) Topic Facilitation Questions. We argue that forensic interviewing requires a switch of focus from the ‘words’ used by interviewers in question types to the ‘function’ of conversational turns within interviews.
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All organisms live in complex habitats that shape the course of their evolution by altering the phenotype expressed by a given genotype (a phenomenon known as phenotypic plasticity) and simultaneously by determining the evolutionary fitness of that phenotype. In some cases, phenotypic evolution may alter the environment experienced by future generations. This dissertation describes how genetic and environmental variation act synergistically to affect the evolution of glucosinolate defensive chemistry and flowering time in Boechera stricta, a wild perennial herb. I focus particularly on plant-associated microbes as a part of the plant’s environment that may alter trait evolution and in turn be affected by the evolution of those traits. In the first chapter I measure glucosinolate production and reproductive fitness of over 1,500 plants grown in common gardens in four diverse natural habitats, to describe how patterns of plasticity and natural selection intersect and may influence glucosinolate evolution. I detected extensive genetic variation for glucosinolate plasticity and determined that plasticity may aid colonization of new habitats by moving phenotypes in the same direction as natural selection. In the second chapter I conduct a greenhouse experiment to test whether naturally-occurring soil microbial communities contributed to the differences in phenotype and selection that I observed in the field experiment. I found that soil microbes cause plasticity of flowering time but not glucosinolate production, and that they may contribute to natural selection on both traits; thus, non-pathogenic plant-associated microbes are an environmental feature that could shape plant evolution. In the third chapter, I combine a multi-year, multi-habitat field experiment with high-throughput amplicon sequencing to determine whether B. stricta-associated microbial communities are shaped by plant genetic variation. I found that plant genotype predicts the diversity and composition of leaf-dwelling bacterial communities, but not root-associated bacterial communities. Furthermore, patterns of host genetic control over associated bacteria were largely site-dependent, indicating an important role for genotype-by-environment interactions in microbiome assembly. Together, my results suggest that soil microbes influence the evolution of plant functional traits and, because they are sensitive to plant genetic variation, this trait evolution may alter the microbial neighborhood of future B. stricta generations. Complex patterns of plasticity, selection, and symbiosis in natural habitats may impact the evolution of glucosinolate profiles in Boechera stricta.
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Trees and shrubs in tropical Africa use the C3 cycle as a carbon fixation pathway during photosynthesis, while grasses and sedges mostly use the C4 cycle. Leaf-wax lipids from sedimentary archives such as the long-chain n-alkanes (e.g., n-C27 to n-C33) inherit carbon isotope ratios that are representative of the carbon fixation pathway. Therefore, n-alkane d13C values are often used to reconstruct past C3/C4 composition of vegetation, assuming that the relative proportions of C3 and C4 leaf waxes reflect the relative proportions of C3 and C4 plants. We have compared the d13C values of n-alkanes from modern C3 and C4 plants with previously published values from recent lake sediments and provide a framework for estimating the fractional contribution (areal-based) of C3 vegetation cover (fC3) represented by these sedimentary archives. Samples were collected in Cameroon, across a latitudinal transect that accommodates a wide range of climate zones and vegetation types, as reflected in the progressive northward replacement of C3-dominated rain forest by C4-dominated savanna. The C3 plants analysed were characterised by substantially higher abundances of n-C29 alkanes and by substantially lower abundances of n-C33 alkanes than the C4 plants. Furthermore, the sedimentary d13C values of n-C29 and n-C31 alkanes from recent lake sediments in Cameroon (-37.4 per mil to -26.5 per mil) were generally within the range of d13C values for C3 plants, even when from sites where C4 plants dominated the catchment vegetation. In such cases simple linear mixing models fail to accurately reconstruct the relative proportions of C3 and C4 vegetation cover when using the d13C values of sedimentary n-alkanes, overestimating the proportion of C3 vegetation, likely as a consequence of the differences in plant wax production, preservation, transport, and/or deposition between C3 and C4 plants. We therefore tested a set of non-linear binary mixing models using d13C values from both C3 and C4 vegetation as end-members. The non-linear models included a sigmoid function (sine-squared) that describes small variations in the fC3 values as the minimum and maximum d13C values are approached, and a hyperbolic function that takes into account the differences between C3 and C4 plants discussed above. Model fitting and the estimation of uncertainties were completed using the Monte Carlo algorithm and can be improved by future data addition. Models that provided the best fit with the observed d13C values of sedimentary n-alkanes were either hyperbolic functions or a combination of hyperbolic and sine-squared functions. Such non-linear models may be used to convert d13C measurements on sedimentary n-alkanes directly into reconstructions of C3 vegetation cover.
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Communities can be defined as assemblages of species coexisting under particular environments. The relationship between environment and species are regulated by both environmental requirements –which ultimately determine the species capacity to establish and survive in a particular environment– and the ecological interactions occurring during assembly processes –which also determine community composition by conditioning species coexistence. In this context, plant functional traits are attributes that represent ecological strategies and determine how plants respond to environmental factors and interact with other species. Therefore, the analysis of how traits vary through the dynamics of communities, such as along successions, can give insights about how environmental requirements and species interactions may determine the composition and functional structure of these communities. The xerophytic shrub communities inhabiting inland sand dunes in SW Portugal are characterized by successional processes that are mainly driven by local (edaphic gradients and human disturbance) and regional (climate) processes. Therefore, they constitute an appropriate system for studying species interactions and environmentcommunity co-variations based on functional terms. Using these communities as a model, we evaluate the hypothesis that successional community changes in species composition of xerophytic shrub communities can result in concurrent changes in functional diversity
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Globally, peatlands occupy a small portion of terrestrial land area but contain up to one-third of all soil organic carbon. This carbon pool is vulnerable to increased decomposition under projected climate change scenarios but little is known about how plant functional groups will influence microbial communities responsible for regulating carbon cycling processes. Here we examined initial shifts in microbial community structure within two sampling depths under plant functional group manipulations in mesocosms of an oligotrophic bog. Microbial community composition for bacteria and archaea was characterized using targeted 16S rRNA Illumina gene sequencing. We found statistically distinct spatial patterns between the more shallow 10-20 cm sampling depth and the deeper 30-40 cm depth. Significant effects by plant functional groups were found only within the 10-20 cm depth, indicating plant-mediated microbial community shifts respond more quickly near the peat surface. Specifically, the relative abundance of Acidobacteria decreased under ericaceous shrub treatments in the 10-20 cm depth and was replaced by increased abundance of Gammaproteobacteria and Bacteroidetes. In contrast, the sedge rhizosphere continued to be dominated by Acidobacteria but also promoted an increase in the relative recovery of Alphaproteobacteria and Verrucomicrobia. These initial results suggest microbial communities under ericaceous shrubs may be limited by anaerobic soil conditions accompanying high water table conditions, while sedge aerenchyma may be promoting aerobic taxa in the upper peat rhizosphere regardless of ambient soil oxygen limitations.
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Effective knowledge transfer between infrastructure projects plays a significant role in organisational success and discovery of new technologies, helping to achieve and maintain competitive advantage and, in effect, sustainable infrastructure development. Knowledge is recognised as an important organisational asset that adds value while being shared. To date, research on knowledge transfer has focused on traditional (functional) types of organisations. However, existing knowledge transfer approaches fail to address the issue of unique characteristics of project-based organisations, and the fact that functional and project-based organisations significantly differ in terms of structure, processes, and characteristics. Therefore, there is a need for a different, separate approach for managing knowledge in the project environment. The aim of this chapter is to highlight this need. An extensive literature review is provided on the areas of project management, knowledge management, and organisational structure; this is further supported by empirical evidence from interviews with project management practitioners. Conducting a ‘cross-field’ literature review provides a better understanding of the knowledge transfer mechanisms and its application to projects, and of the importance of knowledge transfer across projects. This research is crucial to gaining a better understanding of knowledge transfer in the project environment. It stresses that there are dissimilarities between project-based organisations and functional organisations in terms of organisational structure, duration of processes, viewpoint of time, response to change, and mobility of people, and that there is a need for a unique strategic approach in order to achieve effective transfer of knowledge. Furthermore, findings presented in this chapter reveal key elements that play an important role in across project knowledge transfer. These elements include: social communication, lessons learned databases, and project management offices.
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Regrowing forests on cleared land is a key strategy to achieve both biodiversity conservation and climate change mitigation globally. Maximizing these co-benefits, however, remains theoretically and technically challenging because of the complex relationship between carbon sequestration and biodiversity in forests, the strong influence of climate variability and landscape position on forest development, the large number of restoration strategies possible, and long time-frames needed to declare success. Through the synthesis of three decades of knowledge on forest dynamics and plant functional traits combined with decision science, we demonstrate that we cannot always maximize carbon sequestration by simply increasing the functional trait diversity of trees planted. The relationships between plant functional diversity, carbon sequestration rates above-ground and in the soil are dependent on climate and landscape positions. We show how to manage ‘identities’ and ‘complementarities’ between plant functional traits in order to achieve systematically maximal co-benefits in various climate and landscape contexts. We provide examples of optimal planting and thinning rules that satisfy this ecological strategy and guide the restoration of forests that are rich in both carbon and plant functional diversity. Our framework provides the first mechanistic approach for generating decision-making rules that can be used to manage forests for multiple objectives, and supports joined carbon credit and biodiversity conservation initiatives, such as Reducing Emissions from Deforestation and forest Degradation REDD+. The decision framework can also be linked to species distribution models and socio-economic models in order to find restoration solutions that maximize simultaneously biodiversity, carbon stocks and other ecosystem services across landscapes. Our study provides the foundation for developing and testing cost-effective and adaptable forest management rules to achieve biodiversity, carbon sequestration and other socio-economic co-benefits under global change.
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小G蛋白作为信号转导中重要的分子开关, 进化相当保守,与许多不同的调控因子和效应器分子相互作用,产生细胞功能的多样性。近年来,人们不断发现植物中小G蛋白家族的新成员,也不断揭示小G蛋白的新功能,许多植物特有的信号途径和功能需要小G蛋白这个重要的分子开关来完成,使它越来越成为人们研究的热点问题。但是,有关植物中Ran GTPase及其编码基因的研究工作报道很少,对与之相互作用的调控蛋白研究进展也刚刚开始。 TaRAN1 (AF488730) 是小麦来源的Ran同源蛋白编码基因,全长1055 bp, 编码221个氨基酸,它在植物发育过程中的功能还没有任何报道。本论文在验证了它是小G蛋白Ran家族的成员后,从分子水平上还发现它在植物细胞周期调控、对生长素以及胁迫应答信号转导过程中都起着重要作用,这也说明了它可能作为信号转导过程中重要的转换因子,参与了很多细胞的基本生理过程。 利用原核表达系统及亲和色谱的方法纯化了TaRAN1融合蛋白,并用放射性标记的GTP和竞争实验证实了它具有特异的GTP结合活性。TaRAN1的转录产物在小麦幼茎和花芽等分生组织活动旺盛的器官表达较多,而在老叶中表达较少。利用洋葱表皮瞬时表达系统分析表现,TaRAN1蛋白主要定位于细胞核,但其没有典型的核定位信号。 细胞周期一直是生物学领域中的热门问题,人们虽然在动物细胞中取得了很大进展,但在植物细胞中的研究远落后于动物。裂殖酵母(Schizosaccharomyces pombe)是研究细胞形态和细胞周期的良好系统,利用此系统发现超表达TaRAN1的酵母细胞表现出许多新的细胞学表型,例如G2细胞周期延滞、染色体对紫外线敏感、细胞超长或多隔细胞的出现等;反义表达TaRAN1的酵母细胞呈近圆型、具有高度凝集的核并且生长速度缓慢、核质混合和无核细胞的数目明显增加。流式细胞仪检测实验也证实其细胞周期的异常。这些结果推测TaRAN1蛋白可能参与细胞周期的有丝分裂过程和发育的调控机制,并且在维持染色体结构稳定和完整性方面起着重要的作用。通过免疫荧光实验观察表明,超表达转基因酵母的微管多呈异常的狭小扇形结构,反义表达TaRAN1的酵母微管不能形成丝状结构,推测TaRAN1还可能参与微管(包括纺锤体)的结构形成过程。最后,我们用超表达TaRAN1的转基因拟南芥和水稻也证实了它的功能,其生长点表现出分生组织增多的原基、根生长点的有丝分裂指数有所改变、出现异常的细胞分裂时相等有关细胞周期异常的现象,更进一步说明了TaRAN1确实参与着细胞周期的调控过程,推测其与细胞周期从G2期进入M期的过程有关。 TaRAN1基因受IAA的诱导表达,且随着浓度的增加表达量增强。超表达的TaRAN1植株(包括拟南芥和水稻)的根表现出对外源生长素异常敏感,侧根显著变少,地上部分表现出生长素过量的表现型,顶端优势减弱,分蘖增多,生长周期延长等。HPLC测定转基因植物的IAA含量,明显高于对照。所以,TaRAN1可能还参与了复杂的生长素信号转导过程。TaRAN1基因还受各种胁迫处理的诱导表达,并且超表达植株对胁迫的忍受能力有明显提高,这说明TaRAN1还参与了胁迫信号应答的相应机制。Ran蛋白这些新功能目前还未见到其它报道。
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中国东北样带(NorthEast China Transect, NECT)是位于中纬度温带以降水量作为主要驱动因素的陆地样带。本文的工作以此作为研究平台,利用生态信息系统(Ecological Information System, EIS)以及Microsoft Excel 7.0软件包建立了样带的地理数据库和植物多样性数据库,包括气候数据库、植被数据库、遥感数据库和内蒙内C_4植物数据库以及样带内生态系统特征数据库。在此基础上,主要研究了以下四个方面的内容: 1. 利用Holdridge的生命地带方法对NECT内的生物群区进行了划分。 主要是确定了生物群区间过渡带的位置与宽度,并预测了在全球变化三种模式下NECT内生物群区,尤其是过渡带的变化图景。湿度升高2 ℃后,过渡带的面积都呈扩大化的趋势。森林区对于降水量的变化反应很敏感。荒漠灌丛(即荒漠草原类型)由于其水热条件处于样带内较极端类型,因而对于全球气候变化反应也比较敏感。 2. 研究了NECT内的α、β多样性以及包括生活型、水分生态型、区系地理成分等在内的植物群落特征多样性的梯度变化规律。 研究了样带内的多样性梯度,提出了在样带内存在的α多样性测度问题以及β多样性沿样带的变化规律:样带内由东到西,β多样性逐渐升高,群落内物种被替代的速率变慢;两种植被类型边界上的两个样地之间的相似程度由东到西呈上升趋势;同一类型群落之间的物种周转率比不同类型群落间的物种周转率相对要低。同时将各个环境因子与α、β多样性作了回归分析,找出样带内决定α、β多样性的主要环境因子指标。 样带内沿43.5°N一线附近植物群落的生活型共有17类,水分生态型8类,区系地理成分包括17类,以此为基础分析了群落特征沿样带的变化规律。并探讨了生活型分布的历史地理原因。 3. 对样带气候-NDVI间的关系以及植被-NDVI的关系进行了探讨。 利用来自气象卫星的遥感数据一归一化植被指数(NDVI),和数值化后的样带1:100万植被图进行叠加,找到NECT内每种植被类型对应的NDVI值。样带内共有植被类型147种,反映在NDVI变化上的植被类型有106类。其中,自然植被101种。 影响年均NDVI分布的因子主要有经度、辐射日照百分率及7月温度,与经度呈正相关,与辐射日照时数及7月温度呈负相关。回归方程如下: NDVI = -220.426 + 3.273Lon - 80.338Ratio - 1.962T_7 (R~2 = 0.9714, F = 521.52, p < 0.001) 4. 研究了NECT内的光合功能型。 主要包括内蒙古地区的C_4植物及其生态地理特性。揭标C_4植物的分类群特性、生活型、水分生态型与区系地理成分等生态学特性。C_4植物分布的科属极其集中。C_4光合型为维管植物某些分类群(科、属、种)的特性,为它们固有的遗传特性。推断C_4起源于草本的某些科属。C_4植物为喜热、耐旱的类群。世界种、泛热带种、泛地中海种C_4植物较集中。 样带内的C_3、C_4功能型及其与环境因子的相关性。样带内C_4和C_3光合型植物组成比例由东到西表现出两高两低的趋势。分布主要与年均温和降水量呈显著相关。 提出了一种新的C_3、C_4鉴别方法。即根据野外测定的光合数据建立了C_3、C_4的判别模型: f_1(x) = -1.5493 + 0.1427Pn + 0.1035Tr + 0.3768ΔT + 0.1000Gs f_2(x) = -15.6142 + 1.0542Pn - 0.2503Tr - 0.2957ΔT + 0.6491Gs 最后,综合7个GCMs模型(GFDL,GISS,LLNL,MPI,OSU,UKMOH,UKMOL)的输出结果,利用此结果和本文建立的回归模型,模拟了样带内生物多样性的窨分布格局,并预测了末来全球变化下归一化植被指数NDVI的空间分布格局的变化。
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通过野外测定和控制实验结果发现: 在成林内林窗能促进发芽率、幼苗存活率和光合作用等。高光下,会发生多次生长。幼苗干物质积累与光照明显正相关。生长速度与存活无相关,但对第二年存活有影响。基径可作为光反应的无损伤测定指标。直射光和散射光对幼苗生长影响不同。 适当厚度的枯落物覆盖促进种子发芽和补充更新,埋藏太深则对辽东栎幼苗的生长、生理和存活等有抑制。灌木和树木的冠层对辽东栎在灌丛中的建立。 模拟实验表明完全去叶可导致16.7%的幼苗死亡,完全去除子叶可导致50%幼苗死亡,都严重影响幼苗的生理过程和干物质积累。土壤养分和干旱对辽东栎幼苗生长和光合也有很大影响。 运用通径分析精确测定,结果发现辽东栎冠层不同位置的叶片气体交换的限制因子有很大的差别。上层叶主要是气孔导度影响,叶温是通过饱和蒸汽压(VPD)有间接负作用。冠层下方光照的不足的限制,叶温有促进光合作用。不同部位叶片光合作用对气孔导度的依赖程度不同。 在辽东栎林演替过程中,生理生态变化趋势明显。根据所测的20多个生理指标,可将主要物种划分成不同的功能群。早期种具有较高的光合速率,气孔导度, 蒸腾速率和抗旱性, 而辽东栎和棘皮桦单独为一类。
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近二十年来,碳同位素技术己被广泛应用于植物生态学,特别是植物“碳一水”关系的研究中。植物的碳同位素组成(δ13C值)是叶片组织合成过程中光合活动的整合,它反映了植物长期的水分利用效率。内蒙古锡林河流域位于我国温带典型草原的核心区域,水分是制约本区植物生产力和群落稳定性的限制因素。因此关于本区植物水分利用效率和水分利用状况的研究,对探讨植物对生境干旱化的适应与响应机制具有十分重要的理论和实践意义。本研究沿土壤水分梯度在锡林河流域选取了沼泽化草甸、盐化草甸、草甸草原、典型草原、退化草地和疏林沙地等8个代表性植物群落,研究主要植物种、功能群和群落的碳同位素组成及叶片含水量、脯氨酸含量等与植物抗旱性相关的生理指标的变化,从植物种、功能群和群落三个层次研究了不同水分条件下植物水分利用效率的变化及其对不同水分生境的响应与适应机制。 1)在所调查的8个植物群落中,C3植物占绝对优势;C3植物的δ13C值和水分利用效率越大,其在整个流域中的分布频度越高,生物量也越大;与生长在湿润生境中的植物相比,生长在较干旱生境中的植物能积累更高水平的脯氨酸。以上结果表明,锡林河流域的植物可能通过两种机制适应当地的干旱生境:一是通过调节气孔导度提高植物的水分利用效率;止是通过积累高水平的脯氨酸增强植株的渗透调节能力并维持相对稳定的水分含量。 2)依照生活型将锡林河流域主要植物种划分成6个植物功能群:乔木、灌木、半灌木、多年生禾草、多年生杂类草和一年生植物。在较湿润生境,多年生杂类草更加丰富并构成了群落地上生物量的绝大部分;而在较干旱生境下,多年生禾草在群落中起更重要的作用;随着土壤含水量下降,灌木和半灌木逐渐增多,且在退化草地和沙地中其相对生物量迅速增加;多年生禾草别3c值显著高于其它功能群;随着土壤水分可利用性降低,多年生禾草和杂类草的别3c值表现出增加的趋势,而灌木/半灌木则表现出相反的趋势。以上结果进一步证明了,在典型草原区以生活型为基础划分的植物功能群可以用来进行较大尺度植物一水分关系的研究。 3)依照植物的水分生态类群,将锡林河流域主要植物种划分为六个植物功能群:旱生植物、中旱生植物、旱中生植物、中生植物、湿中生植物和湿生植物。在较湿润生境中(沼泽化草甸和盐化草甸),湿中生和湿生植物成为优势种并构成地上生物量的主体;在干旱生境中(草甸草原、典型草原和退化草地),旱生和中早生植物占绝对优势并构成群落生物量的90%以上;随着不同水分生态类群所适应的生境从干旱到湿润逐渐转变,植物的δ13C值和水分利用效率显著降低;旱生植物叶片脯氨酸含耸最高,湿中生和湿生植物脯氨酸含量最低,不同水分生态类群脯氨酸含量与其δ13C值和地上生物星.显著正相关关系。 4)不同群落类型的平均δ13C值有显著不同,表现为:典型草原>退化草地>沙地>退化恢复草地>草甸草原之盐化草甸>沼泽化草甸。C4植物的出现、不同物种δ13C值的差异和同一物种在不同生境下δ13C值的变化是影响群落平均δ13C值的主要因素,而这些因素与土壤水分状况和干扰历史(特别是放牧)密切相关。 此外,本文还研究了氮素添加对羊草和大针茅光合和水分利用效率的影响。土壤含氮量的增加可以显著提高羊草叶片光合能力和叭JE,而对大针茅的影响不大。作为锡林河流域两种优势植物,羊草和大针茅通过不同的生理机制来维持较高的WUE适应干旱生境:羊草为高光合、高蒸腾,而大针茅为低光合、低蒸腾。羊草较高的WUE是以降低氮利用效率 (NuE)为代价的;而大针茅在维持较高WUE的同时仍能维持较高的NUE,这一特征使大针茅可以广泛分布于更加干旱和贫瘩的地区。 以上研究结果,为深入开展典型草原生态系统植物与水分关系的研究提供了有价值的信息,进一步证实了稳定性碳同位素技术可以有效地指示不同群落类型中主要植物种长期水分利用效率。同时,通过对其它相关生理指标的测定,可以更好地探讨植物对水分限制的适应策略。我们的研究结果从植物种、功能群和群落三个层次进一步揭示了植物对干旱生境的适应机制,并初步阐明了人类干扰特别是过度放牧对草原群落建群种和优势种的生态替代或/和灌丛入侵的影响。这些研究对生物多样性保护、全球变化和区域可持续发展等热点问题的研究都具有重要的意义。在今后的研究中,结合其它稳定性同位素(如2H,18O和15N)技术,将有助于我们进一步深入研究蒙古高原植物对气候变化和过度放牧的适应与响应机制。
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元素化学计量学指从化学计量学的角度出发,通过分析比较生命物质不同结构层次(分子、细胞、器官、机体、种群、群落等)或生态系统中元素的相对比值,来研究各层次相互之间以及生态学过程中元素之间的关系。生态化学计量学研究可以把生态实体的各个层次存元素水平上统一起来,足近年来新兴的一个生态学研究领域,广泛应用于生态学研究中。C,N,P是生物地球化学循环中的重要元素,在生态系统中占有重要地位,许多环境问题都与它们有关,由此这三种元素的化学计量学受到生态学家们的普遍关注。C:N:P化学计量学在水生生态系统中研究较为深入,目前已发展到染色体水平,而在陆地生态系统中的研究较为匮乏近年来由于人类活动的强烈影响,这三种元素的循环在速度和规模上都发生了前所未有的改变,导致一系列环境问题的出现,因此C:N:P化学计量学在陆地生态系统中的研究就显得尤为重要。作为地球生命存在基础的绿色植物,在地球上已有数亿年的演化历史,研究陆地植物的元素化学计量学不仅有助于深入了解植物存在于地球上的内在机制,而且可以为许多环境问题的解决提供理论依据。本文首先建立中国不同地区植物氮磷含量数据库,通过数据分析找出一般规律,并进一步揭示植物不同进化阶段N:P化学计量比的变化规律。在此基础上,通过在内蒙古羊草草原设立不同施肥样地来模拟自然界不同氮磷环境,从试验水平上研究不同施肥处理及施肥梯度下生态系统中氮、磷、有机质的变化规律,并从化学计量学角度研究其内在机制。 利州新建成的中国维管植物数据库(包含1603种植物)研究了不同进化水平以及不同功能群(生活型)间植物N:P比的变化规律,并沿胡焕庸线(胡线)把中团分为为东西两部分,从总体水平上对比了东、西部间叫植物氮磷含量以及N:P的异同。结果表明:l)从演化水平来看,尽管氮磷含量表现出极大的差异,除豆科植物外,植物N:P基本保持稳定水平;2)木本植物与草本植物的N:P比差异.显著,木本植物之间(常绿乔木,常绿灌木,落叶乔木,落叶灌木)N:P不具有显著差异;3)中国东西部植物养分含量和N:P比表现出极显著差异,东部的养分含量低于西部,而N:P显著高于西部。 在内蒙古羊草草原两块永久实验样地(样地A:1980年围封样地和样地B:1999年田封样地)进行了为期两年的N素和P素添加试验。氮素添加梯度为0,5,15,30,50,80 g NHN03.m.2.yr-1。P素添加梯度为0,2,4,8,16,and 32 g P2Osm-2 yr-1(仪分析了羊草器官的结果)。分别从植物器官、物种、功能群水平研究了N素添加对N:P化学计量学的影响,此外还研究了土壤和凋落物C:N:P化学计量学对N素添加的响应。结合生物量的变化趋势,探讨了元素化学计量学对养分状况的指示作用。 1.羊草器官对施肥的响应结果表明,添加N素可以显著提高羊草器官中的含N量,p素可以显著提高器官中的含P量:除2001年样地A中的根茎外,根茎中的含P量基本不受N素添加的影响;茎中的含P量同样表现出不受N素添加影响的趋势(2000年B区茎除外):N素添加可以显著增大羊草叶片中的含P量(B区2000年叶片除外)。P素添加对羊草器官的含N量没有影响;羊草器官中的氮磷含量施肥处理下表现出显著的正相关关系(N素添加下B区叶片除外)。N素添加对羊草器官的N:P比没有显著影响(A区茎2000年和B区叶片2000年除外):P素添加显著降低了羊草器官中的N:P比。 2.四种优势植物(羊草、羽茅、针茅和苔草)地上生物量和N:P化学计量学对氮肥的响应研究发现,四个物种的氮磷含量均具有极显著相关关系;氮肥可以显著提高样地A中的羽茅生物量,降低苔草的生物量,而使样地B中的羊草生物量增大;两块样地中,四个物种的氮磷含量及N:P比均随N素水平的增高而增大(样地A中的羽茅N:P比除外)。 3.基于生活型划分的功能群(多年生根茎禾草,多年生丛生禾草,豆科植物,多年生杂类草,一二年生植物,灌木和半灌木)对N素添加的响应研究表明:施N可以提高样地A中的多年生丛生禾草的生物量,而使样地B中的多年生根苇禾草增加;多年生杂类草的相对多度在两个样地中均随施氨水平的增加而显著 降低:在样地B中,施氮可以显著提高不同功能群的氮磷含量;在样地A中,功能群N、P含量对施肥的响应并没有一致的变化规律,添加N素可以显著提高不同功能群的含N量(豆科植物除外),多年生根茎禾草和多年生杂类草的P含量有显著增大的趋势(P < 0.005),而其它功能群(豆科植物、灌木和小半灌木、多年生杂类草和~二年生杂类草)的P含量基本恒定(P>0.05);在样地A中,多年生丛生禾草,多年生杂类草,一二年生植物,灌木和半灌木的N:P比随施氨水平的增加而显著增大,多年生根茎禾草和豆科植物的N:P比基本不变;在样地B中,多年生丛生禾草的N:P比随施氨水平的增加而显著增大,多年生根茎禾草、多年生杂类草和…二年生杂类草不受施氨水平的影响。 4.添加N素对根实验结果表明:两块样地中,上层根(0-10 cm)的生物量仅在施N后第一年显著增加,而下层根(10-20 cm)的地下生物量在两年的施N处理下均不受施肥梯度的影响i在样地A中,施肥后第一年对根的N、P含量影响不显著,施肥后第二年可以显著增大上层根的N、P含量;在样地B中,添加N素后第一年可以显著增大根的含P量; 在两个样地中,两年的N肥处理对根的N:P比没有显著影响:在施氨处理中,根的N、P含量及N:P比在施肥第一年的响应要高于第二年。 5.所有处理中,上层土壤(O-lO cm)养分含量(有机碳,全氮,全磷)均高于下层土壤(10-20 cm);在样地A中,氮素添加对r十壤有机碳没有显著性作用,在施肥第一年可以显著增加上层土壤的N、P含量,而在施肥后第二年对土壤N、P含量没有显著影响;在样地B中,添加N素对两年的土壤养分均没有显著影响:养分添加两个样地土壤中的元素比值(C:N比,C:P比,N:P比)没有显著影响;土壤养分对施N一年后的响应要高于第二年。 6.养分添加对凋落物化学特征及化学计量学特征的影响研究结果表明:凋落物现存量不受施肥的影响;2001年凋落物现存量与2000年和2001年的地上生物量相关关系不显著;添加N素可以显著提高凋落物的N含量,而对有机碳含量和P含量没有显著影响;凋落物C:N比随施肥梯度的增大而显著降低,N:P比显著增高,而C:P比没有明显变化。 以上研究结果表明,不同植物功能群的N:P比存在差异,人类活动强烈影响自然植被中的植物N:P比;但植物的N:P比不受植物进化的影响(豆科植物除外);由于植物已有数亿年的演化历史,同时N与P在植物的结构和功能上具有密切的联系,在生物地球化学循环中办存在耦合作用。因此植物N:P比值恒定可能是一普适性规律。 N素添加试验表明,在植物根、地上器官、物种和功能群水平上N与P均呈显著正相关关系,反映了植物体内的氮磷含量具有协同作用。共存种对N肥的响应不同,表明物种受不同元素的制约。因此除非把生态系统中所有物种对施肥的响应刻画清楚,笼统的认定生态系统缺乏某种元素是不适当的。 施肥试验表明,两种围封时间样地的主要限制性元素不同。极度退化(样地B)植物生长主要缺N,而在保护较好样地(样地A),P也逐步成为一种限制因素。反映了随着保护时间的增加,植物生长逐渐由N限制型向N、P共同限制型过渡。添加的养分要么被植物吸收,挥发到大气中,或以凋落物的形式返还到土壤表层。但是对养分的预算有待于进一步研究。土壤中的养分含量对N素添加有…个滞后效应,而植物响应较为迅速。功能群N:P比在施肥实验中不能保持恒定,可能是由于实验时间较短的缘故;化学计量学的研究表明羊草草原分解凋落物的微生物受P素的制约,可能是由于植物体内具有高的P素再转运机制。这一结论有待于进一步的验证。氮肥降低了凋落物的C:N比,因此凋落物的分解速率可能将要发生改变。这需要进一步开展C循环的研究。
