基于功能性状的铁杆蒿对环境变化的响应与适应

以延河流域3个植被区(森林区、森林草原区及典型草原区)稳定的自然植物群落中的铁杆蒿为研究对象,测定铁杆蒿的比叶面积、叶组织密度、叶氮含量、叶磷含量、叶氮磷比、比根长、细根组织密度、细根氮含量、细根磷含量、细根氮磷比10项能够反映植物生存对策且易于测量的功能性状,研究了不同生境下铁杆蒿功能性状的种内差异,以及气象因子和地形因子对铁杆蒿植物功能性状的影响,并分析了各功能性状间的相关关系.结果表明： 铁杆蒿各功能性状中除了叶磷含量、叶氮磷比、比根长、根组织密度和根氮磷比在各植被带间的差异显著外,其他5个性状差异均不显著.各性状在坡度、坡向间的差异不显著.比叶面积与叶组织密度呈显著负相关,比根长与根组织密度和根氮磷比呈显著负相关,根组织密度与根氮含量和根氮磷比呈显著正相关,叶组织密度、叶氮含量和叶氮磷比与其他功能性状的相关性不显著.表明铁杆蒿对恶劣环境的适应是通过叶片和细根功能性状间的相互作用和调节实现的.不同环境因素在不同程度上对铁杆蒿功能性状产生影响,对铁杆蒿功能性状影响大小依次是年均降雨量、年均温和年均蒸发量.     

环境及遗传背景对延河流域植物叶片和细根功能性状变异的影响

研究环境筛选作用和植物系统发育背景对植物群落构建产生的影响,有助于理解植物在生长过程中对资源的分配利用和对环境的适应规律。以延河流域3个植被带(森林带、森林草原带及典型草原带)稳定的自然植物群落为研究对象,调查了31个样地107种植物,隶属于35个科78个属,测量了6种叶片和3种细根性状。分别对3个植被带和不同植物科植物的叶片和细根性状做单因素方差分析,结果表明:叶片氮含量和细根氮含量在3个植被带间无显著差异,叶厚度、比叶面积、叶组织密度、叶片磷含量、叶片氮磷比、比根长、根组织密度在3个植被带间差异极显著。由南向北随着气候干旱的加剧,植物通过调节叶片和细根性状,表现出了不同的适应策略:森林带植物叶片相对生长速率高,根系防御力强;森林草原带植物叶片防御力强,根系相对生长速率快。不同科的植物在相同的环境条件下,对于资源的竞争力和胁迫的忍耐力也有所不同,比如豆科植物具有远远高于其他科的叶片和细根氮含量,但是对养分的利用效率并不高。GLM分析结果说明,所涉及的植物功能性状的空间变异主要来自于年均降雨量的变化及植物科的差异,如16.26%的比叶面积的变异可由年均降雨量变化解释,4.02%可由植物科的差异解释。物种水平上,叶厚度、比叶面积、叶组织密度、比根长、根组织密度、叶片磷含量是对气候干燥度变化响应敏感的植物功能性状,其空间变异主要由环境差异所致。延河流域的植物群落在形成过程中,存在明显的环境筛选效应。这表明,环境异质性在植被恢复实践中必须予以考虑。     

New insights into leaf and fine‐root trait relationships: implications of resource acquisition among 23 xerophytic woody species

Functional traits of leaves and fine root vary broadly among different species, but little is known about how these interspecific variations are coordinated between the two organs. This study aims to determine the interspecific relationships between corresponding leaf and fine‐root traits to better understand plant strategies of resource acquisition. SLA (Specific leaf area), SRL (specific root length), mass‐based N (nitrogen) and P (phosphorus) concentrations of leaves and fine roots, root system, and plant sizes were measured in 23 woody species grown together in a common garden setting. SLA and SRL exhibited a strong negative relationship. There were no significant relationships between corresponding leaf and fine‐root nutrient concentrations. The interspecific variations in plant height and biomass were tightly correlated with root system size characteristics, including root depth and total root length. These results demonstrate a coordinated plant size‐dependent variation between shoots and roots, but for efficiency, plant resource acquisition appears to be uncoupled between the leaves and fine roots. The different patterns of leaf and fine‐root traits suggest different strategies for resource acquisition between the two organs. This provides insights into the linkage between above‐ and belowground subsystems in carbon and nutrient economy.     

延河流域不同植被带植物功能性状变化及其对环境因子的响应

植物功能性状是表征植物对环境差异的适应性及植物内功能的进化与平衡关系的重要属性,功能性状-环境条件相互关系对于探讨植被对多变生境的适应策略具有重要意义。对黄土丘陵区延河流域3个生物地理气候区（草原区、森林草原区和森林区）进行分层采样,通过野外试验测定植物群落功能性状和土壤理化性质,结合气象数据分析了植物功能性状沿植被带的变化及其对环境变化的响应。研究结果如下：（1）比叶面积（SLA）、叶氮含量（LNC）、叶氮磷比（LN/LP）、根碳含量（RCC）、根碳氮比（RC/RN）和根氮磷比（RN/RP）从草原区到森林区显著上升,而叶组织密度（LTD）、叶碳氮比（LC/LN）和比根长（SRL）显著下降。森林草原区的植物磷含量显著高于森林区和草原区。（2）水分条件是调节植物群落功能性状变异的最主要因素,其能够直接影响叶和根性状,还会通过影响土壤养分和土壤水分间接作用于叶片功能性状。（3）从草原区至森林区,随着养分和水分可获取性的升高,植物群落会通过增大SLA,降低LTD和SRL以提高对干旱贫瘠立地条件的适应能力。氮（N）是草原区植物生长主要限制元素,而森林草原区则同时受到N、磷（P）的限制。     

A Multidimensional Functional Trait Approach Reveals the Imprint of Environmental Stress in Mediterranean Woody Communities

Water availability is one of the most important factors determining species distribution, plant community structure and ecosystem functioning. We explore how the functional structure of Mediterranean woody plant communities varies along a regional gradient of aridity in the Andalusian region (south Spain). We question whether communities located in more arid sites show more similarity in their functional structure when compared with communities located in wetter sites or whether, instead, there is divergence in their functional spaces. We selected five aridity zones (three sampling sites per zone) and measured 13 traits of different functional dimensions (including leaf, stem and root traits) in 74 woody plant species. We quantified functional space differences using the n-dimensional niche space approach (hypervolume). We found a larger functional space for the wetter communities compared with the more arid communities, which showed greater overlap of the trait space occupation. Our results indicate that aridity acts as a key abiotic filter affecting various metrics of the community trait structure, in accordance with the plant economics spectrum. We have also documented consistent variation in the functional space, supporting lower functional diversity under more harsh climatic conditions. The trend of functional space variation along the aridity gradient was different when considering traits from only one plant organ. Thus, the filtering process driving the functional structure of the communities studied here largely depends on the trait axis considered; for example, the root dimension showed considerable variation in wet environments, whereas the leaf dimension exhibited a larger functional space in the drier habitats.     

Independent evolution of leaf and root traits within and among temperate grassland plant communities

In this study, we used data from temperate grassland plant communities in Alberta, Canada to test two longstanding hypotheses in ecology: 1) that there has been correlated evolution of the leaves and roots of plants due to selection for an integrated whole-plant resource uptake strategy, and 2) that trait diversity in ecological communities is generated by adaptations to the conditions in different habitats. We tested the first hypothesis using phylogenetic comparative methods to test for evidence of correlated evolution of suites of leaf and root functional traits in these grasslands. There were consistent evolutionary correlations among traits related to plant resource uptake strategies within leaf tissues, and within root tissues. In contrast, there were inconsistent correlations between the traits of leaves and the traits of roots, suggesting different evolutionary pressures on the above and belowground components of plant morphology. To test the second hypothesis, we evaluated the relative importance of two components of trait diversity: within-community variation (species trait values relative to co-occurring species; α traits) and among-community variation (the average trait value in communities where species occur; β traits). Trait diversity was mostly explained by variation among co-occurring species, not among-communities. Additionally, there was a phylogenetic signal in the within-community trait values of species relative to co-occurring taxa, but not in their habitat associations or among-community trait variation. These results suggest that sorting of pre-existing trait variation into local communities can explain the leaf and root trait diversity in these grasslands.     

延河流域植物功能性状变异来源分析

由于遗传背景对植物性状的影响,直接研究环境与植物性状的关系有一定的不确定性。因此,研究植物性状对环境变化的响应,必须明确遗传背景与环境对植物性状的相对影响,以排除遗传背景的作用。本研究以延河流域为研究区域,选取19个典型样点,调查了64种植物的6种功能性状,即比叶面积(SLA)、比根长(SRL)、叶片氮(LN)与磷含量(LP)、根的氮(RN)与磷含量(RP),并通过野外定位信息,从已有专题信息图中获取环境数据,采用方差分析和逐步回归的方法,分析了植物性状变异来源,研究了不同科属植物对环境变化的响应。结果表明：(1)不同气候条件下,植物的SLA、LN和RP性状存在显著差异,森林区植物SLA、RP较草原区植物偏低33.02%、19.94%,而LN则高于草原区植物19.33%;不同科属植物之间SLA、SRL、LN和RN存在显著差异,豆科植物具有较高的SLA、LN、RN,分别高出研究区平均值16.33%、65.23%、97.78%,而禾本科植物SRL具有最大值,高出平均值103.11%;(2)遗传背景差异是植物性状变异的首要决定因子,遗传背景对SRL、LN、RN变异的解释比例分别达到了27.86%、32.78%、42.70%,而LP、RP则受环境因子的影响更大,环境因子对LP、RP解释比例分别达到24%、15.58%;(3)豆科Leguminosae、禾本科Poaceae、菊科Asteraceae、蔷薇科Rosaceae植物性状的环境因子逐步线性回归模型,表明不同科属的植物对环境因子是否产生响应和响应的方式均不相同,豆科和禾本科植物对区域性气候条件较为敏感,而菊科和蔷薇科植物受地形因子和土壤含水量影响较大。     

Decoupled drought responses of fine-root versus leaf acquisitive traits among six Prunus hybrids

要预测干旱对森林和果树种植的影响，就需要更好地了解干旱胁迫对叶片和细根的资源获取性状(比叶面积SLA、比根面积SRA以及比根长SRL)的影响。本研究试图验证以下科学假设：在重度干旱胁迫下，叶片与细根的资源获取性状具有协同效应，使得植物能够采取整合的资源节约策略。我们收集了不同干旱敏感性的六种李属砧木的幼树，通过在温室中对它们进行干旱试验来验证我们的科学假设。这些幼树被分为两组进行水分处理试验，即对照处理组(浇水量为100%田间持水量)与重度干旱处理组(每种砧木的浇水量为该砧木对照组植物每日蒸散量的33%)。在处理开始后的第30天和第60天，分别对两组处理下的六种砧木的植物叶片与细根进行取样。结果表明，在重度干旱胁迫下，没有任何一种植物同时显著降低了SLA和SRA(或SRL)。六种李属砧木植物的细根性状表现出两种主要的干旱响应组合：(1)根组织密度(RTD)增大，同时平均根径减小，而SRL没有显著变化；(2) RTD增大，同时SRL减小，而平均根径没有显著变化。六种砧木植物性状的干旱响应展现出两个相互垂直的变化梯度，这两个梯度均以从对照处理组到干旱处理组植物的资源节约性变化为特征，其中一个梯度展现了叶片气体交换，SRA，SRL以及RTD的干旱响应之间的密切相关关系，而另一个梯度以SLA的降低为特征。这些发现突出了(1)根系性状干旱响应的多维性；(2)重度干旱胁迫下，叶片经济性状与叶片水力性状之间的解耦联关系；(3)重度干旱胁迫下，叶片水力性状与根系水力性状之间的协同变化关系。这项研究有助于在种内尺度上确认根系干旱响应多维性的起源，并重点突出了不同植物如何通过不同的叶片与细根性状的干旱响应组合而得以在重度干旱胁迫下存活。     

Plasticity in above‐ and belowground resource acquisition traits in response to single and multiple environmental factors in three tree species

Functional trait plasticity is a major component of plant adjustment to environmental stresses. Here, we explore how multiple local environmental gradients in resources required by plants (light, water, and nutrients) and soil disturbance together influence the direction and amplitude of intraspecific changes in leaf and fine root traits that facilitate capture of these resources. We measured population‐level analogous above‐ and belowground traits related to resource acquisition, i.e. “specific leaf area”–“specific root length” (SLA–SRL), and leaf and root N, P, and dry matter content (DMC), on three dominant understory tree species with contrasting carbon and nutrient economics across 15 plots in a temperate forest influenced by burrowing seabirds. We observed similar responses of the three species to the same single environmental influences, but partially species‐specific responses to combinations of influences. The strength of intraspecific above‐ and belowground trait responses appeared unrelated to species resource acquisition strategy. Finally, most analogous leaf and root traits (SLA vs. SRL, and leaf versus root P and DMC) were controlled by contrasting environmental influences. The decoupled responses of above‐ and belowground traits to these multiple environmental factors together with partially species‐specific adjustments suggest complex responses of plant communities to environmental changes, and potentially contrasting feedbacks of plant traits with ecosystem properties. We demonstrate that despite the growing evidence for broadly consistent resource‐acquisition strategies at the whole plant level among species, plants also show partially decoupled, finely tuned strategies between above‐ and belowground parts at the intraspecific level in response to their environment. This decoupling within species suggests a need for many species‐centred ecological theories on how plants respond to their environments (e.g. competitive/stress‐tolerant/ruderal and response‐effect trait frameworks) to be adapted to account for distinct plant‐environment interactions among distinct individuals of the same species and parts of the same individual.     

武夷山不同海拔毛竹细根功能性状

细根作为植物最重要的资源获取功能器官,是影响陆地生态系统的重要组成部分。定量化毛竹的细根功能性状对于理解其生理生态特征响应及生活史策略至关重要。为揭示毛竹细根功能性状随海拔梯度的变化规律以及细根的适应策略,对武夷山不同海拔(840 m、1040 m、1240 m)毛竹细根的碳(C)、氮(N)、磷(P)含量和比根长(SRL)、比根面积(SRA)等性状进行测定,分析细根性状在海拔上的差异及其异速生长关系。结果表明：(1)不同海拔毛竹细根养分性状存在显著差异。毛竹细根C含量在海拔1040 m最大。随海拔升高,细根N、P含量均呈下降趋势,细根C∶N、C∶P随着海拔的升高而增加。(2)细根的结构性状在海拔梯度上差异显著。随海拔升高,细根平均根直径(AvgDiam)、SRL及SRA均呈下降趋势,而根组织密度(RTD)呈升高趋势。(3)细根性状间存在显著的异速生长关系。细根N与P含量存在显著的等速生长关系,二者与C含量存在显著异速生长关系;SRL与SRA存在显著的等速生长关系,二者与RTD存在显著的负等速生长关系,与N含量存在显著的异速生长关系;细根AvgDiam与RTD存在显著的负异速生长关系。毛...     

How do leaf trait values change spatially and temporally with light availability in a grassland diversity experiment?

Complementarity in light use might increase light exploitation and could be an important mechanism explaining the coexistence of multiple species in plant communities of increasing diversity. We measured vertical light profiles and leaf traits related to light acquisition and light use in 40 mixtures of varying species richness (SR, 2, 4, 8 and 16) and functional group richness (FR, 1‐4) in a large grassland biodiversity experiment at five different times during the growing season. Light attenuation within the canopy differed significantly among mixtures of varying SR at peak biomass, with 40% in 2‐species mixtures and up to 80% in 16‐species mixtures. In contrast, increasing SR did not affect light attenuation at the beginning of the growing season or during regrowth after mowing, when large fractions of incoming radiation reached the ground level. These patterns suggested the presence of highly variable light niches over space and time. Trait expression differed among functional groups (except specific leaf area (SLA)) and varied within the growing season. However, we found no direct effect of increased SR or FR on the expression of leaf traits, except for positive species richness‐effects on SLA at peak biomass time. SLA and stomatal conductance increased and leaf dry matter content decreased at lower light at leaf height, while leaf greenness was independent of relative light availability. Dissimilarity of leaf traits (except SLA) at the community level increased with increasing SR. Thus, our results suggest that after accounting for light availability, which was driven by SR and time of year, variations in leaf trait expression within the grassland canopies did not depend on SR, but rather on functional group identity and time of year. Consequently, increased complementarity in light use at higher plant diversity is due to presence of more species with different leaf trait expression and trait variation in response to the actual light environment.     

Within- and among-species variation in specific leaf area drive community assembly in a tropical cloud forest

Specific leaf area (SLA) is a key functional trait reflecting the trade-off between resource capture and conservation, and has been identified as playing an important role in plant community assembly. Mechanistic models of community assembly state that the assemblage of species in a local community is controlled by environment filters operating on functional traits. We measured within- and among-species variation of SLA, and environmental conditions in a tropical cloud forest to explore how variation in this functional trait contributes to community assembly. SLA variation at the species level was also decomposed into alpha (within assemblage variation), and beta (across assemblage variation) values. SLA decreased with increasing solar irradiance (approximated using plant height) within the three study sites, and differed among the three sites both for within- and among-species comparisons. Mean plot SLA, accounting for both within and among species across the three sites, increased significantly in relation to air temperature but not local photosynthetic photon flux density and soil total phosphorus. Alpha SLA decreased with increasing solar irradiance within the three sites and beta SLA differed among the three sites. Our results clearly demonstrate that light and air temperature are key environmental factors involved in organizing plant species within and among communities in tropical cloud forests. The strong relationship between both intra- and interspecific variation in SLA and environmental conditions strongly confirms the role of trait variation in the assembly of plant species in tropical cloud forest communities via environment filtering related to light availability and air temperature.     

羌塘高原降水梯度植物叶片、根系性状变异和生态适应对策

叶片和根系是植物获取资源的最重要的器官,其性状随环境梯度的变化反映了植物光合碳获取和水分与养分的吸收能力及其对环境变化适应的生态对策。羌塘高原降水梯度带高寒草地群落叶片和根系成对性状关系研究不仅能揭示环境梯度对植物性状的塑造作用,也可为理解寒、旱和贫瘠等极端环境下植物的适应策略提供依据。为此,选择3组具有代表性的叶片和根系成对性状:比叶面积(SLA)和比根长(SRL);单位质量叶氮含量(LN_(mass))和单位质量根氮含量(RN_(mass));单位面积叶氮含量(LN_(area))和单位长度根氮含量(RN_(length)),分析不同优势植物地上、地下成对性状变异特征及其与环境因子的关系,探讨植物性状对高寒生态系统水分和养分限制因素的适应策略。研究表明,区域气候和土壤环境导致的叶片性状变异大于根系性状的变异,干旱端的植物既具有高的SRL,又具有高的叶片和根系的养分含量(LN_(mass),LN_(area)和RN_(mass))。SLA-SRL、LN_(mass)-RN_(mass)、LN_(area)-RN_(length)均表现为权衡关系,在干旱端(年降雨量MAP 400 mm)的高寒草原、荒漠草原和极湿润端(MAP 600 mm)的高寒草甸这种权衡关系更为明显,而中间区域(400 MAP 600 mm)的高寒草甸养分和水分限制不是很强烈,叶片和根系性状更多地表现出协同关系。从植物功能类群来看,苔草和禾草类植物叶片和根系成对性状之间具有更强烈的权衡关系。干旱端植物通过增加SRL和叶片、根系养分含量来提高水分和养分的吸收能力,同时通过叶片高的氮含量提高光合碳获取能力,保障了根系生长的物质来源,表现出地上和地下同时投入的策略。干旱端植物保持较高的养分含量是抵御和适应严酷的寒、旱和贫瘠的环境胁迫的重要策略。而在湿润端植物则采取增加SLA,维持地上光合生产力的生态策略。     

The effects of clipping and soil moisture on leaf and root morphology and root respiration in two temperate and two tropical grasses

Numerous studies have explored the effect of environmental conditions on a number of plant physiological and structural traits, such as photosynthetic rate, shoot versus root biomass allocation, and leaf and root morphology. In contrast, there have been a few investigations of how those conditions may influence root respiration, even though this flux can represent a major component of carbon (C) pathway in plants. In this study, we examined the response of mass-specific root respiration (μmol CO₂ g⁻¹ s⁻¹), shoot and root biomass, and leaf photosynthesis to clipping and variable soil moisture in two C₃ (Festuca idahoensis Elmer., Poa pratensis L.) and two C₄ (Andropogon greenwayi Napper, and Sporobolus kentrophyllus K. Schum.) grass species. The C₃ and C₄ grasses were collected in Yellowstone National Park, USA and the Serengeti ecosystem, Africa, respectively, where they evolved under temporally variable soil moisture conditions and were exposed to frequent, often intense grazing. We also measured the influence of clipping and soil moisture on specific leaf area (SLA), a trait associated with moisture conservation, and specific root length (SRL), a trait associated with efficiency per unit mass of soil resource uptake. Clipping did not influence any plant trait, with the exception that it reduced the root to shoot ratio (R:S) and increased SRL in P. pratensis. In contrast to the null effect of clipping on specific root respiration, reduced soil moisture lowered specific root respiration in all four species. In addition, species differed in how leaf and root structural traits responded to lower available soil moisture. P. pratensis and A. greenwayi increased SLA, by 23% and 33%, respectively, and did not alter SRL. Conversely, S. kentrophyllus increased SRL by 42% and did not alter SLA. F. idahoensis responded to lower available soil moisture by increasing both SLA and SRL by 38% and 33%, respectively. These responses were species-specific strategies that did not coincide with photosynthetic pathway (C₃/C₄) or growth form. Thus, mass-specific root respiration responded uniformly among these four grass species to clipping (no effect) and increased soil moisture stress (decline), whereas the responses of other traits (i.e., R:S ratio, SLA, SRL) to the treatments, especially moisture availability, were species-specific. Consequently, the effects of either clipping or variation in soil moisture on the C budget of these four different grasses species were driven primarily by the plasticity of R:S ratios and the structural leaf and root traits of individual species, rather than variation in the response of mass-specific root respiration.     

武夷山不同海拔黄山松细根性状季节变化

细根作为植物吸收养分和水分的主要器官,其功能性状对森林生态系统功能具有重要影响。以武夷山黄山松为研究对象,通过对不同季节(春季、夏季、秋季和冬季)和不同海拔(1200、1400、1600、1800 m和2000 m)的黄山松细根的功能性状的测定,分析其细根性状特征随海拔和季节变化的规律。结果表明:(1)黄山松细根比根长(SRL),比根面积(SRA)均随海拔先升高后降低,其均值分别为(9.32±0.35) cm/g与(276.41±68.10) cm~2/g;根组织密度(RTD)随海拔先降低后升高,均值为(0.16±0.05) g/cm~3。根平均直径(AvgDiam)随海拔增加变化不显著,均值为(0.097±0.004) mm。SRL和SRA在海拔1600 m处达到最大,而RTD和AvgDiam的最大值出现在海拔1800 m或2000 m处。(2)SRL和SRA在夏季或秋季达到最大,RTD和AvgDiam最大值则出现在冬季或春季。季节和海拔对各细根性状都有显著影响(P0.01),但季节与海拔对根性状并没有产生显著的交互作用(P0.05)。(3)SRL与SRA间的异速生长指数是1.25,显著大于1.0(P0.01);SRL与RTD存在负等速生长关系,而与AvgDiam存在显著负异速生长关系(P0.01);SRA与RTD,以及RTD与AvgDiam间均存在显著负异速生长关系(P0.01),但SRA与AvgDiam之间不存在异速生长关系。黄山松的细根性状在1600 m处倾向于增加比根长和比根面积,而在海拔1800 m或2000 m处则倾向于增加组织密度与根直径,这与黄山松细根性状从夏秋到冬春的季节变化规律相类似。同时,相对于比根面积来说,黄山松的细根在海拔1600 m处和夏秋季节更倾向于投资比根长来增加养分的吸收。     

Suites of root traits differ between annual and perennial species growing in the field

Here, we tested whether root traits associated with resource acquisition and conservation differed between life histories (annuals, perennials) and families (Fabaceae, Asteraceae and Poaceae). Root topology, morphology, chemistry and mycorrhizal colonization were measured on whole root systems of 18 field-grown herbaceous species grown and harvested in central Argentina. Annuals differed from perennials in several root traits important in resource uptake and conservation. They exhibited higher specific root length (SRL), root nitrogen concentration (RNC) and mycorrhizal colonization but had lower root tissue density (RTD) than perennials. They did not differ in topology or construction cost. These differences were consistent among families. Families differed only in a few root traits known to be strongly associated with certain lineages such as topology and nitrogen concentration. There was a strong parallel between root traits and analogous leaf traits described in the literature for annuals and perennials. Our results suggest the existence at the root level of an acquisitive vs conservative syndrome consistent among families similar to that previously reported for above-ground traits.     

Population variation and natural selection on leaf traits in cork oak throughout its distribution range

A central issue in evolutionary biology is the exploration of functional trait variation among populations and the extent to which this variation has adaptive value. It was recently proposed that specific leaf area (SLA), leaf nitrogen concentration per mass (N_mass) and water use efficiency in cork oak play an important role in adaptation to water availability in the environment. In order to investigate this hypothesis, we explored, first, whether there was population-level variation in cork oak (Quercus suber) for these functional traits throughout its distribution range; if this were the case, it would be consistent with the hypothesis that different rainfall patterns have led to ecotypic differentiation in this species. Second, we studied whether the population-level variation matched short-term selection on these traits under different water availability conditions using two fitness components: survival and growth. We found high population-level differentiation in SLA and N_mass, with populations from dry places exhibiting the lowest values for SLA and N_mass. Likewise, reduced SLA had fitness benefits in terms of growth for plants under dry conditions. However, contrary to our expectations, we did not find any pattern of association between functional traits and survival in nine-year-old saplings despite considerable drought during one year of the study period. These results together with findings from the literature suggest that early stages of development are the most critical period for this species. Most importantly, these findings suggest that cork oak saplings have a considerable potential to cope with dry conditions. This capacity to withstand aridity has important implications for conservation of cork oak woodlands under the ongoing climate change.     

Convergent succession of plant communities is linked to species’ functional traits

Functional traits reflecting the resource economy and growth strategy of plants vary widely both within and among ecosystems. Theory suggests that trait variation within a community may determine the relative abundance of species, though this idea requires more empirical support.We set up a long-term succession experiment in a nutrient-poor wetland, planting seedlings of twelve fenland species in different relative abundances and absolute densities, thereby creating 24 communities. The biomass of these species and the soil water and nutrient status of the system were monitored over ten years. Using these data, we could relate the changing relative abundance of species to five traits – leaf dry matter content (LDMC), leaf nitrogen concentration (LNC), specific leaf area (SLA), relative growth rate (RGR), and seed mass (SM).The initial communities converged after ten years to a common dominance–diversity structure, with two species accounting for 82% of total biomass. Soil water and nutrient conditions remained largely constant. By the end of the experiment, community trait structure had changed so that species functional traits were significantly related to their relative abundance. The most abundant species had high LDMC and SM, but low RGR and SLA, and varied little in LNC, suggesting that investment in leaf structure and retention of nutrients were most important for species dominance under low nutrient conditions. Our results provide experimental evidence that dominance–subdominance structures in plant communities are governed by functional traits.     

青藏高原北部戈壁植物群落物种、功能与系统发育β多样性分布格局及其影响因素

戈壁荒漠广泛分布于全球干旱和极旱区域, 是我国陆地生态系统的重要组成部分。由于自然环境恶劣和交通条件限制, 目前有关戈壁植物群落物种、功能和系统发育等多维度β多样性形成机制的系统研究还很缺乏, 严重制约着对戈壁植物多样性维持机制的认知。本文以青藏高原北部61个典型戈壁生境植物群落为研究对象, 通过构建系统发育树和测量8个关键功能性状, 获取戈壁生境的物种、功能和系统发育β多样性, 比较3个维度β多样性格局与零模型的差异, 同时量化环境距离和地理距离对其的相对影响, 以探讨戈壁植物多样性的形成机制。结果显示: (1)戈壁植物的物种、功能和系统发育β多样性均表现出显著的距离衰减效应; (2)戈壁植物的物种、功能和系统发育β多样性均表现为非随机的格局; (3)由于功能性状趋同进化, 植物功能和系统发育β多样性变化趋势并不一致; (4)环境差异对植物3个维度β多样性均有着比空间距离更为重要的影响, 且土壤含水量、地表砾石盖度等局域生境因素的影响比气候更为强烈。以上结果表明, 戈壁植物的β多样性可能主要由局域生境过滤作用控制, 且不同维度的β多样性分布格局并不一致。