海拔对青海湖流域群落水平植物功能性状的影响

海拔变化会引起气压、温度、降水、土壤湿度和风速等环境因子发生急剧变化, 植物功能性状-海拔的相互关系对于预测全球变化背景下山地植物的适应方式具有重要意义。该研究在青海湖流域海拔3 400-4 200 m范围内布设了5个样地(海拔间隔约200 m), 通过植物群落调查, 测定植物功能性状和土壤理化性质, 结合气象数据, 探讨了海拔对青海湖流域群落水平植物功能性状的影响。结果如下: (1)群落加权平均植株高度(H)、叶片干物质含量(LDMC)、叶片碳氮比(C:N)和叶片氮磷比(N:P)随海拔升高显著降低, 比根表面积(SRA)随海拔升高波动下降, 比叶面积(SLA)、叶片氮含量(LNC)和叶片磷含量(LPC)随海拔升高显著升高, 叶片碳含量(LCC)、比根长(SRL)和根组织密度(RTD)随海拔未发生显著变化。(2)所有性状的变异来源以物种组成变化为主, N:P和LPC的种内性状变异与物种组成变化呈现正的协变效应, 其余性状为负的协变效应。(3)降水和0- 10 cm土层土壤养分含量对SLA变化的解释率较高, 温度和10-20 cm土层土壤养分含量对其余性状随海拔变化的解释率较高。以上结果表明青海湖流域植物群落主要通过物种更替来适应随海拔升高而剧烈变化的环境, 且各群落中的非优势种倾向于占据与优势种相反的性状空间来提高资源利用率, 随海拔变化的热量和深层土壤养分含量是群落水平植物功能性状变化的主要影响因子。     

准噶尔盆地荒漠植物的叶片水分吸收策略

在干旱地区, 经常出现只能湿润植物地上部分和表层土壤的小量级降雨和凝结水输入, 此量级的水分输入无法通过入渗进入根区土壤而被植物根系吸收利用。最近研究发现, 叶片吸收水分是利用小量级降水和凝结水的主要方式。该研究通过鉴定和观测准噶尔盆地东南部5个自然植物群落中夏季地上部分仍存活的所有51种荒漠植物叶片的单位面积吸水量(LWUC)、叶片含水量增加率(Rw)以及其他7种植物功能性状, 探讨了这些植物功能性状与植物叶片吸收水分能力的关系。研究结果表明: (1)与Rw相比, LWUC是更加适合评价植物叶片吸收水分能力的指标; (2)植物生活型是相对合理的评价荒漠植物叶片吸收水分能力的植物性状; (3)荒漠植物地上(叶片)和地下(根系)部分吸收水分策略存在着权衡; (4)荒漠植物叶片耗水和吸水存在着权衡。总之, 叶片吸收水分策略对于荒漠植物, 特别是一年生草本植物最大限度地利用有限的水资源渡过持续的干旱并完成生活史具有重要的意义。     

功能多样性和谱系多样性对热带云雾林群落构建的影响

近年来, 功能多样性和谱系多样性为探究群落构建机制提供了新方法。为了更准确地了解海南岛高海拔热带云雾林群落构建机制, 该研究以海南岛霸王岭热带云雾林为对象, 测定7个环境因子和13个植物功能性状。利用主成分分析(PCA)筛选环境因子, 以霸王岭、尖峰岭和黎母山热带云雾林分布物种建立区域物种库, 结合模型, 分析Rao二次熵(RaoQ)和平均成对谱系距离(MPD)变化对植物群落构建的影响。结果表明: 林冠开阔度、土壤全磷含量和坡度是影响植物群落构建的关键环境因子。多数功能性状的系统发育信号很低且不显著, 说明热带云雾林群落的系统发育关系与功能性状随历史进程变化不一致。RaoQ和MPD的实际观测值都显著低于期望值, 且其标准效应值与土壤磷含量显著相关, 说明生境过滤是驱动热带云雾林群落构建的关键因子, 土壤磷含量是群落构建的关键环境筛。     

毛乌素沙地植被不同恢复阶段植物群落物种多样性、功能多样性和系统发育多样性

进入21世纪以来, 中国荒漠化恢复取得显著成效, 荒漠化、沙化土地面积持续减少, 植被覆盖度大幅提升, 但关于植被恢复过程中生物多样性如何变化的研究不足, 这制约着对荒漠化恢复成效的全面评估。本文基于群落调查和叶功能性状(叶片厚度、叶片干物质含量、比叶面积和叶片密度)的测定, 分析了毛乌素沙地不同恢复阶段(半固定沙地、固定沙地、结皮覆盖沙地和草本植物覆盖沙地)的植物群落物种多样性、功能多样性和系统发育多样性特征。结果表明: (1)多数叶功能性状的系统发育信号不显著, 表明环境因子对研究区植物功能性状的塑造作用很强。(2)对于α多样性, 结皮覆盖沙地的物种多样性(Shannon-Wiener多样性, H)、物种丰富度(S)、功能丰富度(FRic)及系统发育多样性(PD)指数均显著低于其他恢复阶段, 而其他3个阶段间无显著差异; 这些指数间均显著正相关, 表明物种多样性、功能多样性和系统发育多样性在植被恢复过程中协同变化。(3) β多样性指数随恢复阶段间隔增加而逐渐增大, 表明物种组成、功能属性及系统发育关系随植被恢复持续变化, 且半固定沙地到固定沙地的群落物种组成、功能属性及系统发育关系更替最快, 导致群落间差异最大。(4)固定沙地、结皮覆盖沙地和草本植物覆盖沙地群落系统发育结构均趋向于发散, 表明竞争排斥是群落构建的主要驱动力; 而半固定沙地群落系统发育结构无一致规律, 表明群落构建可能受到生境过滤和竞争排斥的综合作用。研究结果可为植被建设与管理提供参考, 为毛乌素沙地生态保育和生物多样性的保护提供科学依据。     

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     

退化草地物种种内和种间功能性状变异对放牧的响应

研究草地植物功能性状变异对放牧干扰的响应机制,有助于解析草地生态系统群落构建和功能多样性维持机制及植物对环境的适应及权衡策略。以科尔沁沙地退化草地为对象,研究围封和放牧草地物种多种功能性状(植株高度、根系长度、叶面积、根面积、叶片干物质含量、地上干物质含量、根系干物质含量、比叶面积、比根长和根冠比)变异特征及其对放牧干扰的响应机制。结果表明: 退化草地物种种间性状变异明显高于种内变异,种间性状变异对总体变异的贡献率占比高达70.2%～95.1%,而种内变异仅为4.9%～29.8%,但群落构建中物种的种内变异仍不可忽视。放牧草地物种种间性状变异低于围封草地,且放牧草地种内变异增加而种间变异减小。放牧导致不耐牧的优良禾本科牧草叶面积和叶片干物质含量下降而比根长增加,但耐牧的杂类草则通过增加叶面积和叶片干物质含量并降低比根长来提高在群落中的优势地位。退化草地对放牧响应较为敏感的功能性状有叶面积、叶片干物质含量、比根长和比叶面积。植物叶片性状和根系性状自身及彼此间均呈显著正相关,但放牧会增强根系性状的协同效应而减弱叶片性状的协同效应。说明放牧会驱动植物个体和种群功能性状权衡策略发生改变,进而起到调控植物群落结构和功能的作用。     

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。     

基于功能性状及系统发育的亚高寒草甸群落构建北大核心CSCD

为了解甘南藏族自治州亚高寒草甸植物群落在坡向梯度上的构建机制,该文选取5个坡向的样地,构建了植物群落系统发育树,测定了各坡向土壤环境因子和植物叶片的功能性状,检验了叶片功能性状的系统发育信号。结果表明:坡向变化对土壤含水量、土壤养分含量影响显著。大部分植物的叶片特征在不同坡向的差异显著,叶片干物质含量在南坡、西南坡较高,比叶面积和叶片氮、磷含量在北坡和西北坡较高。叶片的磷含量具有微弱的系统发育信号,而叶片干物质含量、比叶面积、叶片的氮含量均没表现出显著的系统发育信号。从南坡到北坡,群落的系统发育结构由发散到聚集。生境过滤作用是南坡、西南坡群落构建的驱动因素,种间竞争是北坡和西北坡群落构建的主要驱动力。西坡系统发育指数相反,其构建机制比较复杂,可能是几种机制共同作用的结果。     

Above- and belowground trait linkages of dominant species shape responses of alpine steppe composition to precipitation changes in the Tibetan Plateau

青藏高原高寒草原植物群落对降雨的响应依赖于优势种的功能性状 人类活动和全球变化引起了全球和区域降雨格局的改变。大量的研究表明，降雨影响全球不同草地生态系统的群落组成，但目前很少有研究从物种水平揭示高寒草原植物群落如何响应降雨变化的生态学过程。本研究利用在青藏高原建立的长期(6年)控雨试验平台，包括减少降雨50%、增加降雨50%和对照3个处理，从优势种地上和地下性状揭示高寒草原植物群落响应降雨变化的生态学过程。研究结果表明，长期减少降雨改变了植物群落的结构，主要体现在优势种丛生禾草紫花针茅(Stipa purpurea)逐渐被根茎禾草赖草(Leymus secalinus)所取代。进一步通过比较紫花针茅和赖草的地上和地下性状，发现减少降雨主要促进了赖草根系向深土层的生长、增加了地下碳的分配和减少了叶片宽度，而紫花针茅的这些性状并没有发生显著的改变；另外，减少降雨增加了赖草根茎生物量、总长度、直径及其节上根的数目。赖草这些性状的改变可能增加了对深土层水分的利用能力，以及减少了水分的蒸腾，从而增强了其在干旱胁迫过程中的竞争力。因此，我们的研究结果强调了优势种的地上和地下性状在高寒草原植物群落组成对降雨变化响应过程中起着极其重要的作用。     

基于功能性状及系统发育的亚高寒草甸群落构建

为了解甘南藏族自治州亚高寒草甸植物群落在坡向梯度上的构建机制,该文选取5个坡向的样地,构建了植物群落系统发育树,测定了各坡向土壤环境因子和植物叶片的功能性状,检验了叶片功能性状的系统发育信号。结果表明:坡向变化对土壤含水量、土壤养分含量影响显著。大部分植物的叶片特征在不同坡向的差异显著,叶片干物质含量在南坡、西南坡较高,比叶面积和叶片氮、磷含量在北坡和西北坡较高。叶片的磷含量具有微弱的系统发育信号,而叶片干物质含量、比叶面积、叶片的氮含量均没表现出显著的系统发育信号。从南坡到北坡,群落的系统发育结构由发散到聚集。生境过滤作用是南坡、西南坡群落构建的驱动因素,种间竞争是北坡和西北坡群落构建的主要驱动力。西坡系统发育指数相反,其构建机制比较复杂,可能是几种机制共同作用的结果。     

荒漠区植被对地下水埋深响应研究进展

荒漠区植被包括以旱生植物为主的荒漠植被和以中生植物为主的荒漠河岸林。综述了荒漠区植被对地下水埋深在个体、种群、群落以及斑块尺度上响应的研究成果,指出:荒漠区植物对地下水埋深的响应并不是简单的线性关系,而是植物适应气候、土壤、地下水等环境因素综合作用的结果,应在地下水与植被达到平衡态的基础上充分考虑生境土壤异质性、植被可塑性并采用长期定位和控制试验相结合的方法进行综合研究。强调在今后的研究中,加强同位素示踪技术和高光谱遥感技术的应用,开展植物水力提升及其机理研究;加强荒漠区植被对地下水响应机理研究特别是微观尺度(分子水平)和响应过程长期定位研究;重视植被响应地下水位波动和水质变化的研究;强化在景观尺度和生态系统尺度集成研究,以便为管理包括地下水在内的荒漠生态系统提供依据。     

物种多样性及生物量与地下水位的关系——以海流兔河流域为例

以3条样带上117块植被群落调查样方为基础资料,研究了海流兔河流域植被物种多样性及生物量与地下水位之间的关系。结果表明:1)地下水位高低及地貌类型均会影响草本层植物群落组成及优势种构成。滩地样地中,随地下水位降低,优势草本的更替方向为寸草,芨芨草,马蔺,狗尾草,碱茅;沙坡样地中,优势草本的更替方向为大针茅,沙鞭,沙蓬,沙打旺。2)地下水位为1.5 m时是草本植物群落生长发育最适宜区域,物种多样性及丰富度达到最大,而灌木层物种多样性及丰富度随地下水位下降呈现波动变化的特征;当地下水位埋深小于5.0 m时,草本层物种多样性及丰富度明显高于灌木层,在地下水位埋深大于5.0 m时,草本层物种多样性指数开始出现低于灌木层的现象。3)草本植物多样性及丰富度和生物量之间关联性不强,滩地样地中,草本层地上生物量及地下生物量在地下水位为1.8 m时具有最大值,但植物群落结构较为单一;沙坡样地中,地上生物量最大值出现在地下水位为5.0 m的区域内,而地下生物量最大值出现在地下水位为3.5 m时。综上,物种多样性、地上及地下生物量与地下水位都不是简单的线性关系,而是有一个最适水位;高于或低于这个最适水位,多样性和生物量都会下降。     

天山南麓山前平原植物群落物种多样性及空间分异研究

荒漠灌丛是天山南麓山前平原主要植被类型.本研究定量分析了山前平原植物群落物种多样性及生境尺度异质性的影响.结果表明:(1)天山南麓山前平原的植物群落多样性指数Simpson、均匀度指数McIntosh及丰富度指数Margalef都较低,在地貌带的过渡上,植物分布呈现均匀化.(2)海拔和地下水埋深是影响天山南麓山前平原植物群落物种多样性的重要环境指标.海拔梯度与物种多样性指数Simpson、Margalef及McIntosh均呈显著的线性正相关关系,物种多样性均随海拔高度的增加而增加;地下水埋深与物种多样性指数呈极显著的线性负相关关系,物种多样性随地下水埋深的增加而减小.(3)土壤含盐量与物种多样性指标无显著关系,但土壤含盐量与地下水埋深相关性显著,这是天山南麓山前平原土壤盐分空间异质性的一个重要特点.土壤盐分含量变化影响着植物群落物种组成,随土壤盐分含量增加,群落中盐生植物种类逐渐占据优势.(4)海拔的变化是决定天山南麓山前平原灌丛群落生境差异的主导因子.海拔差异表征了山前平原地貌、水文地质条件及土壤的变化,而随海拔变化的水热、水盐等干扰体系的差异则进一步导致了异质性的生境,进而影响不同植被类型中群落组成结构和多样性的差异.     

Effect of groundwater depth on riparian plant diversity along riverside-desert gradients in the Tarim River

Aims Riparian plant diversity is sensitive to changes in groundwater in arid regions. However, little is known about how plant diversity responds to changes in environment along riverside-desert gradients in riparian ecosystem. Our objectives were to (i) identify riparian plant diversity along riverside-desert gradients in Tarim desert riparian forests, (ii) analyze the impact of environment variables on plant diversity, (iii) determine the optimum groundwater depth for different plant life-forms.     

Plant Species Numbers Predicted by a Topography-based Groundwater Flow Index

The lack of a clear understanding of the factors governing the often-great variation of species numbers over entire landscapes confounds attempts to manage biodiversity. We hypothesized that in a topographically variable boreal forest landscape the availability of shallow groundwater is a major determinant of plant species numbers. We then developed a topographically derived hydrologic index based on multidirectional flow algorithms to account for the variation in availability of such groundwater in the landscape. We found a positive correlation between species numbers of vascular plants in plots ranging from 0.01 to 200 m² and the hydrologic index. Generally, the landscape was relatively dry and species-poor, but interspersed patches with shallow groundwater had high species numbers and high proportions of regionally uncommon plant species. The index explained 30% of the variation in vascular plant number and correlated quite well (r_s = 0.50) with groundwater level, but not as well with a community H⁺ concentration value (instead of community pH, r_s = −0.31), based on species composition. In addition, we found a very strong correlation between species number and the community H⁺ concentration value (r_s −0.84). The hydrologic index is a useful tool for the identification of spatial of species number patterns across entire landscapes. This is an important step in identifying the areas most in need of protection or restoration, designing survey techniques, and understanding the fundamental processes that control the spatial distribution of species.     

Priority effects: How the order of arrival of an invasive grass,Bromus tectorum,alters productivity and plant community structure when grown with native grass species

Theories and models attempt to explain how and why particular plant species grow together at particular sites or why invasive exotic species dominate plant communities. As local climates change and human‐use degrades and disturbs ecosystems, a better understanding of how plant communities assemble is pertinent, particularly when restoring grassland ecosystems that are frequently disturbed. One such community assembly theory is priority effects, which suggests that arrival order of species into a community alters plant–plant interactions and community assembly. Theoretically, priority effects can have lasting effects on ecosystems and will likely be altered as the risk of invasion by exotic species increases. It is difficult to predict how and when priority effects occur, as experimental reconstruction of arrival order is often difficult in adequate detail. As a result, limited experimental studies have explored priority effects on plant community assembly and plant invasions. To determine if and how priority effects affect the success of invasive species, we conducted a greenhouse study exploring how the arrival order of an invasive grass, Bromus tectorum, affects productivity and community composition when grown with native grasses. We found evidence for priority effects, as productivity was positively related to dominance of B. tectorum and was greater the earlier B. tectorum arrived. This suggests that priority effects could be important for plant communities as the early arrival of an invasive species drastically impacted the productivity and biodiversity of our system at the early establishment stages of plant community development.     

草原露天煤矿区植被对地下水位埋深变化的响应

草原采矿活动疏排地下水导致区域地下水位下降,植被退化严重。明确草原采矿活动影响区域地下水位埋深的强度和范围,确定影响植被生长的地下水位埋深阈值,对草原矿区生态环境保护有着重要意义。以呼伦贝尔草原伊敏露天煤矿为例,利用遥感方法,建立采矿前后区域地下水埋深变化与NDVI的定量响应关系;通过样方调查,确定研究区植被群落随地下水位埋深变化的演替模式,分析草原矿区地下水位变化对草原植被类型、物种丰富度、植被覆盖度、地上生物量和综合优势比的影响;结合两种方法,确定维持研究区植被正常生长的地下水位埋深阈值。其结果如下：从柴达敏诺尔湖至采坑边缘,地下水位埋深从0 m逐渐下降至60 m,植被群落演替为盐化草地→典型草原→退化典型草原→退化草甸草原→盐化草甸草原;研究区最适宜植被生长的地下水位埋深约为1 m;1-30 m为维持研究区植被正常生长的阈值地下水位埋深。最后根据以上结论,将研究区划分为地下水开发的一级敏感区、二级敏感区和三级敏感区,针对不同敏感区提出了不同的地下水开发政策,以防止采矿活动疏排地下水引起草原退化。     

Climate change effects on plant biomass alter dominance patterns and community evenness in an experimental old‐field ecosystem

Atmospheric and climatic change can alter plant biomass production and plant community composition. However, we know little about how climate change‐induced alterations in biomass production affect plant species composition. To better understand how climate change will alter both individual plant species and community biomass, we manipulated atmospheric [CO₂], air temperature, and precipitation in a constructed old‐field ecosystem. Specifically, we compared the responses of dominant and subdominant species to our climatic treatments, and explored how changes in plant dominance patterns alter community evenness over 2 years. Our study resulted in four major findings: (1) all treatments, elevated [CO₂], warming, and increased precipitation increased plant community biomass and the effects were additive rather than interactive, (2) plant species differed in their response to the treatments, resulting in shifts in the proportional biomass of individual species, which altered the plant community composition; however, the plant community response was largely driven by the positive precipitation response of Lespedeza, the most dominant species in the community, (3) precipitation explained most of the variation in plant community composition among treatments, and (4) changes in precipitation caused a shift in the dominant species proportional biomass that resulted in lower community evenness in the wet relative to dry treatments. Interestingly, compositional and evenness responses of the subdominant community to the treatments did not always follow the responses of the whole plant community. Our data suggest that changes in plant dominance patterns and community evenness are an important part of community responses to climatic change, and generally, that such compositional shifts can alter ecosystem biomass production and nutrient inputs.     

Enhanced biotransformation of TCE using plant terpenoids in contaminated groundwater

Aims:  To examine plant terpenoids as inducers of TCE (trichloroethylene) biotransformation by an indigenous microbial community originating from a plume of TCE-contaminated groundwater.
Methods and Results:  One-litre microcosms of groundwater were spiked with 100 μmol 1⁻¹ of TCE and amended weekly for 16 weeks with 20 μl 1⁻¹ of the following plant monoterpenes: linalool, pulegone, R-(+) carvone, S-(−) carvone, farnesol, cumene. Yeast extract-amended and unamended control treatments were also prepared. The addition of R-carvone and S-carvone, linalool and cumene resulted in the biotransformation of upwards of 88% of the TCE, significantly more than the unamendment control (61%). The aforementioned group of terpenes also significantly ( P  < 0·05) allowed more TCE to be degraded than the remaining two terpenes (farnesol and pulegone), and the yeast extract treatment which biotransformed 74–75% of the TCE. The microbial community profile was monitored by denaturing gradient gel electrophoresis and demonstrated much greater similarities between the microbial communities in terpene-amended treatments than in the yeast extract or unamended controls.
Conclusions:  TCE biotransformation can be significantly enhanced through the addition of selected plant terpenoids.
Significance and Impact of the Study:  Plant terpenoid and nutrient supplementation to groundwater might provide an environmentally benign means of enhancing the rate of in situ TCE bioremediation.     

Consequences of variation in plant defense for biodiversity at higher trophic levels

Antagonistic interactions between insect herbivores and plants impose selection on plants to defend themselves against these attackers. Although selection on plant defense traits has typically been studied for pairwise plant-attacker interactions, other community members of plant-based food webs are unavoidably affected by these traits as well. A plant trait might, for example, affect parasitoids and predators feeding on the herbivore. Consequently, defensive plant traits structure the diversity and composition of the complex community associated with the plant, and communities as a whole also feed back to selection on plant traits. Here, we review recent developments in our understanding of how plant defense traits structure insect communities and discuss how molecular mechanisms might drive community-wide effects.