水蚀风蚀交错区柠条锦鸡儿叶片比叶面积和营养元素变化动态

通过对黄土高原水蚀风蚀交错区主要生长月份柠条锦鸡儿(Caragana korshinlii Kom.)叶片比叶面积(SLA)和矿质元素含量的测定,探讨其对生境条件及生长时间的响应规律,结果表明:不同生境柠条锦鸡儿叶片SLA随生长月份的变化趋势基本一致,但变化差异不显著;不同生境叶片有机碳(C)含量变化差异不显著;叶片全氮(N)含量、全钾(K)含量对生长月份的变化响应明显,变异幅度较大,而随生境条件发生的变异较小;叶片全磷(P)含量在不同生境随着生长月份发生的变异较大。不同生境叶片N/P随月份发生的变异较大、C/P的变异较小;叶片C/N、C/K在不同生境间无明显差异,但均随生长月份而产生较大变化,叶片N、P、K的含量与SLA相关性不明显。所以,生境条件和生长时间是柠条锦鸡儿叶片结构特性和养分组成发生变化的重要原因,其叶片比叶面积与矿质养分含量受外界环境因子和自身发育状况的共同调控。     

基于地理种源的刨花楠苗木比叶面积与叶片化学计量学关系

探讨植物比叶面积(SLA)与叶片碳(C)、氮(N)、磷(P)化学计量学关系,能够反映植物为获取最大光合生产所采取的内部调控机制,共同体现植物的适应策略。利用生长于同一土壤与气候环境中培育的刨花楠(Machilus pauhoi)1年生苗木,对其SLA与叶片C、N、P含量进行测定,并对SLA与叶片C、N、P化学计量学特征及其与种源地环境因子的关系进行分析。结果表明:(1)叶片养分含量的变异系数大小排序为CNP;SLA与叶片N、P含量呈显著的正相关,与叶片C∶N及C∶P呈极显著的负相关。(2)SLA与经度、年均温、年降水量呈显著负相关;叶片C、N、P含量也受种源地环境因子影响,其中以海拔最为重要。研究结果有助于理解刨花楠苗木的生存适应对策,对探究刨花楠对养分的资源利用效率等具有重要意义。     

黄土高原水蚀风蚀交错带不同生境植物的叶性状

研究不同生境和不同植被演替阶段的叶性状,将为区域植被建设提供重要科学指导。以黄土高原水蚀风蚀交错带的典型区——神木六道沟流域为研究地点,研究了不同生境植物叶性状的种间和种内差异、退耕地植被演替过程中叶性状的变化及其相互关系。结果表明:(1)不同生境植物的光合特征和叶片结构特征的种间差异较大,这可能是植物长期适应生态环境的结果,同时也与其本身固有的遗传特性有关。(2)在物种水平上,最大光合速率(Pmax)、光合氮素利用效率(PNUE)和比叶面积(SLA)随退耕年限的增加呈显著下降趋势,而水分利用效率(WUE)、叶氮含量(Nmass)与退耕年限相关关系不显著。在群落水平上,除SLA与退耕年限的相关性不显著以外,其它指标皆与物种水平的变化趋势一致。(3)研究区32个物种的Pmax与WUE、PNUE、Nmass呈显著正相关(P0.05),而与SLA的相关关系不显著。PNUE与WUE、SLA呈显著正相关(P0.001),而与Nmass的相关性不显著;物种的Nmass与SLA呈显著正相关(P0.001)。同其它地区相比,研究区物种的Pmax、PNUE、SLA较低。具有较低Pmax、PNUE、SLA的物种可能更适宜研究区土壤贫瘠的生境。     

五大连池新期火山熔岩台地3种共有植物的叶功能性状及其相互关系

以五大连池新期火山熔岩台地13个稳定的自然植物群落共有种香杨、万年蒿、岩败酱为研究对象,测定其叶干物质含量(LDMC)、比叶面积(SLA)、叶氮含量(LNC)、叶磷含量(LPC)、叶氮磷比(N/P)等叶功能性状,研究不同生境下3种植物叶功能性状的变异特征,探讨新期火山熔岩台地植物叶功能性状相互之间的内在联系及其对环境的适应性。结果表明:(1)3种植物LDMC变化在0.294~0.359g·g~(-1)之间,SLA变化在9.082~22.347m2·kg~(-1)之间;与其他区域的研究结果相比,新期火山熔岩台地植物的LDMC值相对偏大、SLA值相对偏小,说明五大连池新期火山熔岩台地的植物采用高LDMC低SLA策略适应贫瘠恶劣的环境。(2)3种植物LNC变化在9.690~15.710g·kg~(-1)之间,LPC变化在0.669~1.078g·kg~(-1)之间,叶钾含量(LKC)变化在10.410~29.830g·kg~(-1)之间,叶N/P的变化在9.781~20.990之间;与其他区域的研究结果相比,新期火山熔岩台地植物LNC和LPC值相对偏小,LKC和N/P值相对偏大,说明五大连池新期火山熔岩台地的植物生长主要受磷素的限制,而且LNC偏小和LKC偏高与新期火山熔岩台地土壤中全N、全K的含量变化特征有关。(3)通过ANVOA分析发现,群落间植物叶功能性状的变异幅度较小,3种植物之间N/P、LDMC和SLA的变异幅度也较小,这说明在水分和养分极缺的火山熔岩台地植物对其生境的适应对策相似。(4)Pearson相关分析发现,SLA与LDMC以及N/P与LDMC和SLA均呈显著负相关关系。     

滨海沙地主要造林树种叶片功能性状及养分重吸收特征

为探讨不同树种对滨海沙地干旱贫瘠环境的适应策略,以滨海沙地主要造林树种木麻黄、湿地松、厚荚相思和尾巨桉为对象,研究了不同树种叶片功能性状及养分重吸收特征.结果表明:阔叶树种(厚荚相思和尾巨桉)的叶面积、比叶面积显著高于针叶树种(木麻黄和湿地松),而针叶树叶干物质含量、叶厚度最高.成熟叶和凋落叶的N、P含量表现为阔叶树高于针叶树,成熟叶高于凋落叶,但凋落叶N∶P较高.针叶树种的N、P养分重吸收效率大于阔叶树种,P重吸收效率明显高于N,木麻黄、湿地松、厚荚相思和尾巨桉的N、P吸收效率分别为64.2%、63.1%、47.0%、16.8%和92.5%、81.6%、80.3%、18.0%.比叶面积与叶片N、P含量呈显著正相关,与叶干物质含量,叶厚度以及N、P养分重吸收效率呈显著负相关;叶干物质含量与叶厚度及N、P养分重吸收效率呈显著正相关.就叶片功能的权衡关系而言,木麻黄和湿地松属于缓慢投资-收益型物种,具有较高的养分重吸收效率,而厚荚相思和尾巨桉属于快速投资-收益型物种,养分的重吸收效率较低.不同滨海沙地造林树种通过叶片功能性状及养分重吸收之间的相互协调实现对滨海沙地特殊生境的适应性.     

甘南高寒草甸植物元素含量与土壤因子对坡向梯度的响应

通过测定甘南高寒草甸不同坡向条件下25科86种植物叶片氮(N)、磷(P)、钾(K)含量、有机碳(C)含量、叶片含水量和相对叶绿素(SPAD)值,以及不同坡向的土壤含水量、有机碳、全氮、全磷含量等土壤指标,分析了不同坡向植物叶片元素含量与土壤环境因子之间的关系。研究结果表明,在南坡-北坡梯度上,随着土壤含水量的增加,植物叶片P含量、叶K含量和叶片含水量显著增加,而相对叶绿素显著降低。土壤养分含量与植物叶片P、叶K含量和叶含水量显著正相关,与叶片相对叶绿素显著负相关。说明不同坡向条件下叶片养分含量受土壤因子的影响显著,土壤的水分及养分状况对植物叶片元素含量的贡献不同。土壤含水量是坡向梯度上影响植物叶片特征的最主要因子。坡向梯度上土壤含水量对植物叶片各种元素含量的影响和植物叶片含水量对不同土壤因子的响应模式支持了生长在南坡的植物能以提高水分和养分利用效率而适应南坡较为干旱和贫瘠的生境。     

黄土高原退耕还草地C、N、P生态化学计量特征对植物多样性的影响

为探讨退耕还草地生态化学计量特征随恢复年限的变化以及其对植物多样性的影响,选取黄土高原不同恢复年限退耕还草地为研究对象,分别为农田（对照）、恢复8 a、15 a、25 a和35 a,测定了植物地上部分和土壤C、N、P含量,并分析了其C：N：P化学计量特征与植物多样性之间的关系。结果表明：（1）总体上,随着恢复年限的增加,植物地上部分C、N、P含量呈现增长趋势,而其C：N、C：P以及N：P呈现降低趋势,其中C含量在恢复35 a时达到最大值（434.95 g/kg）;N含量在农田阶段最高（2.29 g/kg）,P含量在恢复25 a时达到最高（1.23 g/kg）。（2）土壤C、N、P含量及N：P随恢复年限的增加总体上呈现增加趋势,C：N呈现降低趋势,而C：P基本保持不变;土壤C、N、P含量的最大值均出现在恢复35 a,其值分别为10.94 g/kg、0.07 g/kg、0.06 g/kg。（3）随着植物地上部分C含量和C：N的增加,Shannon-Weiner指数降低;植物地上部分C含量和土壤P含量是影响Simpson指数的主要因子,其与植物地上部分C含量负相关,而与土壤P含量显著正相关;Pielou均匀度指数与土壤N含量、N：P、C：P以及植物地上部分C含量等因子正相关;Margalef指数与植物地上部分N含量、P含量等因子正相关。研究表明草地恢复中植物和土壤C：N：P化学计量特征对植物多样性具有重要的影响。     

水分对敦煌阳关湿地芦苇叶片与土壤C、N、P生态化学计量特征的影响

土壤水分是影响干旱区植物养分吸收和利用策略的关键因子之一。研究不同水分梯度叶片与土壤生态化学计量特征,有助于揭示植物对环境变化的响应特征及生态适应性。通过野外调查与实验分析,对敦煌阳关不同水分梯度芦苇叶片与土壤碳(C)、氮(N)、磷(P)生态化学计量特征及其关系进行了研究。结果表明:(1)随土壤含水率升高,叶片C、N、P含量降低,叶片C/N、C/P、N/P升高。(2)随土壤含水率升高,土壤有机碳(OC)、总氮(TN)、总磷(TP)含量及土壤N/P升高,土壤C/N降低,土壤C/P先升后降。(3)低水分梯度叶片N、C/N与土壤N、C/N显著负相关(P0.05),叶片C、P、C/P、N/P与土壤C、P、C/P、N/P无显著相关性(P0.05);高、中水分梯度叶片C、N、P与土壤C、N、P化学计量特征相关性均不显著(P0.05)。低水分梯度叶片受干旱胁迫和土壤养分制约,且能够保持较高的叶养分含量,体现了干旱区湿地植物异质生境下独特的养分调节机制。     

荒漠植物红砂(Reaumuria soongorica)叶片元素和水分含量与土壤因子的关系

通过测定中国境内荒漠植物红砂(Reaumuria soongorica)主要分布区21个自然种群407个植株叶片的氮(N)、磷(P)、钾(K)含量、有机质和叶片含水量,以及不同种群内土壤含水量、可溶性盐分含量、有机质、全氮、全磷含量等土壤理化性状指标,分析不同自然种群红砂叶片元素含量与土壤环境因子之间的关系.研究结果表明,随着不同土壤层含水量的增加,红砂叶片N含量和叶片含水量显著增加,而叶片K含量显著降低.土壤养分含量、可溶性盐分含量与红砂叶片P含量显著正相关,与叶片含水量显著负相关.随着土壤pH值的增加,红砂叶片N含量显著下降,叶片含水量显著增加.说明不同自然种群中红砂叶片养分含量受土壤状况的影响显著,不同土壤理化性状指标对红砂叶片元素含量的贡献显著不同.土壤水分含量是生境中影响红砂叶片特征的最关键因子,而红砂叶片含水量则最易受各种土壤理化性状的影响.生境中土壤含水量对红砂各种元素含量的影响和红砂叶片含水量对不同土壤条件的这种响应模式支持了红砂是一种以提高水分利用效率而适应于极端干旱生境的典型超旱生植物.     

半干旱黄土小流域不同植被类型植物与土壤生态化学计量特征

生态化学计量学是研究生态系统元素平衡与能量流动的有效方法,明确不同植被恢复类型下植物与土壤化学计量特征对揭示黄土高原植被恢复中生态系统养分循环具重要意义,可为黄土高原植被恢复类型的选择提供可行性依据。以典型半干旱黄土小流域3种植被恢复方式下（天然荒草、自然恢复、人工恢复）的5种植被类型（长芒草草地、赖草草地、苜蓿草地、柠条灌丛、山杏林）为研究对象,分析不同植被类型下叶、茎、根及土壤碳（C）、氮（N）、磷（P）含量及化学计量特征。结果表明：1）植物不同器官和植被类型对植物生态化学计量特征都具有显著影响,C、N、P含量在5种典型植被中均表现为叶>茎>根。人工恢复植被各器官C、N含量及N ∶ P均显著高于天然荒草地,与自然恢复植被无显著差异;其中,在人工恢复植被中山杏各器官C含量最高,柠条各器官N含量最高。叶、茎、根的C ∶ N则表现为自然恢复植被显著高于人工恢复植被与天然荒草地。P含量、C ∶ P则在不同植被恢复类型间无显著差异。2）不同植被恢复类型下土壤C、N、P含量及化学计量特征具一定差异。人工恢复植被土壤C、N、P含量及C ∶ P、N ∶ P均为最高,显著高于自然恢复植被土壤;人工恢复植被中柠条土壤C、N含量及C ∶ P、N ∶ P均显著高于其他植被土壤。土壤C ∶ N在各植被类型间无显著差异。3）不同植被恢复类型下C、N、P含量在植物叶片与土壤间的相关性存在差异,说明植物自身生长特性影响着养分在植物与土壤间转化与传递。以5种典型植被整体来看,植物叶、茎、根的生态化学计量特征在彼此间均呈显著正相关。在植物与土壤间,植物各器官N含量与土壤C、N、P含量呈显著正相关,植物各器官N ∶ P与土壤N ∶ P呈显著正相关,表明该黄土小流域生态系统中植物与土壤生态化学计量特征的变化是相互制约,相互影响的。     

Variations in leaf morphological and chemical traits in response to life stages,plant functional types,and habitat types in an old-growth temperate forest

Intraspecific leaf trait variations are becoming a topic of interest for many ecologists because individual-based traits are essentially the drivers of variations at the community level. Six coexisting major tree species in an old-growth temperate forest, Northeast China (i.e., Abies nephrolepis, Pinus koraiensis, Acer mono, Fraxinus mandshurica, Tilia amurensis, and Ulmus laciniata) were sampled, and three habitat types (i.e., Hab I: high soil organic carbon with a moderate slope; Hab II: low soil organic carbon with a gentle slope; and Hab III: low soil organic carbon with a strong slope) were used in the plot. We performed a two-way ANOVA to compare the specific leaf area (SLA), leaf dry matter content (LDMC), leaf nitrogen content (LNC), leaf phosphorus content (LPC), and leaf carbon content (LCC) between saplings (1 < DBH ≤ 5 cm) and adults (DBH ≥ 10 cm) and between habitat types within species. We simultaneously evaluated the effects of life stage, plant functional type, and habitat type on the six leaf traits. Our results showed that life stage and habitat type had varied influences on the leaf traits of the six species. Life stage was an important determinant for all leaf traits. Plant functional type was included in the best models for SLA, LNC, and LCC. Habitat type had a greater influence on LDMC than SLA. Meanwhile, habitat type had a greater influence on LNC and LPC than LCC. The correlation between leaf traits with local environmental factors varied across different plant functional types and life stages. We suggest conducting individual-based analyses of leaf trait variations according to plant functional type and life stage to understand the plant life strategies along an environmental gradient may improve understanding of the forest dynamics in an old-growth temperate forest.     

重庆石灰岩地区主要木本植物叶片性状及养分再吸收特征

以重庆石灰岩地区15种常绿木本植物和14种落叶木本植物为研究对象,对两种生活型植物叶片衰老前后叶干物质含量(LDMC)、比叶面积(SLA)和叶片厚度(LT)进行了比较,并采用不同的计算方法(单位质量叶片养分含量、单位面积叶片养分含量)分析了两类植物叶片衰老前后养分含量及再吸收特征,最后对养分再吸收效率与其他叶性状因子之间的关系进行了相关分析。结果表明:常绿植物成熟叶LDMC、LT及衰老叶LT显著低于落叶植物,落叶植物成熟叶和衰老叶SLA均显著高于常绿植物(P0.05);基于单位质量叶片计算的养分含量,常绿植物成熟和衰老叶N、P量均低于落叶植物,而基于单位面积叶片计算的N、P含量则表现出相反的趋势;基于不同方法计算的N、P再吸收效率差异不明显,其中常绿植物基于单位质量叶片养分含量计算的N、P平均再吸收效率为39.42%、43.79%,落叶植物的为24.08%、33.59%;常绿和落叶植物N、P再吸收效率与LDMC、SLA、LT和成熟叶N、P含量之间没有显著相关性,但与衰老叶养分含量存在显著负相关(P0.05)。研究发现,无论是常绿植物还是落叶植物,衰老叶N、P含量均较低,表明石灰岩地区植物具有较高的养分再吸收程度。     

Drivers of within-tree leaf trait variation in a tropical planted forest varying in tree species richness

In plant ecology, community-weighted trait means are often used as predictors for ecosystem functions. More recently, also within-species trait variation has been confirmed to contribute to ecosystem functioning. We here go even further and assess within-individual trait variation, assuming that every leaf in a plant individually adjusts to its micro-environment. Using forest plots varying in tree species richness (Sardinilla experiment, Panama), we analysed how leaf traits within individual trees vary along the vertical crown gradient. Furthermore, we tested whether niche partitioning in mixed stands results in a decrease of within-species leaf trait variation and whether niche partitioning can be also observed at the level of individual trees. We focused on leaf traits that describe the growth strategy along the conservative-acquisitive spectrum of growth. We found a decrease in within-species variation of specific leaf area (SLA) with increasing neighbourhood species richness. Both sampling height and local neighbourhood richness contributed to explaining within-species leaf trait variation, which however, varied in importance among different species and traits. With increasing sampling height, leaf dry matter content (LDMC), carbon to nitrogen ratio and lignin content increased, while leaf nitrogen concentration (leaf N), SLA, cellulose and hemicellulose decreased. Variation in leaf N decreased with increasing neighbourhood species richness, while the magnitude of within-individual variation of most traits was unaffected by neighbourhood species richness. Our results suggest an increased niche partitioning with increasing species richness both in a plant community and at the level of individual plants. Our findings highlight the importance of including within-individual trait variation to understand biodiversity-ecosystem functioning relationships.     

Contrasting effects of plant inter‐ and intraspecific variation on community trait responses to restoration of a sandy grassland ecosystem

Changes in plant community traits along an environmental gradient are caused by interspecific and intraspecific trait variation. However, little is known about the role of interspecific and intraspecific trait variation in plant community responses to the restoration of a sandy grassland ecosystem. We measured five functional traits of 34 species along a restoration gradient of sandy grassland (mobile dune, semi‐fixed dune, fixed dune, and grassland) in Horqin Sand Land, northern China. We examined how community‐level traits varied with habitat changes and soil gradients using both abundance‐weighted and non‐weighted averages of trait values. We quantified the relative contribution of inter‐ and intraspecific trait variation in specific leaf area (SLA), leaf dry matter content (LDMC), leaf carbon content (LCC), leaf nitrogen content (LNC), and plant height to the community response to habitat changes in the restoration of sandy grassland. We found that five weighted community‐average traits varied significantly with habitat changes. Along the soil gradient in the restoration of sandy grassland, plant height, SLA, LDMC, and LCC increased, while LNC decreased. For all traits, there was a greater contribution of interspecific variation to community response in regard to habitat changes relative to that of intraspecific variation. The relative contribution of the interspecific variation effect of an abundance‐weighted trait was greater than that of a non‐weighted trait with regard to all traits except LDMC. A community‐level trait response to habitat changes was due largely to species turnover. Though the intraspecific shift plays a small role in community trait response to habitat changes, it has an effect on plant coexistence and the maintenance of herbaceous plants in sandy grassland habitats. The context dependency of positive and negative covariation between inter‐ and intraspecific variation further suggests that both effects of inter‐ and intraspecific variation on a community trait should be considered when understanding a plant community response to environmental changes in sandy grassland ecosystems.     

Ecological significance of leaf life span among Central European grass species

Interspecific variation in leaf life span reflects the variation in nutrient conservation ability among different plant species and is considered to be associated with nutrient availability in the characteristic habitat. As defoliation interferes with nutrient conservation by the long-lived leaves, we hypothesized that disturbance rate is another important environmental factor working as a selective force on interspecific variation in leaf life span. In order to investigate this, we measured leaf life span of 32 grass species in mature garden-grown individuals. Variation in leaf life span was compared to measured leaf traits, to available data on species occurrence along gradients of nutrient availability and disturbance, and to published relative growth rates of the species. Leaf life span was associated positively with leaf tissue mass density and negatively with specific leaf area. Leaf life span correlated negatively with the disturbance rate in the characteristic habitat of a species, but not with nutrient availability. The latter relationship did not come about due to the long leaf life spans of species from nutrient-rich habitats with a relatively low disturbance rate, and to some extent also due to the short leaf life spans of annual species from relatively nutrient-poor sites. We conclude that although leaf longevity is an important means of reducing nutrient losses, this is a selective advantage only if the plant is not subjected to frequent defoliation. The frequently postulated association between leaf life span of a species and nutrient availability in its characteristic habitat may occur among species of habitats with positively correlated nutrient availability and disturbance rate. Leaf life span is negatively associated with seedling RGR, but there may be deviations in this relationship due to species with contrasting characteristics at seedling stage and at maturity.     

Reprint of: Drivers of within-tree leaf trait variation in a tropical planted forest varying in tree species richness

In plant ecology, community-weighted trait means are often used as predictors for ecosystem functions. More recently, also within-species trait variation has been confirmed to contribute to ecosystem functioning. We here go even further and assess within-individual trait variation, assuming that every leaf in a plant individually adjusts to its micro-environment. Using forest plots varying in tree species richness (Sardinilla experiment, Panama), we analysed how leaf traits within individual trees vary along the vertical crown gradient. Furthermore, we tested whether niche partitioning in mixed stands results in a decrease of within-species leaf trait variation and whether niche partitioning can be also observed at the level of individual trees. We focused on leaf traits that describe the growth strategy along the conservative-acquisitive spectrum of growth. We found a decrease in within-species variation of specific leaf area (SLA) with increasing neighbourhood species richness. Both sampling height and local neighbourhood richness contributed to explaining within-species leaf trait variation, which however, varied in importance among different species and traits. With increasing sampling height, leaf dry matter content (LDMC), carbon to nitrogen ratio and lignin content increased, while leaf nitrogen concentration (leaf N), SLA, cellulose and hemicellulose decreased. Variation in leaf N decreased with increasing neighbourhood species richness, while the magnitude of within-individual variation of most traits was unaffected by neighbourhood species richness. Our results suggest an increased niche partitioning with increasing species richness both in a plant community and at the level of individual plants. Our findings highlight the importance of including within-individual trait variation to understand biodiversity-ecosystem functioning relationships.     

Species differences in carbon isotope ratios, specific leaf area and nitrogen concentrations in leaves of Eucalyptus growing in a common garden compared with along an aridity gradient

Leaves produced in 2004 of 422 species of Eucalyptus whose natural habitat is southern Australia were sampled at the Currency Creek Arboretum in South Australia where the annual (mainly winter) rainfall is about 400 mm. Tree height, leaf area, leaf dry weight, leaf nitrogen (N) concentration and leaf carbon isotope ratio (δ¹³C) were measured and the specific leaf area (SLA) calculated. Among the 422 species, the SLA varied from 1.5 to 8.8 m² kg^?1 and N concentration varied from 0.6 to 2.1%, much greater than in 64 species collected along an aridity transect from southwestern Western Australia to central Australia in 2003. Also, the range of leaf δ¹³C values was similar in the common garden to that across the aridity transect. For the 45 species present in both studies, the SLA and leaf N concentration in the common garden were similar to those measured in leaves along the aridity transect, indicating that these characteristics are inherent in the species and vary little with environment. The variation in leaf δ¹³C in the common garden was just as great as along the transect, but the values measured in the one location were poorly correlated with those along the transect. This was not expected, as the variation in δ¹³C at one common site in South Australia was anticipated to be less than along the aridity gradient where annual rainfall varied from 250 to 1200 mm. Path analysis on the 45 species common to both studies indicated that rainfall did not have a direct effect on δ¹³C, but the differences in δ¹³C resulted from indirect effects of rainfall on SLA and N concentration. δ¹³C was negatively correlated with SLA but positively correlated with N. Thus, both effects may compensate for each other so that no significant relationship between δ¹³C and rainfall was observable. However, there is a large degree of variation of δ¹³C at any level of rainfall. The origin and ecological implications of this observation are discussed.     

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。