Rhizome Severing Increases Root Lifespan of Leymus chinensis in a Typical Steppe of Inner Mongolia

Background

Root lifespan is an important trait that determines plants'' ability to acquire and conserve soil resources. There have been several studies investigating characteristics of root lifespan of both woody and herbaceous species. However, most of the studies have focused on non-clonal plants, and there have been little data on root lifespan for clonal plants that occur widely in temperate grasslands.

Methodology/Principal Findings

We investigated the effects of rhizome severing on overall root lifespan of Leymus chinensis, a clonal, dominant grass species in the temperate steppe in northern China, in a 2-year field study using modified rhizotron technique. More specifically, we investigated the effects of rhizome severing on root lifespan of roots born in different seasons and distributed at different soil depths. Rhizome severing led to an increase in the overall root lifespan from 81 to 103 days. The increase in root lifespan exhibited spatial and temporal characteristics such that it increased lifespan for roots distributed in the top two soil layers and for roots born in summer and spring, but it had no effect on lifespan of roots in the deep soil layer and born in autumn. We also examined the effect of rhizome severing on carbohydrate and N contents in roots, and found that root carbohydrate and N contents were not affected by rhizome severing. Further, we found that root lifespan of Stipa krylovii and Artemisia frigida, two dominant, non-clonal species in the temperate steppe, was significantly longer (118 d) than that of L. chinensis (81 d), and this value became comparable to that of L. chinensis under rhizome severing (103 d).

Conclusions/Significance

We found that root lifespan in dominant, clonal L. chinensis was shorter than for the dominant, non-clonal species of S. krylovii and A. frigida. There was a substantial increase in the root lifespan of L. chinensis in response to severing their rhizomes, and this increase in root lifespan exhibited temporal and spatial characteristics. These findings suggest that the presence of rhizomes is likely to account for the observed short lifespan of clonal plant species in the temperate steppe.     

草原植物根系起始吸水层深度测定方法及其在不同群落状态下的表现

通过比较实验导出用于研究草原群落中不同植物种群起始吸水层研究方法,暂称之为"土体挖空法"。该方法是将土壤剖面的下部挖空,保留上面0—5、0—10、0—15 cm的土层和上面的全部植物,当从地表浇的水在被挖空部分的向下表面开始渗出时测定哪些植物种群吸收了水分。实验中用于检验植物是否吸水的方法是用水势仪测定法。在内蒙古锡林郭勒盟白音锡勒牧场中国科学院草原生态系统定位研究站的实验样地上,通过对处于不同退化恢复演替阶段的草原群落中主要植物种群的研究得出以下结论:1)同一群落中不同植物种间根系起始吸水层存在差异,在恢复群落中存在根系起始吸水位置的生态位分离和重叠现象,其中黄囊苔草(Carex korshinskyi)、冷蒿(Artemisia frigida)、糙隐子草(Cleistogenes squarrosa)的起始吸水层位置表明它们在对土壤中水资源利用空间维上存在空间生态位重叠现象;羊草(Leymus chinensis)、大针茅(Stipa grandis)、米氏冰草(Agropyron michnoi)之间也存在类似的生态位重叠;两组植物种群间存在对土壤中水资源利用空间维上的空间生态位分离现象。2)无论是否退化的草原群落,其中黄囊苔草、冷蒿、糙隐子草的根系起始吸水层深度保持不变;在严重退化的群落中羊草、大针茅、米氏冰草同种个体的起始吸水层则变浅,即呈浅层化分布现象。退化群落中,植物体小型化和根系浅层化的同时植物根系对水分吸收的起始位置总体呈浅层化。3)典型草原群落中各植物种群间存在较大幅度的生态位重叠和一定的生态位分离,其中生态位分离的幅度较小,重叠的程度较大。     

Long-Term Nitrogen Addition Leads to Loss of Species Richness Due to Litter Accumulation and Soil Acidification in a Temperate Steppe

Background

Although community structure and species richness are known to respond to nitrogen fertilization dramatically, little is known about the mechanisms underlying specific species replacement and richness loss. In an experiment in semiarid temperate steppe of China, manipulative N addition with five treatments was conducted to evaluate the effect of N addition on the community structure and species richness.

Methodology/Principal Findings

Species richness and biomass of community in each plot were investigated in a randomly selected quadrat. Root element, available and total phosphorus (AP, TP) in rhizospheric soil, and soil moisture, pH, AP, TP and inorganic N in the soil were measured. The relationship between species richness and the measured factors was analyzed using bivariate correlations and stepwise multiple linear regressions. The two dominant species, a shrub Artemisia frigida and a grass Stipa krylovii, responded differently to N addition such that the former was gradually replaced by the latter. S. krylovii and A. frigida had highly-branched fibrous and un-branched tap root systems, respectively. S. krylovii had higher height than A. frigida in both control and N added plots. These differences may contribute to the observed species replacement. In addition, the analysis on root element and AP contents in rhizospheric soil suggests that different calcium acquisition strategies, and phosphorus and sodium responses of the two species may account for the replacement. Species richness was significantly reduced along the five N addition levels. Our results revealed a significant relationship between species richness and soil pH, litter amount, soil moisture, AP concentration and inorganic N concentration.

Conclusions/Significance

Our results indicate that litter accumulation and soil acidification accounted for 52.3% and 43.3% of the variation in species richness, respectively. These findings would advance our knowledge on the changes in species richness in semiarid temperate steppe of northern China under N deposition scenario.     

<Emphasis Type="Italic">Artemisia frigida</Emphasis> and <Emphasis Type="Italic">Stipa krylovii</Emphasis>, two dominant species in Inner Mongolia steppe,differed in their responses to elevated atmospheric CO<Subscript>2</Subscript> concentration

Aims

Despite extensive studies on effects of elevated CO₂ concentration ([CO₂]_e) on plant growth, few studies have investigated the responses of native grassland plant species to [CO₂]_e in terms of nutrient acquisition.

Methods

The effects of [CO₂]_e (769 ± 23 ppm) on Artemisia frigida and Stipa krylovii, two dominant species in Inner Mongolia steppe were investigated by growing them for 7 weeks in Open-Top Chambers (OTC).

Results

Exposure to [CO₂]_e enhanced shoot and root growth of A. frigida and S. krylovii. Elevated [CO₂] increased photosynthetic rates (Pn) by 34 % in A. frigida but decreased Pn by 52 % in S. krylovii. Moreover, root-secreted acid phosphatase activity in A. frigida was stimulated by [CO₂]_e, while exudation of malate from roots of S. krylovii was suppressed by [CO₂]_e. Exposure to [CO₂]_e led to a decrease in P concentration in shoots and roots of A. frigida and S. krylovii, but total amount of P accumulated in shoots and roots of both species was increased by [CO₂]_e.

Conclusions

The two dominant species in temperate steppes differed in their responses to [CO₂]_e, such that A. frigida was more adapted to [CO₂]_e than S. krylovii under low availability of soil P.

     

感染内生真菌的羊草对克氏针茅种子萌发的影响

以我国内蒙古草原常见优势种羊草（Leymus chinensis（Trin.) Tzvel.）及克氏针茅（Stipa krylovii Roshev.）为实验材料,在离体器官和整株植物水平上探讨内生真菌感染是否会影响宿主植物羊草对克氏针茅种子萌发的作用。实验结果表明：内生真菌感染能够影响羊草对克氏针茅种子萌发的作用,其影响程度与羊草的作用部位、处理方法以及处理浓度相关。与未染菌羊草相比,染菌羊草绿叶在低浓度处理下显著促进了克氏针茅的萌发,高浓度下显著抑制了克氏针茅的幼根生长;染菌羊草枯叶显著抑制了克氏针茅幼根的生长,而染菌羊草地下部显著促进了克氏针茅的萌发;感染和不感染内生真菌的整株羊草对克氏针茅的发芽率和发芽速度无显著影响。在处理浓度相同的情况下,草粉对克氏针茅种子萌发的抑制作用比浸提液处理更为显著,绿叶比枯叶抑制作用更为显著。     

Nitrogen fertilization and fire act independently on foliar stoichiometry in a temperate steppe

Nitrogen (N) fertilization, as a grassland management strategy, has been widely used to improve forage quality and increase the productivity of grasslands degraded by overstocking. It is widely accepted that N addition will alter ecosystem structure and function, and that these effects may be altered by natural disturbances, such as fire. We examined the effects of annual burning and N fertilization (17.5 g N m^?2 year^?1, at a surplus rate in order to simulate agriculture treatment) on foliar chemistry and stoichiometric ratios of eight dominant species (Leymus chinensis, Stipa grandis, Cleistogenes squarrosa, Potentilla bifurca, Thalictrum squarrosum, Artemisia frigida, Kochia prostrata and Caragana microphylla) in a temperate steppe in northern China. After 3 years of treatments, annual burning significantly increased soil extractable phosphorus (P) concentration but showed no effects on soil inorganic N concentration, whereas N fertilization caused a significant increase in inorganic N concentration but not of extractable P. Species differed substantially with respect to all nutritional and stoichiometric variables. Both annual burning and N fertilization caused significant increases in foliar N and P concentrations and thus decreases in carbon (C):N and C:P ratios. While annual burning showed no effects on N:P ratios, N fertilization produced higher N:P ratios. However, species responded idiosyncratically to both fire and N fertilization in terms of foliar N concentration, C:N and N:P ratio. In addition, there was no interaction between fire and N fertilization that affected all variables. This study suggests that both annual burning and N fertilization have direct impacts on plant elemental composition and that fire- and N addition-induced changes of community composition may have important consequences for plant-mediated biogeochemical cycling pathways in temperate steppe ecosystem.     

Responses of litter decomposition and nutrient release rate to water and nitrogen addition differed among three plant species dominated in a semi-arid grassland

Background and aims

Precipitation and nitrogen (N) deposition are predicted to increase in northern China. The present paper aimed to better understand how different dominant species in semi-arid grasslands in this region vary in their litter decomposition and nutrient release responses to increases in precipitation and N deposition.

Methods

Above-ground litter of three dominant species (two grasses, Agropyron cristatum and Stipa krylovii, and one forb, Artemisia frigida) was collected from areas without experimental treatments in a semi-arid grassland in Inner Mongolia. Litter decomposition was studied over three years to determine the effects of water and N addition on litter decomposition rate and nutrient dynamics.

Results

Litter mass loss and nutrient release were faster for the forb species than for the two grasses during decomposition. Both water and N addition increased litter mass loss of the grass A. cristatum, while the treatments showed no impacts on that of the forb A. frigida. Supplemental N had time-dependent, positive effects on litter mass loss of the grass S. krylovii. During the three-year decomposition study, the release of N from litter was inhibited by N addition for the three species, and it was promoted by water addition for the two grasses. Across all treatments, N and potassium (K) were released from the litter of all three species, whereas calcium (Ca) was accumulated. Phosphorus (P) and magnesium (Mg) were released from the forb litter but accumulated in the grass litter after three years of decomposition.

Conclusions

Our findings revealed that the litter decomposition response to water and N supplementation differed among dominant plant species in a semi-arid grassland, indicating that changes in dominant plant species induced by projected increases in precipitation and N deposition are likely to affect litter decomposition, nutrient cycling, and further biogeochemical cycles in this grassland. The asynchronous nutrient release of different species’ litter found in the present study highlights the complexity of nutrient replenishment from litter decomposition in the temperate steppe under scenarios of enhancing precipitation and N deposition.

     

Changes in nitrogen resorption traits of six temperate grassland species along a multi-level N addition gradient

Nitrogen (N) resorption from senescing leaves is an important mechanism of N conservation for terrestrial plant species, but changes in N-resorption traits over wide-range and multi-level N addition gradients have not been well characterized. Here, a 3-year N addition experiment was conducted to determine the effects of N addition on N resorption of six temperate grassland species belonging to three different life-forms: Stipa krylovii Roshev. (grass), Cleistogenes squarrosa (T.) Keng (grass), Artemisia frigida Willd. (semishrub), Melissitus ruthenica C.W.Wang (semishrub and N-fixer), Potentilla acaulis L. (forb) and Allium bidentatum Fisch.ex Prokh. (forb). Generally, N concentrations in green leaves increased asymptotically for all species. N concentrations in senescent leaves for most species (5/6) also increased asymptotically, except that the N concentration in senescent leaves of A. bidentatum was independent of N addition. N-resorption efficiency decreased with increasing N addition level only for S. krylovii and A. frigida, while no clear responses were found for other species. These results suggest that long-term N fertilization increased N uptake and decreased N-resorption proficiency, but the effects on N-resorption efficiency were species-specific for different temperate grassland species in northern China. These inter-specific differences in N resorption may influence the positive feedback between species dominance and N availability and thus soil N cycling in the grassland ecosystem in this region.     

Short-term regrowth responses of four steppe grassland species to grazing intensity, water and nitrogen in Inner Mongolia

Inner Mongolia steppe grasslands are widely used for livestock farming and the regrowth ability of grassland species is therefore strongly influenced not only by water and nutrient availability but also quite heavily by grazing. However, little is known on how grazing, water and nitrogen interactively affect the dominant C3 species (Leymus chinensis, Stipa grandis, Agropyron cristatum) and the C4 species (Cleistogenes squarrosa). Therefore in the 2007 and 2008 growing seasons, a field experiment was carried out to test the hypothesis that under different grazing intensities the dominant species show different short-term regrowth response to simultaneous variation in the availability of water and nitrogen. Single factor and interaction effects of the addition of water (rainfed vs. simulated wet-year) and nitrogen (0 or 25 kg N ha^?1) were analysed along a gradient of four grazing intensities (ungrazed, lightly, moderately and heavily grazed) after one month of grazing exclusion. Water and nitrogen addition affected short-term regrowth of all species in a similar way whereas species responded differently to grazing. Simulated wet-year water availability consistently resulted in higher standing biomass, relative growth rate and cellulase digestible organic matter yield. Supplementary nitrogen promoted standing biomass and crude protein concentration. The nutritive value of all species’ standing biomass showed a similar increase with more intensive grazing. However, heavy grazing led to a clear shift in the relative biomass of the species, i.e. mainly a promotion of the C4 grass, C. squarrosa. In contrast to our hypothesis, there were no differences among species in their response to water or nitrogen addition, whereas, heavy grazing induced the expected species-specific response. Our results suggest that heavy grazing rather than nitrogen or water determine short-term shifts in species composition of the investigated steppe ecosystem. Furthermore, differences in the species-specific growth response to grazing may increase the proportion of the C4 grass C. squarrosa in steppe communities, whereas higher availability of nitrogen and water may lead to higher forage biomass and nutritive value of all investigated species but in short-term cannot compensate for the grazing induced changes in species composition.     

Response of dominant grassland species in the temperate steppe of Inner Mongolia to different land uses at leaf and ecosystem levels

In order to study the responses of dominant species to different land uses in the semiarid temperate grassland of Inner Mongolia, we tested the physiological responses of Stipa grandis, Leymus chinensis, and Artemisia frigida to mowing, grazing exclusion, and grazing land uses at the leaf and ecosystem levels. The grazing-exclusion and mowing sites released CO₂, but the grazing site was a net carbon sink. L. chinensis and S. grandis contributed more to the ecosystem CO₂ exchange than A. frigida. At the grazing-exclusion and mowing sites, Leymus chinensis and Stipa grandis both exhibited a higher light-saturation point and higher maximum photosynthetic rate than that at the grazing site, which increased photosynthesis and growth compared to those at the grazing site. In contrast, A. frigida possessed a higher nitrogen content than the other species, and more of the light energy used for photosynthesis, particularly at the grazing site.     

Transgenerational effect alters the interspecific competition between two dominant species in a temperate steppe

One of the key aims of global change studies is to predict more accurately how plant community composition responds to future environmental changes. Although interspecific relationship is one of the most important forces structuring plant communities, it remains a challenge to integrate long‐term consequences at the plant community level. As an increasing number of studies have shown that maternal environment affects offspring phenotypic plasticity as a response to global environment change through transgenerational effects, we speculated that the transgenerational effect would influence offspring competitive relationships. We conducted a 10‐year field experiment and a greenhouse experiment in a temperate grassland in an Inner Mongolian grassland to examine the effects of maternal and immediate nitrogen addition (N) and increased precipitation (Pr) on offspring growth and the interspecific relationship between the two dominant species, Stipa krylovii and Artemisia frigida. According to our results, Stipa kryloii suppressed A. frigida growth and population development when they grew in mixture, although immediate N and Pr stimulated S. kryloii and A. frigida growth simultaneously. Maternal N and Pr declined S. krylovii dominance and decreased A. frigida competitive suppression to some extent. The transgenerational effect should further facilitate the coexistence of the two species under scenarios of increased nitrogen input and precipitation. If we predicted these species'' interspecific relationships based only on immediate environmental effects, we would overestimate S. krylovii''s competitive advantage and population development, and underestimate competitive outcome and population development of A. frigida. In conclusion, our results demonstrated that the transgenerational effect of maternal environment on offspring interspecific competition must be considered when evaluating population dynamics and community composition under the global change scenario.     

不同邻居物种的基因型多样性对冷蒿生长的影响

植物物种多样性与基因型多样性对群落的结构和功能具有重要的生态作用,近年来植物基因型多样性对植物间相互作用的影响已成为研究者关心的重要科学问题。实验选择退化草原优势种冷蒿(Artemisia frigida)为目标植物,稳定群落建群种羊草(Leymus chinensis)和群落伴生种洽草(Koeleria cristata)为邻居植物,来研究基因型多样性不同的邻居植物对冷蒿生长表现(株高、地上生物量、地下生物量和总生物量)的影响,并通过测量植物相对竞争强度及邻居植物性状变异来进一步探究邻居植物基因型多样性对目标植物影响的内在机制。结果表明:(1)邻居物种为羊草时,基因型多样性对冷蒿的生长表现影响显著,当邻居为6基因型时,冷蒿的株高、地上生物量以及总生物量显著低于单基因型和3基因型时的表现(P0.05),且相对竞争强度高于其他两种处理;而邻居物种为洽草时,基因型多样性对冷蒿所有观测指标以及相对竞争强度的影响均不显著(P0.05)。(2)利用主成分分析法来分析基因型多样性对自身性状变异的影响发现,邻居物种为羊草时,基因型多样性对性状变异响应显著,主要表现为3基因型时,羊草种群的株高、总生物量、地上生物量显著高于单基因型时的表现(P0.05);而邻居物种为洽草时,基因型多样性对性状变异影响不显著(P0.05)。(3)邻居物种为羊草时,羊草总生物量和比叶面积与冷蒿的地上生物量和总生物量呈显著负相关(P0.05);邻居物种为洽草时,洽草各性状与冷蒿性状间无显著相关性(P0.05)。实验结果揭示,基因型多样性对目标植物生长的效应受邻居植物种类的影响,稳定群落建群种羊草高基因型组合能显著抑制冷蒿的生长,这可能与羊草高基因型多样性种群性状变异大且对冷蒿有较高的相对竞争强度有关。所得结果为建群种基因型多样性影响种间相互作用提供了实验证据,为草原的合理利用和保护提供了理论指导。     

Asymmetric effects of grazing intensity on macroelements and microelements in grassland soil and plants in Inner Mongolia Grazing alters nutrient dynamics of grasslands

Grazing is a traditional grassland management technique and greatly alters ecosystem nutrient cycling. The effects of grazing intensity on the nutrient dynamics of soil and plants in grassland ecosystems remain uncertain, especially among microelements. A 2‐year field grazing experiment was conducted in a typical grassland with four grazing intensities (ungrazed control, light, moderate, and heavy grazing) in Inner Mongolia, China. Nutrient concentration was assessed in soil and three dominant plant species (Stipa krylovii, Leymus chinensis, and Cleistogenes squarrosa). Assessed quantities included four macroelements (carbon (C), nitrogen (N), phosphorus (P), and magnesium (Mg)) and four microelements (copper (Cu), iron (Fe), manganese (Mn), and zinc (Zn)). Soil total C, total N, total P, available N, and available P concentrations significantly increased with grazing intensity but soil Mg, Cu, Fe, Mn, Zn concentrations had no significant response. Plant C concentration decreased but plant N, P, Mg, Cu, Fe, Mn, and Zn concentrations significantly increased with grazing intensity. In soil, macroelement dynamics (i.e., C, N, and P) exhibited higher sensitivity with grazing intensity, conversely in plants, microelements were more sensitive. This result indicates macroelements and microelements in soil and plants had asymmetric responses with grazing intensity. The slopes of nutrient linear regression in C. squarrosa were higher than that of S. krylovii and L. chinensis, indicating that C. squarrosa had higher nutrient acquisition capacity and responded more rapidly to heavy grazing. These findings indicate that short‐term heavy grazing accelerates nutrient cycling of the soil–plant system in grassland ecosystems, elucidate the multiple nutrient dynamics of soil and plants with grazing intensity, and emphasize the important function of microelements in plant adaptation in grazing management.     

Effects of forage composition and growing season on methane emission from sheep in the Inner Mongolia steppe of China

Understanding the effects of dietary composition on methane (CH₄) production of sheep can help us to understand grassland degradation resulting in an increase of CH₄ emission from ruminant livestock and its resulting significance affecting CH₄ source/sink in the grazing ecosystem. The objective of this study was to investigate the effect of forage composition in the diet of sheep in July and August on CH₄ production by sheep in the Inner Mongolia steppe. The four diet treatments were: (1) Leymus chinensis and Cleistogenes squarrosa (LC), (2) Leymus chinensis, Cleistogenes squarrosa and concentrate supplementation (LCC), (3) Artemisia frigida and Cleistogenes squarrosa (AC), and (4) Artemisia frigida, Cleistogenes squarrosa and concentrate supplementation (ACC). CH₄ production was significantly lower in July than in August (31.4 and 36.2 g per sheep-unit per day, respectively). The daily average CH₄ production per unit of digestive dry matter (DM), organic matter (OM) and neutral detergent fiber (NDF) increased by 10.9, 11.2 and 42.1% for the AC diet compared with the LC diet, respectively. Although concentrate supplementation in both the AC and LC diets increased total CH₄ production per sheep per day, it improved sheep productivity and decreased CH₄ production by 14.8, 12.5 and 14.8% per unit of DM, OM and NDF digested by the sheep, respectively. Our results suggested that in degraded grassland CH₄ emission from sheep was increased and concentrate supplementation increased diet use efficiency. Sheep-grazing ecosystem seems to be a source of CH₄ when the stocking rate is over 0.5 sheep-units ha⁻¹ during the growing season in the Inner Mongolia steppe. Shiping Wang and He Zhou contributed equally to this work.     

Responses of two dominant plant species to drought stress and defoliation in the Inner Mongolia Steppe of China

There has been a dramatic shift in dominance from Stipa grandis communities to S. krylovii communities in the Inner Mongolia steppe of China, in recent decades due to climate change and human activity. We examined the growth and carbohydrate allocation pattern of S. grandis and S. krylovii under controlled conditions. The experimental approach involved a drought stress treatment and a simulated defoliation (clipping) treatment of both species. Growth (above ground biomass and root biomass) and carbon allocation (concentration of leaf total phenolics and pool of total non-structural carbohydrate) variables were evaluated at the end of the experiment. Responses to drought stress differed significantly between S. grandis and S. krylovii. For S. krylovii, growth and the pool of total non-structural carbohydrate were more negatively affected by drought stress, whereas concentration of total phenolics was positively affected. Drought stress reinforced responses to defoliation, and drought stress × defoliation interaction was significant for all of the variables. There was a distinct defoliation response level for growth after drought stress between the two species. For aboveground biomass, both species responded positively to drought stress, which changed from responses equivalence to S. krylovii being superior; for root biomass, the two species responded oppositely to drought stress, which changed from S. grandis being superior to S. krylovii being superior. There was a weak and reverse defoliation response level for the carbon allocation pattern after drought stress between the two species, with S. krylovii changing from superior in defense to superior in storage. These results suggested that S. grandis utilized an avoidance strategy (investment in defense compounds) and S. krylovii utilized a tolerance strategy (investment in storage for regrowth) in response to defoliation under drought stress, supporting the idea that stress-tolerant species may become the new dominant species because of their ability to re-grow after disturbance. This provided a possible explanation for the replacement of S. grandis communities from the view point of adaptive strategy.     

Effect of slight vegetation degradation on soil properties in Brachypodium pinnatum grasslands

Water is the most important factor controlling plant growth, primary production, and ecosystem stability in arid and semi-arid grasslands. Here we conducted a 2-year field study to explore the contribution of winter half-year (i.e. October through April) and summer precipitation (May through September) to the growth of coexisting plant species in typical steppe ecosystems of Inner Mongolia, China. Hydrogen stable isotope ratios of soil water and stem water of dominant plant species, soil moisture, and plant water potential were measured at three steppe communities dominated by Stipa grandis, Caragana microphylla, and Leymus chinensis, respectively. The fraction of water from winter half-year precipitation was an important water source, contributing 45% to plant total water uptake in a dry summer after a wet winter period (2005) and 15% in a summer where subsoil moisture had been exploited in the previous year (2006). At species level, Caragana microphylla exhibited a complete access to deep soil water, which is recharged by winter precipitation, while Cleistogenes squarrosa completely depended on summer rains. Leymus chinensis, Agropyron cristatum, and Stipa grandis showed a resource-dependent water use strategy, utilizing deep soil water when it was well available and shifting to rain water when subsoil water had been exploited. Our findings indicate that differentiation of water sources among plants improves use of available soil water and lessens the interspecific competition for water in these semi-arid ecosystems. The niche complementarity in water sources among coexisting species is likely to be the potential mechanism for high diversity communities with both high productivity and high resilience to droughts.     

施肥与刈割对内蒙古草地生态化学计量特征的影响

为明确施肥和刈割对蒙古半干旱草地四种植物化学计量特征的影响,该文于2014年8月以内蒙古半干旱草地的四种植物冷蒿(Artimesia frigida)、菊叶委陵菜(Potentilla tanacetifolia)、羊草(Aneurotepidimu chinense)、扁蓿豆(Melissitus ruthenica)为研究对象,利用方差分析及多重比较分析对照、施氮肥、割草、割草和施氮肥处理下的植物碳、氮、磷含量的差异以及不同处理下碳氮比和氮磷比的变化。结果表明:施氮肥与割草均未影响植物碳含量。施氮肥显著提高了植物氮含量(P<0.05),进而降低了碳氮比(P<0.05),提高了氮磷比(P<0.05)。割草处理后扁蓿豆的氮含量显著提高了0.18%(P<0.05),羊草的氮含量显著降低了0.13%(P<0.05),冷蒿与菊叶委陵菜的氮含量无显著变化。割草显著提高了冷蒿和菊叶委陵菜的磷含量(P<0.05),但是未影响羊草和扁蓿豆的磷含量。该研究证实了氮添加或割草会影响部分草地物种的化学计量特征,但是氮添加或割草对植物化学计量特征的影响存在种间差异。     

降水差异对内蒙古温带草原植物根系和叶片功能性状的影响北大核心CSCD

植物能够调整叶片或根系功能性状的变化来适应气候变化,从而形成多样性的环境适应策略。该研究以内蒙古温带草原降水量存在差异的草原群落(较为湿润的多伦草原和较为干旱的正镶白旗草原)为研究对象,分别测定两个草原群落优势种(多伦20种和正镶白旗13种)和共有种(8种)的根系功能性状(根直径、比根长和根组织密度)和叶片功能性状(叶面积、比叶面积、叶干物质含量、叶碳含量、叶氮含量),分析根叶性状的变异规律及其关系,以探究草种对不同降水环境的适应策略,为不同降水区域草种的选择以及草原经营管理提供理论依据。结果显示:(1)随着降水量的变化,草种的根性状在两个群落间无显著差异,多伦草原植物的比叶面积显著高于正镶白旗草原,而叶干物质含量和叶碳含量则呈相反趋势;两个草原群落的单子叶禾草类植物根直径最小,比根长最大,叶干物质含量最高;单子叶百合科类植物的根组织密度最小,叶干物质含量和叶氮含量最低;双子叶非禾草类植物的根组织密度最大,比叶面积最高而叶面积最低。(2)随降水量的减少,两个群落共有种的叶面积、比叶面积降低,叶干物质含量和叶碳含量增加;其中,羊草、冰草、糙隐子草的直径增加,比根长和根组织密度降低,而猪毛蒿的直径和比根长则呈相反的趋势;糙隐子草、羊草、猪毛蒿的叶氮含量增加,冰草、克氏针茅叶氮含量降低。(3)主成分分析表明,单个草原或综合两个草原的植物根与叶性状几乎不相关。研究表明,单子叶禾草类植物的根系性状在降水变化中差异较为明显,而双子叶非禾草类植物基本没有变化;干旱对植物叶性状的影响大于根性状;在不同降水环境下,草原植物根系存在独特的资源获取方式,根与叶性状对环境变化的适应策略均具有独立性。     

Allelopathic effects of Artemisia frigida Willd. on growth of pasture grasses in Inner Mongolia,China

Research on the causes of grassland degradation in the Inner Mongolia has mostly focused on anthropogenic activities. Few studies examined plant interactions during the processes of grassland degradation. In this study, we found that the major constituents of the VOCs from undamaged Artemisia frigida were eucalyptol, camphene, (E)-3-hexen-1-ol acetate, α-terpineol, β-terpineol, (R)-(–)-p-menth-1-en-4-ol, p-cymene and camphor. The content and amount of these VOCs increased when A. frigida was damaged. The VOCs from A. frigida significantly decreased the seedling growth of three common grass species (Elymus dahuricus, Agropyron cristatum and Leymus chinensis) in the Inner Mongolia pastures. The inhibition effect of the VOCs on the tested grass species was significantly greater from damaged than from undamaged plants of A. frigida. Findings from this study suggest that the dominance of A. frigida in degraded grasslands may affect the recovery of other native plant species through mechanisms of allelopathic effect of VOCs emission, especially when under severe disturbance by overgrazing.     

放牧对大针茅草原建群种与优势种空间分布关系的影响

为探讨放牧下大针茅草原建群种大针茅(Stipa grandis)和优势种羊草(Leymus chinensis)及糙隐子草(Cleistogenes squarrosa)种群空间分布特点及关系,本实验以内蒙古自治区锡林郭勒盟毛登牧场大针茅草原建群种大针茅、优势种羊草和糙隐子草为研究对象,通过野外试验,以地统计学为基础,采用半方差函数、分形维数及克里格插值法,分析了围封(CK)和放牧(G)样地大针茅、羊草及糙隐子草种群小尺度空间分布关系。结果表明:围封样地大针茅、羊草及糙隐子草植株密度分别为10.94株/m~(2 )、12.95株/m~(2 )、13.60株/m~(2 ),放牧样地植株密度分别为16.84株/m~(2 )、48.28株/m~(2 )、28.63株/m~(2 ),放牧显著增加大针茅、羊草及糙隐子草种群密度(P0.05);半方差函数进行模型拟合发现,大针茅、羊草及糙隐子草种群空间分布函数关系均符合高斯模型;通过对空间分布函数关系分析,围封和放牧样地结构比为G (93.3%) CK(60.4%),表明放牧样地大针茅种群空间分布主要受结构性因素影响,而围封大针茅种群则受随机性因素影响较大;围封和放牧样地分形维数值为CK(1.796) G(1.361),表明放牧样地大针茅、羊草和糙隐子草所形成的空间分布格局相比围封样地较为复杂,大针茅空间分布对羊草和糙隐子草空间分布的依赖性较弱;通过立体图分析,在放牧利用过程中,羊草处于中低密度时,及糙隐子草处于高密度时,均与大针茅种群间的关系从围封中的竞争关系变为放牧过程中的亲和关系,可见放牧导致种间关系改变。