戴云山黄山松林土壤碳组分的海拔变化特征及影响因素

海拔梯度可能通过多种环境因子影响土壤有机质,土壤有机碳库是土壤有机质的重要组成部分,其微小变化将会产生极其重要的影响。因此海拔差异可能导致海拔间土壤碳库差异。土壤有机碳是反映土壤肥力的重要指标,可能受土壤理化性质和微生物等多种因素的影响。黄山松是高山地绿化和用材的优良树种,近年来戴云山自然保护区内高海拔地区的黄山松群落呈现衰退趋势。研究戴云山黄山松林土壤有机碳组分沿海拔梯度的变化情况,不仅可以为该区域碳库估算提供科学依据,而且有助于揭示影响黄山松生长变化的机理。因此,选取戴云山不同海拔[1300 m (L)、1450 m (M)和1600 m (H)]梯度的黄山松林,对其土壤基本理化性质、有机碳组分及微生物特征进行测定和分析。研究发现,海拔梯度下土壤养分含量呈先升高后降低的变化趋势,土壤碳组分含量与其变化一致,且微生物生物量碳和微生物生物量氮均在M海拔处最高,海拔梯度对碳水解酶没有显著影响。冗余分析表明,总氮是影响土壤有机碳变化的最主要因素,其次是碳氮比。因此在海拔跨度不大的情况下,土壤有机碳动态可能主要受氮素而非温度的影响。高海拔地区土壤惰性碳占比高,未来可能会持续加剧该地区黄山松的生长困境,使该区域碳库受到影响。     

复方泛影葡胺速率区带密度梯度离心法纯化衣原体

目的利用速率区带密度梯度离心法建立纯化高纯度、高感染力衣原体的方法。方法采用HeLa229细胞扩增衣原体,制作含有大量衣原体的细胞裂解液,以国产复方泛影葡胺作为介质,利用速率区带密度梯度离心法纯化衣原体,负染纯化产物后使用透射电镜观察形态,并将纯化产物感染HeLa229细胞,测定纯化产物的感染力。结果在透射电镜下观察,证实纯化产物为直径300 nm左右的高纯度原体。纯化产物的感染力为8.62×10~8 IFU/mL,证实该纯化产物具有高感染力。结论通过复方泛影葡胺速率区带密度梯度离心法,可获得高纯度、高感染力的衣原体,为开展衣原体感染机制、免疫反应等研究提供了有效而可靠的保证。     

Do different rates of gene flow underlie variation in phenotypic and phenological clines in a montane grasshopper community?

Species responses to environmental change are likely to depend on existing genetic and phenotypic variation, as well as evolutionary potential. A key challenge is to determine whether gene flow might facilitate or impede genomic divergence among populations responding to environmental change, and if emergent phenotypic variation is dependent on gene flow rates. A general expectation is that patterns of genetic differentiation in a set of codistributed species reflect differences in dispersal ability. In less dispersive species, we predict greater genetic divergence and reduced gene flow. This could lead to covariation in life‐history traits due to local adaptation, although plasticity or drift could mirror these patterns. We compare genome‐wide patterns of genetic structure in four phenotypically variable grasshopper species along a steep elevation gradient near Boulder, Colorado, and test the hypothesis that genomic differentiation is greater in short‐winged grasshopper species, and statistically associated with variation in growth, reproductive, and physiological traits along this gradient. In addition, we estimate rates of gene flow under competing demographic models, as well as potential gene flow through surveys of phenological overlap among populations within a species. All species exhibit genetic structure along the elevation gradient and limited gene flow. The most pronounced genetic divergence appears in short‐winged (less dispersive) species, which also exhibit less phenological overlap among populations. A high‐elevation population of the most widespread species, Melanoplus sanguinipes, appears to be a sink population derived from low elevation populations. While dispersal ability has a clear connection to the genetic structure in different species, genetic distance does not predict growth, reproductive, or physiological trait variation in any species, requiring further investigation to clearly link phenotypic divergence to local adaptation.     

Nitrogen economy of alpine plants on the north Tibetan Plateau: Nitrogen conservation by resorption rather than open sources through biological symbiotic fixation

Nitrogen (N) is one of the most important factors limiting plant productivity, and N fixation by legume species is an important source of N input into ecosystems. Meanwhile, N resorption from senescent plant tissues conserves nutrients taken up in the current season, which may alleviate ecosystem N limitation. N fixation was assessed by the ¹⁵N dilution technique in four types of alpine grasslands along the precipitation and soil nutrient gradients. The N resorption efficiency (NRE) was also measured in these alpine grasslands. The aboveground biomass in the alpine meadow was 4–6 times higher than in the alpine meadow steppe, alpine steppe, and alpine desert steppe. However, the proportion of legume species to community biomass in the alpine steppe and the alpine desert steppe was significantly higher than the proportion in the alpine meadow. N fixation by the legume plants in the alpine meadow was 0.236 g N/m², which was significantly higher than N fixation in other alpine grasslands (0.041 to 0.089 g N/m²). The NRE in the alpine meadows was lower than in the other three alpine grasslands. Both the aboveground biomass and N fixation of the legume plants showed decreasing trends with the decline of precipitation and soil N gradients from east to west, while the NRE of alpine plants showed increasing trends along the gradients, which indicates that alpine plants enhance the NRE to adapt to the increasing droughts and nutrient‐poor environments. The opposite trends of N fixation and NRE along the precipitation and soil nutrient gradients indicate that alpine plants adapt to precipitation and soil nutrient limitation by promoting NRE (conservative nutrient use by alpine plants) rather than biological N fixation (open sources by legume plants) on the north Tibetan Plateau.     

Seed quality and seed quantity in red maple depends on weather and individual tree characteristics

Under future climate change, plant species are expected to shift their ranges in response to increasing temperatures and altered precipitation patterns. As seeds represent the single opportunity for plants to move, it is critical to quantify the factors that influence reproduction. While total seed production is clearly important, seed quality is equally as critical and often overlooked. Thus, to quantify how environmental and tree‐level characteristics affect seed quality and quantity, the reproductive output of red maple (Acer rubrum) was measured along an elevation gradient in the Monongahela National Forest, WV. A variety of individual‐level characteristics were measured (e.g., DBH, canopy area, height, and tree cores were taken to quantify growth), and seed traps were placed under seed‐bearing trees to collect samaras and quantify total seed production. A random subsample of collected seeds from each tree was micro‐CT scanned to determine embryo volume, photographed for morphology measurements, and used for germination trials. The number of seeds produced was negatively affected by frost events during flowering, and stand density. The trees with the most seeds also showed reduced growth in recent years. Only 63% of scanned seeds showed embryo development, and of those seeds—only 23% germinated. The likelihood of embryo presence increased as growth rate decreased, while embryo size increased with tree height, smaller DBH, and in areas dominated by hemlock. Both larger embryo volume and larger overall seed size increased the likelihood of germination. The results highlight the importance of including seed quality in addition to seed quantity for a more complete representation of reproductive output.     

Impacts of soil temperature,phenology and plant community composition on invertebrate herbivory in a natural warming experiment

Species and community-level responses to warming are well documented, with plants and invertebrates known to alter their range, phenology or composition as temperature increases. The effects of warming on biotic interactions are less clearly understood, but can have consequences that cascade through ecological networks. Here, we used a natural soil temperature gradient of 5–35°C in the Hengill geothermal valley, Iceland, to investigate the effects of temperature on plant community composition and plant–invertebrate interactions. We quantified the level of invertebrate herbivory on the plant community across the temperature gradient and the interactive effects of temperature, plant phenology (i.e. development stage) and vegetation community composition on the probability of herbivory for three ubiquitous plant species, Cardamine pratensis, Cerastium fontanum and Viola palustris. We found that the percentage cover of graminoids and forbs increased, while the amount of litter decreased, with increasing soil temperature. Invertebrate herbivory also increased with soil temperature at the plant community level, but this was underpinned by different effects of temperature on herbivory for individual plant species, mediated by the seasonal development of plants and the composition of the surrounding vegetation. This illustrates the importance of considering the development stage of organisms in climate change research given the variable effects of temperature on susceptibility to herbivory at different ontogenetic stages.     

广州市主城区城市地形类型与风环境评价

对城市地形组合类型及其地形对风场影响的研究,有助于城市风场机理的认识与生态环境的优化。以高层建筑密集的广州市主城区为例,在确定城市宏观地形类型的基础上,基于最小成本路径（LCP）辨识了风道,并对风环境质量进行评价。主要结论有：（1）将城市地形简要概括划分为4个一级地形、11个二级地形类型。（2）以LCP路径与盛行风交角不超过22.5°的标准,筛选确定通风路径作为风道。根据LCP格网的密度与频次,结合不同风向下风速与风频,评价分析了风环境类型与空间分布。（3）根据自然与城市地形的配置,北风风环境质量远高于西北风和东风;东风由于风频与风速最低,因此通风条件较差。（4）珠江航道在三种风向下都是尺度最宽贯穿城市最好的风道;区域性的风道与风环境较好的地段集中在与主风向平行的主干道上,但以近似南北走向的居多;由于广州城市地形高度以珠江新城峰林为中心向外递减,以低地地形为主的主城区外围通风优于中心区域,特别是珠江新城峰林与网络状台地为主的老城区,通风环境较差。基于LCP的评价结果需要同其他方法相互验证,才能使其不断完善优化。     

海拔梯度变化对武夷山黄山松林土壤磷组分和有效性的影响

土壤磷（P）是植物生长必需的养分元素,也是亚热带森林生产力的主要限制元素。目前,关于不同海拔土壤P组分和P有效性的变化规律尚无统一定论,其原因主要是忽略了植被类型变化导致的P组分和P有效性对海拔的响应更为复杂。因此,以武夷山不同海拔黄山松林为研究对象,通过测定土壤环境因素、理化性质、微生物生物量（SMB）、酸性磷酸单酯酶（ACP）和磷酸双酯酶（PD）活性以及土壤P组分,探究土壤P组分和P有效性的变化及其影响因素。结果表明,随海拔降低,速效P含量显著增加,而易分解P、中等易分解P、难利用P和总磷含量显著减少。冗余分析结果表明,微生物生物量磷和微生物生物量氮是影响土壤P组分和P有效性变化的关键因素。研究表明,随海拔降低,黄山松林土壤微生物通过提高ACP、PD活性和降低SMB含量的能量分配策略,促进更多较难分解P组分的矿化,从而提高速效P含量,以满足微生物对P的需求。因此,在低海拔地区,微生物通过能量分配策略获取更多有效P,可能有利于提高武夷山黄山松林土壤速效P的供应,但从长期来看,可能使P矿化速率提高和P损耗增加,导致P库的储备不足,不利于土壤P素养分的可持续供应。     

卧龙自然保护区典型生态系统服务时空变化研究

自然保护区作为生态系统服务的产生区和生物多样性保护的重点区,评估其关键生态系统服务,对提高保护区管理水平和生态保护与建设效率有重要意义。利用CASA模型、RUSLE模型、InVEST模型及水量平衡原理等方法分别定量评估了卧龙自然保护区2000年和2015年碳固定（NPP）、土壤保持、生境质量和水源涵养4种生态系统服务并分析了其时空分布及其变化特征,揭示了不同地形位梯度和土地利用类型上生态系统服务的差异,识别了生态系统服务的热点区域。研究结果揭示了2000-2015年4种生态系统服务及其变化的时空异质性：1）研究期间保护区4种生态系统服务供给量均有所增加,且增益面积大于减损面积;2）空间上,NPP、土壤保持和生境质量3种服务表现为东南高、西北低,水源涵养空间分布无明显规律,4种服务的空间分布特征均变化不大且保持相对稳定;3）4种生态系统服务空间分布及变化与地形位和土地利用类型有关。4种服务的高值和增益的优势分布区均位于较低地形位指数梯度上,以保护区东南部最为突出;林地和草地是对保护区生态系统服务贡献较大的土地利用类型,尤以林地突出;4）热点分析表明保护区东南部是主要的生态系统服务供给热点区,研究期间Ⅳ类热点区面积显著增加。结合研究区域生态系统特征和生态恢复与管理政策,探讨分析了目标生态系统服务时空变化的自然生态和社会经济驱动力,为本区域生态系统恢复和生物多样性保护提供依据和建议。     

白云山国家森林公园不同人为干扰强度的群落冠层结构和光照特征

为探究森林冠层结构与林下光照的变化规律及其相关性,在河南省白云山国家森林公园选取人工林、择伐林、皆伐林和老龄林建立四块面积为1 hm²（100 m×100 m）的固定监测样地,利用半球面影像技术获取冠层结构及林下光照数据。研究发现：1）随着人为干扰强度降低,冠层覆盖度与叶面积指数呈增加趋势,林下散射辐射与直接辐射呈减少趋势;2）择伐林冠层覆盖度与叶面积指数最大,平均叶倾角与透光比最小,林下光照（直接辐射、散射辐射）与冠层覆盖度和叶面积指数都呈显著负相关,林下散射辐射与冠层覆盖度和叶面积指数的负相关关系最强;3）处于不同干扰强度的群落由于冠层结构的差异,形成了不同群落内特定的光照环境。研究结果丰富了暖温带-亚热带生态过渡区森林冠层结构与林下光照动态变化研究资料,同时也为该区域森林的恢复与重建等提供科学的依据。