土壤细菌16SrRNA基因变异型及其与植被的相关研究

绕过细菌的分离培养,直接提取土壤DNA,扩谱,克隆土壤细菌群体的16S核糖体RNA基因（16S,rDNA),根据该基因各种变异类型的限制性片段长度多型性,分析土壤细菌分子遗传多样性及其与植被的相关关系,植被的改变影响土壤养分,进而改变土壤细菌群落结构,土壤细菌遗传多样性和分化能反映植被的变化。     

昆阳磷矿不同植被恢复模式对土壤理化性质和细菌群落的影响

土壤微生物在物质循环过程中具有重要作用且对环境变化敏感,是衡量土壤质量的重要指标．在恢复生态学研究中具有重要意义。为探究不同植被恢复模式对土壤理化性质和细菌群落的影响以及土壤细菌群落差异的原因,本研究以云南省昆阳磷矿为研究对象,运用PCR-DGGE技术和理化指标测定分析了三种植被恢复模式（芒草丛、旱冬瓜藏柏麻栎混交林、藏柏旱冬瓜混交林）下土壤细菌群落多样性、物种组成及土壤理化性质。结果表明：（1）植被恢复有助于改善土壤养分,不同植被恢复模式下土壤理化性质以及细菌群落多样性和物种组成均存在差异。（2）土壤细菌多样性与植被恢复模式之间具有显著相关性,但与土壤理化指标均无显著相关性。（3）土壤细菌群落物种组成与土壤碱解氮含量以及植被恢复模式间具有极显著相关性,与其他土壤理化指标间无显著相关性。本研究表明磷矿区不同植被恢复模式下土壤理化性质和细菌群落均具有差异,土壤细菌群落多样性差异的主要原因为植被恢复模式不同,物种组成差异的主要原因为土壤碱解氮含量不同,其次为植被恢复模式不同。     

贵州草海流域三种不同植被类型根际土壤真菌结构组成和多样性

为了解草海流域3种不同植被类型（湿地、草坡和灌木林地）根际土壤真菌结构组成和多样性的差异,采集3种植被根际土壤,利用第二代高通量测序技术,对土壤真菌结构组成及其多样性进行分析,测定土壤理化性质和酶活性,并与土壤真菌多样性进行相关性分析。结果表明：3种植被类型根际土壤真菌物种隶属于4个门、34纲、109目、250科、537属,其中灌木林地和湿地的真菌结构组成相似性较高,优势种群均为座囊菌纲Dothideomycetes,分别占21.18%和11.13%,而草坡优势类群为属级未确定的真菌,占29.26%;土壤真菌的多样性表现为灌木林地>草坡>湿地;植被根际土壤酶活性随土层加深逐渐降低,其中灌木林地根际土壤酶活性最高,湿地根际土壤酶活性最低,植被根际土壤真菌多样性和土壤全N、全K和速效K显著相关。3种不同植被类型根际土壤理化性质和酶活性与土壤真菌组成、丰度和多样性显著相关（P<0.05）,不同植被类型凋落物归还土壤并改变根际土壤理化性质和酶活性,进而影响根际土壤真菌组成结构和多样性。     

樟子松固沙林更新迹地草本植物多样性及其对土壤理化性质的影响

以科尔沁沙地南缘的彰武县章古台万亩林为研究对象,野外取样调查和实验室检测分析相结合,以樟子松固沙林采伐迹地为对照,研究不同植被恢复类型下樟子松固沙林更新迹地生境的改良效果,探讨植被重建后植物多样性及土壤理化性质的响应。结果表明:1)樟子松(Pinus sylvestris)固沙林更新迹地植被重建后,草本植物物种多样性增加,林下植物偶见种数目增多,13种草本植物在8个样地中未重复出现;2)与采伐迹地相比,不同植被重建类型土壤理化性质均有所改善,土壤容重、田间持水量、有机质、全氮、碱解氮、速效钾在彰武小钻杨(Populus xiaozhuanica)、五角枫(Acer mono)林地改良效果较好,全钾在红刺榆林(Hemiptelea davidii)地含量明显提高、山杏(Armeniaca sibirica)林地的有效磷相比采伐迹地明显提高,且均表现为上层改良效果优于下层;3)不同植被恢复类型土壤理化性质间存在显著差异,随着物种多样性的增加,土壤理化性质逐渐改善,土壤容重、田间持水量、有机质、全磷与植物多样性具有显著的相关性,土壤理化性质的与植物多样性相互作用,共同促进生态系统正向演替。研究结果为控制科尔沁沙地土壤沙化,加速该区生态系统的恢复与重建提供理论依据。     

黄河三角洲刺槐臭椿混交林与纯林土壤细菌群落结构和多样性特征分析

为研究黄河三角洲地区混交人工林土壤细菌群落特征,应用高通量测序技术,比较分析了刺槐臭椿混交林以及臭椿和刺槐纯林土壤细菌结构及多样性,并结合土壤理化性质进行分析。试验结果表明：在细菌门分类水平上,臭椿纯林、刺槐纯林、刺槐臭椿混交林土壤中分别检测出27、25、31门细菌,3种不同林分土壤中酸杆菌门、变形菌门、放线菌门、硝化螺旋菌门、绿弯菌门、浮霉菌门、芽单胞菌门、疣微菌门8种细菌是土壤中的主要细菌群落,其中酸杆菌门、变形菌门和放线菌门为优势细菌群落。不同类型人工林土壤中各门细菌相对丰度差异显著。混交林土壤细菌物种数和Shannon指数值分别为1910和9.1高于两种纯林。通过对土壤主要细菌群落与土壤理化性质进行主成分分析发现,3种不同林分之间在土壤细菌群落结构上有较高程度的分离,差异显著（P < 0.05）,有效磷含量与混交林土壤细菌群落有较强的正相关关系。因此可以得出结论,不同林分类型、土壤理化性质和细菌群落结构三者相互影响,刺槐臭椿混交增加了土壤细菌群落多样性,土壤理化性质在一定程度上影响土壤细菌结构和多样性。     

祁连山不同类型草地的土壤理化性质与植被特征

祁连山草地生态系统在维护我国西部生态安全方面起着举足轻重的作用。为了解祁连山不同类型草地土壤水分、养分等理化性质与植被分布特征,及土壤理化性质与植被特征的相关关系,于祁连山选取7种类型的草地,测定土壤水分含量、养分含量、容重、颗粒组成和植被特征,计算土壤颗粒的分形维数、0～40 cm土层土壤有机碳、全氮和全磷储量、植物多样性指数。结果表明: 祁连山不同类型草地的土壤理化性质与植被特征差异显著,高寒草甸相比于其他类型草地具有较高的土壤水分、养分和黏粒含量,及较低的容重和砂粒含量;0～40 cm土层土壤有机碳、全氮、全磷储量变化范围分别为3084～45247、164～2358、100～319 g·m^-2,整体表现为有机碳和全氮含量高、全磷含量低;土壤全磷储量与植物多样性指数呈显著正相关关系,表明土壤全磷含量是祁连山草地植物多样性的关键影响因素。相比其他草地类型,高寒草甸具有较好的植被状况和土壤水分、养分条件。     

林下植被管理措施对杉木大径材林土壤细菌群落结构的影响

林下植被是人工林生态系统的重要组成部分。本研究采用高通量测序技术,分析林下植被保留、林下植被去除和林下套种3种林下植被管理措施对杉木大径材人工林土壤细菌多样性、细菌群落结构组成以及相对丰度的影响,并分析土壤理化性质与细菌群落多样性的关系。结果表明: 林下植被保留处理的土壤细菌群落Chao1指数、Ace指数和Shannon指数高于林下植被去除和林下套种;放线菌门、酸杆菌门和绿弯菌门为本研究区杉木人工林土壤主要优势细菌;与林下植被去除和林下套种处理杉木人工林土壤细菌群落相比,林下植被保留处理土壤变形菌门、浮霉菌门、厚壁菌门和疣微菌门等相对丰度较高,而放线菌门、酸杆菌门和绿弯菌门的相对丰度较低;3种林下植被管理措施之间,土壤厚壁菌门、浮霉菌门、疣微菌门、Parcubacteria门和放线菌门等类群相对丰度差异显著;土壤含水率、全氮、全磷、水解氮和速效磷含量是影响细菌群落结构的重要因子,细菌多样性指数与土壤全氮、全磷、全钾、水解氮和速效钾含量呈显著正相关。     

岩溶区植被和季节对土壤微生物遗传多样性的影响

基于土壤微生物遗传多样性随植被和季节的变化而变化的假设,运用变性梯度凝胶电泳技术(DGGE)检测岩溶区草丛(T)、灌丛(S)、次生林(SF)和原生林(PF)群落演替过程中土壤细菌和真菌群落的遗传多样性及其季节变化.随着地上植被的演替土壤细菌群落具有连续性但优势种群不明显,真菌群落没有连续性但优势种群明显.植被和季节对于细菌和真菌群落的Shannon多样性具有不同程度的显著影响,同时存在显著的植被和季节交互作用.草丛土壤中细菌和真菌群落的Shannon多样性有显著的季节变化(p<0.01);灌丛土壤中仅细菌群落多样性有显著季节变化(p<0.05);而森林土壤中细菌和真菌群落多样性没有显著的季节变化.土壤真菌和细菌多样性具有显著正相关关系.随着地上植被的正向演替,土壤微生物遗传结构逐渐稳定;植被恢复早期阶段,土壤中存在着丰富的微生物遗传多样性,但并不稳定.     

Reasonable management of perennial planting grassland contributes to positive succession of soil microbial community in Sanjiangyuan of Qinghai-Tibetan Plateau,China

合理管理多年生人工建植草地有助于中国青藏高原三江源土壤微生物群落的正向演替 摘要：草地重建是缓解青藏高原三江源“黑土滩”的一种主要方法,同时了解如何管理建植草地也至关重要。而哪种人工管理模式更能有效地恢复“黑土滩”退化草地？为恢复“黑土滩”提供科学依据,我们研究了不同管理模式下人工草地植被特性、土壤理化性质和土壤微生物群落结构的变化,并探讨了不同管理模式对人工草地群落的影响。在本研究中,植被特性和土壤理化性质分别通过实地调查和实验室分析等方法得出,并且运用高通量测序技术测定了土壤微生物群落组成。研究结果表明,在不同管理模式下的人工建植草地植被特性、土壤理化性质和土壤微生物群落结构存在明显差异,而且植被植物多样性、地上生物量、土壤有机碳显著控制着放线菌门和担子菌门。当建植一次时Shannon-Wiener指数、地上生物量和土壤有机碳达到峰值,此时放线菌门和担子菌门所被注释的ASVs的相对丰度显著富集。此外,该管理模式下土壤的细菌多样性最高,真菌多样性最低,土壤逐渐成为“细菌型”土壤。由此得出,建植一次的人工草地植被特性和土壤环境更有利于整体群落的正向演替,是恢复“黑土滩”最合理的管理模式。     

贡嘎山海拔梯度上不同植被类型土壤甲烷氧化菌群落结构及多样性

甲烷是仅次于CO₂的第二大温室气体.森林表层土壤中甲烷好氧氧化作用是大气甲烷重要的汇,在碳循环和减缓全球变暖方面起着重要作用.研究不同植被类型土壤中甲烷氧化菌的群落结构及多样性,有助于更好地理解植被演替、人为干扰和不同土地利用背景下甲烷氧化菌群落组成和多样性变化与地上植被之间的相互关系.本研究在贡嘎山东坡海拔梯度上的4种不同植被类型中采集了92个土壤样品,利用Miseq测序技术和生物信息学方法评估了甲烷氧化菌群落组成及多样性在4种不同植被类型间的变化,并探讨了其变异的潜在原因.结果表明: 常绿阔叶林和针阔叶混交林土壤中甲烷氧化菌的群落结构较为相似,暗针叶林和灌丛草甸土壤甲烷氧化菌的群落结构较为相似.4种不同植被生态系统中,针阔叶混交林土壤中的甲烷氧化菌α多样性显著高于其他3种植被生态系统(P＜0.001),且暗针叶林和灌丛草甸土壤中甲烷氧化菌β多样性显著高于常绿阔叶林和针阔叶混交林(P＜0.001).Spearman相关分析表明,不同类型甲烷氧化菌的相对丰度对环境变化的响应模式不同.造成α多样性差异的主要因子可能是土壤总氮、电导率和土壤温度.偏Mantel检验分析和冗余分析(RDA)表明,常绿阔叶林和针阔叶混交林土壤甲烷氧化菌多样性受环境因子的影响较大,而暗针叶林和灌丛草甸土壤中甲烷氧化细菌多样性变化可能存在其他潜在的影响因素或者机制.降水可能是造成低海拔常绿阔叶林和针阔叶混交林与高海拔暗针叶林和灌丛草甸土壤甲烷氧化细菌群落结构差异的主要原因.贡嘎山海拔梯度上不同植被类型土壤中甲烷氧化菌的群落结构和多样性变化可能主要是由于土壤理化性质和气候变化综合作用的结果.     

Application of filamentous phages in environment: A tectonic shift in the science and practice of ecorestoration

Theories in soil biology, such as plant–microbe interactions and microbial cooperation and antagonism, have guided the practice of ecological restoration (ecorestoration). Below‐ground biodiversity (bacteria, fungi, invertebrates, etc.) influences the development of above‐ground biodiversity (vegetation structure). The role of rhizosphere bacteria in plant growth has been largely investigated but the role of phages (bacterial viruses) has received a little attention. Below the ground, phages govern the ecology and evolution of microbial communities by affecting genetic diversity, host fitness, population dynamics, community composition, and nutrient cycling. However, few restoration efforts take into account the interactions between bacteria and phages. Unlike other phages, filamentous phages are highly specific, nonlethal, and influence host fitness in several ways, which make them useful as target bacterial inocula. Also, the ease with which filamentous phages can be genetically manipulated to express a desired peptide to track and control pathogens and contaminants makes them useful in biosensing. Based on ecology and biology of filamentous phages, we developed a hypothesis on the application of phages in environment to derive benefits at different levels of biological organization ranging from individual bacteria to ecosystem for ecorestoration. We examined the potential applications of filamentous phages in improving bacterial inocula to restore vegetation and to monitor changes in habitat during ecorestoration and, based on our results, recommend a reorientation of the existing framework of using microbial inocula for such restoration and monitoring. Because bacterial inocula and biomonitoring tools based on filamentous phages are likely to prove useful in developing cost‐effective methods of restoring vegetation, we propose that filamentous phages be incorporated into nature‐based restoration efforts and that the tripartite relationship between phages, bacteria, and plants be explored further. Possible impacts of filamentous phages on native microflora are discussed and future areas of research are suggested to preclude any potential risks associated with such an approach.     

Molecular approaches: advantages and artifacts in assessing bacterial diversity

Bacteria account for a major proportion of Earth’s biological diversity. They play essential roles in quite diverse environments and there has been an increasing interest in bacterial biodiversity. Research using novel and efficient tools to identify and characterize bacterial communities has been the key for elucidating biological activities with potential for industrial application. The current approach used for defining bacterial species is based on phenotypic and genomic properties. Traditional and novel DNA-based molecular methods are improving our knowledge of bacterial diversity in nature. Advances in molecular biology have been important for studies of diversity, considerably improving our knowledge of morphological, physiological, and ecological features of bacterial taxa. DNA–DNA hybridization, which has been used for many years, is still considered the golden standard for bacteria species identification. PCR-based methods investigating 16S rRNA gene sequences, and other approaches, such as the metagenome, have been used to study the physiology and diversity of bacteria and to identify novel genes with potential pharmaceutical and other biotechnological applications. We examined the advantages and limitations of molecular methods currently used to analyze bacterial diversity; these are mainly based on the 16S rRNA gene. These methods have allowed us to examine microorganisms that cannot be cultivated by routine methods and have also been useful for phylogenetic studies. We also considered the importance of improvements in microbe culture techniques and how we can combine different methods to allow a more appropriate assessment of bacterial diversity and to determine their real potential for industrial applications.     

Patterns of bacterial diversity across a range of Antarctic terrestrial habitats

Although soil-borne bacteria represent the world's greatest source of biological diversity, it is not well understood whether extreme environmental conditions, such as those found in Antarctic habitats, result in reduced soil-borne microbial diversity. To address this issue, patterns of bacterial diversity were studied in soils sampled along a > 3200 km southern polar transect spanning a gradient of increased climate severity over 27 degrees of latitude. Vegetated and fell-field plots were sampled at the Falkland (51 degrees S), South Georgia (54 degrees S), Signy (60 degrees S) and Anchorage Islands (67 degrees S), while bare frost-sorted soil polygons were examined at Fossil Bluff (71 degrees S), Mars Oasis (72 degrees S), Coal Nunatak (72 degrees S) and the Ellsworth Mountains (78 degrees S). Bacterial 16S rRNA gene sequences were recovered subsequent to direct DNA extraction from soil, polymerase chain reaction amplification and cloning. Although bacterial diversity was observed to decline with increased latitude, habitat-specific patterns appeared to also be important. Namely, a negative relationship was found between bacterial diversity and latitude for fell-field soils, but no such pattern was observed for vegetated sites. The Mars Oasis site, previously identified as a biodiversity hotspot within this region, proved exceptional within the study transect, with unusually high bacterial diversity. In independent analyses, geographical distance and vegetation cover were found to significantly influence bacterial community composition. These results provide insight into the factors shaping the composition of bacterial communities in Antarctic terrestrial habitats and support the notion that bacterial diversity declines with increased climatic severity.     

Microbial Diversity and Community Structure in Two Different Agricultural Soil Communities

Abstract In this study, two different agricultural soils were investigated: one organic soil and one sandy soil, from Stend (south of Bergen), Norway. The sandy soil was a field frequently tilled and subjected to crop rotations. The organic soil was permanent grazing land, infrequently tilled. Our objective was to compare the diversity of the cultivable bacteria with the diversity of the total bacterial population in soil. About 200 bacteria, randomly isolated by standard procedures, were investigated. The diversity of the cultivable bacteria was described at phenotypic, phylogenetic, and genetic levels by applying phenotypical testing (Biolog) and molecular methods, such as amplified rDNA restriction analysis (ARDRA); hybridization to oligonucleotide probes; and REP-PCR. The total bacterial diversity was determined by reassociation analysis of DNA isolated from the bacterial fraction of environmental samples, combined with ARDRA and DGGE analysis. The relationship between the diversity of cultivated bacteria and the total bacteria was elucidated. Organic soil exhibited a higher diversity for all analyses performed than the sandy soil. Analysis of cultivable bacteria resulted in different resolution levels and revealed a high biodiversity within the population of cultured isolates. The difference between the two agricultural soils was significantly higher when the total bacterial population was analyzed than when the cultivable population was. Thus, analysis of microbial diversity must ultimately embrace the entire microbial community DNA, rather than DNA from cultivable bacteria.     

Changes in Diversity, Abundance, and Structure of Soil Bacterial Communities in Brazilian Savanna Under Different Land Use Systems

The Brazilian Savanna, also known as “Cerrado”, is the richest and most diverse savanna in the world and has been ranked as one of the main hotspots of biodiversity. The Cerrado is a representative biome in Central Brazil and the second largest biome in species diversity of South America. Nevertheless, large areas of native vegetation have been converted to agricultural land including grain production, livestock, and forestry. In this view, understanding how land use affects microbial communities is fundamental for the sustainable management of agricultural ecosystems. The aim of this work was to analyze and compare the soil bacterial communities from the Brazilian Cerrado associated with different land use systems using high throughput pyrosequencing of 16S rRNA genes. Relevant differences were observed in the abundance and structure of bacterial communities in soils under different land use systems. On the other hand, the diversity of bacterial communities was not relevantly changed among the sites studied. Land use systems had also an important impact on specific bacterial groups in soil, which might change the soil function and the ecological processes. Acidobacteria, Proteobacteria, and Actinobacteria were the most abundant groups in the Brazilian Cerrado. These findings suggest that more important than analyzing the general diversity is to analyze the composition of the communities. Since soil type was the same among the sites, we might assume that land use was the main factor defining the abundance and structure of bacterial communities.     

Succession of Bacterial Community Structure and Diversity in Soil along a Chronosequence of Reclamation and Re-Vegetation on Coal Mine Spoils in China

The growing concern about the effectiveness of reclamation strategies has motivated the evaluation of soil properties following reclamation. Recovery of belowground microbial community is important for reclamation success, however, the response of soil bacterial communities to reclamation has not been well understood. In this study, PCR-based 454 pyrosequencing was applied to compare bacterial communities in undisturbed soils with those in reclaimed soils using chronosequences ranging in time following reclamation from 1 to 20 year. Bacteria from the Proteobacteria, Chloroflexi, Actinobacteria, Acidobacteria, Planctomycetes and Bacteroidetes were abundant in all soils, while the composition of predominant phyla differed greatly across all sites. Long-term reclamation strongly affected microbial community structure and diversity. Initial effects of reclamation resulted in significant declines in bacterial diversity indices in younger reclaimed sites (1, 8-year-old) compared to the undisturbed site. However, bacterial diversity indices tended to be higher in older reclaimed sites (15, 20-year-old) as recovery time increased, and were more similar to predisturbance levels nearly 20 years after reclamation. Bacterial communities are highly responsive to soil physicochemical properties (pH, soil organic matter, Total N and P), in terms of both their diversity and community composition. Our results suggest that the response of soil microorganisms to reclamation is likely governed by soil characteristics and, indirectly, by the effects of vegetation restoration. Mixture sowing of gramineae and leguminosae herbage largely promoted soil geochemical conditions and bacterial diversity that recovered to those of undisturbed soil, representing an adequate solution for soil remediation and sustainable utilization for agriculture. These results confirm the positive impacts of reclamation and vegetation restoration on soil microbial diversity and suggest that the most important phase of microbial community recovery occurs between 15 and 20 years after reclamation.     

The bacterial biogeography of British soils

Despite recognition of the importance of soil bacteria to terrestrial ecosystem functioning there is little consensus on the factors regulating belowground biodiversity. Here we present a multi-scale spatial assessment of soil bacterial community profiles across Great Britain (> 1000 soil cores), and show the first landscape scale map of bacterial distributions across a nation. Bacterial diversity and community dissimilarities, assessed using terminal restriction fragment length polymorphism, were most strongly related to soil pH providing a large-scale confirmation of the role of pH in structuring bacterial taxa. However, while α diversity was positively related to pH, the converse was true for β diversity (between sample variance in α diversity). β diversity was found to be greatest in acidic soils, corresponding with greater environmental heterogeneity. Analyses of clone libraries revealed the pH effects were predominantly manifest at the level of broad bacterial taxonomic groups, with acidic soils being dominated by few taxa (notably the group 1 Acidobacteria and Alphaproteobacteria). We also noted significant correlations between bacterial communities and most other measured environmental variables (soil chemistry, aboveground features and climatic variables), together with significant spatial correlations at close distances. In particular, bacterial and plant communities were closely related signifying no strong evidence that soil bacteria are driven by different ecological processes to those governing higher organisms. We conclude that broad scale surveys are useful in identifying distinct soil biomes comprising reproducible communities of dominant taxa. Together these results provide a baseline ecological framework with which to pursue future research on both soil microbial function, and more explicit biome based assessments of the local ecological drivers of bacterial biodiversity.     

Phenotypic diversity and antibiotic resistance in soil bacterial communities

The community structure in two different agricultural soils has been investigated. Phenotypic diversity was assessed by applying BIOLOG-profiles on a total of 208 bacterial isolates. Diversity indices were calculated from cluster analysis of the BIOLOG data. The bacterial isolates were also evaluated for resistance towards six different antibiotics, mercury resistance and the presence of plasmids. The presence of tetracycline-resistant determinants class A to E among Gram-negative bacteria was analysed with DNA probes. The distribution of tetracycline resistance markers among colonies growing on non-selective and tetracycline-selective plates were compared. The phenotypic approach demonstrated some difference in the diversity within the two soils. The frequency of antibiotic resistance isolates was high in both soils, whereas the frequency of mercury resistance differed significantly. We found no correlation between plasmid profiles and antibiotic resistance patterns. We found all the tetracycline resistance determinants except class B, indicating that the diversity of the tetracycline resistance determinants was complex in populations of resident soil bacteria under no apparent selective pressure for the genes in question.     

模拟植物多样性的大尺度分布：从气候和生产力推知的一种可能性（英文）

 鉴于全球植被/生物群区在现状气候条件下已经被很好地模拟并在未来气候变化情景下得到很好的预测,人们有必要和急需模拟大尺度（区域、洲际至全球）植物多样性的分布格局。陆地生物圈模型的发展（从生物地理模型和生物地球化学模型到动态和耦合的植被模型）,气候-生物多样性相互关系和生产力-生物多样性相互关系研究成果的增多,以及基于现有生物多样性调查的全球生物多样性理论和经验制图的进步,加大了模拟大尺度植物多样性格局的可能性。本文的目的是：综述当前气候-生物多样性相互关系和生产力-生物多样性相互关系的主要研究成果以及大尺度     

Can Organic Amendments Be Useful in Transforming a Mediterranean Shrubland into a Dehesa?

Transforming a shrubland into a dehesa system may be useful for recovering certain productive and regulatory functions of ecosystems such as grazing potential, soil erosion control, and also for reducing the risk of wildfire. However, the productivity of the herbaceous cover and tree development in the transformed system may be limited by soil fertility, especially after wildfire events. Previous studies have shown that adequate doses of sewage sludge may improve soil fertility and facilitate plant recovery, but few studies have focused on plant biodiversity assessment. Here, we compare the effects of sewage sludge that has undergone different post‐treatments (dewatering, composting, or thermal drying) as a soil amendment used to transform a fire‐affected shrubland into a dehesa, on tree growth and pasture composition (vegetation cover, species richness, and diversity). In the short term, sewage sludge causes changes in both pasture cover and tree growth. Although no major differences in vegetation species richness and composition have been detected, fertilization using sewage sludge was shown to modify the functional diversity of the vegetation community. Rapid replacement of shrubs by herbaceous cover and ruderal plants (e.g. Bromus hordeaceus and Leontodon taraxacoides) and of the three grass species sown (Festuca arundinacea, Lolium perenne, and Dactylis glomerata) was observed, whereas N‐fixing species (leguminous) tended to be more abundant in nonfertilized soils and soils amended with composted sludge. These results indicate that sewage sludge modifies the functionality of vegetation when applied to soils, and that the response varies according to the treatment that the sludge has undergone.