Seasonal changes in an alpine soil bacterial community in the colorado rocky mountains

The period when the snowpack melts in late spring is a dynamic time for alpine ecosystems. The large winter microbial community begins to turn over rapidly, releasing nutrients to plants. Past studies have shown that the soil microbial community in alpine dry meadows of the Colorado Rocky Mountains changes in biomass, function, broad-level structure, and fungal diversity between winter and early summer. However, little specific information exists on the diversity of the alpine bacterial community or how it changes during this ecologically important period. We constructed clone libraries of 16S ribosomal DNA from alpine soil collected in winter, spring, and summer. We also cultivated bacteria from the alpine soil and measured the seasonal abundance of selected cultured isolates in hybridization experiments. The uncultured bacterial communities changed between seasons in diversity and abundance within taxa. The Acidobacterium division was most abundant in the spring. The winter community had the highest proportion of Actinobacteria and members of the Cytophaga/Flexibacter/Bacteroides (CFB) division. The summer community had the highest proportion of the Verrucomicrobium division and of beta-PROTEOBACTERIA: As a whole, alpha-Proteobacteria were equally abundant in all seasons, although seasonal changes may have occurred within this group. A number of sequences from currently uncultivated divisions were found, including two novel candidate divisions. The cultured isolates belonged to the alpha-, beta-, and gamma-Proteobacteria, the Actinobacteria, and the CFB groups. The only uncultured sequences that were closely related to the isolates were from winter and spring libraries. Hybridization experiments showed that actinobacterial and beta-proteobacterial isolates were most abundant during winter, while the alpha- and gamma-proteobacterial isolates tested did not vary significantly. While the cultures and clone libraries produced generally distinct groups of organisms, the two approaches gave consistent accounts of seasonal changes in microbial diversity.     

Seasonal Changes in an Alpine Soil Bacterial Community in the Colorado Rocky Mountains

The period when the snowpack melts in late spring is a dynamic time for alpine ecosystems. The large winter microbial community begins to turn over rapidly, releasing nutrients to plants. Past studies have shown that the soil microbial community in alpine dry meadows of the Colorado Rocky Mountains changes in biomass, function, broad-level structure, and fungal diversity between winter and early summer. However, little specific information exists on the diversity of the alpine bacterial community or how it changes during this ecologically important period. We constructed clone libraries of 16S ribosomal DNA from alpine soil collected in winter, spring, and summer. We also cultivated bacteria from the alpine soil and measured the seasonal abundance of selected cultured isolates in hybridization experiments. The uncultured bacterial communities changed between seasons in diversity and abundance within taxa. The Acidobacterium division was most abundant in the spring. The winter community had the highest proportion of Actinobacteria and members of the Cytophaga/Flexibacter/Bacteroides (CFB) division. The summer community had the highest proportion of the Verrucomicrobium division and of β-Proteobacteria. As a whole, α-Proteobacteria were equally abundant in all seasons, although seasonal changes may have occurred within this group. A number of sequences from currently uncultivated divisions were found, including two novel candidate divisions. The cultured isolates belonged to the α-, β-, and γ-Proteobacteria, the Actinobacteria, and the CFB groups. The only uncultured sequences that were closely related to the isolates were from winter and spring libraries. Hybridization experiments showed that actinobacterial and β-proteobacterial isolates were most abundant during winter, while the α- and γ-proteobacterial isolates tested did not vary significantly. While the cultures and clone libraries produced generally distinct groups of organisms, the two approaches gave consistent accounts of seasonal changes in microbial diversity.     

氮肥添加对高寒藏嵩草(Kobresia tibetica)沼泽化草甸和土壤微生物群落的影响

以藏嵩草沼泽化草甸为研究对象,利用磷脂脂肪酸(PLFA)技术,研究连续6年N素添加对地上植被群落数量特征、土壤微生物群落结构的影响。结果表明:①藏嵩草沼泽化草甸群落生物量、枯枝落叶对施肥处理无明显响应,且莎草科植物对土壤氮素的吸收和利用率较低。②施肥增加了0-10 cm土壤微生物类群PLFAs丰富度尤其细菌和革兰氏阳性菌PLFAs,降低了10-20 cm PLFAs丰富度;③磷脂脂肪酸饱和脂肪酸/单烯不饱和脂肪酸、细菌PLFAs/真菌PLFAs的比值随土壤层次增加而增加;④0-10 cm土层革兰氏阳性菌、真菌PLFAs含量与pH、土壤速效磷、速效氮、土壤有机质显著正相关(P0.05或P0.01);10-20 cm土层,细菌、革兰氏阳性菌、真菌和总PLFAs含量与土壤有机质含量显著正相关(P0.05或P0.01)。表明藏嵩草沼泽化草甸微生物PLFAs含量和丰富度对施肥的响应存在明显的土层梯度效应,土壤微生物PLFAs含量和丰富度主要受表层土壤初始养分含量的影响。     

青藏高原多年冻土区不同水分条件的高寒草甸根系功能性状对增温的响应

在青藏高原多年冻土广泛分布的风火山地区,选择小嵩草（Kobresia pygmea）草甸和藏嵩草（Kobresia tibetica）沼泽化草甸为研究对象,采用开顶增温室（Open top chambers, OTCs）模拟气候变暖,探讨模拟增温对土壤水分差异的两种草甸地下生物量及根系功能性状的影响。结果显示,（1）增温显著增加小嵩草草甸0—20 cm根系生物量,主要是由于表层（0—10 cm）根系生物量显著增加,而对藏嵩草沼泽化草甸根系生物量无影响。（2）增温显著增加了小嵩草草甸根组织密度,同时提高了藏嵩草沼泽化草甸10—20 cm的比根长和比根面积（3）增温降低了小嵩草草甸的根系碳含量及10—20 cm根系氮含量,增加了藏嵩草沼泽化草甸的碳含量及10—20 cm根系氮含量,显著提高了小嵩草草甸和藏嵩草沼泽化草甸深层（10—20 cm）根系碳氮比。这些结果预示着增温使得土壤水分较低的小嵩草草甸朝着资源保守的慢速生长型发展,以适应暖干化的环境;土壤水分较高的藏嵩草沼泽化草甸朝着资源获取的快速生长型发展,加速利用土壤中的养分满足植物生长需要。可见,土壤水分可以调节高寒草甸对气候变暖的演变趋势,强调了水分的重要性。     

高寒地区不同海拔梯度西北小檗生境土壤微生物群落结构及多样性分析

以青海高原2 300～4 000 m海拔范围的6处西北小檗(Berberis vernae)生境土壤为试材,采用高通量测序方法,分析不同海拔梯度西北小檗生境土壤微生物群落结构及多样性。研究结果表明:(1)在西北小檗生境土壤中,细菌群落组成主要包括10个细菌门21个细菌属,真菌群落由子囊菌门、担子菌门等8个真菌门59个真菌属组成。(2)低海拔位置的海东乐都1号样点(hdld1) 0～20 cm土层的细菌群落丰富性及多样性均最高,黄南泽库样点(hnzk) 0～20 cm土层的真菌群落丰富度最高,西宁大通样点(xndt) 0～20 cm土层的真菌群落多样性最高;随着海拔的升高,0～20 cm、40～60 cm土层的细菌群落丰富度及多样性呈现出先降低再升高再降低的趋势,20～40 cm土层的细菌群落丰富度及多样性则呈现出先升高后降低的趋势,0～20 cm、20～40 cm土层土壤微生物真菌群落丰富度呈现出先升高再降低再升高的趋势,0～20 cm、40～60 cm土层真菌群落多样性呈现先升高再降低的趋势,40～60 cm土层的真菌丰富度及20～40 cm土层的真菌多样性的变化趋势不明显。(3)硝态氮、速效磷和速效钾对土壤微生物群落的影响较明显。综上可知,高寒地区不同海拔梯度西北小檗生境土壤微生物群落结构多样性呈现出一定的海拔差异趋势,其海拔差异主要受到环境条件、土壤理化性质和植被分布的影响。     

大兴安岭落叶松林不同演替阶段土壤细菌群落结构与功能潜势

采用土壤细菌16S rDNA高通量测序方法研究了大兴安岭汗马自然保护区落叶松林不同演替阶段的土壤细菌群落结构和功能.结果表明: 不同演替阶段落叶松林土壤细菌优势门为变形菌门、酸杆菌门、疣微菌门、拟杆菌门、放线菌门、浮霉菌门和绿弯菌门,随着演替的进行,酸杆菌门相对丰度逐渐增加,绿弯菌门相对丰度逐渐减少,优势门相对丰度在不同演替阶段不同.细菌群落α多样性在不同演替阶段间无显著差异,但其群落结构分别在落叶松幼龄林与中龄林、幼龄林与过熟林、近熟林与成熟林之间存在显著差异.土壤氧化还原电位、土壤pH和有效磷是影响细菌群落结构的主要环境因素,其中土壤氧化还原电位对微生物群落结构影响最大.随着演替的进行,细菌参与的固氮作用、反硝化作用、氨氧化作用、木质素降解作用呈逐渐减弱的趋势,硫酸盐异化还原作用呈先降后升的趋势,碳固定作用呈先升后降的趋势,碱性磷酸酶没有明显的变化规律,影响土壤功能的主要因素有土壤有效磷和氧化还原电位等.     

高原鼠兔干扰对高寒草甸植物多样性与土壤养分间关系的影响

高原鼠兔干扰虽然能够改变高寒草甸植物多样性与土壤养分含量,但植物多样性与土壤养分间的关系对高原鼠兔干扰的响应尚不清晰。利用高原鼠兔有效洞口密度将高原鼠兔干扰程度划分为T_1(7个/625 m~2)、T_2(12个/625 m~2)、T_3(22个/625m~2)、T_4(38个/625 m~2)4个水平,运用RDA冗余分析法研究了高原鼠兔不同干扰程度下高寒草甸植物多样性与土壤养分间的关系。结果表明:随着高原鼠兔干扰水平的增加,优势种高山嵩草(Kobresia pygmaea)的重要值先增加后降低,而伴生种小花草玉梅(Anemone rivularis var.flore-minors)和莓叶委陵菜(Potentilla fragarioides)的重要值先降低后增加;当高原鼠兔干扰水平从T_1到T_2时植物多样性指数变化不显著,而高原鼠兔干扰程度超过T_2时则植物多样性指数具有降低趋势;土壤全氮和硝态氮含量随高原鼠兔干扰水平增加而降低,而土壤铵态氮含量则降低后增加,土壤有机碳和全磷先增加后降低;多样性指数与0—10cm土壤深度硝态氮、10—20cm土壤深度全钾间的相关性从T_1到T_3时为正相关,而到T_4时则变为负相关,而与0—10cm土壤深度全氮的相关性则表现T_1到T_3时为负相关,T_4时为正相关,与铵态氮间相关性只有T_1时为负相关,这说明高原鼠兔干扰改变了植物多样性与土壤养分间的关系,其变化阈值介于T_2和T_3。     

藏东南典型暗针叶林不同土壤剖面微生物群落特征

深层土壤中的微生物群落对陆地生态系统养分和能量循环转化过程不可或缺,研究青藏高原典型暗针叶林带土壤微生物群落在土壤垂直剖面的变化特征,对深入认识高寒区域森林生态系统土壤微生物群落构建特征及全球变化影响预测具有重要意义。运用Illumina Miseq高通量测序技术和分子生态网络分析,研究藏东南色季拉山暗针叶林带表层（0-20 cm）和底层土壤（40-60 cm）微生物群落组成及分子生态网络结构。研究结果表明随着土壤深度增加,真菌和细菌的丰富度和Shannon多样性指数显著降低。主坐标分析（PCoA）显示土壤深度显著影响真菌和细菌的群落结构（P < 0.01）。不同微生物种群对土壤深度的响应有显著差异,座囊菌纲（Dothideomycetes）、银耳纲（Tremellomycetes）和拟杆菌门（Bacteroidetes）、变形菌门（Proteobacteria）的相对丰度随剖面加深而显著降低,而古菌根菌纲（Archaeorhizomycetes）和绿弯菌门（Chloroflexi）则显著增加。分子生态网络分析发现,真菌网络以负相关连接为主（占总连接数65%-98%）,而细菌网络以正相关连接为主（69%-75%）,真菌和细菌网络中正相关连接的比例均随剖面加深而增加。底层土壤真菌和细菌网络的平均连接度和平均聚类系数均高于表层土壤,说明微生物网络随土壤深度的增加而变得更复杂。真菌网络的平均路径距离和模块性在底层土壤均大于表层土壤,意味着真菌网络应对环境变化的稳定性随剖面加深而增加,而细菌网络则正相反,在表层土壤的稳定性更强。真菌网络中连接节点的个数随剖面加深而增加,锤舌菌纲（Leotiomycetes）是连接网络模块的关键菌种;在细菌网络中模块枢纽和连接节点则随剖面加深而降低,并且放线菌门、变形菌门等关键种群在分子生态网络中的功能在表层和底层土壤有明显差异。综上所述,藏东南色季拉山暗针叶林带深层土壤中微生物群落特征与表层土壤有显著差别,揭示影响深层土壤微生物网络构建和稳定的关键种群,对深入理解和预测青藏高原森林生态系统对全球变化的响应与反馈有重要意义。     

季节性冻结初期川西亚高山/高山森林土壤细菌多样性

高山/亚高山显著的季节性冻结过程可能对土壤细菌多样性产生重要影响。为了解季节性冻结初期土壤完全冻结前后川西亚高山/高山森林群落土壤细菌多样性变化特征,于2008年11月5日(土壤冻结前期)—11月25日(土壤完全冻结期)期间,采用PCR-DGGE技术同步研究了原始冷杉(Abies faxoniana)林(PF)、针阔混交林(MF)和次生冷杉林(SF)的土壤细菌群落多样性变化特征。土壤完全冻结后,3个森林群落仍然具有较高的土壤细菌多样性。3个森林的土壤细菌类群总数在土壤冻结前表现为MFSFPF,但在土壤完全冻结后表现为PFMFSF。土壤冻结明显降低了土壤细菌多样性,但提高了土壤细菌群落的优势度。冻结作用对土壤细菌群落的影响随着土壤深度增加而降低,随着海拔升高而降低。这些结果表明季节性冻结过程对亚高山/高山森林土壤细菌多样性有着显著的影响,这对深入认识冬季土壤生态过程具有重要意义。     

Responses of Soil Microbial Communities to Experimental Warming in Alpine Grasslands on the Qinghai-Tibet Plateau

Global surface temperature is predicted to increase by at least 1.5°C by the end of this century. However, the response of soil microbial communities to global warming is still poorly understood, especially in high-elevation grasslands. We therefore conducted an experiment on three types of alpine grasslands on the Qinghai-Tibet Plateau to study the effect of experimental warming on abundance and composition of soil microbial communities at 0–10 and 10–20 cm depths. Plots were passively warmed for 3 years using open-top chambers and compared to adjacent control plots at ambient temperature. Soil microbial communities were assessed using phospholipid fatty acid (PLFA) analysis. We found that 3 years of experimental warming consistently and significantly increased microbial biomass at the 0–10 cm soil depth of alpine swamp meadow (ASM) and alpine steppe (AS) grasslands, and at both the 0–10 and 10–20 cm soil depths of alpine meadow (AM) grasslands, due primarily to the changes in soil temperature, moisture, and plant coverage. Soil microbial community composition was also significantly affected by warming at the 0–10 cm soil depth of ASM and AM and at the 10–20 cm soil depth of AM. Warming significantly decreased the ratio of fungi to bacteria and thus induced a community shift towards bacteria at the 0–10 cm soil depth of ASM and AM. While the ratio of arbuscular mycorrhizal fungi to saprotrophic fungi (AMF/SF) was significantly decreased by warming at the 0–10 cm soil depth of ASM, it was increased at the 0–10 cm soil depth of AM. These results indicate that warming had a strong influence on soil microbial communities in the studied high-elevation grasslands and that the effect was dependent on grassland type.     

Microbial biodiversity of thermophilic communities in hot mineral soils of Tramway Ridge, Mount Erebus, Antarctica

Tramway Ridge, located near the summit of Mount Erebus in Antarctica, is probably the most remote geothermal soil habitat on Earth. Steam fumaroles maintain moist, hot soil environments creating extreme local physicochemical differentials. In this study a culture-independent approach combining automated rRNA intergenic spacer analysis (ARISA) and a 16S rRNA gene library was used to characterize soil microbial (Bacterial and Archaeal) diversity along intense physicochemical gradients. Statistical analysis of ARISA data showed a clear delineation between bacterial community structure at sites close to fumaroles and all other sites. Temperature and pH were identified as the primary drivers of this demarcation. A clone library constructed from a high-temperature site led to the identification of 18 novel bacterial operational taxonomic units (OTUs). All 16S rRNA gene sequences were deep branching and distantly (85–93%) related to other environmental clones. Five of the signatures branched with an unknown group between candidate division OP10 and Chloroflexi . Within this clade, sequence similarity was low, suggesting it contains several yet-to-be described bacterial groups. Five archaeal OTUs were obtained and exhibited high levels of sequence similarity (95–97%) with Crenarchaeota sourced from deep-subsurface environments on two distant continents. The novel bacterial assemblage coupled with the unique archaeal affinities reinvigorates the hypotheses that Tramway Ridge organisms are relics of archaic microbial lineages specifically adapted to survive in this harsh environment and that this site may provide a portal to the deep-subsurface biosphere.     

疏勒河源高寒草甸土壤微生物生物量碳氮变化特征

土壤微生物生物量是土壤有机质的活性部分,是反映土壤质量和碳氮循环机制的重要指标。本文以青藏高原东北缘疏勒河源高寒草甸为研究对象,对土壤微生物生物量碳（SMBC, mg/kg）和微生物生物量氮（SMBN, mg/kg）的不同季节（春、夏、秋、冬）和土层（0—10、10—20、20—30、30—40、40—50 cm）变化特征及其影响因素进行研究。结果表明：（1）不同土层SMBC均表现为春季开始逐渐升高、夏季达到最大值、秋季逐渐降低、冬季值最小,而SMBN春季开始逐渐降低、夏季值最小、秋季逐渐升高、冬季达到最大值。（2）SMBC、SMBN随着土壤深度的增加而下降,0—10 cm层SMBC、SMBN显著高于40—50 cm层,且SMBC、SMBN0—10 cm层的季节变幅显著大于40—50 cm层。（3）0—50 cm土层SMBC/SMBN表现为春季开始逐渐升高、夏季达到最大值、秋季逐渐降低、冬季值最小,其季节变化范围为8.77—23.59,处于较高水平。（4）SMBC、SMBN、SMBC/SMBN的季节和土层变化主要受植被地下生物量和土壤温度的影响。（5）各土层SMBC/SOC均表现为春季开始逐渐升高、夏季达到最大值、秋季逐渐降低、冬季值最小,而SMBN/TN春季开始逐渐降低、夏季值最小、秋季逐渐升高、冬季达到最大值。除夏季土层间无显著差异外,SMBC/SOC与SMBN/TN均表现为0—10 cm层显著高于40—50 cm层。（6）0—50 cm土层SMBC/SOC夏秋季显著高于冬春季且其季节变化范围为0.58%—1.18%,而SMBN/TN秋冬季显著高于夏季且其季节变化范围为0.39%—0.72%。综上,季节变化和剖面深度均对SMBC、SMBN产生显著影响且0—10 cm土层对SMBC、SMBN的累积能力最强。     

Influence of sulfide and temperature on species composition and community structure of hot spring microbial mats

In solfataric fields in southwestern Iceland, neutral and sulfide-rich hot springs are characterized by thick bacterial mats at 60 to 80 degrees C that are white or yellow from precipitated sulfur (sulfur mats). In low-sulfide hot springs in the same area, grey or pink streamers are formed at 80 to 90 degrees C, and a Chloroflexus mat is formed at 65 to 70 degrees C. We have studied the microbial diversity of one sulfur mat (high-sulfide) hot spring and one Chloroflexus mat (low-sulfide) hot spring by cloning and sequencing of small-subunit rRNA genes obtained by PCR amplification from mat DNA. Using 98% sequence identity as a cutoff value, a total of 14 bacterial operational taxonomic units (OTUs) and 5 archaeal OTUs were detected in the sulfur mat; 18 bacterial OTUs were detected in the Chloroflexus mat. Although representatives of novel divisions were found, the majority of the sequences were >95% related to currently known sequences. The molecular diversity analysis showed that Chloroflexus was the dominant mat organism in the low-sulfide spring (1 mg liter(-1)) below 70 degrees C, whereas Aquificales were dominant in the high-sulfide spring (12 mg liter(-1)) at the same temperature. Comparison of the present data to published data indicated that there is a relationship between mat type and composition of Aquificales on the one hand and temperature and sulfide concentration on the other hand.     

黄河三角洲盐碱地花生根层土壤菌群结构多样性

花生属豆科固氮作物,具较强的抗旱耐盐性,土壤微生物在盐碱土生态系统中具有重要的生态功能。以花生平作、花生/棉花间作为对象,通过16S rRNA基因克隆文库技术分析了黄河三角洲滨海盐碱地花生旺盛生长期不同含盐量盐碱地和非盐碱地0—40cm根层非培养土壤微生物群落组成及其多样性,分析了盐碱地花生根层土壤细菌群落与非盐碱地花生根层土壤细菌群落的差异,为揭示盐碱地花生根层土壤微生物的多样性以及土地利用变化与生态环境效应间的关系奠定基础。利用免培养技术直接从土壤样品提取总DNA,针对细菌基因组16S rRNA基因的V3高变区进行PCR扩增;利用焦磷酸测序的方法对V3高变区PCR产物进行高通量测序,并对测序数据进行生物信息学分析。结果表明,(1)黄河三角洲滨海盐碱土较高含盐量土壤中根层土壤微生物种类、优势种群数量和群落功能多样性较非盐碱土壤较为丰富。(2)盐碱土花生平作或花生//棉花间作两种种植方式基本不影响二者0—40cm根层土壤微生物优势类群;不同土壤类型和种植模式下,花生和棉花根层土壤中优势菌群均为变形菌门(Proteobacteria)、放线菌门(Actinobacteria)、绿弯菌门(Chloroflexi)和酸杆菌门(Acidobacteria) 4种菌群,其总丰度为80%—90%。非盐碱土壤中花生根层的酸杆菌门(Acidobacteria)丰度是盐碱土壤中的3倍以上,嗜热油菌纲(Thermoleophilia)和放线菌纲(Actinomycetales)丰度远高于各种盐碱土壤花生平作和花生//棉花间作两种植模式下的花生根层土壤;非盐碱土平作花生0—40cm土层中Rubellimicrobium、Pontibacter和Lamia细菌则显著缺失。(3)土壤类型对土壤微生物菌群类型影响较大,聚类分析表明,10个土壤样本依据土壤含盐量高低和根系分布深度聚为3类,即非盐碱土壤归为1类,盐碱土壤根系密集分布层0—20cm、20—40cm各归为1类。     

中亚热带地区米槠天然林土壤微生物群落结构的多样性

为了解土壤微生物群落的结构,采用磷脂脂肪酸方法对武夷山和建瓯的米槠(Castanopsis carlesii)天然林土壤微生物群落的结构多样性进行了研究。结果表明,两地米槠天然林的土壤微生物群落组成十分丰富,多样性指数、丰富度指数和均匀度指数分别为2.92~3.01、25.84~28.23 和0.88~0.90。0~10 cm土层的磷脂脂肪酸总量、细菌特征脂肪酸、真菌特征脂肪酸、放线菌特征脂肪酸、革兰氏阳性菌和阴性菌特征脂肪酸含量均高于10~20 cm土层的,且建瓯万木林自然保护区的高于武夷山国家级自然保护区。10~20 cm土层的革兰氏阳性菌/革兰氏阴性菌高于0~10 cm土层的;细菌特征脂肪酸含量显著高于真菌,表明细菌在土壤微生物群落结构中处于优势地位。主成分分析表明,土壤微生物群落结构的差异主要是由采样地点的不同引起。     

腾格里沙漠东南缘不同生物土壤结皮细菌多样性及其季节动态特征

微生物多样性对于生物土壤结皮在沙漠生态系统中改善局部环境以及提升生态功能具有重要作用。本研究对腾格里沙漠东南缘沙坡头地区藻结皮、藓结皮及其下层的四季样品进行了16S rDNA高通量测序, 以期阐明细菌多样性及其在生物土壤结皮演替过程中的季节变化规律。结果表明4种类型样品的细菌丰富度在夏季显著低于其他3个季节。4种类型样品中主要的细菌类群为变形菌门、放线菌门、绿弯菌门、酸杆菌门、蓝细菌门等, 其中变形菌门和放线菌门为优势类群, 夏季时变形菌门的相对多度显著高于春季、秋季、冬季, 且在结皮层中相对多度显著高于结皮下层。放线菌门的相对多度在春季、夏季显著高于秋季、冬季, 且结皮下层相对多度高于结皮层。生物土壤结皮演替过程中细菌多样性及其相对多度季节动态变化表明其对沙漠土壤局部环境的变化作出了响应, 这为深入理解生物土壤结皮在沙漠生态系统中的生态功能提供了微生物多样性数据。     

基于高通量测序技术的不同年代公园绿地土壤细菌多样性

【背景】细菌多样性对绿地土壤生态功能有重要作用,但不同年代公园绿地土壤的细菌多样性尚未见相关报道。【目的】研究北京市不同年代公园绿地土壤细菌多样性和群落结构特征。【方法】利用IlluminaMiSeq测序技术,分别对北京市代表性古典公园和现代公园绿地土壤细菌群落多样性进行分析。【结果】北京市公园绿地土壤细菌群落共划分为45个已知的菌门,其中变形菌门、酸杆菌门、绿弯菌门和放线菌门为优势细菌群。土壤细菌群落α多样性分析结果表明,古典公园和现代公园的土壤细菌多样性存在差异,表现为古典公园的丰富度和多样性都高于现代公园。此外,土壤细菌群落相似性分析和主坐标分析都表明古典公园和现代公园的土壤细菌群落结构存在显著差异。冗余分析表明,对土壤微生物群落结构产生显著影响的环境因子分别为土壤含水量、有机质和全氮,其它土壤环境因子无统计学意义。首次引入公园年代作为影响因子进行冗余分析的研究结果表明,公园年代为影响公园细菌群落多样性的重要因子。【结论】不同年代公园绿地土壤细菌群落结构和物种多样性具有显著差异,随着公园年代的增加,土壤肥力和微生物多样性增加,绿地生态系统更稳定,可通过制定不同的绿地管理措施改变公园绿地土壤环境,进而优化土壤细菌群落结构,促进土壤碳氮养分循环,提高土壤肥力。     

宜春温泉水体与泉底沉积物细菌多样性分析

研究宜春富硒温泉水体与泉底沉积物的细菌群落多样性。利用高通量测序技术分析泉水与沉积物中细菌群落结构与多样性。温泉水中主要的细菌类群为变形菌门和拟杆菌门,而在沉积物样品中的主要优势菌群为OP1、蓝细菌、浮霉菌门和绿弯菌门。细菌在属分类水平上,温泉水中优势菌群为不动杆菌属、假单胞菌属、水栖菌属、Thermosynechococcus、鞘脂杆菌属和金黄杆菌属等。沉积物样品细菌中优势菌群属于未知物种,在数据库中并没有相关的注释信息;其中已知的优势菌属为Candidatus acetothermum、Thermosynechococcus、亚热栖菌属、不动杆菌属。宜春温汤富硒温泉水体与沉积物中存在着丰富的微生物群落且组成差异性很大,该研究为了解与发掘温泉微生物菌种资源具有重要价值。     

祁连山3种典型生态系统土壤微生物活性和生物量碳氮含量

 测定分析了祁连山高寒草甸、山地森林和干草原土壤中微生物活性、生物量碳氮含量。结果显示：就土壤微生物生物量碳含量,森林比干草原和高寒草甸中分别高60%和120%以上,干草原比高寒草甸中高40%以上(p<0.05)。就土壤微生物生物量氮含量,0～5 cm土层,森林比高寒草甸和干草原中分别高64%和111%以上,高寒草甸比干草原中高29%;5～15 cm土层,森林比干草原和高寒草甸中分别高7%和191%以上,干草原比高寒草甸中高171% 以上(p<0.05)。森林和干草原中土壤微生物生物量碳比例比高寒草甸中高32%以上,0～5和5～15 cm土层,森林和干草原中土壤微生物生物量氮比例比高寒草甸中高150%以上（p<0.05）。就土壤微生物活性,0～5和5～15 cm土层,森林和高寒草甸比干草原中高26%以上;15～35 cm土层,森林比干草原和高寒草甸中高28%以上 (p<0.05)。土壤微生物生物量碳氮含量与有机碳含量及微生物生物量氮含量和比例与微生物生物量碳含量和比例呈现正相关（r²>0.30,p<0.000 1）。土壤微生物生物量氮含量、微生物生物量碳氮含量比例、微生物活性与土壤pH值呈显著负相关,土壤微生物生物量碳氮含量及其比例、微生物活性与土壤湿度呈正相关。说明祁连山3种生态系统土壤中微生物生物量和活性受气候要素、植被、有机碳、pH值和湿度等因素 的共同影响。     

Vertical distribution of bacterial community is associated with the degree of soil organic matter decomposition in the active layer of moist acidic tundra

The increasing temperature in Arctic tundra deepens the active layer, which is the upper layer of permafrost soil that experiences repeated thawing and freezing. The increasing of soil temperature and the deepening of active layer seem to affect soil microbial communities. Therefore, information on soil microbial communities at various soil depths is essential to understand their potential responses to climate change in the active layer soil. We investigated the community structure of soil bacteria in the active layer from moist acidic tundra in Council, Alaska. We also interpreted their relationship with some relevant soil physicochemical characteristics along soil depth with a fine scale (5 cm depth interval). The bacterial community structure was found to change along soil depth. The relative abundances of Acidobacteria, Gammaproteobacteria, Planctomycetes, and candidate phylum WPS-2 rapidly decreased with soil depth, while those of Bacteroidetes, Chloroflexi, Gemmatimonadetes, and candidate AD3 rapidly increased. A structural shift was also found in the soil bacterial communities around 20 cm depth, where two organic (upper Oi and lower Oa) horizons are subdivided. The quality and the decomposition degree of organic matter might have influenced the bacterial community structure. Besides the organic matter quality, the vertical distribution of bacterial communities was also found to be related to soil pH and total phosphorus content. This study showed the vertical change of bacterial community in the active layer with a fine scale resolution and the possible influence of the quality of soil organic matter on shaping bacterial community structure.