茶树连作障碍形成机制及调控措施研究进展

茶树多年宿根连作后茶园土壤退化严重, 茶叶产量和品质大幅下降, 严重制约了我国茶叶的可持续生产。面对如何维持茶树高产高质这一科学难题, 连作障碍机制及其调控措施成为当前茶树栽培中急待解决的科学问题。据此文章从土壤养分失衡、土壤酸化、自毒作用、土壤微生物群落结构失衡、根际微生态等方面概述了茶树连作障碍形成机制的研究进展, 同时从化学改良、增施有机肥、生物质材料、生物菌肥、茶园多样性栽培等方面介绍缓解茶树连作障碍的主要措施, 并对今后茶树连作障碍形成机制的进一步研究及防控技术的发展方向提出展望, 以期为解决茶树连作障碍问题提供一些科学依据。     

不同年限茶树根际土壤微生物群落PLFA生物标记多样性分析

以1年生、6年生与20年生茶树根际土壤为研究对象,利用磷脂脂肪酸(PLFAs)生物标记法,对不同年限茶树根际土壤微生物多样性进行了研究.结果表明:6年生茶树根际土壤的PLFA总量最大,其细菌、放线菌与原生动物的PLFA含量高于其他土壤样品;20年生茶树根际土壤的真菌PLFA含量高于其他土壤样品,细菌PLFA含量与1年生茶树根际土壤相近(P＞0.05),放线菌与原生动物PLFA含量均低于其他土壤样品(P＜0.01);在20年生茶树土壤中,一些参与土壤物质循环的微生物类群的丰度在下降,一些代谢能力低的类群丰度增加;土壤酶活性分析结果表明,与6年生茶树土壤相比,20年生茶树土壤的脲酶、酸性磷酸单酯酶与过氧化物酶活性较低,蔗糖酶与多酚氧化酶活性较高;通过相关性分析发现,不同年限茶树土壤细菌、放线菌、真菌、原生动物各总PLFA与酶活性、土壤肥力因子之间密切相关;随着茶树种植年限的增加,茶树根际土壤的微生物群落结构发生了较大的变化,体现在微生物群落的多样性降低,适应于贫瘠条件与低代谢能力的种群增多,反映出根际土壤质量与一些关键酶活性出现较大幅度下降.     

施磷对干旱胁迫下箭竹根际土壤养分及微生物群落的影响

以箭竹及其根际土壤作为研究对象,采用两因素随机区组实验,设置2种水分处理（正常浇水和干旱胁迫）和2种施磷量处理（施磷和不施磷）,探究施磷对干旱胁迫下箭竹根际土壤养分及微生物群落结构和多样性的影响。结果表明：（1）干旱胁迫显著降低了箭竹根际土壤中微生物量碳、可溶性有机氮和有效磷的含量,虽对箭竹根际土壤微生物群落的多样性无显著影响,但显著降低了箭竹根际土壤中总PLFA（phospholipid fatty acid contents）的含量和真菌、细菌、革兰氏阳性菌与革兰氏阴性菌的PLFA含量以及革兰氏阳性菌/革兰氏阴性菌的PLFA比值,显著改变了箭竹根际土壤微生物群落结构,结果显著降低了箭竹的生物量。（2）施磷显著增加了受旱箭竹根际土壤中微生物量碳和有效磷的含量,虽大体上对受旱箭竹根际土壤微生物群落的多样性无显著影响,但显著增加了受旱箭竹根际土壤中总PLFA和真菌PLFA的含量,并在一定程度上增加了细菌、革兰氏阳性菌、革兰氏阴性菌和放线菌的PLFA含量以及革兰氏阳性菌/革兰氏阴性菌和真菌/细菌的PLFA比值,也在一定程度上改善了受旱箭竹根际土壤微生物群落结构,从而改善受旱箭竹的生长。（3）主成分分析表明,干旱对箭竹根际土壤微生物群落结构的影响显著,而施磷的影响不明显。（4）相关分析发现,箭竹根际土壤微生物群落结构与箭竹根际土壤微生物量碳、可溶性有机氮及箭竹生物量呈显著正相关。综上,干旱降低了箭竹根际土壤养分含量和微生物生物量,改变了箭竹根际土壤微生物群落结构,抑制了箭竹的生长;施磷能增加受旱箭竹根际土壤养分含量和微生物生物量,改善受旱箭竹根际土壤微生物群落结构,进而改善受旱箭竹的生长。     

施用棉秆炭对新疆连作棉花根际土壤微生物群落结构和功能的影响

以棉秆移除(NPK)和棉秆还田(NPKS)为对照,采用平板计数、Biolog和DGGE等3种方法,研究了棉秆移除基础上施用常量棉秆炭(22.50 t·hm^-2,NPKB-1)和增量棉秆炭(45.00 t·hm^-2,NPKB-2)对新疆连作棉花根际土壤微生物数量、群落功能和结构多样性的影响.结果表明：与NPK和NPKS处理相比,棉秆炭施用显著增加了连作棉田根际土壤中细菌和放线菌数量;NPKB-1处理真菌数量显著高于NPK处理,但增量棉秆炭NPKB-2处理与NPK处理差异不显著;2个棉秆炭处理的真菌数量均低于NPKS处理.棉秆炭处理AWCD值较高,显著提高了微生物丰富度指数,可促进利用糖类、氨基酸类和羧酸类碳源的微生物生长,尤其是利用与根系分泌物相关的酚酸类碳源的微生物.DGGE电泳结果表明,施用棉秆炭(尤其是增量棉秆炭)后,土壤细菌DGGE图谱条带数增多,增加了土壤中芽单胞菌门、酸杆菌门、变形菌门和放线菌门中一些菌群的丰度.UPGMC聚类分析表明,NPKB-2处理明显区别于其他处理,而NPKS、NPK和NPKB-1处理细菌群落结构相似.表明高量施用棉秆炭可显著提高棉花根际土壤微生物多样性,并明显改变土壤细菌群落结构,对连作棉田生态系统健康有改善作用.     

不同肥料对退化茶园根际土壤微生物代谢活性和群落结构的影响

于福建省安溪县桃舟乡,选择宿根连作20年茶园进行田间试验。以未施肥(CK)、氮肥(NF)、羊粪(GM)及豆科绿肥(LF)等处理后的茶树根际土壤作为供试土样,分析不同肥料对茶树根际土壤理化特性、微生物代谢活性及其不同类型磷脂脂肪酸含量变化等影响。结果表明:NF、GM和LF均能够提高茶园土壤pH值和有机质(OM)及速效钾(AK)等含量,其pH分别提高0.47%、2.36%和2.13%;OM分别提高17.56%、27.48%和54.96%;AK分别提高56.10%、63.41%和73.17%;碱解氮(AN)和速效磷(AP)在NF处理下分别下降了9.10%和335.00%;在GM处理下分别提高了17.06%和2.11倍;在LF处理下分别提高了16.70%和3.88倍;同时,施肥能提高土壤脲酶、蔗糖酶、多酚氧化酶和过氧化物酶等活性,且提高效果由高到底依次为LF、GM、NF;酸性磷酸酶活性(ACP)和微生物对磷素利用率(UTP)在NF处理下分别降低70.04%和249.00%;在GM处理下分别提高了24.74%和1.80倍;在LF处理下分别提高34.28%和2.51倍;与此同时,GM和LF还能够提高根际土壤微生物群落丰度以及菌群多样性。综上所述,豆科绿肥和羊粪能够有效改善茶园土壤肥力,促进根际微生物对养分的代谢活性,对提升茶园经济效益和生态效益具有现实意义。     

化肥有机替代对连作花生田土壤有机碳和微生物群落的影响

为揭示化肥有机替代措施下连作花生田土壤有机碳(SOC)积累的微生物机制,在连作5年的花生田设置了蚯蚓粪配施化肥(VM)、生物有机肥配施化肥(BF)、全量化肥(CF)和无施入对照(CK)4个处理,采用磷脂脂肪酸法(PLFA)分析了土壤微生物群落组成及多样性,测定了SOC及其组分含量以及花生产量,分析了化肥有机替代、SOC和土壤微生物群落三者间的关系。结果表明：花生连作土壤环境严重恶化并显著影响了花生产量,而有机肥部分替代化肥明显提高了SOC和各组分含量以及土壤微生物生物量,改变了土壤微生物群落组成及其多样性,提高了花生产量,其中VM处理效果最显著(P<0.05)。与CK相比,VM处理的花生产量增加了56%,SOC含量增加了11.4%,土壤总PLFA含量增加了149.4%。冗余分析和逐步回归分析表明,VM和BF处理与SOC及其各组分含量、土壤微生物各类群PLFA含量均呈正相关,尤其VM处理相关性最强(P<0.05);CK和CF处理与除了G⁺/G^-比值以外的其他所有变量均呈负相关;SOC各组分含量与土壤微生物各类群PLFA含量显著相关。...     

生物炭对茶园土壤CO2和N2O排放量及微生物特性的影响

以茶叶修剪物制备的生物炭为试验材料,采集多年种植茶树的酸化土壤进行室内培养试验,探究以0.5%、1.5%、2.5%和3.5%的不同生物炭比例添加至茶园土壤中,对茶园土壤CO₂和N₂O气体排放、pH值和微生物群落的影响.结果表明： 与空白对照处理相比,生物炭添加在短期内对CO₂和N₂O气体排放具有一定的促进作用,增强C、N的矿化率,但促进作用随着生物炭施用量的增加而减弱.不同生物炭处理对土壤pH值、脱氢酶及微生物生物量碳具有增加作用.检测土壤中不同标记的磷脂脂肪酸PLFA发现,添加1.5%的生物炭处理组中土壤磷脂脂肪酸含量最高,为(203.93±3.14) μg·g^-1,与对照差异显著(P<0.05).其中16:0、14:0(细菌)、18:1ω9c(真菌)、10Me18:0(放线菌)标记含量较高,不同处理的单个磷脂脂肪酸含量差异显著(P<0.05).表明添加生物炭能改善茶园酸性土壤,提升土壤微生物生物量及微生物数量.     

甘肃省麦积山景区3种典型裸子植物土壤微生物群落结构分析

【目的】探明不同种类的植物对其根际土壤微生物数量分布与群落结构的影响。【方法】将微生物计数法与磷脂脂肪酸(PLFA)法相结合,分析比较麦积山景区3种典型裸子植物根际土壤微生物的数量分布和PLFA种类、含量及主成分结构。【结果】3种植物根际土壤微生物数量均以细菌最多,真菌最少;总PLFA含量以红豆杉[Taxus chinensis(Pilg)Rehder.]最高、种类最多,日本落叶松[Larix kaempferi(Lamb)Carriere.]最低,红豆杉与云杉(Picea asperata Mast)PLFA主要成分相似度高于日本落叶松;外来种日本落叶松无论微生物数量,还是种类以及PLFA结构组成与红豆杉、云杉均有较大的差异,多样性显著下降。【结论】与土著裸子植物相比,外来种日本落叶松能明显改变根际土壤微生物数量分布与群落结构。     

生物质炭对水稻土团聚体微生物多样性的影响

生物质炭施用对土壤微生物群落结构的影响已有报道,但土壤团聚体粒组中微生物群落对生物质炭施用的响应的研究还相对不足。以施用玉米秸秆生物质炭两年后的水稻土为对象,采用团聚体湿筛法,通过高通量测序对土壤团聚体的微生物群落结构与多样性进行分析,结果表明:(1)与对照相比,生物质炭施用显著促进了大团聚体(2000—250μm)的形成,并提高了团聚体的稳定性。(2)不同粒径团聚体间微生物相对丰度存在显著差异。在未施生物质炭的处理(C0)中,随着团聚体粒径增大,变形菌门、子囊菌门、β-变形杆菌目、格孢腔菌目的相对丰度逐渐降低,而酸杆菌门、担子菌门、粘球菌目、类球囊霉目的相对丰度逐渐升高。(3)生物质炭施用显著改变了团聚体间的微生物群落结构。与C0处理相比,生物质炭施用处理的大团聚体中变形菌门、鞭毛菌门和β-变形杆菌目的相对丰度分别显著提高了14.37%、33.28%和33.82%;微团聚体(250—53μm)中酸杆菌门、子囊菌门和粘球菌目的相对丰度分别显著降低了20.15%、19.93%和17.66%;粉、黏粒组分(<53μm)中担子菌门的相对丰度升高90.25%,而子囊菌门和鞭毛菌门的相对丰...     

施用韩国假单胞菌(Pseudomonas koreensis)CLP-7对连作烟田土壤质量及微生物群落功能多样性的影响

针对目前连作导至植烟土壤酸化和根茎病害发生重的问题,田间条件下,研究了嗜酸性韩国假单胞Pseudomonas koreensis CLP-7对酸化植烟土壤pH、养分、酶活性及微生物群落功能多样性的影响。结果表明:CLP-7可以提高酸化植烟土壤pH;同时,CLP-7显著提高根际土壤速效钾、有效磷、铵态氮、硝态氮和有机质含量,其中有机质含量增加最显著;根际土壤脲酶、蔗糖酶活性呈上升趋势且均高于未施菌土壤,过氧化氢酶活性变化不明显。CLP-7处理不同时间的土壤微生物代谢多样性指数表现出明显的差异,施菌30 d时Shannon指数、Simpson指数,Richness及McIntosh指数均达到最高;所有处理的Pielou指数变化较小。微生物碳代谢主成分分析结果显示,施菌30 d时,根际土壤微生物对碳源利用与其他处理差异显著,主要为羧酸类和糖类碳源;随着施菌时间增加,微生物对氨基酸类、羧酸类、双亲化合物类、聚合物类和糖类利用率明显提高,说明CLP-7有利于提高连作烟田根际土壤微生物对碳源的利用能力。综上所述,P.koreensis CLP-7能够明显提高土壤pH、土壤酶活性,增加土壤养分含量和土壤微生物群落功能多样性,进而改善酸化植烟土壤质量,在微生物修复酸化土壤和减轻根茎病害发生的烟草绿色防控中具有较大的应用潜力。     

Dynamics of a microbial community associated with manure hot spots as revealed by phospholipid fatty acid analyses.

Microbial community dynamics associated with manure hot spots were studied by using a model system consisting of a gel-stabilized mixture of soil and manure, placed between layers of soil, during a 3-week incubation period. The microbial biomass, measured as the total amount of phospholipid fatty acids (PLFA), had doubled within a 2-mm distance from the soil-manure interface after 3 days. Principal-component analyses demonstrated that this increase was accompanied by reproducible changes in the composition of PLFA, indicating changes in the microbial community structure. The effect of the manure was strongest in the 2-mm-thick soil layer closest to the interface, in which the PLFA composition was statistically significantly different (P < 0.05) from that of the unaffected soil layers throughout the incubation period. An effect was also observed in the soil layer 2 to 4 mm from the interface. The changes in microbial biomass and community structure were mainly attributed to the diffusion of dissolved organic carbon from the manure. During the initial period of microbial growth, PLFA, which were already more abundant in the manure than in the soil, increased in the manure core and in the 2-mm soil layer closest to the interface. After day 3, the PLFA composition of these layers gradually became more similar to that of the soil. The dynamics of individual PLFA suggested that both taxonomic and physiological changes occurred during growth. Examples of the latter were decreases in the ratios of 16:1 omega 7t to 16:1 omega 7c and of cyclopropyl fatty acids to their respective precursors, indicating a more active bacterial community. An inverse relationship between bacterial PLFA and the eucaryotic 20:4 PLFA (arachidonic acid) suggested that grazing was important.     

间作绿肥对油菜根际土壤碳氮及根际微生物的影响

在我国西南紫色土地区,农田生态环境极为脆弱,绿肥应用也面临严峻问题。为改善农田土壤健康状况,探索绿肥的应用途径,通过紫云英与油菜间作,重点探讨了绿肥紫云英对油菜根际土壤碳氮及其微生物特征的影响,同时与秸秆覆盖的效应作了比较,其创新性在于将绿肥紫云英应用于西南旱地,并且为建立新的油菜种植模式作铺垫。结果表明:与秸秆覆盖相比,间作绿肥紫云英是影响油菜根际土壤环境的主要因素。间作紫云英减少了油菜根际土壤碳、氮含量,改变了油菜根际土壤碳氮比。间作紫云英也减少了油菜根际土壤微生物量,改变了油菜根际土壤微生物群落结构,改善了油菜根际土壤通气状况,抑制了厌氧细菌的生长。     

应用磷脂脂肪酸和聚合酶链式反应-变性梯度凝胶电泳分析技术研究湿地植物根际微生物群落多样性

以天津大学校内两个相邻的小型湖泊(青年湖和爱晚湖)为研究区域, 通过采样分析, 利用磷脂脂肪酸(PLFA)和聚合酶链式反应-变性梯度凝胶电泳(PCR-DGGE)分析技术, 研究了湿地植物种类(芦苇(Phragmites australis)和东方香蒲(Typha orientalis))和生长方式(单生和混生)对根际微生物生物量和群落结构的影响。PLFA分析结果表明, 植物根际微生物生物量大于非根际(爱晚湖芦苇除外); 植物种间的差异较大, 东方香蒲根际沉积物中微生物生物量大于芦苇根际; 种内根际微生物受植物的生长状况影响较大, 采样期间两个湖泊中东方香蒲的生长状况(株高)相似, 根际微生物生物量相差不大, 而爱晚湖芦苇由于与东方香蒲共生, 受到东方香蒲的抑制, 使得根际微生物生物量明显低于单独生长的芦苇; 革兰氏阳性细菌数量小于革兰氏阴性细菌的数量, 且根际的革兰氏阳性细菌与革兰氏阴性细菌的比值小于非根际。沉积物中的细菌群落结构主要与植物种类有关, 同一种植物的根际细菌群落结构差异较小(这些根际细菌聚为一类); 不同植物的根际细菌群落结构差异较大。     

Characterization of the rhizosphere microbial community from different Arabidopsis thaliana genotypes using phospholipid fatty acids (PLFA) analysis

Total and culturable rhizosphere microbial communities structure from three different genotypes of Arabidopsis thaliana growing on three different substrates was studied with phospholipid fatty acid analysis (PLFA) and multivariate statistical analyses: correspondence analysis (CA) and distance based redundancy analyses (db-RDA). In addition, microbial biomass from different groups (total bacteria, Gram+, Gram? and fungi) was calculated from biomarkers PLFA peak area, both from total and culturable microbial community. db-RDA analysis showed significant differences between soils but not between plant genotypes for culturable microbial community structure. Total microbial community was significantly different between soils, and also between plant lines in each soil. Biomass of different bacterial groups showed significant higher values in soil two rhizosphere irrespective of the plant line. In addition, significant differences between plant lines were also found for microbial biomass of different bacterial groups both in total and culturable microbial community. Throughout the work we have demonstrated that PLFA analysis has been able to show a different behaviour of total microbial community with regard to the culturable fraction analyzed in this work under the influence of plant roots. Microbial biomass of different microbial groups calculated with PLFA biomarkers was a suitable tool to detect differences between soils irrespective of the plant line, and differences in the same soil between plant lines. According to this data, a previous study should be carried out before GMPs are used in field conditions to evaluate the potential alterations that may take place on rhizosphere microbial communities structure which may further affect soil productivity. In conclusion, based on data presented in this work, GMPs alter rhizosphere microbial communities structure and this effect is different depending on the soil. Furthermore, total microbial community is affected to a greater extent than the culturable fraction analyzed.     

Effects of genetically modified starch metabolism in potato plants on photosynthate fluxes into the rhizosphere and on microbial degraders of root exudates

A high percentage of photosynthetically assimilated carbon is released into soil via root exudates, which are acknowledged as the most important factor for the development of microbial rhizosphere communities. As quality and quantity of root exudates are dependent on plant genotype, the genetic engineering of plants might also influence carbon partitioning within the plant and thus microbial rhizosphere community structure. In this study, the carbon allocation patterns within the plant-rhizosphere system of a genetically modified amylopectin-accumulating potato line (Solanum tuberosum L.) were linked to microbial degraders of root exudates under greenhouse conditions, using (13)C-CO(2) pulse-chase labelling in combination with phospholipid fatty acid (PLFA) analysis. In addition, GM plants were compared with the parental cultivar as well as a second potato cultivar obtained by classical breeding. Rhizosphere samples were obtained during young leaf developmental and flowering stages. (13)C allocation in aboveground plant biomass, water-extractable organic carbon, microbial biomass carbon and PLFA as well as the microbial community structure in the rhizosphere varied significantly between the natural potato cultivars. However, no differences between the GM line and its parental cultivar were observed. Besides the considerable impact of plant cultivar, the plant developmental stage affected carbon partitioning via the plant into the rhizosphere and, subsequently, microbial communities involved in the transformation of root exudates.     

Effects of water stress, organic amendment and mycorrhizal inoculation on soil microbial community structure and activity during the establishment of two heavy metal-tolerant native plant species

Our aim was to examine the effect of water stress on plant growth and development of two native plant species (Tetraclinis articulata and Crithmum maritimum) and on microbial community composition and activity in the rhizosphere soil, following the addition of an organic amendment, namely sugar beet residue (SBR), and/or the inoculation with an arbuscular mycorrhizal (AM) fungus, namely Glomus mosseae, in a non-sterile heavy metal-polluted soil. The AM inoculation did not have any significant effect on plant growth of both species. In T. articulata, SBR increased shoot growth, foliar P, total phospholipid fatty acids (PLFA), fungi-related PLFA, AM fungi-related neutral lipid fatty acid, bacterial gram-positive/gram-negative PLFA ratio and the β-glucosidase and dehydrogenase activities. SBR and AM inoculation increased phosphatase activity in T. articulata plants grown under drought conditions. In both plants, there was a synergistic effect between AM inoculation and SBR on mycorrhizal colonisation under drought conditions. In C. maritimum, the increase produced by the SBR on total amounts of PLFA, bacterial gram-positive-related PLFA and bacterial gram-negative-related PLFA was considerably higher under drought conditions. Our results suggest that the effectiveness of the amendment with regard to stimulating microbial communities and plant growth was largely limited by drought, particularly for plant species with a low degree of mycorrhizal colonisation.     

The responses of soil organic carbon mineralization and microbial communities to fresh and aged biochar soil amendments

While biochar soil amendment has been widely proposed as a soil organic carbon (SOC) sequestration strategy to mitigate detrimental climate changes in global agriculture, the SOC sequestration was still not clearly understood for the different effects of fresh and aged biochar on SOC mineralization. In the present study of a two‐factorial experiment, topsoil samples from a rice paddy were laboratory‐incubated with and without fresh or aged biochar pyrolyzed of wheat residue and with and without crop residue‐derived dissolved organic matter (CRM) for monitoring soil organic matter decomposition under controlled conditions. The six treatments included soil with no biochar, with fresh biochar and with aged biochar treated with CRM, respectively. For fresh biochar treatment, the topsoil of a same rice paddy was amended with wheat biochar directly from a pyrolysis wheat straw, the soil with aged biochar was collected from the same soil 6 years following a single amendment of same biochar. Total CO₂ emission from the soil was monitored over a 64 day time span of laboratory incubation, while microbial biomass carbon and phospholipid fatty acid (PLFA) were determined at the end of incubation period. Without CRM, total organic carbon mineralization was significantly decreased by 38.8% with aged biochar but increased by 28.9% with fresh biochar, compared to no biochar. With CRM, however, the significantly highest net carbon mineralization occurred in the soil without biochar compared to the biochar‐amended soil. Compared to aged biochar, fresh biochar addition significantly increased the total PLFA concentration by 20.3%–33.8% and altered the microbial community structure by increasing 17:1ω8c (Gram‐negative bacteria) and i17:0 (Gram‐positive bacteria) mole percentages and by decreasing the ratio of fungi/bacteria. Furthermore, biochar amendment significantly lowered the metabolic quotient of SOC decomposition, thereby becoming greater with aged biochar than with fresh biochar. The finding here suggests that biochar amendment could improve carbon utilization efficiency by soil microbial community and SOC sequestration potential in paddy soil can be enhanced by the presence of biochar in soil over the long run.     

生物炭对茶园土壤CO2和N2O排放量及微生物特性的影响

以茶叶修剪物制备的生物炭为试验材料,采集多年种植茶树的酸化土壤进行室内培养试验,探究以0.5%、1.5%、2.5%和3.5%的不同生物炭比例添加至茶园土壤中,对茶园土壤CO₂和N₂O气体排放、pH值和微生物群落的影响.结果表明： 与空白对照处理相比,生物炭添加在短期内对CO₂和N₂O气体排放具有一定的促进作用,增强C、N的矿化率,但促进作用随着生物炭施用量的增加而减弱.不同生物炭处理对土壤pH值、脱氢酶及微生物生物量碳具有增加作用.检测土壤中不同标记的磷脂脂肪酸PLFA发现,添加1.5%的生物炭处理组中土壤磷脂脂肪酸含量最高,为(203.93±3.14) μg·g^-1,与对照差异显著(P<0.05).其中16:0、14:0(细菌)、18:1ω9c(真菌)、10Me18:0(放线菌)标记含量较高,不同处理的单个磷脂脂肪酸含量差异显著(P<0.05).表明添加生物炭能改善茶园酸性土壤,提升土壤微生物生物量及微生物数量.