长期连栽杨树林根际土壤自毒作用的生物测定

选取10—40a不同代际的长期集约连栽杨树土壤为对象,从自毒作用的角度探讨人工林连栽障碍的原因与机理。实施了不同连栽代际的杨树人工林土壤对莴苣种子发芽和扦插杨树枝条生长的抑制活性的系统生物测定试验。结果表明,连栽杨树林的根际土壤比非根际土壤能够显著抑制莴苣种子萌发率。对Ⅰ、Ⅱ、Ⅲ代林根际土壤的浓度梯度试验都表明浸提液的质量浓度越大,对种子萌发的抑制性越强,其中Ⅲ代林处理液的浓度效应最明显。将Ⅰ、Ⅱ、Ⅲ代杨树林根际土壤配置成加营养液组与无营养液组两组对照水培溶液测定扦插杨树枝条的胚芽生长长度和根伸长长度。结果表明,III代林根际土壤处理液的胚芽生长长度和根伸长长度显著小于Ⅱ代林根际土壤处理液,Ⅱ代林处理又显著小于Ⅰ代林处理,Ⅰ代林处理液与对照组无显著差别,这种随林代增大、根际土壤对植株生长的抑制活性增大的趋势在加营养液组更为显著。本文确定了连栽土壤抑制活性的根际效应与浓度效应,为连栽杨树人工林的自毒作用研究提供了重要的实验依据,并推断连栽杨树人工林通过根系分泌物的方式在根际部分逐代积累自毒物质,由于自毒物质的浓度效应,Ⅰ代林阶段自毒效应不显著甚至促进林木生长;随着集约时间增长,到Ⅲ代林阶段自毒效应显著抑制杨树生长和更新。在集约抚育中,对土壤实施人工添加营养液的方式无法缓解其抑制性自毒作用,有可能加剧连栽障碍的产生。     

根际微生物与植物再植病的发生发展关系

植物再植病严重危害农作物的生长发育,形成原因复杂,最新的研究显示它与根际微生态的变化相关,其中主要涉及根际微生物菌群结构的变化。现代高通量测序技术的迅速推广使得根际微生物和再植病间关系成为新的研究热点;本文根据国内外植物再植病病因、根际土壤微生物多样性以及它们与植物生长发育关系等多方面的研究成果,综合分析植物再植病与根际微生物间的关系,以期从根际微生物种群动态变化的角度认识植物再植病的病因并为防治提供新的思路。     

Impact of soil heat on reassembly of bacterial communities in the rhizosphere microbiome and plant disease suppression

The rhizosphere microbiome offers a range of ecosystem services to the plant, including nutrient acquisition and tolerance to (a)biotic stress. Here, analysing the data by Mendes et al. (2011), we show that short heat disturbances (50 or 80 °C, 1 h) of a soil suppressive to the root pathogenic fungus Rhizoctonia solani caused significant increase in alpha diversity of the rhizobacterial community and led to partial or complete loss of disease protection. A reassembly model is proposed where bacterial families that are heat tolerant and have high growth rates significantly increase in relative abundance after heat disturbance, while temperature‐sensitive and slow‐growing bacteria have a disadvantage. The results also pointed to a potential role of slow‐growing, heat‐tolerant bacterial families from Actinobacteria and Acidobacteria phyla in plant disease protection. In conclusion, short heat disturbance of soil results in rearrangement of rhizobacterial communities and this is correlated with changes in the ecosystem service disease suppression.     

根际微生物组中细菌趋化系统的生态功能

在根际微环境中,特定的土壤微生物能够利用自身独特的趋化系统感应根系分泌物,响应植物的选择性招募。细菌的趋化系统介导了植物-微生物以及微生物间相互作用,在植物对根际微生物组的选择中发挥着关键的生态学功能。综述了根际微生物组中细菌趋化系统的研究进展,从生态学的角度提出了未来针对根际细菌趋化系统的研究方向,旨在阐明根际细菌趋化系统的生态学功能,为增进理解作物根际微生物组的募集过程,以及未来农业中根际微生物组的重组构建奠定理论基础。     

格氏栲天然林和人工林土壤呼吸对干湿交替的响应

通过室外定位观测前期连续干旱情况下天然降雨及室内模拟不同温度 (10℃、19℃和 2 8℃ )下测定格氏栲天然林、格氏栲人工林和杉木人工林土壤增湿后呼吸动态 ,探讨不同林型土壤呼吸对土壤干湿交替的响应。结果发现室外定位观测和室内模拟试验均出现了增湿后土壤呼吸骤升至最大值及随后逐渐衰减的现象 ,且这种变化可由时间过程模型 (R=ate- bt c)较好地进行拟合。温度升高提升了土壤呼吸对干湿交替的响应值 RV。格氏栲天然林土壤呼吸对干湿交替的响应对温度最为敏感 ,随温度升高其响应指数 RE增加 ;杉木林土壤呼吸对干湿交替的响应指数 RE最高 ,且对土壤水分变化最敏感 ,但随温度升高超过一定限度后其响应指数 RE反而降低     

不同改良措施对太子参根际土壤酚酸含量及特异菌群的影响

太子参为石竹科多年生草本植物,以根部入药,药用价值高,市场需求大,但其栽培过程中存在严重的连作障碍问题,连作导致产量品质严重下降,病虫害猖獗,探索太子参连作障碍形成的机制及其消减措施意义重大.本研究以广泛栽培的“柘参2号”为试验材料,采用土壤农化分析、高效液相色谱(HPLC)分析、荧光定量PCR(qPCR)等技术对不同连作年限或不同消减措施下太子参根际土壤的主要养分、酚酸含量动态及特异菌群变化进行分析.结果显示: 太子参连作导致产量显著下降,与正茬相比产量下降达43.5%,而水旱轮作和微生物菌肥处理可不同程度缓解其障碍效应.太子参连作土壤主要养分(如速效氮、速效磷、速效钾、全钾)未降反升,但导致土壤酸化.HPLC分析表明,太子参连作下或者随生长时期的推进,土壤酚酸类物质并未表现出明显的积累效应,膨大中期和收获期重茬土壤中大部分酚酸含量甚至低于正茬土壤.进一步荧光定量PCR分析发现,太子参连作导致前期分离筛选到的几类病原菌(如尖孢镰刀菌、踝节霉菌、Kosakonia sacchari)的绝对含量显著上升,而水旱轮作和微生物菌肥处理可有效降低3类病原菌的含量,改善微生态结构.综上认为,太子参连作障碍的发生并非由土壤养分匮乏或者酚酸持续积累直接造成,可能主要与连作下土传病原微生物的大量繁殖爆发有关,本研究结果为深入揭示太子参连作障碍的形成机制及消减修复机制提供了理论依据.     

夏玉米对土壤水分持续减少的响应及其转折点阈值分析

玉米是世界三大粮食作物之一,玉米生产在中国粮食安全与畜牧业发展中具有举足轻重的作用。干旱是夏玉米生产最主要气象灾害,及时准确地获取干旱信息对夏玉米安全生产至关重要。以夏玉米郑单958品种为材料,设置充分供水和拔节期开始土壤水分持续减少两种水分处理,研究夏玉米对土壤水分持续减少的响应及其转折点阈值,为夏玉米干旱识别与监测提供依据。结果表明,土壤水分持续减少10d后生理指标开始陆续受到胁迫,20d后生物量积累受到抑制,30d左右形态特征开始受到胁迫。夏玉米生理指标中最先受到胁迫的是顶端第1片完全展开叶的含水量和水势,生物量积累指标中为茎生物量,形态指标中为叶数。夏玉米顶端第1片完全展开叶的含水量或水势、茎生物量和叶数开始受到土壤干旱过程胁迫的时间阈值分别为11、21、27d,水分亏缺阈值分别为34、66、86mm,土壤相对湿度阈值分别为64%、56%和52%。表明夏玉米对土壤干旱过程的响应首先表现为生理特征变化、其次为生物量积累变化、最后为形态特征变化。研究结果可为客观辨识夏玉米干旱的发生发展及监测预警提供参考。     

Wetting and drying cycles in the maize rhizosphere under controlled conditions. Mechanics of the root-adhering soil

Mechanical properties of the topsoil (sandy Podsol and silty Luvisol, FAO) adhering to maize (Zea mays L.) roots and its bulk soil counterpart were studied as a function of soil texture and final soil water suction at harvest, with three soil water suction values of approximately 30, 50 and 60 kPa. Two scales of observation were also selected: the whole soil:root system and the root-adhering soil aggregates. Three methods were used to characterize the stability of the soil:root system: mechanical shaking in air, and dispersion by low-power ultrasonication, with or without preliminary immersion of the soil:root system in water. Soil disruption kinetics, which were fitted with first-order kinetics equations, were analyzed and discussed. For example, silty soil ultrasonication kinetics, without preliminary water-immersion, could be divided into two parts: the first faster part, which was characterized by a mean rate K value of 6.8–7.2 mJ^-1, is attributed to soil slaking, whereas the second slower part, which was characterized by a mean rate K value of 1.5–1.6 mJ^-1, was attributed to the rupture of the `firmly root-adhering soil' from the roots. A clear plant effect was observed for both aggregate tensile strength and friability, with higher aggregate strength for the root-adhering silty soil (450–500 kPa) than for its bulk silty soil counterpart (410–420 kPa), and lower friability (coefficient of variation of the aggregate strength) for the root-adhering silty soil (e.g. 67% at a soil water suction value of 30 kPa) than for its bulk silty soil counterpart (e.g. 49% at asoil water suction value of 30 kPa). These effects were attributed to root exudation, which was significantly higher for the driest silty topsoil than for the wetter ones. In conclusion, the mechanical properties of the silty topsoil adhering to the maize roots are attributed to both physical and biological interactions occurring in the maize rhizosphere. This revised version was published online in June 2006 with corrections to the Cover Date.     

瓜菜枯萎病及生防根际微生物组研究进展

枯萎病是顽固性土传病害,称为瓜菜中的“癌症”,已成为制约我国瓜菜产业可持续健康发展的瓶颈问题。本文简要介绍瓜菜枯萎病危害,并从细胞壁降解酶、毒素、信号传导和致病基因等方面综述瓜菜枯萎病灾变机制,然后从根际微生物组自身与病原菌、土壤层面和植物层面等重点阐述了根际微生物组防治和抵御瓜菜枯萎病的机理,最后对枯萎病发生和抑制关键因子挖掘、核心微生物组构建及根际微生物组分子机制等进行了展望,期望生防微生物防治病害发生进入一个崭新且高效的阶段,为加快提升作物抗逆性机理研究提供一定思路。     

生姜水浸液对生姜幼苗根际土壤酶活性、微生物群落结构及土壤养分的影响

本文以生姜为材料,研究生姜不同部位（根茎、茎和叶）、不同浓度（10、20、40和80 g L-1）的水浸液对生姜幼苗根际土的微生物数量、土壤酶活性及土壤养分含量的影响,并通过HPLC定量分析了生姜各部位水浸液中所含酚酸类（香草酸、丁香酸、对羟基苯甲酸、香豆酸和阿魏酸）、香豆素类（伞花内脂和7-甲氧基香豆素）化合物的含量。结果表明：三种生姜水浸液对所测六种土壤酶活性均产生了不同程度的影响,其中影响最大的是酸性磷酸酶和蔗糖酶,在10 g L-1 时就达到了显著性差异水平,并且所有酶均有随着水浸液浓度的增加而呈增大的趋势;相同部位的水浸液随着浓度的增加,细菌和真菌的数量呈增加趋势,而放线菌的数量呈减少趋势;三种生姜水浸液均随着浓度的增加降低了土壤中有机质的含量,加剧了土壤中硝态氮含量的积累,根茎水浸液对土壤有效磷、速效钾和铵态氮均显示出低浓度提高其含量而高浓度降低其含量的趋势,而茎和叶水浸液则随着浓度的增加均降低了其含量。生姜水浸液中主要化感成分包括：根茎水浸液主要是丁香酸和伞花内脂;茎水浸液主要是阿魏酸,且其含量最高为73.4 ug/g;叶水浸液除了阿魏酸,其他六种物质均被检测出,但含量较高的主要有丁香酸、伞花内脂和香豆酸。     

库布齐沙地两种植被恢复类型根际土壤微生物和土壤化学性质比较研究

油蒿(Artemisia ordosica)与中间锦鸡儿(Caragana intermedia)是库布齐沙地分布广泛的优良固沙植被类型,在植被恢复过程中受到关注。以库布齐沙地自然恢复的油蒿群落与人工种植的中间锦鸡儿群落为研究对象,以流动沙地为对照,采用野外调查、室内生化实验与统计分析相结合的方法,分析两种植被恢复类型根际与非根际土壤微生物、土壤化学性质的差异,研究土壤微生物与土壤化学性质间的相关关系,并运用综合指数法评价两种植被恢复类型对土壤生态系统的恢复效果,为库布齐沙地植被恢复与重建提供科学依据。主要结论如下:(1)与流沙对照相比,两种植被恢复类型根际、非根际土壤微生物数量、微生物生物量碳、氮含量均有不同程度的提高,其中,自然恢复的油蒿群落根际土壤微生物总数、细菌数量、微生物量碳和氮含量均显著高于中间锦鸡儿根际,真菌和放线菌数量分布表现为中间锦鸡儿油蒿;(2)两种植被恢复类型根际、非根际土壤有机质、全氮、全磷、速效氮、速效钾含量均比流动沙地有不同程度地提高,其中,油蒿根际、非根际土壤有机质、全氮、速效氮含量显著高于中间锦鸡儿;(3)影响油蒿和中间锦鸡儿群落土壤微生物数量、生物量碳和氮的土壤因子是有机质、p H值、全氮、速效氮、速效钾、速效磷,其中,对两种植被恢复类型土壤微生物数量和生物量有正向促进作用的主要因子是土壤有机质、速效钾和全氮含量;(4)运用综合指数法计算出基于14个土壤指标的土壤质量综合指数(SQI),SQI值排序为:油蒿根际中间锦鸡儿根际油蒿非根际中间锦鸡儿非根际流沙对照。自然恢复的油蒿群落对土壤质量的改良效果显著优于人工种植的中间锦鸡儿群落,是库布齐沙地生态恢复的适合途径之一。     

Growth promotion ability of zoysiagrass rhizosphere fungi in consecutive plantings of wheat and soybean

Several isolates ofPhoma sp., certain nonsporulating fungi, as well asPenicillium andTrichoderma, all isolated from zoysiagrass rhizosphere, promoted growth of wheat and soybean under greenhouse conditions. However, the ability of these rhizosphere fungi to enhance plant growth varied with the crop tested. For example, most of the fungi effectively promoted the growth of wheat, whereas only a few fungi were effective on soybean. In consecutive plantings of wheat and soybean grown in soil previously infested with these zoysiagrass rhizosphere fungi, the growth promotion ability of the fungi was lowered. However, addition of fresh potting medium appeared to restore their growth-promotive effects. It appears that the activation of plant growth-promoting fungi in soil might depend on the availability of organic substrates to colonize, as evidenced by the promotion of plant growth.     

根际效应对大豆田土壤线虫群落组成及多样性的影响

根际作为重要的环境界面是植物与环境之间物质能量交换的场所,关于根际效应的研究已成为土壤生态学的新兴热点领域,然而有关大豆根际效应对土壤动物多样性影响的研究报道并不多见。在三江平原选择连续耕作15a的大豆田,对大豆根际区与非根际区土壤线虫群落结构组成进行了对比分析。结果表明:大豆根际区土壤线虫总数、辛普森多样性指数(Dom)显著高于非根际区,根际区的物种数(S)、物种丰富度指数(SR)显著低于非根际区。说明大豆根际效应增加土壤线虫的丰度,但降低了线虫群落结构的复杂性。大豆根际区植物寄生线虫(PP)、食真菌线虫(FF)和食细菌线虫(BF)数量显著高于非根际区,而PP类群的比例在根际区却显著低于非根际区。这一研究结果表明食微线虫(FF和BF)类群在大豆根际区的比例增加更显著。食真菌与食细菌线虫数量比值(F/B)指示大豆根际区细菌生物量相对高于真菌生物量。研究结果丰富了农田土壤线虫多样性的研究内容,并为我国东北大豆田线虫病害的防治及定制相应的农业管理措施提供参考。     

The role of the gut microbiome and its metabolites in metabolic diseases

It is well known that an unhealthy lifestyle is a major risk factor for metabolic diseases,while in recent years,accumulating evidence has demonstrated that the gut microbiome and its metabolites also play a crucial role in the onset and development of many metabolic dis-eases,including obesity,type 2 diabetes,nonalcoholic fatty liver disease,cardiovascular disease and so on.Numerous microorganisms dwell in the gastrointestinal tract,which is a key interface for energy acquisition and can metabolize dietary nutrients into many bioactive substances,thus acting as a link between the gut microbiome and its host.The gut microbiome is shaped by host genetics,immune responses and dietary fac-tors.The metabolic and immune potential of the gut microbiome determines its significance in host health and diseases.Therefore,targeting the gut microbiome and relevant metabolic pathways would be effective therapeutic treatments for many metabolic diseases in the near future.This review will summarize information about the role of the gut microbiome in organism metabolism and the relationship between gut micro-biome-derived metabolites and the pathogenesis of many metabolic diseases.Furthermore,recent advan-ces in improving metabolic diseases by regulating the gut microbiome will be discussed.     

Adsorption of Cd(II) by rhizosphere and non-rhizosphere soil originating from mulberry field under laboratory condition

In this study, the adsorption behavior of Cd ions by rhizosphere soil (RS) and non-rhizosphere soil (NS) originated from mulberry field was investigated. The Langmuir, Freundlich and the Dubinin–Radushkevich (D-R) equations were used to evaluate the type and efficiency of Cd adsorption. The RS was characterized by lower pH but the higher content of soil organic matter and cation exchange capacity (CEC) as compared to NS. Also, the maximum adsorption of Cd²⁺ for RS (5.87 mg/g) was slightly bigger than that for NS (5.36 mg/g). In Freundlich isotherm, the K_f of the adsorption of Cd²⁺ to surface of the RS components was higher than that of the NS, indicating stronger attraction between Cd²⁺ and components of the RS. According to the D-R model, the adsorption of Cd²⁺ by both soils was dominated by ion exchange phenomena. These results indicated that mulberry roots modified physical and chemical properties of the RS under field conditions, which also affected the Cd sorption efficiency by soil components during laboratory experiments. Current knowledge of the Cd²⁺ sorption processes in the rhizosphere of mulberry may be important if these trees are planted for use in phytoremediation of Cd contaminated soils.     

Plant induced alteration in the rhizosphere and the utilisation of soil heterogeneity

Plant-soil interactions result in a special rhizosphere soil chemistry, differing from that of the bulk soil found only a few mm from the root. The aim of this study was to investigate adaptation mechanisms of herbs growing in acid soils through studying their rhizosphere chemistry in a greenhouse experiment and in a field study. Ten herbs were grown in acid soil (pH 4.2 in the soil solution) in the greenhouse. The concentrations of NO₃ ^-, SO₄ ^2-, phosphates, Ca²⁺, Mg²⁺, Mn²⁺, K⁺, Na⁺, NH₄ ⁺ and pH were analysed in soil solutions obtained by centrifugation. The general pattern found was a depletion of nutrients in the rhizosphere compared with their concentrations in the bulk soil. The pH increase (up to 0.7 units) in the rhizosphere soil appeared to be caused by plant uptake of NO₃ ^- (r²=0.88). The ion concentrations in the soil solution of the rhizosphere were dependent on plant species and biomass increase. Although species with a larger biomass and higher growth rates showed a higher degree of ion depletion (except for Na⁺, SO₄ ^2-) in the rhizosphere, there were also species specific responses. A field study of five herbs at five oak forest sites in Southern Sweden (Scania) was also carried out. In addition to the soil solution concentrations, the loss on ignition (LOI) and the concentrations of 0.1 M BaCl₂ extractable K⁺, Mg²⁺, Mn²⁺, Ca²⁺, and Al ions were measured. The amount of soil solution Al was determined as free ionic (quickly reacting) Al. For all species and sites, the LOI and the concentrations of exchangeable cations were higher in the rhizosphere than in the bulk soil, apparently due to the roots preferably growing at organic-rich microsites. The concentrations of the ions as measured in the centrifuged soil solution, were either higher in the rhizosphere than in the bulk soil or were the same in both, except for NO₃ ^- and quickly reacting Al. The lower concentrations of quickly reacting Al in the rhizosphere, compared with the bulk soil could indicate the uptake of Al by the plant or the exudation of complexing substances. The pH differences were only small and mostly non-significant. Plant-soil interactions and the ability of plants to utilise heterogeneity of the soil appear to be more important for plant growth in acid soils than recognised heretofore. Rhizosphere studies provide an important means of understanding plant strategies in acid soils. This revised version was published online in June 2006 with corrections to the Cover Date.     

土壤灭菌-生物有机肥联用对连作马铃薯及土壤真菌群落结构的影响

甘肃省中部沿黄灌区是全国重要的加工型马铃薯生产基地,然而因集约化生产带来的连作障碍问题已经严重影响到当地马铃薯种植业的健康发展。结合田间试验和相关的室内分析,从马铃薯块茎产量和品质、植株生理特征和土壤真菌群落结构等角度,初步评估土壤灭菌和生物有机肥联用(Ammonia Disinfection plus Bio-organic Fertilizer Regulation,ABR)对马铃薯连作障碍的防控效果。同对照相比,ABR处理的块茎产量和商品薯率分别显著增加约71.1%—152.1%和39.2%—53.3%,但块茎化学品质变化不大。ABR处理叶绿素含量和根系活力较CK均显著增加,而叶片和根系丙二醛含量显著下降。PCR-DGGE分析发现,ABR处理显著影响了马铃薯连作土壤的真菌群落结构,表现为真菌群落的多样性指数较CK相比显著下降。ABR处理还有效抑制了土传病害的滋生,植株发病率和收获后的病薯率较CK分别显著下降约67.2%—82.2%和69.1%—70.5%。采用Real-time PCR评估连作土壤中3种优势致病真菌的数量变化,显示ABR处理下立枯丝核菌、茄病镰刀菌和接骨木镰刀菌的数量在生育期内较CK均有不同程度的下降。综合来看,土壤灭菌和生物有机肥联用技术在防控甘肃省中部沿黄灌区马铃薯连作障碍上具有较大的应用潜力,而对土传病害的抑制和微生物群落结构的改善是其主要的作用机理。     

不同植物对黄顶菊根际土壤微生物和土壤养分的影响

[目的] 不同植物对外来入侵植物的抵御能力不同,研究不同植物对入侵植物根际土壤生态的影响可为筛选入侵植物的竞争替代植物提供科学依据。[方法] 利用同质园试验,以入侵植物黄顶菊为研究对象,设置黄顶菊单种、黄顶菊与不同植物（地肤、苘麻、苏丹草、反枝苋）混种处理,采用磷脂脂肪酸分析方法来研究不同植物对黄顶菊根际土壤微生物群落结构的影响,并结合土壤养分的变化探究不同植物对黄顶菊根际土壤生态的影响。[结果] 与黄顶菊单种相比,地肤和苘麻降低了黄顶菊根际微生物的总含量,改变了黄顶菊根际微生物群落结构。地肤、苘麻能竞争性抑制黄顶菊对铵态氮的吸收,从而抑制黄顶菊的生长。[结论] 不同植物的抵御能力与其土壤生态有关,替代植物通过改变黄顶菊根际土壤微生物,抑制黄顶菊对氮的吸收,从而抑制黄顶菊的生长,实现对黄顶菊的替代控制。     

Immobilization and mobilization of labelled sulphur in relation to soil arylsulphatase activity in rhizosphere soil of field-grown rape,barley and fallow

During plant growth, rhizosphere soils from fallow, barley (Hordeum vulgare L. cv Esterel) and rape (Brassica napus L. cv Capitole) grown in a calcareous soil were sampled 5 times (every fortnight) from May to July 2001 at plant maturity. In order to estimate the impact of C derived from photosynthesis, the aerial parts of rape and barley in an area of 1 m² were cut off about 2 cm from the soil surface, and left a fortnight before each sampling. Both soil arylsulphatase activity and a 1-week immobilization of S fertilizer in the sampled soils were then measured. The immobilization of S fertilizer was higher in fallow, followed by barley and rape rhizosphere soil. A strong positive linear correlation (r ²=0.71, P<0.001) was found between soil arylsulphatase activity and S fertilizer immobilized. Conversely, the mobilization of endogenous organic ³⁵S (obtained after leaching free and adsorbed SO₄ ^2–-³⁵S by 0.009 M Ca(H₂PO₄)₂) in the rhizosphere soil of each plant cover pooled at the end of the 5 samplings and materialized by ryegrass (Lolium perenne L. cv Massa) ³⁵S uptake, was about 3 and 2 times higher, respectively, in rape and barley than in fallow rhizosphere soil. Accordingly, strong inverse polynomial relationships were observed between soil arylsulphatase activity and ³⁵S uptake by the whole plant (r ²=0.904, P<0.02) and roots (r ²=0.970, P<0.01) of ryegrass. Plant cuttings affected both the immobilization and mobilization of S. It is concluded that the turnover of S freshly immobilized in rape rhizosphere soil was relatively high. Therefore, rape as a preceding crop in the rotations may have a beneficial effect by increasing S availability on the succeeding crop.     

茶园根际土壤细菌群落结构及多样性

【背景】茶园根际土壤的细菌群落结构与茶园生境土壤营养循环密切相关,其组成及多样性可以作为健康茶园的一个生物指标。【方法】采用PCR．变性梯度凝胶电泳（PCR—DGGE）分子指纹图谱技术,检测安溪铁观音种植区不同海拔茶园根际土壤样本的细菌群落结构,利用Shannon．Wiener多样性指数分析其多样性,采用非加权组平均法进行聚类分析得到其分布特征,利用蒙特卡罗检验和冗余分析分别揭示影响细菌群落分布的环境因子及细菌群落分布和环境变量之间的关系。【结果】茶园根际土壤细菌的DGGE结果显示,检测到的14种主要细菌中有11种细菌是不可培养的,3种细菌是可培养的,分别属于根瘤菌属、中华根瘤菌属和苍白杆菌属。聚类分析得到,同一海拔梯度茶园根际土壤细菌群落结构相似。Shan-non—Wiener多样性指数分析表明,400m海拔处茶园根际土壤细菌群落多样性最高。蒙特卡罗检验分析得到环境因子协同作用对茶园根际土壤细菌群落结构贡献率为59．6％。冗余分析显示,茶园根际土壤细菌群落结构与海拔密切相关。【结论与意义】茶园根际土壤细菌群落结构分布与海拔梯度密切相关,考虑不同海拔高度土壤细菌群落对茶园营养循环的影响,在铁观音的健康栽培和管理过程中具有重要意义。