铝对养麦和金荞麦根际土壤微生物及酶活性的影响

以两种耐铝性不同蓼科荞麦属植物荞麦和金荞麦为材料,通过土培盆栽试验,比较研究其根际土壤微生态对铝胁迫反应的差异。结果表明,一定质量分数的Al对荞麦和金荞麦根际土壤细菌具有显著刺激效应,对金荞麦的影响更大,但Al质量分数过高,对细菌的刺激效应明显减弱,甚至产生抑制作用,荞麦和金荞麦根际土壤真菌数量均随着Al质量分数的升高而明显增加,荞麦根际土壤真菌增加幅度更为显著,Al胁迫下二者根际放线菌数量的变化亦表现出一定的差异;Al胁迫下,荞麦和金荞麦根际土壤氨化细菌、硝化细菌、反硝化细菌等氮素生理群微生物的变化趋势亦显示出明显差异,整体上荞麦根际土壤细菌生理群对Al胁迫比金荞麦更敏感;Al胁迫对荞麦和金荞麦根际土壤过氧化氢酶活性均表现出较弱的抑制效应,但荞麦根际土壤始终维持较金荞麦更高的过氧化氢酶活性,这与荞麦具有更强的耐铝性有一定的关系,荞麦和金荞麦根际土壤转化酶对Al非常敏感,随着铝的加入,其活性显著下降,荞麦和金荞麦根际土壤脲酶活性的变化趋势基本一致,但整体上荞麦根际土壤脲酶活性均明显低于金荞麦,这是否与其耐铝毒特性的差异有关有待于进一步探讨。     

磷对铝胁迫下荞麦根际土壤铝形态和酶活性的影响

采用土培法,以耐铝性明显差异的两个荞麦Fagopyrum esculentum基因型“江西养麦”(耐性)和“内蒙荞麦”(敏感)为材料,研究铝胁迫下磷对荞麦生长和根际土壤铝形态、土壤酶活性的影响.结果表明,0.4 g·kg~(-1)铝配施0.2 g·kg~(-1)磷的内蒙和江西荞麦根系生物量分别比不施磷组增加了67.9%和21.2%,磷能显著缓解铝对荞麦根系生长的抑制,提高根系生物量和根冠比.磷铝互作下根际土壤的交换态铝含量显著降低,毒性较小的吸附态羟基铝和络合态铝含量显著增加.根际土壤酶活性变化复杂,过氧化氢酶活性与磷质量分数呈正相关,w_p=0.2 g·kg~(-1)对铝胁迫下荞麦根际土壤转化酶活性最有利.说明施磷降低铝胁迫根际土壤的交换态铝含量,提高土壤过氧化氢酶活性,减缓铝毒对植株生长的抑制作用.     

烟区烟草根际与非根际土壤微生物的生态因子作用分析

烟草根际和非根际土壤的理化性质、微生物区系和土壤酶之间的相互关系尚缺乏系统研究。对南阳烟区6种土壤包括黄褐土和黄棕壤等共13个取样点的烟草根际和非根际土壤的分析表明,根际与非根际微生物之间没有对应相关关系。根际土壤真菌数与解钾菌数、硝化细菌数显著正相关;非根际土壤荧光假单胞菌数与细菌芽孢数极显著正相关,氨化细菌数与放线菌数显著负相关。与土壤容重和空隙度显著相关的仅有根际真菌数(正相关)。与土壤全氮呈显著正相关的分别有根际荧光假单胞菌、纤维素分解菌(正相关)以及根际解磷菌和非根际真菌(负相关)。土壤全C与根际细菌总数显著负相关。土壤pH与非根际纤维素分解菌显著正相关。速效P与非根际放线菌数呈显著正相关。根际土壤蛋白酶活性与根际细菌总数极显著负相关。非根际土壤蛋白酶活性则分别与非根际放线菌和解钾菌显著正相关。根际土壤脲酶活性分别与根际真菌、解磷菌显著正相关,非根际脲酶活性则与非根际纤维分解菌显著正相关。非根际土壤过氧化氢酶活性与非根际细菌总数显著正相关。     

豆科植物对根际土壤微生物种群及代谢的影响

自然界中很多种类的植物与固氮微生物共生,故其自身可进行氮同化,尤以豆科植物为甚。豆科植物由于与固氮微生物共生,所以豆科植物根际土壤的氮素较高于非固氮类植物种类。由于氮素是微生物代谢必需的营养元素之一,所以,豆科植物与非豆科植物的根际微环境存在一定的差异,自然而然两者根际土壤微生物的种群数量及其代谢活性也应存在一定的差异。基于此,本研究拟选取两种豆科植物(合欢Albizia julibrissin和豌豆Pisum sativum)及两种非豆科植物(樱花Prunus serrulata和艾蒿Artemisia argyi)的根际土壤微生物为研究对象,以平板梯度稀释法测定其种群数量,并通过测定纤维素酶、转化酶、脲酶、硝酸还原酶和酸性磷酸酶的活性为切入点分析其代谢活性,进而分析豆科植物对根际土壤微生物种群数量及其代谢的影响。本研究结果显示豆科植物的根际土壤细菌和真菌数量显著低于非豆科植物的。木本非豆植物和木本豆科植物根际土壤放线菌数量无显著差异,但是草本豆科植物根际土壤放线菌数量却显著高于草本非豆科植物的。另外,豆科植物根际土壤纤维素酶、转化酶、硝酸还原酶和酸性磷酸酶活性均显著大于非豆科植物的,而豆科植物根际土壤脲酶活性却显著低于非豆科植物的。另外,转化酶和脲酶活性与真菌数量呈显著相关。     

罗红霉素对不同生长期小麦土壤氮形态和脲酶活性的影响

抗生素类药物作为添加剂被用于养殖业中,大部分以原形或其代谢产物形式进入土壤环境,对土壤环境造成生态危害。通过盆栽实验,研究了不同浓度罗红霉素(ROX)对小麦各生长期根际土壤微生物生物量氮、脲酶和无机氮的影响。结果表明,添加ROX后土壤微生物生物量氮在小麦苗期、拔节期和抽穗期受到显著抑制,而在灌浆期和收获期,土壤微生物生物量氮却显著增长;与对照相比,低浓度(0.2和0.5 mg·kg~(-1))和中浓度(1.0和2.0 mg·kg~(-1))ROX胁迫显著抑制小麦生长苗期、灌浆期和收获期的根际土壤脲酶活性,而在拔节期和抽穗期,却显著诱导脲酶活性;但高浓度(10.0 mg·kg~(-1))ROX胁迫却显著抑制小麦生长期内脲酶活性。低、中浓度ROX胁迫显著诱导小麦生长期中根际土壤中铵态氮浓度增长,而高浓度组ROX胁迫显著抑制土壤中铵态氮浓度。ROX胁迫抑制硝态氮,显示出ROX会影响土壤氮循环。     

多金属硫化物矿区不同品种水稻根际土壤酶活的变化

选取酸性矿山废水污灌形成的多重金属污染水稻土,采用多格层根际箱模拟水稻根际环境,研究高镉积累水稻长香谷fOryzasativaL．cv．Choukoukoku）和低镉积累水稻金农丝苗（OryzasativaL．cv．Jinnongsimiao）2个品种水稻生育中后期（分蘖期、孕穗期、扬花期、蜡熟期）根际土壤脲酶、酸性磷酸酶和过氧化氢酶活性的变化特征。结果表明：高镉积累水稻比低镉积累水稻各时期根际土壤脲酶活性低,随着生育期的延长,2个品种水稻土壤脲酶活性先降低后升高（分蘖期酶活性最高）,2种水稻土壤脲酶活性均在根际s0层达到最高,但其他各层土壤脲酶活性与根系距离无显著关系。随着水稻生育期的延长,高镉积累水稻根际土壤酸性磷酸酶活性先升高（在孕穗期酶活性达最高）,随后降低;低镉积累水稻土壤酸性磷酸酶活性则在分蘖期最高,之后逐渐降低。除分蘖期高镉积累水稻土壤酸性磷酸酶活性低于低镉积累水稻酶活性外,其他2个时期前者酸性磷酸酶酶活性均高于后者的酶活。2个品种水稻土壤过氧化氢酶活性随生育期延长不断升高,在整个生育后期,高镉吸收水稻比低镉吸收水稻各时期土壤过氧化氢酶活性高,但在蜡熟期时两者无显著差异;在各时期2种水稻过氧化氢酶活性在根系S0层达到最大,随着与水稻根系距离的增加呈先降低后增加的趋势。可见,在多重金属污染矿区,土壤酶活性明显受水稻品种、水稻生长时期和水稻根系的影响。该结果可以为研究多重金属污染矿区分析土壤酶活性与不同重金属积累程度的水稻品种作物相关关系提供数据支持,给农业生产及土壤修复提供依据。     

六氯苯胁迫下2种湿地植物根际土壤微生物数量与酶活性变化

为揭示人工湿地植物根际效应对氯苯类化合物生物降解的影响,选取典型湿地植物芦苇(Phragmites australis)和香蒲(Typha angustifolia),模拟室外人工湿地微宇宙系统,研究六氯苯(hexachlorobenzene,HCB)胁迫下根际土壤中微生物数量和酶活性变化。结果显示:芦苇和香蒲表现出明显的根际效应,根际土壤微生物(细菌、真菌、放线菌)数量以及土壤脱氢酶(DEH)、过氧化氢酶(CAT)和多酚氧化酶(PPO)活性均表现为根际土大于非根际土,且香蒲组土壤微生物数量和酶活性均显著高于芦苇组(P0.05);芦苇和香蒲组土壤中HCB含量与微生物数量和3种酶活性呈负相关,香蒲组土壤中HCB含量与DEH活性和PPO活性呈显著负相关(P0.05)。研究表明随着芦苇和香蒲根际土壤微生物数量与酶活性的增加,2种植物的根际效应增强,进而促进湿地系统对HCB的去除。     

蜈蚣草生长对其根际铜尾矿土壤酶活性的影响

通过盆栽模拟试验,研究了蜈蚣草(Pteris vittata)生长对其根际铜尾矿土壤酶活性的影响。结果表明,蜈蚣草根际土壤中过氧化氢酶、脲酶、多酚氧化酶和蔗糖酶活性均随着植物的生长而呈现不同程度的升高,其中过氧化氢酶和脲酶活性均与植物生长时间之间呈显著正相关,多酚氧化酶和蔗糖酶活性在植物生长旺盛期达到峰值,分别为对照组的3.59和2.58倍,随后逐渐下降;而磷酸酶活性却随着植物的生长而显著降低。过氧化氢酶、脲酶和磷酸酶活性与蜈蚣草地下部分干质量的相关性大于其地上部分,且5种土壤酶活性与土壤有机质含量之间相关显著。蜈蚣草生长可有效改善根际铜尾矿的基质环境和根际土壤肥力水平,因此,在铜尾矿废弃地恢复实践中具有较大的应用潜力。     

玉米/花生间作条件下土壤环境因子的相关性和主成分分析

玉米/花生间作具有明显的间作优势,对作物生长和产量均有促进作用。为了阐明玉米/花生间作效应机制,测定了玉米/花生间作根际土壤养分含量、酶活性和微生物数量的变化规律,并对这些环境因子进行相关性和主成分分析。结果表明,与单作玉米和单作花生相比,玉米/花生间作显著提高了根际土壤的全氮、有效氮、有效磷含量以及脲酶和酸性磷酸酶活性,促进了间作玉米根际土壤细菌和微生物总数量显著增加。相关分析表明,有效磷含量与脲酶和酸性磷酸酶活性呈极显著正相关(P<0.01),脲酶活性和酸性磷酸酶活性显著正相关(P<0.05),真菌和放线菌数量显著正相关(P<0.05)。总钾含量和p H值、蔗糖酶活性呈显著负相关(P<0.05),蛋白酶和过氧化氢酶呈极显著负相关(P<0.01)。主成分分析获得3个主成分,解析贡献率分别为48.981%,43.617%和7.402%。第一主成分主要是放线菌、真菌、有效磷等组成,第二主成分主要为有机质和p H,第三主成分主要是总氮和细菌。经标准化后计算栽培措施得分显示:间作花生得分最高1.937,其次是间作玉米1.008,两者均显著高于单作玉米和单作花生。该研究表明玉米/花生间作系统的生态环境优于单作系统,机制解析为玉米/花生间作可明显促进土壤有效氮磷含量、脲酶和酸性磷酸酶活性及微生物数量的增加,进而改善土壤微生态环境。     

低浓度Pb^2＋对Cd^2＋污染下冬小麦幼苗根微域土壤水解酶活性及与根微域土壤生化特征关系的影响

采用盆栽试验法探讨了Cd^2＋、低于国家“土壤环境质量标准”规定的II类土壤环境基准值300mg-kg^-1干土时的Pb^2＋与Cd^2＋复合处理对冬小麦幼苗根微域土壤磷酸酶、转化酶和脲酶活性及与根微域土壤微生物数量和生化特征关系的影响特征。结果表明：（1）Cd^2＋对冬小麦幼苗根微域土壤转化酶、脲酶和磷酸酶活性表现为显著抑制效应;而低浓度Pb^2＋主要表现为协同Cd抖污染抑制根微域土壤水解酶活性效应;（2）Cd^2＋处理下,磷酸酶活性与微域土壤有机质含量呈极显著正相关;转化酶活性与细菌、真菌和放线菌数量呈显著负相关,与有机质呈显著正相关;脲酶活性与细菌、真菌和放线菌数量及微生物量碳表现为极显著正相关;（3）Pb^2＋／cd^2＋处理下,碱性磷酸酶活性与微生物量碳表现为显著正相关;转化酶活性与全氮含量表现为显著负相关,与有机质含量呈极显著正相关;脲酶活性与全氮呈极显著正相关,与有机质为极显著负相关,总体来讲,Cd^2＋／Pb2＋与Cd^2＋处理之间酶活性与生化特征的关系存在明显差异;同时Pb^2＋／Cd^2＋处理下磷酸酶、转化酶和脲酶活性与土壤微生物数量之间的相关性特点与Cd^2＋处理下也明显不同。     

Biosorption of Cr（VI） by carbonized Eupatorium adenophorum and Buckwheat straw： thermodynamics and mechanism

High quality and low cost carbon can be prepared from Eupatorium adenophorum （E. adenophorum） and Buckwheat straw. The biosorbent was used for Cr（VI） removal. The effect of experimental parameters, such as pH, sorbent dosage and temperature were examined and the optimal experimental condition was determned. Solution pH is found influencing the adsorp- tion. Cr（VI） removal efficiency is found to be maximum （98%） at pH= 1. Langmuir and Freundlich adsorption isotherms were applicable to the adsorption process and their constants were evaluated. The adsorption data obtained agreed well with the Langmuir sorption isotherm model. The maximum adsorption capacities for Cr（VI） ranged from 46.23 to 55.19mg.g^-1 for temperature between 298 K and 308 K under the condition of pH = 1.0. Thermodynamic parameters such as free energy change （AG）, enthalpy （AH） and entropy （AS） indicate a spontaneous, endothermic and increased randomness nature of Cr（VI） adsorption. Studies found that the raw E. adenophorum and buckwheat straw mixed materials with simple treatment had a high efficiency for the removal of Cr（VI） and would be a promising adsorbent.     

减量施氮对苦荞产量形成及氮代谢酶活性的影响

为明确减量施氮对苦荞强弱势粒及产量形成的影响,以苦荞品种晋荞2号为试验材料,研究在225 kg/hm²(N1)、135 kg/hm²(N2)、45 kg/hm²(N3)、0 kg/hm²(N4,对照)4个氮肥处理下苦荞强弱势粒的灌浆动态、根系形态生理、叶片中叶绿素含量及氮代谢相关酶活性、农艺性状和产量的差异.结果显示:减氮处理下,N2处理时晋荞2号籽粒的灌浆起始势(R0)、最大灌浆速率(Gmax)和平均灌浆速率(Gmean)最大,达最大灌浆速率的时间(Tmax.G)最小;强弱势粒间以强势粒的A值(生长终值量)、R0、Gmax和Gmean大于弱势粒,而N值(形状参数)和Tmax.G则低于弱势粒. 4个氮肥处理和强弱势粒均以灌浆中期对粒重的贡献率最大,灌浆后期次之,灌浆前期最小.随着施氮量的减少,晋荞2号的根系长度等形态指标及根系活力呈先增加后降低的趋势,以N2处理最大;随着施氮量的减少,晋荞2号叶片中的叶绿素含量及谷氨酰胺合成酶(GS)、谷氨酸脱氢酶(GDH)、谷氨酰胺合酶(GOGAT)、硝酸还原酶(NR)活性呈先增加后降低的趋势,N2处理最大,强弱势粒间以强势粒的叶绿素含量较高、氮代谢酶活性较大. N2处理时的株高等农艺性状及产量形成指标均大于其余3个氮肥处理.本研究表明适当减量施氮可延缓苦荞衰老、促进苦荞强弱势粒的灌浆和氮代谢酶活性的增加,提高粒重和最终产量,进而实现节肥和高产.(表7参31)     

Microbial community and functional genes in the rhizosphere of alfalfa in crude oil-contaminated soil

A rhizobox system constructed with crude oil-contaminated soil was vegetated with alfalfa (Medicago sativa L.) to evaluate the rhizosphere effects on the soil microbial population and functional structure, and to explore the potential mechanisms by which plants enhance the removal of crude oil in soil. During the 80-day experiment, 31.6% of oil was removed from the adjacent rhizosphere (AR); this value was 27% and 53%higher than the percentage of oil removed from the far rhizosphere (FR) and from the non-rhizosphere (NR), respectively. The populations of heterotrophic bacteria and hydrocarbon-degrading bacteria were higher in the AR and FR than in the NR. However, the removal rate of crude oil was positively correlated with the proportion of hydrocarbon-degrading bacteria in the rhizosphere. In total, 796, 731, and 379 functional genes were detected by microarray in the AR, FR, and NR, respectively. Higher proportions of functional genes related to carbon degradation and organic remediation, were found in rhizosphere soil compared with NR soil, suggesting that the rhizosphere selectively increased the abundance of these specific functional genes. The increase in water-holding capacity and decrease in pH as well as salinity of the soil all followed the order of AR>FR>NR. Canonical component analysis showed that salinity was the most important environmental factor influencing the microbial functional structure in the rhizosphere and that salinity was negatively correlated with the abundance of carbon and organic degradation genes.     

Comparison on bacterial community of rhizosphere and bulk soil of poplar plantation based on pyrosequencing北大核心CSCD

By the 454 pyrosequencing technology, this research compared the bacterial communities in poplar plantation rhizosphere and bulk soil for an accurate understanding of bacterial community colonization in the two soil environments. The species annotation showed that rhizosphere soil contained 145 bacterial genera and bulk soil contained 141 bacterial genera, with 8 common genera shared by both at a relative abundance of more than 4%. The 8 genera in common were Acidobacterium GP1, Acidobacterium GP3, Acidobacterium GP6, Gemmatimonas, Bradyrhizobium, Burkholderia, Streptomyces and Acidobacterium GP4. The relative abundance of the same bacterial community was significantly different between rhizosphere and bulk soil environments. Alpha diversity analysis showed that the bacterial community diversity of rhizosphere soil was higher than that of bulk soil, but the difference was not significant. The results of bacterial communities sorting could reflect the variation of soil bacterial communities from rhizosphere to the bulk and the spatial variation among different sampling points, indicating a contribution of about 21.2% variance of bacterial communities by the effect of rhizosphere. Beta diversity analysis showed great difference between rhizosphere and bulk soil samples in bacterial community composition. There were 15 genera specific to rhizosphere soil and 11 to bulk soil. The abundance of 23 genera, mainly cellulose degrading bacteria and nitrogen-fixing bacteria, changed significantly. Selectivity of root to rhizosphere microorganisms is an important mechanism leading to significant differences in the rhizosphere microbial community composition and structure, which may significantly impact the carbon and nitrogen cycles of the root-soil interface.     

Diversity of root associated microorganisms of selected medicinal plants and influence of rhizomicroorganisms on the antimicrobial property of Coriandrum sativum

The total heterotrophic bacteria, actinomycetes and fungus were enumerated from the rhizosphere and non-rhizosphere soil of 50 selected locally available medicinal plants in and around Bharathiar University. In all the plants, population of microorganism were higher in the rhizosphere soil than in the non rhizosphere soil. Among the microorganisms, bacterial population was higher in number followed by fungus and actinomycetes. Of the medicinal plants, the maximum rhizosphere effect was observed in Annona squamosa and the minimum effect was seen in Eclipta alba and Cassia auriculata. Among the bacteria the dominant species was Bacillus followed by Pseudomonas, Enterobacter, Corynebacterium, Micrococcus and Serratia. The Streptomyces species was found to be dominant followed by Deuteromycetes and Frankia among the actinomycetes. Among the fungal isolates Rhizopus was found to be higher in number followed by Aspergillus, Penicillium, Mucor and Fusarium. About 70.96% of the bacterial isolates were found to be nitrate reducers and 90.60% of the bacteria solubilised phosphate. The rhizosphere bacterial isolates were also capable of hydrolyzing starch, cellulose, casein, urea and gelatin. The isolates of bacteria, actinomycetes and fungus were also able to produce phytohormone Indole-3-acetic acid (IAA). The maximum IAA production was recorded by Fusarium sp (5.8 mg/l). The rhizosphere bacterial isolates showed resistance to 14 commercially used antibiotics. In an attempt to check the influence of these plant growth promoting microorganisms on the antimicrobial property of Coriandrum sativum against Escherichia coli MTCC-443 and Aeromonas hydrophila MTCC-646, the results observed was not encouraging since the inoculants did not influence the antibacterial property. However extensive and in depth study is required to find out the influence of rhizomicroorganisms on the antibacterial property of medicinal plants. The other results clearly indicated that the rhizosphere microorganisms could be exploited for its innumerable properties and active metabolites.     

不同栽杉代数根际土壤肥力及生物学特性变化

通过对位于南平溪后安曹下和邓窠２９ａ龄１代、２代、３代实生杉木的根际养分、微生物、酶及生化活性的为期２ａ的研究,结果表明：随杉木连栽代数增加,根际微域土壤酸化趋势增强,有机质和全氮沉积量下降,速效性养分亏缺程度减弱,根际土壤中三大类微生物所占的比例发生一定的变化,真菌和放线菌所占比例增加,细菌所占比例减少,生理类群数量下降,除接触酶活性变化不大外,其它土壤酶和生化活性均有明显下降,体现了杉木多代连栽根际土壤的基本特征;亦是杉木连栽导致地力衰退重要原因之一     

铝胁迫下马尾松幼苗有机酸分泌和根际pH值的变化

以马尾松幼苗为试验材料,选用砂培法研究铝胁迫对马尾松根际pH值、有机酸分泌以及植株中铝累积变化的影响。结果表明,高浓度铝导致根际pH值增加,当铝浓度高于300μmol.L-1时,根际pH值则趋于平稳。在测试的5种有机酸(草酸、苹果酸、柠檬酸、琥珀酸、乙酸)中,当铝浓度由0升至300μmol.L-1时,草酸和苹果酸根系分泌量随之升高,与根际pH值呈正相关关系;而当铝浓度高于300μmol.L-1时,草酸和苹果酸分泌量则趋于平稳,草酸和苹果酸的分泌影响根际pH值的变化。其次,活性铝通过根系进入植株后,由于营养作用和运输机制,出现分布差异,根部铝积累量明显高于茎和叶。当根系接触的铝浓度低于300μmol.L-1时,植株铝积累量与根际pH值,以及草酸、苹果酸分泌量呈显著正相关。     

马铃薯连作对土壤微生物群落结构和功能的影响

采用BIOLOG技术,研究马铃薯连作对土壤微生物群落结构和功能的影响。研究发现：连作土壤湿热灭菌后,细菌、放线菌及微生物总量都明显升高,真菌数量显著降低。连作土壤添加马铃薯残茬后,细菌数量降低,真菌数量增加。连作土壤中微生物对多聚化合物和碳水化合物的利用能力较高;湿热灭菌后,土壤微生物对6类碳源的利用率有升有降,表现为对羧酸类化合物、芳香化合物的利用率升高,对多聚化合物、碳水化合物、氨基酸、胺类化合物的利用率降低,微生物丰富度和均匀度降低。土壤病源微生物可能是马铃薯连作障碍发生的原因之一。