草莓连作土壤酚酸类物质积累对土壤线虫的影响

通过大田试验和盆栽试验相结合的方式,对不同连作年限草莓土壤酚酸类物质含量、土壤线虫数量和食细菌线虫数量以及外源酚酸类物质对土壤线虫数量和食细菌线虫数量的影响进行了研究。结果表明:随连作年限的增加,草莓连作土壤中酚酸类物质含量明显增加,土壤线虫总数和食细菌线虫总数整体呈现下降趋势,且连作5年的土壤线虫总数和食细菌线虫数量最低,酚酸类物质含量与土壤线虫总数和食细菌线虫数量呈负相关;对羟基苯甲酸和对香豆酸在浓度低于200μg·g-1时使土壤线虫总数和食细菌线虫数量增加,而高于200μg·g-1时起抑制作用;肉桂酸在浓度低于100μg·g-1时增加了土壤线虫总数和食细菌线虫数量,而高于100μg·g-1时起抑制作用;随阿魏酸浓度的增加,线虫数量变化规律不明显,当其浓度高于100μg·g-1时起抑制作用;混合酚酸随浓度增加对土壤线虫总数和食细菌线虫数量的抑制作用增强。     

苜蓿化感作用的初步研究

利用生物测定法和气相色谱 /质谱 (GC/MS)联用技术对中国北方广为种植的紫花苜蓿的化感作用进行了初步研究。结果表明 ,紫花苜蓿全草的水和 95 %乙醇浸提液对玉米和小麦种子萌发均有显著的抑制作用 ,进一步用柱层析对苜蓿浸提液进行了初步分离 ,分离组份对玉米和小麦种子萌发的影响有所变化。抑制玉米萌发的活性物质主要在弱极性的二氯甲烷组份中 ,而抑制小麦萌发的活性物质不仅存在于二氯甲烷组份中 ,也存在于水中。采用GC/MS技术 ,初步推测苜蓿的化感物质是酚和皂甙两类化合物     

黄瓜连作土壤酚酸类物质积累对土壤微生物和酶活性的影响

伴随连作年限的增加,日光温室黄瓜连作土壤中酚酸类物质(对羟基苯甲酸、阿魏酸、苯甲酸)明显积累,连作5～9年的土壤酚酸类物质含量显著高于连作1～3年的土壤.伴随外源酚酸类物质处理浓度的增加,黄瓜根区土壤中细菌、放线菌和微生物总量以及N生理群均呈先升后降趋势,在80 μg·g^-1处理浓度下细菌、放线菌数量最多,处理浓度在120μg·g^-1以下土壤真菌数量(包括尖孢镰刀菌、疫霉)急剧增长;多酚氧化酶、过氧化氢酶、蔗糖酶、脲酶和蛋白酶活性也同样呈先升后降趋势,但其峰值对应的浓度不同.     

胜红蓟化感作用研究 Ⅸ.主要化感物质在土壤中的转化

在田间条件下,胜红蓟挥发油能抑制花生的出苗和生长发育,进一步用高效液相色谱（HPLC）研究证实;胜红蓟挥发油中的主要化感物质胜红蓟素在土壤中的转化与土壤的有机质和营养元素水平显著相关,在高有机质和营养元素水平的土壤中,胜红蓟素先聚合形成二聚体,26d后又解聚成胜红蓟素,然后逐步降解成苯甲酸类,2-甲基丙酸和乙酸等小分子,而在低有机质和营养元素水平的土壤中,胜红蓟素不经过二聚化过程,而是直接降解成小分子,经液质（LC/MS）和核磁共振（NMR）等技术分离鉴定了胜红蓟素二聚体的结构,生物测定表明：胜红蓟素二聚体对花生和黑牧草的生长没有抑制活性。     

酚酸类物质的化感作用研究进展

酚酸类物质是普遍存在于高等植物组织并与植物生长密切相关的次级代谢产物。几十年来,人们对酚酸类化合物的认识逐渐加深,但关于其在生物学、生态学以及农业上的作用机制仍不是很清楚。因此,进一步了解这些生物分子将有助于生态系统的维持与保护。重点介绍了酚酸类物质的来源及化感作用,微生物对酚酸类物质的降解机理,代谢途径及相应分子水平的研究,指出了酚酸类物质研究中存在的问题,同时展望了酚酸类物质的研究方向与前景。     

生石灰对林下酸化土壤的调控作用及三七生长的影响

土壤酸化是导致林下三七生长不良和根腐病发生的重要因素。本试验利用不同量(0、500、1000、1500和2000 kg·hm^-2)的生石灰改良林下酸化土壤,评价生石灰对土壤理化性质、酚类物质、根际微生物和三七生长的影响。结果表明: 适量的生石灰(500～1000 kg·hm^-2)可显著提高土壤pH值,降低酚类物质(羟基苯甲酸、香草醛、丁香酸、阿魏酸和香草酸)含量,促进三七的生长,并降低根腐病的发生。适量的生石灰(500～1000 kg·hm^-2)能显著降低土壤的真菌/细菌,提高细菌多样性,提高门水平上子囊菌门、变形菌门和属水平上马赛菌属和鞘脂单胞菌属的相对丰度。但是过量的生石灰(1500～2000 kg·hm^-2)会降低土壤碱解氮和有机质含量,抑制三七的生长。因此,500～1000 kg·hm^-2生石灰可显著改善林下土壤的化学性质和微生物群落,从而促进三七生长,降低根腐病的发生。     

消毒灭菌的土壤中多效唑的降解作用（简报）

示踪技术研究的结果表明，未经消毒灭菌的土壤中ＰＰ３３３及其降解物降解速度快于经过消毒的土壤，且其降解能力和速度与土壤类别有关。     

蚯蚓调控土壤微生态缓解连作障碍的作用机制

连作障碍不仅严重影响作物产量, 而且会导致土壤生物多样性下降、有益微生物减少及病原菌增加等一系列微生态失衡问题。土壤微生态失衡反作用于植物, 导致植物发生更严重的病害、减产等。作为土壤生态系统工程师, 蚯蚓的取食、掘洞和爬行等活动对土壤微生态具有重要的调控作用, 既可以改善土壤环境, 又可以强化土壤生物群落功能, 有望为缓解作物的连作障碍问题提供一条新途径。本文总结了土壤微生态与土壤功能维持及蚯蚓调控土壤生物作用的研究进展, 在此基础上, 结合蚯蚓对化感物质降解作用的研究, 分析了蚯蚓通过调控土壤微生态缓解作物连作障碍的微生物作用机制的三条途径: 直接调控微生物群落、通过改变化感物质组成以及通过调控土壤动物区系调控微生物群落。蚯蚓对微生物群落的调控可改善失衡的土壤根际微生态, 有效缓解作物连作障碍。     

真菌对石油污染土壤的降解研究

利用微生物对石油污染土壤进行生物降解，具有操作简单，费用低廉，场地适用性强等特点。挑选了2种菌株，进行了室内油降解实验，在摇床实验油降解率：微生物真菌（Faserium．LK）（土著）和真菌（Phanerochaete．Chrysosprium），在20d分别为41.2％和28．1％，真菌（Fusarium．LK）高于真菌（Phane－rochate．Chrysosprium）的降解率，而在培养箱石油污染土壤中，真菌（Fusarium．LK）（土著）和真菌（Phane－rochaete.Chrysosprium），在50d分别为61.8％和66．1％，（Fusarium.LK）低于（Phanerochaete.Chrysosri-um）。     

Use of Fenton's Reagent for the Degradation of TCE in Aqueous Systems and Soil Slurries

Fenton's reaction is comprised of hydrogen peroxide (H₂O₂) catalyzed by iron, producing the hydroxyl radical (·OH), a strong oxidant. ·OH in turn may react with H₂O₂ and iron and is capable of destroying a wide range of organic contaminants. In this laboratory study, Fenton's reaction was observed in aqueous and soil slurry systems using trichloroethylene (TCE) as the target contaminant, with the goal of maximizing TCE degradation while minimizing H₂O₂ degradation. Fenton's reaction triggers a complex matrix of reactions involving ·OH, H₂O₂, iron, TCE, and soil organics. In soil slurries with a high fraction of organic carbon (f_OC), iron tends to sorb to soil organics and/or particles. In aqueous systems the optimal ratio of H₂O₂:Fe²⁺:TCE to degrade TCE in a timely fashion, minimize costs, and minimize H₂O₂ degradation is 300?mg/L: 25?mg/L: 60?mg/L (19:1:1 molar ratio), while soil slurries with a f_OC up to approximately 1% and a soil:water ratio of 1:5 (weight ratio) require about ten times the amount of H₂O₂, the optimal ratio being 3000?mg/L: 5?mg/L: 60?mg/L (190:0.2:1 molar ratio). TCE degradation rates were observed to decrease in soil slurries with higher f_OC because of competition by soil organic matter, which appears to act as a sink for ·OH. H₂O₂ degradation rates tended to increase in soil slurries with higher f_OC, most likely due to increased demand for ·OH by soil organics, increased available iron and other oxidation processes.     

氰化物在土壤中的自然降解模拟实验

通过对3种含不同氰化物浓度的粘黄土泥样的测定,探索氰化物在粘土中的降解规律。结果表明：粘黄土对氰化物（CN^-）有较强的吸附与净化作用;CN^-浓度随时间的变化符合一级动力学模式;制备土样中CN^-的初始浓度高降解慢,初始浓度低降解快。     

Degradation of Metolachlor in Tobacco Field Soil

The extensive use of metolachlor to control weeds in tobacco fields in China has aroused concern about its environmental fate. The aim of this study was to investigate the degradation and residue fate of metolachlor in tobacco field soil (silt loam) under laboratory and field conditions. In laboratory experiments, metolachlor in bulk soil exhibited fast degradation in a temperature range from 10 to 35°C and a soil moisture level of 20–80%, with half-lives (T_1/2) from 66.7 to 28.8 days. The degradation rate of metolachlor decreased as the application dose increased. Owing to higher microbial populations and enzymatic activities, metolachlor rapidly dissipated in rhizosphere soil as compared to bulk soil. Field persistence of metolachlor was evaluated in the same soil during the tobacco (Nicotiana tabacum K326) growing season in 2012 and 2013. The dissipation of metolachlor followed the first-order kinetics and its T_1/2 values were 11.7–13.5 days in soil and 9.0–9.6 days in green tobacco leaves, respectively. At harvest time, the residual levels of metolachlor in soil and green tobacco leaves were in the range of 0.626–1.623 and 0.083-0.481 mg kg^?1, respectively. These findings might have practical implications for the fate of metolachlor residue in tobacco fields. Environmental factors, especially temperature and moisture, should be considered in combination with the appropriate application dose of metolachlor for achieving satisfactory weed-control efficacy, reducing runoff, and minimizing effects on environmental quality.     

Carbohydrate oxidases in ericoid and ectomycorrhizal fungi: a possible source of Fenton radicals during the degradation of lignocellulose

Isolates of the ericoid mycorrhizal fungus Hymenoscyphus ericae (Read) Korf et Kernan, and the ectomycorrhizal fungi Suillus variegatus (Swartz ex Fr.) and Pisolithus tinctorius (Pers.) Coker & Couch, along with a Cortinarius sp. and the white rot Phanerochaete chrysosporium Burdsall were examined for the ability to oxidize carbohydrates to their corresponding lactones and to excrete the H₂O₂ produced thereby. All except Phanerochaete chrysosporium were found to express cellobiose oxidase (cellobiose dehydrogenase, EC 1.1.19.88) and glucose oxidase (β- d -glucose:oxygen 1-oxidoreductase, EC 1.1.3.4) when grown on cellobiose and glucose respectively. Production of extracellular H₂O₂ was visualized during growth on both substrates using ABTS as the chromogen. According to the Fenton reaction, H₂O₂ will react with hydrated or chelated Fe(II) in the environment to produce hydroxyl (Fenton) radicals, HO^·. Mycelial extracts from each of the mycorrhizal fungi produced HO^· in the presence of cellobiose and Fe(II), presumably mediated by H₂O₂ produced by cellobiose oxidase activity in the extracts. Conditions favourable to HO^· production were shown to exist in Modified Melin–Norkrans medium, and the data discussed in relation to previously observed lignin degradation by mycorrhizal fungi.     

Folin-Ciocalteu分光光度法测定夏枯草总酚含量的研究(英文)

通过采用Folin-Ciocalteu试剂,以没食子酸为对照品,用紫外可见分光光度法,研究测定夏枯草中总酚含量。结果表明,在装有样品的10 mL容量瓶中依次加入Folin-Ciocalteu试剂0.5 mL,20%Na2CO31.7 mL,室温放置60 min后,在波长660 nm或760 nm测定吸光度。多酚质量浓度在0～10.3μg/mL范围内与吸光度有良好的线性关系,回归方程在660 nm为Y=94.542X-0.0067,R2=0.9999,加样回收率为101.7～105.0%;760 nm为Y=101.13X-0.0191,R2=0.9990,加样回收率为105.1～107.6%。本研究在稳定性、准确性和重复性方面都具有较好的实验结果,可为夏枯草多酚的定量分析提供方法参考。     

Allelochemicals released by rice roots and residues in soil

A few rice (Oryza sativa L.) varieties or rice straw produce and release allelochemicals into soil in which interfere with the growth of neighboring or successive plants. Allelopathic rice PI312777 and Huagan-1 at their early growth stages released momilactone B, 3-isopropyl-5-acetoxycyclohexene-2-one-1, and 5,7,4′-trihydroxy-3′,5′-dimethoxyflavone into soil at phytotoxic levels, but non-allelopathic rice Huajingxian did not. Both allelopathic and non-allelopathic rice residues released momilactone B and lignin-related phenolic acids (p-hydroxybenzoic, p-coumaric, ferulic, syringic and vanillic acids) into the soil during residue decomposition to inhibit successive plants. The results indicated that allelochemicals involved in rice allelopathy from living and dead plants are substantially different. Interestingly, the concentrations of the allelochemicals released from the allelopathic rice seedlings in soil increased dramatically when they were surrounded with Echinochloa crus-galli. The concentrations of the allelochemicals were over 3-fold higher in the presence of E. crus-galli than in the absence of E. crus-galli. However, the same case did not occur in non-allelopathic Huajingxian seedlings surrounded with E. crus-galli. In addition to allelochemical exudation being promoted by the presence of E. crus-galli, allelopathic rice seedlings also increased allelochemical exudation in response to exudates of germinated E. crus-galli seeds or lepidimoide, an uronic acid derivative exuded from E. crus-galli seeds. These results imply that allelopathic rice seedlings can sense certain allelochemicals released by E. crus-galli into the soil, and respond by increased production of allelochemicals inhibitory to E. crus-galli. This study suggests that rice residues of both allelopathic and non-allelopathic varieties release similar concentrations and types of allelochemicals to inhibit successive plants. In contrast, living rice plants of certain allelopathic varieties appear to be able to detect the presence of interspecific neighbors and respond by increased allelochemicals.     

杉木解酚菌的研究

从杉木林土壤中筛选到5株高效解酚菌(F₂、F₃、F₄、F₇、F₁₅),结果表明,F₄、Fd,F₂、F₁₅5d能将600rng·L^-1的阿魏酸降解完,F₇的降解率为91.3%;F₄、F₃、F₂、F₇d,F₁₅、4d能将600mg·L^-1的对羟基苯甲酸完全降解;5株解酚菌对邻香草醛的降解能力较弱,除F₂5d能将300mg·L^-1的邻香草醛完全降解外,其余4株5d的降解率为83%～96%.同时发现,F₄能抑制杉苗生长,而其余4株则能在不同条件下促进杉苗生长,将5种菌按等比例混合使用,在土壤添加酚酸的情况下,仍能促进菌根苗Z和非菌根苗生长,杉木苗干重增长率为8.9%～168%.     

落叶松人工林土壤衰退趋势

落叶松人工林土壤衰退趋势＊阎德仁王晶莹杨茂仁（内蒙古林业科学研究院,呼和浩特０１００１０）ＴｅｎｄｅｎｃｙｏｆＳｏｉｌＤｅｇｒａｄａｔｉｏｎｉｎｔｈｅＰｕｒｅＬａｒｃｈＰｌａｎｔａｔｉｏｎｓ．ＹａｎＤｅｒｅｎ,ＷａｎｇＪｉｎｇｙｉｎｇ,ＹａｎｇＭａｏ...     

杉木解酚菌的研究

从杉木林土壤中筛选到5株高效解酚菌(F2、F3、F4、F7、F15),结果表明,F4、F33d,F2、F155d能将600rng     

敌敌畏在3种豆类蔬菜及其土壤中残留降解研究

对敌敌畏在毛豆、豌豆、豇豆等豆类蔬菜及在豌豆田土壤中的残留降解动态进行田间测定。结果表明,80%敌敌畏乳油500~2000倍液施用1 d后的降解率均达93%以上;3 d后残留量≤0.02 mg/kg,降解率均达99%以上;5 d后未能检测到残留(检出限<0.005 mg/kg)。敌敌畏农药在豌豆田土壤中的降解规律符合一级动力学关系,半衰期(DT₅₀)为4.3 d。