东省不同地区玉米内生真菌的群落组成和多样性分析

为探究山东省玉米内生真菌的资源分布、群落组成及多样性，采用叶片组织分离法对山东省52个市县的玉米内生真菌进行分离纯化，通过内转录间隔区（internal transcribed spacer，ITS）序列分析技术进行内生真菌的种属鉴定，并分析内生真菌的群落组成和多样性。结果表明，共分离到857株内生真菌，隶属25个属，其中链格孢属Alternaria的菌株数量最多，为583株，占总菌株数的68.03%，其次为镰刀菌属Fusarium有71株，占总菌株数的8.28%；大部分地区的优势属为链格孢属，少数地区的优势属为镰刀菌属、炭疽菌属Colletotrichum和弯孢属Curvularia。不同地区的内生真菌定殖率变化很大，在12.50%~100.00%之间，平均定殖率为76.15%；陵城的多样性指数和均匀度指数最高，分别为1.74和0.97；莱芜的丰富度指数最高为2.22。山东省玉米内生真菌可以分为5个类群，其中黄河流域地区内生真菌定殖率相对较高。表明山东省玉米内生真菌种类丰富，不同地区间多样性水平存在差异。     

黑龙江省部分稻区稻瘟病菌对多菌灵的敏感性测定

采用生长速率法测定采自黑龙江省部分稻区的稻瘟病菌菌株对多菌灵的敏感性。试验结果表明,供试稻瘟病菌菌株抑制中浓度(EC50)大多数分布在200～300mg/kg之间,最高为405mg/kg,最低为158mg/kg,其EC50值相差2倍以上,说明供试稻瘟病菌对多菌灵的敏感性均较差,且供试菌株对多菌灵已产生不同程度的敏感性差异。     

植物病原丝状真菌寄生性与RGS蛋白的关系研究

以49个全基因组序列已经公布的真菌为研究对象，通过OrthoVenn2同源基因簇比对、BLASTp比对和关键词搜索3种方法对G蛋白信号调控因子（regulators of G-protein signaling，RGS）同源基因进行比对分析，并结合SMART进行保守结构域分析，结果发现，49个真菌中共有229个RGS蛋白，每种真菌中所含有RGS蛋白的数量范围为3~9个，且死体营养型病原菌和半活体营养型病原菌的RGS蛋白数量高于活体营养型病原菌；根据RGS蛋白中保守结构域进行分类，可以划分为DEP-RGS、RGS-TM、PXA-RGS-PX、RGS、RGS-PAS-PAC、TM-RGS等6种，其中，具有RGS-PAS-PAC和TM-RGS这2种特殊保守结构域的RGS蛋白主要集中在半活体营养型病原菌和死体营养型病原菌；进一步对229个RGS蛋白进行遗传关系分析，发现具有同种保守结构域的RGS蛋白亲缘关系较近。上述研究结果表明植物病原丝状真菌的寄生性与RGS蛋白数量和种类之间存在着一定的关联性。     

Distribution of Arbuscular Mycorrhizal Fungi in Upland Field Soil of Japan 1. Relationship Between Spore Density and The Soilenvironmental Factor

Abstract

To Quantify The Effects of Arbuscular Mycorrhizal Fungi (Am Fungi) On The Growth of Upland Field Crops Cultivated in Japan, We Analyzed Soil Samples From 124 Sites in 18 Japanese Prefectures For Available P Content, Ph and Am Fungal Spore Density. The Am Fungal Spore Density in The 124 Soil Samples Was 1.7 Per G Dw On The Average, and Lower Than 1.0 Per G Dry Soil (Dw) in About Half of The Soil Samples. The Maximum Spore Density Was 20.6 Spores Per G Dw. The Density of Am Fungal Spore Did Not Vary Significantly With The Sampling Site and The Kind of Cultivated Crop in The Sampling Field. The Ph of The Soil With A High Spore Density Ranged From 6 To 8, and in The Soil Samples With A Ph Lower Than 6 and Higher Than 8, TheSpore Density Was Lower Than 5 Spores Per G Dw. Thus, in The Acid Or Alkaline Soil, The Sporogenesis of Am Fungi Is Suppressed. Because Available P Content Was Consistently Low in The Soil Samples With A High Spore Density, P Content Was Considered To Correlate With The Am Fungal Spore Density. Therefore, Crop Cultivation With Limited P Fertilizer Application and Reduced Available P Content May Be Important To increase Am Fungal Spore Density in Upland Field Soil.     

白腐菌降解玉米秸秆条件的优化试验

针对白腐菌对木质素的独特降解能力和玉米秸秆在制取燃料乙醇方面的应用,对白腐菌降解玉米秸秆的降解条件进行优化,通过正交实验得出较好的发酵培养基的组成:玉米秸秆为5g,酒石酸铵为1 g/L,pH值为4.5,微量元素的体积为15mL, VB1的质量为100ug, 吐温80的质量浓度为0.01%,最佳诱导剂是二甲苯胺,表面活性剂是吐温80,最佳通气状况是用4层纱布封口.     

白鲜碱体外抗白色念珠菌活性研究

白色念珠菌等真菌是能够引起人类及动物患病的重要致病菌。本实验测定了白鲜碱对临床22株临床分离氟康唑耐药白色念珠菌的最小抑菌浓度（MIC），采用棋盘式微量稀释实验测定了两药联合应药的分级抑制浓度指数（ractional inhibitory concentration index，FICI）值。结果表明，白鲜碱有较好的抗白色念珠菌活性且与氟康唑有协同作用。     

天山野果林塞威士苹果和短距凤仙花叶斑病病原真菌的鉴定

为了解新疆天山野果林中塞威士苹果Malus sieversii与其林下伴生植物短距凤仙花Impatiens brachycentra两种植物叶斑病病原菌的多样性及同源性,采用组织分离法获得病原菌,基于rDNA-ITS序列构建系统发育树,并进行ITS序列BLAST同源性比对,对病原菌进行鉴定分类,并依据科赫氏法则测定致病性。结果显示,从新疆新源县天山野果林中的塞威士苹果及短距凤仙花病叶上共分离得到18株菌落形态各异的病原菌,分属于2属4种,绝大多数属于半知菌亚门。其中,链格孢属Alternaria sp.为塞威士苹果和短距凤仙花叶斑病病原真菌中的优势菌群。致病性测定结果显示,其中11株病原真菌对塞威士苹果具有致病性,7株病原真菌对短距凤仙花具有致病性;塞威士苹果所有的病原真菌对短距凤仙花均有致病性,而且短距凤仙花所有的病原真菌对塞威士苹果也有致病性。推测2种植物叶斑病可能由相同来源的病原真菌引发,短距凤仙花染病加剧了塞威士苹果叶斑病暴发,可能是野果林退化的重要原因。     

江苏小麦全蚀病菌生物学特性的初步研究

对江苏滨海、响水、灌云和盱眙等县５个菌株研究结果表明，小麦全蚀病菌（Ｇａｅｕｍａｎｎｏｍｙｃｅｓｇｒａｍｉｎｉｓ）生长适温在２０～２５℃之间，３０℃生长受到明显抑制，３５℃停止生长；适宜生长的ｐＨ范围较广，在ｐＨ５～９的范围内生长良好，以ｐＨ７～８最适宜；淹水条件下对全蚀病菌生长有较强的抑制作用，当平均气温２８℃以上（日最高温达３７．５℃），受淹病菌即死亡；全蚀病菌对有机氮利用较铵态氮和硝态氮好；硫酸铵对全蚀病菌的抑制作用是由于高浓度和改变基质ｐＨ两方面的因素。不同来源菌株间在生长适温、ｐＨ及对淹水的反应存在明显差异     

Proteolytic activity in soil: A review

The aim of this work is to review current knowledge on inputs, sources and regulation of protease activities in soils from different ecosystems, while exploring limitations to proteolysis and N mineralisation. Extracellular proteases enter the soil via microbial production and other sources, including plant root exudates, animal excrements, decomposition processes and leaching from agro-industrial fertilisers. The synthesis and activities of proteases in soil are regulated by many factors, including climate, soil properties and the presence of organic compounds of plant and microbial origin. Two particularly important areas for future research are the regulation of proteolysis by low-molecular-weight organic compounds, including amino acids, sugars, flavonoids, plant hormones and siderophores, as well as the identification and characterisation of proteinaceous protease inhibitors of plant and microbial origin in the soil. Despite all the work that has been performed on soil proteases, our understanding of the roles of extracellular plant root proteases in N nutrition is weak. Furthermore, the regulation of soil proteolytic activities of different ecosystems, especially in terms of pollutant inputs and the impact of climate change, requires investigation. Other areas that pose important questions for the future include assessments of protease inhibitor inputs to the soil, regulation of these inhibitors via naturally occurring soil organic compounds and the interactions between soil organisms.