斜茎黄芪根瘤菌的16SrDNA和23SrDNAPCR—RFLP比较分析

在表型性状数值分析和ＡＦＬＰ指纹图谱分析的基础上,选取５４株斜茎黄芪根瘤菌的代表菌株及已知根瘤菌参比菌株,进行１６ＳｒＤＮＡ和２３ＳｒＤＮＡ的ＰＣＲ－ＲＦＬＰ比较分析。结果表明斜茎黄芪根瘤菌具有极大的系统发育多样性,分别具有２４个１６ＳｒＤＮＡ遗传图谱类型和２２个２３ＳｒＤＮＡ遗传图谱类型,１６ＳｒＤＮＡ与２３ＳｒＤＮＡＰＣＲ－ＲＦＬＰ聚类分析树状图谱有较好的一致性,但也存在一些差异。在对较大类群的划分上,它们的结果与表型性状数值分析结果有较好的一致性。将１６ＳｒＤＮＡ和２３ＳｒＤＮＡＰＣＲ－ＲＦＬＰ分析数据合并在一起进行分析时,得出２６个综合遗传图谱类型和１个综合聚类分析树状图谱。很明显,１６ＳｒＤＮＡ与２３ＳｒＤＮＡ的合并,能够得出更可靠的系统发育结论。     

胡枝子属根瘤菌的多相分类研究

采用了数值分类、全细胞可溶性蛋白电泳分析、ＤＮＡＧ＋Ｃｍｏｌ％和ＤＮＡ相关性的测定以及１６ＳｒＤＮＡＰＣＲＲＦＬＰ分析等多相分类技术对来源于不同地区的１６种寄主的胡枝子根瘤菌进行了系统的分类研究。数值分类的结果表明,在６７％的相似性水平上,全部供试菌可以分为快生型根瘤菌和慢性型根瘤菌两大群,在８０％的相似性水平上又可分为四个亚群。在此基础上,对各亚群的胡枝子根瘤菌进行了ＤＮＡ相关性的测定,以进一步证实和确定它们的分类地位,并通过１６ＳｒＤＮＡＰＣＲＲＦＬＰ分析对各亚群的系统发育关系进行了初步研究。     

斜茎黄芪根瘤菌的16S rDNA和23S rDNA PCR-RFLP比较分析

在表型性状数值分析和ＡＦＬＰ指纹图谱分析的基础上,选取５４株斜茎黄芪根瘤菌的代表菌株及已知根瘤菌参比菌株,进行１６ＳｒＤＮＡ和２３ＳｒＤＮＡ的ＰＣＲ－ＲＦＬＰ比较分析。结果表明斜茎黄芪根瘤菌具有极大的系统发育多样性,分别具有２４个１６ＳｒＤＮＡ遗传图谱类型和２２个２３ＳｒＤＮＡ遗传图谱类型,１６ＳｒＤＮＡ与２３ＳｒＤＮＡＰＣＲ－ＲＦＬＰ聚类分析树状图谱有较好的一致性,但也存在一些差异。在对较大类群的划分上,它们的结果与表型性状数值分析结果有较好的一致性。将１６ＳｒＤＮＡ和２３ＳｒＤＮＡＰＣＲ－ＲＦＬＰ分析     

木蓝根瘤菌的16S rDNA全序列分析及DNA-DNA杂交

通过数值分类、ＳＤＳ－全细胞蛋白电泳分析,对分离自西北黄土高原地区的木蓝根瘤菌进行了研究,获得了１个新类群。在此基础上,进行了中心菌株ＳＨＬ０４２的１６Ｓ ｒＤＮＡ全序列分析,得到系统发育树状图。 ＳＨＬ０４２与 Ｒ.ｔｒｏｐｉｃｉ Ａ、 Ｒ.ｔｒｏｐｉｃｉ Ｂ、 Ｒ.ｌｅｇｕｍｉｎｏｓａｒｕｍ、 Ｒ ｅｔｌｉ、 Ｒｈａｎａｎｅｓｉｓ、Ｒ. ｍｏｎｇｏｌｅｎｓｅ和Ｒ.ｇａｌｌｉｃｕｍ构成一个发育分支,其与这些种模式菌株 １６Ｓ　ｒＤＮＡ全序列的相似性分别为９５．４％、９５．５％、９６．３％、９５．８％、９６．３％、９７．９％和９７．７％,均大于９５％,应属于同一个属。新类群群内ＤＮＡ同源性大于８０％,而中心菌株ＳＨＬ０４２与分支内各已知种的ＤＮＡ同源性小于５０％,表明ＳＨＬ０４２代表１个新的根瘤菌菌种。     

木蓝根瘤菌的16S rDNA全序列分析及DNA—DNA杂交

通过数值分类,ＳＤＳ－全细胞蛋白电泳分析,对分离自西北黄土高原地区的木蓝根瘤菌进行了研究,获得了１个新类群。在此基础上,进行了中心菌株ＳＨＬ０４２的１６Ｓ ｒＤＮＡ全序列分析,得到系统发育树状图。ＳＨＬ０４２与Ｒ．ｔｒｏｐｉｃｉ Ａ、Ｒ．ｔｒｏｐｉｃｉ Ｂ、Ｒ．ｌｅｇｕｍｉｎｏｓａｒｕｍ、Ｒ．ｅｔｌｉ、Ｒ．ｈａｎａｎｅｓｉｓ、Ｒ．ｍｏｎｇｏｌｅｎｓｅ和Ｒ．ｇａｌｌｉｃｕｍ构成一个发育分支,其与这些     

新疆地区盐湖的中度嗜盐菌的16S rDNA PCR-RFLP分析*

对来自新疆地区艾丁湖、艾比湖和玛那斯盐湖等盐湖的２８株中度嗜盐菌与９株相关的参比菌株, 进行了１６Ｓ ｒＤＮＡ ＰＣＲ－ＲＦＬＰ分析,这些菌株是革兰氏阴性杆菌,能在０～２５％ＮａＣｌ中生长。在实验中, 选用４种限制性内切酶ＡｌｕＩ、ＨｉｎｆＩ、ＲｓａＩ和ＨａｅⅢ,将供试菌株的１６Ｓ ｒＤＮＡ的ＰＣＲ产物进行酶切,用３％ 的琼脂糖电泳分析酶切产物。结果表明,在７４％的相似性水平上分为３群。群Ⅰ包括新分离的菌株ＣＩ和　　参比菌株死海色盐杆菌（Ｃｈｒ     

高产稳产聚羟基烷酸的重组大肠杆菌的构建

重组大肠杆菌Ｅｓｃｈｅｒｉｃｈｉａ ｃｏｌｉＨＭＳ１７４（ｐＴＺ１８ＵＰＨＢ） 含有携带聚羟基烷酸（ＰＨＡ） 合成基因（ ｐｈａＣＡＢ）＊＊ 的质粒ｐＴＺ１８ＵＰＨＢ,是很有潜力的ＰＨＡ 生产菌,但存在着质粒不稳定和不能合成３羟基丁酸（３ＨＢ） 与３羟基戊酸（３ＨＶ） 共聚物［Ｐ（３ＨＢｃｏ３ＨＶ）］ 的缺陷。将ＲＫ２ 质粒上的ｐａｒ ＤＥ 基因引入ｐＴＺ１８ＵＰＨＢ 构成质粒ｐＪＭＣ２ ,该质粒可以在宿主Ｅ．ＣｏｌｉＨＭＳ１７４ 中稳定遗传。将培养基中的磷酸盐浓度降至１８ ｍ ｍｏｌ／Ｌ,发现Ｅ．Ｃｏｌｉ ＨＭＳ１７４（ｐＪＭＣ２） 能够以丙酸为前体合成Ｐ（３ＨＢｃｏ３ＨＶ） ,其中３ＨＶ 在共聚物中的含量为５ ％ ～８ ％ 。在５Ｌ自动发酵罐中分批补料培养Ｅ．Ｃｏｌｉ ＨＭＳ１７４（ｐＪＭＣ２） ,培养基初始磷酸盐浓度为１５ ｍ ｍｏｌ／Ｌ,３０ ｈ 后每升培养液中干菌体可达４２－５ ｇ,Ｐ（３ＨＢｃｏ３ＨＶ） 占干重的７０ ％ ,其中３ＨＶ 在共聚物中的含量为４－９ ％ 。     

阿特拉津降解菌株的分离和鉴定*

从农药厂废水中分离到６株能以除草剂阿特拉津为唯一氮源生长的细菌，即假单胞菌（Ｐｓｅｕ－ｄｏｍｏｎａｓ ｓｐｐ．）ＡＤ１、ＡＤ２和 ＡＤ６，土壤杆菌（Ａｇｒｏｂａｃｔｅｒｉｕｍ　ｓｐ．）ＡＤ４，黄单胞菌（Ｘａｎｔｈｏｍｏｎａｓ ｓｐ．）ＡＤＳ，欧文氏菌（Ｅｒｗｉｎｉａ ｓｐ．）ＡＤ７。ＡＤ１菌株能使无机盐培养基中的 ０．３ｇ／Ｌ阿特拉津在７２ｈ内降解９９，９％。当以ＡＤ１、ＡＤ２、ＡＤ４、ＡＤ５、ＡＤ６和ＡＤ７菌株的总ＤＮＡ为模板进行ＰＣＲ扩增时，除Ａ     

脱卤脱亚硫酸菌脱氯呼吸链的遗传分析*

以携有结合转座子Ｔｎ９１６的Ｅｎｔｅｒｏｃｏｃｃｕｓ　ｆａｅｃａｌｉｓ　ＪＨ２－２为供体,脱卤脱亚硫酸菌ＨＳＳ１（Ｄｅｓｕｌｆｉｔｏｂａｃｔｅｒｉｕｍ　ｄｅｈａｌｏｇｅｎａｎｓ,Ｓｍ抗性突变株）为受体,在厌氧条件下,通过滤膜杂交、结合转移,将Ｔｈ９１６转移并插入到受体菌的染色体上,其转移频率为：１．１×１０^－７～３×１０^－８。　在丙酮酸／乳酸－３－氯－４－羟基苯氧乙酸、Ｔｃ、Ｓｍ培养基上,筛选脱氯呼吸的缺陷型突变株,并用反向ＰＣＲ（Ｉ     

枯草芽孢杆菌B034拮抗蛋白的分离纯化及特性分析

枯草芽孢杆菌（Ｂａｃｉｌｕｓｓｕｂｔｉｌｉｓ）Ｂ０３４分离自水稻叶面,对水稻白叶枯病菌具有较强的拮抗能力。除去菌体培养液以７０％饱和度硫酸铵沉淀所得的拮抗物粗提液对热稳定,对胰蛋白酶不敏感,对蛋白酶Ｋ、链霉蛋白酶Ｅ部分敏感,对氯仿部分敏感,其作用的活性ｐＨ范围低至４,高至１２以上,比较耐碱性。粗提液经ＰｈｅｎｙｌＳｅｐｈａｒｏｓｅＣＬ４Ｂ柱层析、ＤＥＡＥＳｅｐｈａｃｅｌ柱层析和ＨＰＬＣ的Ｓｕｐｅｒｄｅｘ７５ＨＲ１０／３０柱层析,得到二个拮抗活性峰：Ｐ１和Ｐ２。Ｐ２经ＳＤＳＰＡＧＥ和ＰＡＧＥＩＥＦ电泳显示为单一蛋白带,分子量５０３ｋＤ,等电点６２５。自动Ｅｄｍａｎ降解法从Ｐ２的Ｎ端测出残基序列为ＩｌｅＳｅｒＡｓｎＰｒｏＸＩｌｅＡｓｐＶａｌ     

攀枝花市银合欢根瘤菌遗传多样性

【目的】研究分离自四川攀枝花的银合欢根瘤菌的遗传多样性。【方法】采用联合16S rDNA RFLP和IGS RFLP的综合聚类分析(16S-IGS RFLP)、AFLP及多位点持家基因(16S rDNA,atpD,recA)序列的联合分析对供试银合欢根瘤菌进行研究。【结果】31株未知菌具有15种16S-IGS遗传图谱类型、27种AFLP类型。16S-IGS RFLP结果表明,没有未知菌与Bradyrhizobium的参比菌株聚在一起。在71.4%的相似水平上,31个未知菌按属的水平分成3个分支:S、M和R,分别分布在Sinorhizobium属(28株)、Mesorhizobium属(2株)和Rhizobium属(1株)。S分支的28个菌在84%的相似水平上,16S-IGS RFLP聚类图中构成3个群:群S1、群S2、群S3;在AFLP聚类图中构成9个AFLP群:S1–S9。多位点基因序列表明,代表菌株SCAU215、SCAU231分别与M.Plurifarium、R.huautlense亲缘关系最近。而分布于Sinorhizobium属SCAU222和SCAU228、SCAU213、SCAU216可能代表Sinorhizobium的3个新类群。【结论】攀枝花市银合欢根瘤菌遗传多样性丰富,分布于Sinorhizobium、Mesorhizobium和Rhizobium三个属,且优势类群为Sinorhizobium。     

西北地区天蓝苜蓿根瘤菌16S rDNA RFLP分析

利用RFLP和序列测定方法,对分离自西北地区的67株天蓝苜蓿根瘤菌16S rDNA进行了分析研究。结果表明:所有供试菌株分别归属于中华根瘤菌属(Sinorhizobium)、根瘤菌属(Rhizobium)和土壤杆菌属(Agrobac-terium)。以CCNWNX0042-2为代表的大部分天蓝苜蓿根瘤菌属于草木樨中华根瘤菌(Sinorhizobium meliloti),其余菌株在分群上表现出了较为明显的地域特征。     

金沙江干热河谷区田菁根瘤菌多样性与系统发育

[目的]揭示金沙江干热河谷区这一特殊地理环境下田菁根瘤菌的多样性和系统发育地位. [方法]采用了数值分类、16S rDNA PCR-RFLP、16S rDNA和GSⅡ序列分析方法.[结果]数值分类结果表明:在93%的水平上,待测菌株分布于6个群,其中4个群分别与R.tropici、 R.etli、 S.saheli、A.rubi的参比菌株聚在一起,两个群没有参比菌株与之聚群.16S rDNA PCR-RFLP结果与数值分类基本一致,只有两个独立群有所差异.16S rDNA序列分析表明:两独立群中心菌株SCAU176 和SCAU144与R.huautlense聚在一起,与该种同源性分别为100%和98.9%.GSⅡ序列分析中SCAU176 和SCAU144单独聚在一起,与最近的参比菌株R.tropici的同源性系数在90%以下.[结论]金沙江干热河谷区田菁根瘤菌具有较为丰富的多样性,在系统发育地位上分布于Sinorhizobium、Agrobacterium和Rhizobium三个属.     

黄土高原地区大豆根瘤菌的遗传多样性和系统发育

【目的】研究黄土高原地区大豆根瘤菌的遗传多样性和系统发育。【方法】采用BOX-PCR、16S rDNAPCR-RFLP、16S-23S IGS PCR-RFLP和16S rRNA基因序列分析方法对分离自我国黄土高原地区4个省的15个地区的130株大豆根瘤菌及部分参比菌株进行了遗传多样性和系统发育分析。【结果】BOX-PCR反映的菌株多样性最丰富,形成的遗传群最多,16S rDNA PCR-RFLP方法在属、种水平上聚群较好,16S-23S IGSPCR RFLP反映的多样性介于BOX-PCR和16S rDNA PCR-RFLP之间,能够较好地反映出属、种和亲缘关系很近的菌株间的差异,3种方法聚类分析结果基本一致,可将所有供试菌株分为两大类群,中华根瘤菌属(Sinorhizobium)和慢生根瘤菌属(Bradyrhizobium)。从系统发育来看,供试的快生大豆根瘤菌为费氏中华根瘤菌(Sinorhizobium fredii),慢生大豆根瘤菌为日本慢生大豆根瘤菌(Bradyrhizobium japonicum)和辽宁慢生根瘤菌(Bradyrhizobium liaoningense)。【结论】我国黄土高原地区大豆根瘤菌具有较丰富的遗传多样性,S.fredii优势种,慢生大豆根瘤菌仅占10%,同时,分离到2株B.liaoningense。     

Genetic relationship of Sinorhizobium meliloti and Sinorhizobium medicae strains isolated from Caucasian region

Sinorhizobium meliloti and Sinorhizobium medicae are two closely related species of the genus Sinorhizobium showing a similar host range, nodulating leguminous species of the genera Medicago, Melilotus and Trigonella, but their phylogenic relationship has not been elucidated yet. In this paper we report the application of three different molecular markers, (i) RFLP of nodD genes, (ii) 16S-23S rDNA intergenic gene spacer fingerprinting and (iii) amplification fragment length polymorphism to S. meliloti and S. medicae strains isolated from the Caucasian area, which is the region of origin of the host plant Medicago. The analysis of data could suggest the origin of S. medicae strains from an ancestral S. meliloti population.     

Genetic diversity of fast-growing rhizobia that nodulate soybean ( Glycine max L. Merr)

The fast-growing Rhizobium sp. strain NGR234, isolated from Papua New Guinea, and 13 strains of Sinorhizobium fredii, isolated from China and Vietnam, were fingerprinted by means of RAPD, REP, ERIC and ARDRA. ERIC, REP and RAPD markers revealed a considerable genetic diversity among fast-growing rhizobia. Chinese isolates showed higher levels of diversity than those strains isolated from Vietnam. ARDRA analysis revealed three different genotypes among fast-growing rhizobia that nodulate soybean, even though all belonged to a subcluster that included Sinorhizobium saheli and Sinorhizobium meliloti. Among S. fredii rhizobia, two strains, SMH13 and HH303, might be representatives of other species of nitrogen-fixing organisms. Although restriction analysis of the nifD–nifK intergenic DNA fragment confirmed the unique nature of Rhizobium sp. strain NGR234, several similarities between Rhizobium sp. strain NGR234 and S. fredii USDA257, the ARDRA analysis and the full sequence of the 16S rDNA confirmed that NGR234 is a S. fredii strain. In addition, ARDRA analysis and the full sequence of the 16S rDNA suggested that two strains of rhizobia might be representatives of other species of rhizobia.     

采用PCR-RFLP技术在不同水平上鉴定大豆根瘤菌

采用16S rRNA基因PCR扩增与限制性酶切片段多态性分析(RFLP)技术对选自弗氏中华根瘤菌(S.fredii)、大豆慢生根瘤菌(B.japonicum)和埃氏慢生根瘤菌(B.elkanii)的19株代表菌进行了比较分析,根据用3种限制性内切酶的RFLP分析结果,可将供试菌株分为S.fredii,B.japonicum, B.elkanii Ⅱ和B.elkanii Ⅱa等4种基因型。各类菌株之间没有交叉,因此本研究采用的PCR-RFLP技术不失为一种快速鉴别大豆根瘤菌的新方法。采用本技术已将分离自中国的22株快生菌和19株慢生菌分别鉴定为S.fredii和B.japonicum。对供试参比菌株和野生型菌株进行的16S～23S基因间隔DNA(IGS)的PCR-RFLP分析结果表明：S.fredii和B.japonicum菌株的IGS长度不同,所有供试S.fredii菌株的IGS为2.1 kb,而供试B.japonicum菌株则为2.0 kb。依据RFLP的差异,可将来自中国两个不同地区的S.fredii株区分为2个基因型,而来自中国东北黑龙江地区的19株B.japonicum菌株则可分为11个基因型。对上述野生型菌株还进行了REP-PCR和ERIC-PCR分析并确定其具有菌株水平的特异性。     

黄华属根瘤茵的16S rDNA-RFLP分析

采用16S rDNA-RFLP及序列分析方法,对分离自黄华属的披针叶黄华、喀什黄华和光叶黄华根瘤菌进行分析研究.结果表明,分离得到的33株根瘤菌在种水平上具有丰富的遗传多样性,它们分别归属于中慢生根瘤菌属(Mesorhizobium)、中华根瘤菌属(Sinorhizobium)、根瘤菌属(Rhizobium)和土壤杆菌属(Agrobacterium).其中,以CCNWGS0011和CCNWGS0010-1为代表的5株根瘤菌构成独立的分支,可能为潜在的新种.     

Genetic diversity of rhizobia isolated from Astragalus adsurgens growing in different geographical regions of China

The genetic diversity among 95 isolates from Astragalus adsurgens was investigated using molecular biological methods. All of the isolates and 24 reference strains could be differentiated by AFLP, REP-, ERIC- and BOX-PCR fingerprinting analysis. By cluster analysis of the data, 31 AFLP and 38 Rep-PCR genomic groups were delineated, indicating considerable genetic diversity among the isolates. Fifty-four representative strains were further analyzed by RFLP of PCR-amplified 16S and 23S rDNA, revealing 26 rDNA genotypes among the isolates. The phylogenetic relationship of the isolates was determined by partial sequencing of 16S rRNA genes of 16 strains. The results suggest that the A. adsurgens rhizobia belong to the genera Agrobacterium, Mesorhizobium, Rhizobium and Sinorhizobium.     

The variable part of the dnaK gene as an alternative marker for phylogenetic studies of rhizobia and related alpha Proteobacteria

DnaK is the 70 kDa chaperone that prevents protein aggregation and supports the refolding of damaged proteins. Due to sequence conservation and its ubiquity this chaperone has been widely used in phylogenetic studies. In this study, we applied the less conserved part that encodes the so-called alpha-subdomain of the substrate-binding domain of DnaK for phylogenetic analysis of rhizobia and related non-symbiotic alpha-Proteobacteria. A single 330 bp DNA fragment was routinely amplified from DNA templates isolated from the species of the genera, Azorhizobium, Bradyrhizobium, Mesorhizobium, Rhizobium and Sinorhizobium, but also from some non-symbiotic alpha Proteobacteria such as Blastochloris, Chelatobacter and Chelatococcus. Phylogenetic analyses revealed high congruence between dnaK sequences and 16S rDNA trees, but they were not identical. In contrast, the partition homogeneity tests revealed that dnaK sequence data could be combined with other housekeeping genes such as recA, atpD or glnA. The dnaK trees exhibited good resolution in the cases of the genera Mesorhizobium, Sinorhizobium and Rhizobium, even better than usually shown by 16S rDNA phylogeny. The dnaK phylogeny supported the close phylogenetic relationship of Rhizobium galegae and Agrobacterium tumefaciens (R. radiobacter) C58, which together formed a separate branch within the fast-growing rhizobia, albeit closer to the genus Sinorhizobium. The Rhizobium and Sinorhizobium genera carried an insertion composed of two amino acids, which additionally supported the phylogenetic affinity of these two genera, as well as their distinctness from the Mesorhizobium genus. Consistently with the phylogeny shown by 16S-23S rDNA intergenic region sequences, the dnaK trees divided the genus Bradyrhizobium into three main lineages, corresponding to B. japonicum, B. elkanii, and photosynthetic Bradyrhizobium strains that infect Aeschynomene plants. Our results suggest that the 330 bp dnaK sequences could be used as an additional taxonomic marker for rhizobia and related species (alternatively to the 16S rRNA gene phylogeny).