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。     

斜茎黄芪根瘤菌表型性状数值分析

对95株斜茎黄芪根瘤菌与15株已知根瘤菌参比菌及5株来自其它寄本植物的根瘤菌一起进行了130项表型性状分析。结果表明：斜茎黄芪根瘤菌具有极大的表型性状多样性。全部供试菌株在83％相似性水平上分为19个表观群,大部分斜茎黄芪根瘤菌独立成群,与参比菌株的表到性状相似性较低;慢生型斜茎黄芪根瘤菌与快生型斜茎黄芪根瘤菌明显分开,分别构成独立的表现群;某些斜茎黄芪根瘤菌具有很强的抗逆性。     

我国蚕豆根瘤菌的数值分类及其16SrDNA PCR-RFLP研究

对分离自我国11个省24个地区49株蚕豆根瘤菌及11株参比菌株进行了唯一碳源、氮源、抗生素、耐逆性和酶活性等138个表型性状测定,并用MINTS软件进行聚类分析。结果表明,全部供试菌株在59％的相似水平上聚在一起,在80％的相似水平上可分为6个群。其中群4与参比菌株聚在一起,而其他5个群均由未知菌组成。进一步对36株菌进行了16S rDNA PCR—RFLP分析,在85％相似水平上供试菌可分为4个群和1个独立的分支,其聚群结果与数值分类结果有较好的一致性。表型及遗传型分析结果表明,我国蚕豆根瘤菌具有极大的多样性。     

西北部分地区苦马豆根瘤菌的表型多样性研究

将采集自甘肃、新疆、宁夏等地区的苦马豆根瘤,经分离、纯化获得48株未知菌株,并选取7株参比菌株,进行唯一碳、氮源利用、对抗生素及染料抗性、耐盐性、初始pH生长、生长温度范围及酶活性等共113项生理生化测定;采用数值分类方法对未知根瘤菌进行表型多样性分析。结果表明：供试菌株在碳氮源利用、抗生素敏感性、抗逆性等方面存在着差异。该地区苦马豆根瘤菌具有较强的耐盐、耐碱能力,所有菌株均能在初始pH9~12的YMA培养基上生长,35%菌株可耐受6%的NaCl。从数值分类树状图可见,未知供试菌株在56%的相似水平上聚在一起,在72%的相似水平上分为5个表观群。群Ⅰ有39株菌,在74.6%相似水平聚合,中心菌株为CCNWGS0215;群Ⅱ有5株菌,在76%的相似水平聚合,中心菌株为CCNWGS0228;群Ⅳ有2株菌,在81.5%的相似水平聚合,群Ⅲ和群Ⅴ分别只有1株菌,它们与模式株分离,可能为潜在的新种。     

分离自杭子梢等3个宿主的根瘤菌的表型分析*

对86株分离自杭子梢、决明和菜豆的根瘤菌及20株已知参比菌进行了数值分类和全细胞蛋白SDS-PAGE的表型分析。在数值分类聚类中,所有供试菌在68％的相似性水平上分为两群。群I为快生和中侵生根瘤菌,群Ⅱ为慢生根瘤菌。群I在85％的相似性水平上又可分为3个亚群,群Ⅱ在76％的相似性水平上分为3个亚群。蛋白电泳结果表明,群I在68％的相似性水平上,分为4个亚群,其中亚群1和亚群2相当于数值分类中的亚群1,亚群3和亚群4与数值分类中的亚群2和亚群3相对应;群Ⅱ在59％的相似性水平上分为3个亚群,分别与数值分类中的亚群3、亚群1和亚群2大致对应。这说明两种方法在分类上得到的结果比较接近。正在通过进一步的实验确定两种方法一致的未与已知菌株聚在一起的亚群的分类地位。研究结果还表明,三种宿主的根瘤菌存在着多样性。     

费氏中华根瘤菌（Sinorhizobium fredii）的多样性研究

用大豆品种Willimas和黑龙33从多年种植大豆未接种根瘤菌的土壤中集大豆极瘤菌,从分离株中选出50株费氏中华根瘤菌,对供试菌株的培养特性,生长速度,耐酸,耐碱性,生长最终pH值,天然抗药性,CN源利用,刚果红吸收强度,产黑色素能力和质粒图谱类型进行了系统的比较研究,并通过聚类分析得到树状图谱,证实了不同土壤中费氏中华根瘤菌的多样性。     

我国蚕豆根瘤菌的数值分类及其16S rDNA PCR-RFLP研究*

对分离自我国11个省24个地区49株蚕豆根瘤菌及11株参比菌株进行了唯一碳源、氮源、抗生素、耐逆性和酶活性等138个表型性状测定,并用M INTS软件进行聚类分析。结果表明,全部供试菌株在59%的相似水平上聚在一起,在80%的相似水平上可分为6个群。其中群4与参比菌株聚在一起,而其他5个群均由未知菌组成。进一步对36株菌进行了16S rDNA PCR-RFLP分析,在85%相似水平上供试菌可分为4个群和1个独立的分支,其聚群结果与数值分类结果有较好的一致性。表型及遗传型分析结果表明,我国蚕豆根瘤菌具有极大的多样性。     

川中丘陵地区大豆根瘤菌遗传多样性与系统发育关系

【目的】研究分离自川中丘陵地区大豆根瘤菌的遗传多样性和系统发育。【方法】采用16S rDNA PCR-RFLP和16S rRNA基因、glnII、共生基因(nodC)系统发育分析的方法进行研究。【结果】供试未知菌的16S rDNA用4种限制性内切酶(HaeⅢ、HinfⅠ、MspⅠ及TaqⅠ)酶切后获得5种16S遗传图谱类型。16S rDNA PCR-RFLP结果表明,所有供试菌株在83%水平分为慢生根瘤菌属(Bradyrhizobium)和中华根瘤菌属(Sinonrhizobium)两大类群,而75%的菌株为中华根瘤菌。6个代表菌株的16S rDNA、glnII和nodC三个位点基因的系统发育结果基本一致,4株与S.fredii USDA205T相似度最高;有2株分别与B.yuanmingense CCBAU10071T、B.diazoefficiens USDA110T相似度最高。4个Sinonrhizobium代表菌株16S rDNA、glnII序列相似度分别为98.3%-99.9%、98.2%-100%,但它们的nodC基因序列完全相同。【结论】川中丘陵地区大豆根瘤菌具有较丰富的遗传多样性,S.fredii为优势种。     

我国主要生态区域绿豆慢生根瘤菌的遗传多样性和系统发育研究

利用16SrRNAPCR-RFLP、16SrRNA序列分析以及16S-23SrRNAIGS(IntergeneticSpacer)PCR-RFLP技术对分离自中国主要生态区域的44株慢生型绿豆根瘤菌和5株参比菌株进行了遗传多样性和系统发育研究。16SrRNAPCR-RFLP分析表明:在76%的相似水平上,所有供试菌株可分为三大类群:群I由LYG1等13株慢生根瘤菌组成,该群在系统发育上与B.japonicum和B.liaoningense的参比菌株存在一定的差异;群Ⅱ由XJ1等21株供试菌株、B.japonicum和B.liaoningense的代表菌株组成;群Ⅲ由10株来自广东和广西的菌株和B.elkanii的代表菌株组成。16S-23SrRNAIGSPCR-RFLP分析将供试菌株分为A、B两大群。群A由34株供试菌株、B.japonicum和B.liaoningense的代表菌株组成。在85%的相似性水平上,可再分为AⅠ、AⅡ和AⅢ3个亚群。群B由10株分离自广西和广东的菌株和B.elkanii的代表菌株组成。在85%的相似性水平上,可再分为BI和BⅡ两亚群,表现出一定的多样性。与16SrRNAPCR-RFLP相比,16S-23SrRNAIGSPCR-RFLP具有更高的解析度,供试菌株表现出更加丰富的遗传多样性。分离自中国新疆、广东和广西等地的菌株在分群上具有较为明显的地域特征。     

导入三叶草素基因（tfx）的快生型大豆根瘤菌竞争结瘤能力的研究

以导入三叶草素基因（tfx）的快生型大豆根瘤菌H12－2（pXK）和H12－2（p3K）为供试菌株,以出发菌H12－2和8株对三叶草素敏感的快生型大豆根瘤菌混合群体为对照菌,分别在盆栽条件下进行竞争结瘤试验。结果表明,产素菌H12－2（pXK）在两个大豆品种上的占瘤率均高于不产素的重组菌H12－2（p3K）。以H12－2为对照菌时,H12－2（pXK）占瘤率比H12－2（p3K）高出22％～26％;以8株快生型大豆根瘤菌混合群体为对照菌时,可提高30％～34％。     

Phylogeny of fast-growing soybean-nodulating rhizobia support synonymy of Sinorhizobium and Rhizobium and assignment to Rhizobium fredii.

We determined the sequences for a 260-base segment amplified by the polymerase chain reaction (corresponding to positions 44 to 337 in the Escherichia coli 16S rRNA sequence) from seven strains of fast-growing soybean-nodulating rhizobia (including the type strains of Rhizobium fredii chemovar fredii, Rhizobium fredii chemovar siensis, Sinorhizobium fredii, and Sinorhizobium xinjiangensis) and broad-host-range Rhizobium sp. strain NGR 234. These sequences were compared with the corresponding previously published sequences of Rhizobium leguminosarum, Rhizobium meliloti, Agrobacterium tumefaciens, Azorhizobium caulinodans, and Bradyrhizobium japonicum. All of the sequences of the fast-growing soybean rhizobia, including strain NGR 234, were identical to the sequence of R. meliloti and similar to the sequence of R. leguminosarum. These results are discussed in relation to previous findings; we concluded that the fast-growing soybean-nodulating rhizobia belong in the genus Rhizobium and should be called Rhizobium fredii.     

16S rDNA-RFLP分析新疆快生大豆根瘤菌的分类地位

采用１６Ｓ ｒＤＮＡ－ＲＦＬＰ技术,对自新疆土壤中捕捉的３４株快生大豆根瘤菌及相关已知种的模式菌株进行了比较分析。从酶切图谱类型和在结果表明,所有新分离的菌株与Ｓ．ｘｉｎｊｉａｎｇｅｎｓｉｓ的图谱类型基本一致,而与Ｓ．ｆｒｅｄｉｉ的图谱类型有明显差异,与Ｓ．ｍｅｌｉｌｏｔｉ,Ｓ．ｓａｈｅｌｉ,Ｓ．ｍｅｄｉｃａｅ,Ｓ．ｔｅｒａｎｇａ也不相同。３４株新分离的菌株全部与Ｓ．ｘｉｎｇｊｉａｎｇｅｎｓｉｓｉ     

N2-fixation ability of Brazilian soybean cultivars with Sinorhizobium fredii and Sinorhizobium xinjiangensis

The main N₂-fixing symbiotic associations with soybean (Glycine max (L.) Merrill) plants are realized with bacteria belonging to the species Bradyrhizobium japonicum and B. elkanii. However, in 1982, fast-growing rhizobia were isolated from soybean root nodules collected in The People's Republic of China and these bacteria are today classified as Sinorhizobium fredii and S. xinjiangensis. The fast growing strains formed an effective symbiosis with primitive soybean cultivars such as Peking, but not with most North American cultivars, which are the progenitors of almost all Brazilian cultivars. The main purpose of this study was to evaluate the ability of 80 soybean cultivars from the Brazilian germplasm bank to produce effective nodules when inoculated with S. fredii or S. xinjiangensis strains. Sixty-six percent of the Brazilian genotypes formed effective nodules with both Sinorhizobium species. However, when 20 Fix⁺ genotypes were inoculated with a mixture of B. elkanii and S. fredii, at a ratio of 1:1, most or all nodules were occupied by B. elkanii. Consequently, there was no relationship between the growth rate in vitro and the ability to compete for nodule occupancy. Fast-growing strains have also been isolated from soybean nodules in Brazil, but the ecological importance of these symbiotic associations is still to be determined.     

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。     

Citrate synthase mutants of Sinorhizobium fredii USDA257 form ineffective nodules with aberrant ultrastructure

The tricarboxylic acid (TCA) cycle plays an important role in generating the energy required by bacteroids to fix atmospheric nitrogen. Citrate synthase is the first enzyme that controls the entry of carbon into the TCA cycle. We cloned and determined the nucleotide sequence of the gltA gene that encodes citrate synthase in Sinorhizobium fredii USDA257, a symbiont of soybeans (Glycine max [L.] Merr.) and several other legumes. The deduced citrate synthase protein has a molecular weight of 48,198 and exhibits sequence similarity to citrate synthases from several bacterial species, including Sinorhizobium meliloti and Rhizobium tropici. Southern blot analysis revealed that the fast-growing S. fredii strains and Rhizobium sp. strain NGR234 contained a single copy of the gene located in the bacterial chromosome. S. fredii USDA257 gltA mutant HBK-CS1, which had no detectable citrate synthase activity, had diminished nodulation capacity and produced ineffective nodules on soybean. Light and electron microscopy observations revealed that the nodules initiated by HBK-CS1 contained very few bacteroids. The infected cells contained large vacuoles and prominent starch grains. Within the vacuoles, membrane structures that appeared to be reminiscent of disintegrating bacteroids were detected. The citrate synthase mutant had altered cell surface characteristics and produced three times more exopolysaccarides than the wild type produced. A plasmid carrying the USDA257 gltA gene, when introduced into HBK-CS1, was able to restore all of the defects mentioned above. Our results demonstrate that a functional citrate synthase gene of S. fredii USDA257 is essential for efficient soybean nodulation and nitrogen fixation.     

西藏根瘤菌的数值初步分类研究

选取分离自西藏林芝和拉萨地区11种豆科植物的根瘤菌菌株64株,并与6株Rhi-zobium leguminosarum,Sinorhizobium fredii和Mesorhizobium loti的参比菌株一起进行了105项表型特征的测定,数值分类的结果表明,除菌株XZ8-6,XZ47-7和XZ18-1外,全部供试菌株在80%相似性水平上可分为8个表观群,其中表观群1,表观群7分别由13株和7株西藏根瘤菌组成,是不同于已描述根瘤菌种的新表观群,是否为新属种有待于进一步研究。     

Sinorhizobium fredii HH103 has a truncated nolO gene due to a -1 frameshift mutation that is conserved among other geographically distant S. fredii strains

Strain SVQ121 is a mutant derivative of Sinorhizobium fredii HH103 carrying a transposon Tn5-lacZ insertion into the nolO-coding region. Sequence analysis of the wild-type gene revealed that it is homologous to that of Rhizobium sp. NGR234, which is involved in the 3 (or 4)-O-carbamoylation of the nonreducing terminus of Nod factors. Downstream of nolO, as in Rhizobium sp. NGR234, the noeI gene responsible for methylation of the fucose moiety of Nod factors was found. SVQ121 Nod factors showed lower levels of methylation into the fucosyl residue than those of HH103-suggesting a polar effect of the transposon insertion into nolO over the noel gene. A noeI HH103 mutant was constructed. This mutant, SVQ503, produced Nod factors devoid of methyl groups, confirming that the S. fredii noeI gene is functional. Neither the nolO nor the noeI mutation affected the ability of HH103 to nodulate several host plants, but both mutations reduced competitiveness to nodulate soybean. The Nod factors produced by strain HH103, like those of other S. fredii isolates, lack carbamoyl residues. By using specific polymerase chain reaction primers, we sequenced the nolO gene of S. fredii strains USDA192, USDA193, USDA257, and 042B(s). All the analyzed strains showed the same -1 frameshift mutation that is present in the HH103 nolO-coding region. From these results, it is concluded that, regardless of their geographical origin, S. fredii strains carry the nolO-coding region but that it is truncated by the same base-pair deletion.     

A functional myo-inositol dehydrogenase gene is required for efficient nitrogen fixation and competitiveness of Sinorhizobium fredii USDA191 to nodulate soybean (Glycine max [L.] Merr.)

Inositol derivative compounds provide a nutrient source for soil bacteria that possess the ability to degrade such compounds. Rhizobium strains that are capable of utilizing certain inositol derivatives are better colonizers of their host plants. We have cloned and determined the nucleotide sequence of the myo-inositol dehydrogenase gene (idhA) of Sinorhizobium fredii USDA191, the first enzyme responsible for inositol catabolism. The deduced IdhA protein has a molecular mass of 34,648 Da and shows significant sequence similarity with protein sequences of Sinorhizobium meliloti IdhA and MocA; Bacillus subtilis IolG, YrbE, and YucG; and Streptomyces griseus StrI. S. fredii USDA191 idhA mutants revealed no detectable myo-inositol dehydrogenase activity and failed to grow on myo-inositol as a sole carbon source. Northern blot analysis and idhA-lacZ fusion expression studies indicate that idhA is inducible by myo-inositol. S. fredii USDA191 idhA mutant was drastically affected in its ability to reduce nitrogen and revealed deteriorating bacteroids inside the nodules. The number of bacteria recovered from such nodules was about threefold lower than the number of bacteria isolated from nodules initiated by S. fredii USDA191. In addition, the idhA mutant was also severely affected in its ability to compete with the wild-type strain in nodulating soybean. Under competitive conditions, nodules induced on soybean roots were predominantly occupied by the parent strain, even when the idhA mutant was applied at a 10-fold numerical advantage. Thus, we conclude that a functional idhA gene is required for efficient nitrogen fixation and for competitive nodulation of soybeans by S. fredii USDA191.     

鸡眼草根瘤菌的１６SrDNA全序列分析

Based on the previous studies on numerical taxonomy, SDS-PAGE of whole-cell protein and DNA hybridization, the rhizobial strains isolated from Kummerowia sp. in semi-arid area of North-west constituted a new subgroup, the 16S rDNA sequence of representative strain SH714 were tested. The unrooted phylogenetic tree was produced. In this tree, the strain SH714 with Sinorhizobium xinjiangensis, S. fredii, S. meliloti, S. medicae, S. saheli and S. teranga constituted a branch of Sinorhizobium. Within this branch, the similarity valuse of 16S rDNA sequence between strain SH714 and S. xinjiangesis, S. fredii, S. meliloti, S. medicae, S. saheli and S. teranga were 97.4%, 97.5%, 96.8%, 96.7%, 97.2% and 95.6% respectively, the values were more than 95%, this indicated that these known species should belong to the same genus. The values of DNA homology between type strains of these species were less than 70%. Thus, the strain SH714 represented a new rhizobial species, and there were some diversity between SH714 and known rhizobial species in phenotypic feature and composition of protein.     

Diverse rhizobia that nodulate two species of Kummerowia in China

A total of 63 bacterial strains were isolated from root nodules of Kummerowia striata and K. stipulacea grown in different geographic regions of China. These bacteria could be divided into fast-growing (FG) rhizobia and slow-growing (SG) rhizobia according to their growth rate. Genetic diversity and taxonomic relationships among these rhizobia were revealed by PCR-based 16 S rDNA RFLP and sequencing, 16 S-IGS RFLP, SDS-PAGE of whole cell soluble proteins, BOX-PCR and symbiotic gene (nifH/nodC) analyses. The symbiotic FG strains were mainly isolated from temperate regions and they were identified as four genomic species in Rhizobium and Sinorhizobium meliloti based on the consensus of grouping results. The SG strains were classified as five genomic species within Bradyrhizobium and they were mainly isolated fron the subtropic and tropical regions. The phylogenetic analyses of nifH and nodC genes showed relationships similar to that of 16 S rDNA but the symbiotic genes of Bradyrhizobium strains isolated from Kummerowia were distinct from those isolated from Arachis and soybean. These results offered evidence for rhizobial biogeography and demonstrated that the Kummerowia-nodulating ability might have evolved independently in different regions in association with distinctive genomic species of rhizobia.