利用Tn5-1063转座诱变法分离苜蓿中华根瘤菌042BM noeB基因的研究

采用三亲本杂交方法将带有Tn5-1063(含luxAB)的质粒pRL1063a导入苜蓿中华根瘤菌(Sinorhizobium meldoti)042BM,进行转座子插入诱变,在含有氯霉素、卡那霉素的TY平板上筛选接合子。通过结瘤试验,从1000个突变株中,筛选到3个结瘤突变株042BMR5、042BMR11和042BRM29。它们都表现出发光酶活性,表明转座子正向插入到基因组中的某个启动子下游。Southern杂交结果证实,转座子均为单一位点插入。对042BMR5突变株基因组进行反向PCR,扩增位于Tn5-1063两端的侧翼序列。测序结果表明,转座子插入到苜蓿中华根瘤菌的共生质粒pSymA noeB基因内。根据基因组中noeB上游和下游序列扩增出042BM noeB,其与苜蓿中华根瘤菌1021 noeB的同源性为98％,而与NoeB蛋白的氨基酸序列相似性为95％。疏水性分析发现,NoeB是一个跨膜蛋白,在N末端有4个跨膜区,其中包含3个初级螺旋和1个次级螺旋。     

利用Tn51063转座诱变法分离苜蓿中华根瘤菌042BMnoeB基因的研究

采用三亲本杂交方法将带有Tn51063（含luxAB）的质粒pRL1063a导入苜蓿中华根瘤菌(Sinorhizobium meliloti)042BM,进行转座子插入诱变,在含有氯霉素、卡那霉素的TY平板上筛选接合子。通过结瘤试验,从1000个突变株中,筛选到3个结瘤突变株042BMR5、042BMR11和 042BRM29。它们都表现出发光酶活性,表明转座子正向插入到基因组中的某个启动子下游。Southern杂交结果证实,转座子均为单一位点插入。对042BMR5突变株基因组进行反向PCR,扩增位于Tn51063两端的侧翼序列。测序结果表明,转座子插入到苜蓿中华根瘤菌的共生质粒pSymA noeB基因内。根据基因组中noeB上游和下游序列扩增出042BM noeB,其与苜蓿中华根瘤菌1021 noeB的同源性为98％,而与NoeB蛋白的氨基酸序列相似性为95％。疏水性分析发现,NoeB是一个跨膜蛋白,在N末端有4个跨膜区,其中包含3个初级螺旋和1个次级螺旋。     

根瘤菌共生固氮的遗传学研究(二)

2.在根瘤菌研究中成功地运用了转座子诱变技术。转座子(Transposon)是一种特殊的DNA短片段,它带有抗药性基因,并具有在DNA复制子之间转座插入的能力,转座的发生并不需要recA基因产物,一些转座子象Tn 5的转座插入位点的分布是相当随机的,但另一些象Tn 10,它的转座插入似乎具有“热点”(Hot spot),转座子插入到一个新位点时,被插入位点原基因的连续性受到阻断,因而该基因的功     

阴沟肠杆菌B8拮抗活性基因‘admA’及上游调控序列的克隆与功能鉴定

为了阐明水稻白叶枯病拮抗菌阴沟肠杆菌B8的作用机理,文章采用转座子标签法和染色体步移技术克隆到突变株B8B中Tn5插入位点周边拮抗活性相关片段,并通过基因敲除验证了获得的拮抗相关片段admA’上游调控序列的功能。以转座子中Kan抗性基因为标签,克隆了B8B菌株中Tn5插入位点左侧2 608 bp序列,经两次染色体步移得到Tn5插入位点右侧的2 354 bp序列。序列拼接后获得B8菌株拮抗相关序列4 611 bp的Bcontig。生物信息学分析显示该序列含有7个ORF,分别对应于3-磷酸甘油醛脱氢酶(GADPH)基因的部分编码区、2个LysR家族转录调控因子、弧菌假设蛋白VSWAT3-20465及成团泛菌(Pantoea agglomerans)andrimid生物合成基因簇的admA、admB和部分admC基因序列。B8B菌株Tn5插入分别位于同源于弧菌假设蛋白的anrPORF及‘admA’基因上游200 bp和894 bp处。通过同源重组技术,借助敲除质粒pMB-BG,获得拮抗活性消失的突变株B-1和B-3。结果表明B8B突变株中Tn5的插入可能影响了anrP蛋白的转录和表达,进而调控拮抗物质编码基因簇的生物合成。B8菌株中拮抗物质相关基因是类似于andrimid生物合成基因簇的基因家族,其上游调控区对该抗生素的生物合成具有重要的作用。     

苜蓿中华根瘤菌042BMnoeA基因的克隆、敲除与功能的初步分析

通过PCR扩增获得了042BM的noeA基因。该基因与苜蓿中华根瘤菌(Sinorhizobium meliloti)1021noeA的同源性为99%,而其NoeA与1021NoeA的相似性为97%。还发现其NoeA与中慢生根瘤菌（Mesorhizobium sp.）BNC1可能的SAM_依赖性的甲基转移酶相似性为32%,而其303～362氨基酸区域与大肠杆菌（Escherichia coli）的核糖体50S亚基的L11蛋白甲基转移酶(PrmA)的160～220氨基酸区域的相似性达到41%。通过插入卡那盒,敲除noeA,获得突变株042BMA_Km。与苜蓿中华根瘤菌042BM相比,敲除noeA的突变株在普通紫花、保定、宁夏、百发和傲汉苜蓿品种上的结瘤数、根瘤鲜重和植株地上部分的干重都有不同程度的增加,而在秘鲁苜蓿品种上的结瘤数和植株地上部分的干重明显下降,在皇后和美国杂花苜蓿品种上则没有明显的变化。     

中华根瘤菌自体诱导物合成酶基因的筛选及其在大肠杆菌中的表达

通过携带有mariner转座子的质粒pJZ290随机插入诱变中华根瘤菌(Sinorhizobium meliloti)建立突变子文库,并从中筛选到自体诱导物(autoinducer,AI)部分缺失突变株YW1。Arbitrary PCR扩增、DNA测序得到YW1基因组DNA中mariner转座子两端侧翼序列,经DNA序列拼接在GenBank上进行同源性分析后获得一个621bp的完整的开放阅读框(ORF),该ORF编码的酶具有206个氨基酸,与草木樨中华根瘤菌(Sinorhizobium medicae)WSM419的LuxI类自体诱导物合成酶(autoinducer synthase)TraI的同源性高达99%。因此,也将该基因命名为traⅠ。将该基因克隆到广宿主范围表达载体pYC12并在大肠杆菌Escherichia coli DH5α中成功表达,C18反相薄层层析(TLC)在阳性重组子培养上清中检测到四种自体诱导物分子,其中的两种正是AI缺失突变株YW1所缺失的AI,这些结果表明该traⅠ基因在苜蓿中华根瘤菌负责合成两种自体诱导物分子,为进一步研究其群体感应系统奠定了理论基础。     

苜蓿中华根瘤菌042BMnoeA基因的克隆、敲除与功能的初步分析

通过PCR扩增获得了 0 4 2BM的noeA基因。该基因与苜蓿中华根瘤菌 (Sinorhizobiummeliloti) 10 2 1noeA的同源性为 99% ,而其NoeA与 10 2 1NoeA的相似性为 97%。还发现其NoeA与中慢生根瘤菌 (Mesorhizobiumsp .)BNC1可能的SAM_依赖性的甲基转移酶相似性为 32 % ,而其 30 3～ 36 2氨基酸区域与大肠杆菌 (Escherichiacoli)的核糖体 5 0S亚基的L11蛋白甲基转移酶 (PrmA)的 16 0～ 2 2 0氨基酸区域的相似性达到 4 1%。通过插入卡那盒 ,敲除noeA ,获得突变株 0 4 2BMA_Km。与苜蓿中华根瘤菌 0 4 2BM相比 ,敲除noeA的突变株在普通紫花、保定、宁夏、百发和傲汉苜蓿品种上的结瘤数、根瘤鲜重和植株地上部分的干重都有不同程度的增加 ,而在秘鲁苜蓿品种上的结瘤数和植株地上部分的干重明显下降 ,在皇后和美国杂花苜蓿品种上则没有明显的变化。     

一株能在大豆上结瘤的苜蓿中华根瘤菌

苜蓿中华根瘤菌(Sinorhizobium meliloti)XJ96077分离自新疆的苜蓿根瘤中,其原宿主为紫花苜蓿(Medicago sativa)。交叉结瘤试验发现,它既可在苜蓿上又能在大豆上结瘤固氮。DNA(G C)mol％分析表明,XJ96077的DNA(G C)mol％为61．9％,与已报道的根瘤菌属的DNA(G C)mol％范围(59％-64％)相符。DNA同源性分析表明,XJ96077与苜蓿中华根瘤菌USDA1002^T和042BM的同源性分别达到93％和80％,说明XJ96077归属于苜蓿中华根瘤菌。应用绿色荧光蛋白基因标记XJ96077,得到重组菌株XJ96077(G)。将其接种普通紫花苜蓿,通过激光共聚焦荧光显微镜可以检测到标记基因的表达。接种北引1号大豆上,同样可以清楚地观察到标记基因在根瘤中的表达,从而确证了XJ96077能同时在苜蓿和大豆上结瘤。通过不同品种大豆的结瘤试验,发现XJ96077对大豆品种的结瘤能力不同。     

Pseudomonas mosselii E1铁载体合成相关基因cysI的克隆与功能初步分析

从棉花根际分离的铁载体产生菌E1,其16SrDNA与Pseudomonas mosselii ATCCBAA-99的同源性为100%。采用三亲本杂交方法将携带转座子Tn5-1063的质粒pRL1063a导入E1中进行转座子插入诱变。利用CAS法,从1000个突变株中,筛选到一株铁载体合成缺失突变株E1-185。利用TAIL-PCR方法,扩增位于Tn5-1063两端的侧翼序列。测序结果表明,转座子插入到E1的cysI基因内。该基因与Pseudomonas entomophila L48的cysI同源性为96%,其CysI氨基酸序列相似性为97%。该基因与半胱氨酸的合成密切相关,而在加有半胱氨酸的CAS平板上,突变株恢复了铁载体产生能力,证明cysI在E1铁载体合成过程中具有重要作用。据推测,cysI可能与铁载体合成途径中关键蛋白acyl-S-PCPs的形成有关。     

利用TAIL-PCR克隆耐盐基因及其分析

通过大量筛选得到一株高耐盐的豇豆根瘤菌WME7,最高可耐15g/L NaCl,利用Tn5-sacB转座子对该菌株进行随机插入突变,从突变子中筛选获得30个共生缺陷型突变株。利用TAIL-PCR(thermal asymmetric interlaced PCR)方法克隆了突变株Tn5-sacB侧翼序列,通过BLAST发现有1个突变株的插入失活基因与鼠伤寒沙门氏菌抗银的结合蛋白SilE有94%同源性,表明有关Na+离子的抗性基因可能与Ag+离子的抗性基因有某种关系。该基因在其它菌中也能抗其它金属离子(铜、锌、钴、铬)。     

The Sinorhizobium meliloti nutrient-deprivation-induced tyrosine degradation gene hmgA is controlled by a novel member of the arsR family of regulatory genes

The regulation of the nutrient-deprivation-induced Sinorhizobium meliloti homogentisate dioxygenase (hmgA) gene, involved in tyrosine degradation, was examined. hmgA expression was found to be independent of the canonical nitrogen regulation (ntr) system. To identify regulators of hmgA, secondary mutagenesis of an S. meliloti strain harboring a hmgA-luxAB reporter gene fusion (N4) was carried out using transposon Tn1721. Two independent Tn1721 insertions were found to be located in a positive regulatory gene (nitR), encoding a protein sharing amino acid sequence similarity with proteins of the ArsR family of regulators. NitR was found to be a regulator of S. meliloti hmgA expression under nitrogen deprivation conditions, suggesting the presence of a ntr-independent nitrogen deprivation regulatory system. nitR insertion mutations were shown not to affect bacterial growth, nodulation of Medicago sativa (alfalfa) plants, or symbiotic nitrogen fixation under the physiological conditions examined. Further analysis of the nitR locus revealed the presence of open reading frames encoding proteins sharing amino acid sequence similarities with an ATP-binding phosphonate transport protein (PhnN), as well as transmembrane efflux proteins.     

Conservation of structure and location of Rhizobium meliloti and Klebsiella pneumoniae nifB genes.

Using transposon Tn5-mediated mutagenesis, an essential Rhizobium meliloti nitrogen fixation (nif) gene was identified and located directly downstream of the regulatory gene nifA. Maxicell and DNA sequence analysis demonstrated that the new gene is transcribed in the same direction as nifA and codes for a 54-kilodalton protein. In Klebsiella pneumoniae, the nifBQ operon is located directly downstream of a gene which is structurally and functionally homologous to the R. meliloti nifA gene. The DNA sequences of the K. pneumoniae nifB and nifQ genes (which code for 51- and 20-kilodalton proteins, respectively) were determined. The DNA sequence of the newly identified R. meliloti gene was approximately 50% homologous to the K. pneumoniae nifB gene. R. meliloti does not contain a gene homologous to nifQ directly downstream of nifB. The R. meliloti nifB product shares approximately 40% amino acid homology with the K. pneumoniae nifB product, and 10 of the 12 cysteine residues of the R. meliloti nifB product are conserved with 10 of the 17 cysteine residues of the K. pneumoniae nifB product.     

Presence of chromosomal elements resembling the composite structure Tn3701 in streptococci.

Tn3701, carried by Streptococcus pyogenes A454, is the first chromosomal composite element to be described; it contains in its central region Tn3703, a transposon similar to Tn916. A comparison by DNA-DNA hybridization of Tn3701 with omega(cat-tet) and Tn3951, carried by Streptococcus pneumoniae BM6001 and by Streptococcus agalactiae B109, respectively, revealed that the two latter structures are also Tn3701-like composite elements. The DNAs of 27 other antibiotic-resistant group A, B, C, and G streptococci and of S. pneumoniae BM4200 showed sequence homologies to Tn3701 (14 strains, including BM4200), to the regions of Tn3701 outside of Tn3703 (5 strains), and to Tn916 alone (8 strains). The DNAs of five strains did not detectably hybridize with any probe. The tetM gene was identified in most chromosomal genetic elements coding for tetracycline-minocycline resistance. Since Tn3701-like elements are widely disseminated among antibiotic-resistant streptococci (47% of the 34 strains studied), we propose that Tn3701 be considered the prototype of chromosomal composite elements.     

Cloning and mutagenesis of the Rhizobium meliloti isocitrate dehydrogenase gene.

The gene encoding Rhizobium meliloti isocitrate dehydrogenase (ICD) was cloned by complementation of an Escherichia coli icd mutant with an R. meliloti genomic library constructed in pUC18. The complementing DNA was located on a 4.4-kb BamHI fragment. It encoded an ICD that had the same mobility as R. meliloti ICD in nondenaturing polyacrylamide gels. In Western immunoblot analysis, antibodies raised against this protein reacted with R. meliloti ICD but not with E. coli ICD. The complementing DNA fragment was mutated with transposon Tn5 and then exchanged for the wild-type allele by recombination by a novel method that employed the Bacillus subtilis levansucrase gene. No ICD activity was found in the two R. meliloti icd::Tn5 mutants isolated, and the mutants were also found to be glutamate auxotrophs. The mutants formed nodules, but they were completely ineffective. Faster-growing pseudorevertants were isolated from cultures of both R. meliloti icd::Tn5 mutants. In addition to lacking all ICD activity, the pseudorevertants also lacked citrate synthase activity. Nodule formation by these mutants was severely affected, and inoculated plants had only callus structures or small spherical structures.     

The disruption of a gene encoding a putative arylesterase impairs pyruvate dehydrogenase complex activity and nitrogen fixation in Sinorhizobium meliloti

Nitrogen-fixing Sinorhizobium meliloti cells depend upon dicarboxylic acids as carbon and energy sources. The metabolism of these intermediate compounds of the trichloroacetic acid cycle is dependent upon the availability of acetyl-coenzyme A (CoA). In bacteroids, the combined activities of malic enzymes and pyruvate dehydrogenase (PDH) have been proposed to be responsible for the anaplerotic synthesis of acetyl-CoA. We obtained a S. meliloti mutant strain, PD3, in which a Tn5 insertion led to a significant decrease in the overall PDH activity. The genetic characterization of this mutant revealed that the transposon is located at the 3' end of a gene (ada) encoding a putative arylesterase. The mutant PD3 is deficient in nitrogen fixation, which strengthens the physiological importance of PDH activity in the symbiosis of S. meliloti with alfalfa plants.     

TolC mutant of Sinorhizobium meliloti strain SKHM1-188 fails to establish effective symbiosis with alfalfa

The TolC mutant Tr63 of Sinorhizobium meliloti was generated by random Tn5 mutagenesis in the effective strain SKhM1-188. The mutant did not produce fluorescent halos in UV light on the LB medium containing calcofluor white, which suggests that modification occurred in the production of exopolysaccharide EPS1. Mutant Tr63 also manifested nonmucoidness both on minimal and low-phosphate MOPS media, and this was most likely connected with the absence of the second exopolysaccharide of S. meliloti (EPS2). The mutant was defective in symbiosis with alfalfa and formed on roots of host plants Medicago sativa and M. truncatula white round Fix- nodules or nodules of irregular shape. These nodules possessed the structure usually described for nodules of EPS1 mutants. According to the data of sequencing a DNA fragment of the mutant adjacent to the transposon, Tr63 contained a Tn5 insertion in gene SMc02082 located on the S. meliloti chromosome. This gene encodes the protein sharing homology with the TolC protein, a component of a type I secretion system responsible for the export of protein toxins and proteases in Gram-negative bacteria. The presence of proteins ExsH (endoglycanase of EPS1) and protein ExpE1 (essential for excretion of EPS2), which are known to be exported by the type I secretion system, was tested in cultural supernatants of mutant Tr63 and the parental strain by polyclonal antiserum analysis. It was ascertained that secretory proteins ExsH and ExpE1 are absent in the culture medium of mutant Tr63. The TolC protein of S. meliloti is assumed to be involved in the excretion of proteins ExsH and ExpE1.