Phylogeny of γ-proteobacteria inferred from comparisons of 3’ end 16S rRNA gene and 5’ end 16S-23S ITS nucleotide sequences

The phylogeny of γ-proteobacteria was inferred from nucleotide sequence comparisons of a short 232 nucleotide sequence marker. A total of 64 γ-proteobacterial strains from 13 Orders, 22 families, 40 genera and 59 species were analyzed. The short 232 nucleotide sequence marker used here was a combination of a 157 nucleotide sequence at the 3’ end of the 16S rRNA gene and a 75 nucleotide sequence at the 5’ end of the 16S-23S Internal Transcribed Spacer (ITS) sequence. Comparative analyses of the 3’ end of the 16S rRNA gene nucleotide sequence showed that the last 157 bp were conserved among strains from same species and less conserved in more distantly related species. This 157 bp sequence was selected as the first part in the construction of our nucleotide sequence marker. A bootstrapped neighbor-joining tree based on the alignment of this 157 bp was constructed. This 157 bp could distinguish γ-proteobacterial species from different genera from same family. Closely related species could not be distinguished. Next, an alignment of the 16S-23S ITS nucleotide sequences of alleles from same bacterial strain was performed. The first 75 bp at the 5’ end of the 16S-23S ITS was highly conserved at the intra-strain level. It was selected as the second part in the construction of our nucleotide sequence marker. Finally, a bootstrapped neighbor-joining tree based on the alignment of this 232 bp sequence was constructed. Based on the topology of the neighbour-joining tree, four major Groups, Group I to IV, were revealed with several sub-groups and clusters. Our results, based on the 232 bp sequence were, in general, in agreement with the phylogeny of γ-proteobacteria based on the 16S rRNA gene. The use of this 232 bp sequence as a phylogenetic marker presents several advantages over the use of the entire 16S rRNA gene or the generation of extensive phenotypic and genotypic data in phylogenetic analyses. First, this marker is not allele-dependant. Second, this 232 bp marker contains 157 bp from the 3’ end of the 16S rRNA gene and 75 bp from the 5’ end of the 16S-23S ITS. The 157 bp allows discrimination among distantly related species. Owing to its higher rate of nucleotide substitutions, the 75 bp adds discriminating power among closely related species from same genus and closely related genera from same family. Because of its higher percentage of nucleotide sequence divergence than the 16S rRNA gene, the 232 bp marker can better discriminate among closely related γ-proteobacterial species. Third, the method is simple, rapid, suited to large screening programs and easily accessible to most laboratories. Fourth, this marker can also reveal γ-proteobacterial species which may appear misassigned and for which additional characterization appear warranted.

Phylogeny of the Order Bacillales inferred from 3’16S rDNA and 5’16S-23S ITS nucleotide sequences

A short 220 bp sequence was used to study the taxonomic organization of the bacterial Order Bacillales. The nucleotide sequences of the 3’ end of the 16S rDNA and the 16S-23S Internal transcribed spacer (ITS) were determined for 32 Bacillales species and strains. The data for 40 additional Bacillales species and strains were retrieved directly from Genbank. Together, these 72 Bacillales species and strains encompassed eight families and 21 genera. The 220 bp se- quence used here covers a conserved 150 bp sequence located at the 3’ end of the 16S rDNA and a conserved 70 bp sequence located at the 5’ end of the 16S-23S ITS. A neighbor-joining phylogenetic tree was inferred from comparative analyses of all 72 nucleotide sequences. Eight major Groups were revealed. Each Group was sub-divided into sub-groups and branches. In general, the neighbor-joining tree presented here is in agreement with the currently accepted phylogeny of the Order Bacillales based on phenotypic and genotypic data. The use of this 220 bp sequence for phylogenetic analyses presents several advantages over the use of the entire 16S rRNA genes or the generation of extensive phenotypic and genotypic data. This 220 bp sequence contains 150 bp at the 3’ end of the 16S rDNA which allows discrimination among distantly related species and 70 bp at the 5’ end of the 16S-23S ITS which, owing to its higher percentage of nucleotide sequence divergence, adds discriminating power among closely related species from same genus and closely related genera from same family. The method is simple, rapid, suited to large screening programs and easily accessible to most laboratories.

Assessment of a short phylogenetic marker based on comparisons of 3’end 16S rDNA and 5’end 16S-23S ITS nucleotide sequences of the Bacillus cereus group

A short phylogenetic marker previously used in the reconstruction of the Order Bacillales and the genus Bacillus was assessed here at a lower taxa level: species in the Bacillus cereus group: B. anthracis, B. cereus, B. thuringiensis and B. weihenstephanensis. This maker is 220 bp in length. It is a combination of 150 bp at the 3’ end of the 16S rDNA and 70 bp at the 5’ end of the 16S-23S ITS sequence. Three additional Bacillus species, B. halodurans, B. licheniformis and B. subtilis, and Clostridium tetani were included for comparison purposes. A total of eight bacterial species and 12 strains were analyzed. A boot- strapped neighbor-joining tree was inferred from comparative analyses of all allelic sequences of the bacterial species and strains under study. Based on its topology, four major Groups were revealed at the 90% nucleotide sequence identities, Group I to IV. Group I contains all al-leles of the Bacillus cereus group. Group II con-tains all alleles of B. halodurans. Group III con-tains all alleles of B. licheniformis and B. subtilis. Group IV contains all alleles of Clostridium tetani. The 220 bp phylogenetic marker used here could resolve different species from different genera. At the genus level, distant species could be dis-tinguished. Very closely-related species, however, were undistinguishable. Species in the B. cereus group, most notably B. cereus, B. anth- racis and B. thuringiensis, could not be distin- guished. After successfully inferring the phylo- genies of the Order Bacillales and the genus Bacillus, we have met the resolving limit of this short phy-logenetic marker: B. cereus, B. anthracis and B. thuringiensis.

Length polymorphisms for intergenic spacer regions of 16S-23S rDNA in members of the new hydrogen-producing bacteria

A method based on PCR amplification of the 16S rRNA gene (rDNA)-23S rDNA intergenic spacer regions (ISR) was developed for the identification of species within the novel group hydrogen-producing anaerobes. The sizes of the PCR products varied from 1264 to 398 bp. Strain of isolate Rennanqilyf 3 was characterized as having products of 1262,398,638,437 and 436 bp. The isolate Rennanqilyf 1 had product of 1264 bp. The isolate Rennanqilyf 13 had products of 1261,579 and 485 bp. Of the 3 species of the novel group hydrogen-producing anaerobes examined, no one was indistinguishable. Two environmental isolates were identified as hydrogen-producing bacteria, which were new species in present taxon. Rennanqilyf 3 could not be associated with any Clostridium sp. studied. Rennanqilyf 1 could be classified into Clostridium genus. The combination between 16S rDNA equencing and length polymorphisms of IRS in 16S-23S rDNA is a better method for determining species of the hydrogen-producing bacteria.

Assessment of a short phylogenetic marker based on comparisons of 3'end 16S rDNA and 5'end 16S-23S ITS nucleotide sequences on the genus Xanthomonas

A short phylogenetic marker previously used in the reconstruction of the Class γ-proteobacteria was assessed here at a lower taxa level, species in the genus Xanthomonas. This maker is 224 nucleotides in length. It is a combination of a 157 nucleotide sequence at the 3' end of the 16S rRNA gene and a 67 nucleotide sequence at the 5' end of the 16S-23S ITS sequence. A total of 23 Xanthomonas species were analyzed. Species from the phylogenetically related genera Xylella and Stenotrophomonas were included for com- parison purposes. A bootstrapped neighbor- joining phylogenetic tree was inferred from comparative analyses of the 224 bp nucleotide sequence of all 30 bacterial strains under study. Four major Groups were revealed based on the topology of the neighbor-joining tree, Group I to IV. Group I and II contained the genera Steno-trophomonas and Xylella, respectively. Group III included five Xanthomonas species: X. theicola, X. sacchari, X. albineans, X. transluscens and X. hyacinthi. This group of Xanthomonas species is often referred to as the hyacinthi group. Group IV contained the other 18 Xanthomonas species. The overall topology of the neighbor-joining tree was in agreement with currently accepted phylogenetic. The short phylogenetic marker used here could resolve species from three dif-ferent Xanthomonadacea genera: Stenotro-phomonas, Xylella and Xanthomonas. At the level of the Xanthomonas genus, distant spe-cies could be distinguished, and whereas some closely-related species could be distinguished, others were undistinguishable. Pathovars could not be distinguished. We have met the resolving limit of this marker: pathovars and very closely related species from same genus.

基于16SrRNA和16S-23SrRNA基因间隔区序列探讨陆生和水生螺原体菌株的系统发生关系

采集江苏省养殖池塘内发病的中华绒螯蟹、克氏原螯虾和南美白对虾,利用已有螺原体16S rRNA和23S rRNA基因序列保守引物扩增并测序16S rRNA和16S-23S rRNA基因间隔区序列(ISRs).基于已获得的序列和GenBank中下载的螺原体序列分别进行同源性比对,比对的结果分别利用PAUP软件和MrBayes软件提供的最大似然法和贝叶斯法进行系统发生关系分析.分析结果是:所有淡水甲壳动物螺原体菌株Spiroplasma erio-cheiris(中华绒螯蟹)、Spiroplasmasp.CRAYFISH(克氏原螯虾)、Spiroplasmasp.SHRIMP(南美白对虾)严格聚为一支,并且与陆生兔扁虱螺原体(非凡螺原体)Spiroplasma mirum关系最近,而与中国报道的陆生植物螺原体菌株Spiroplasmasp.CR-1(油菜)、Spiroplasmasp.CNR-1(油菜)、Spiroplasmasp.CNR-2(油菜)、Spiroplasmasp.CAN-1(杜鹃花)、Spiroplasmasp.CRW-1(红花酢浆草)及昆虫螺原体菌株Spiroplasmasp.CH-1(蜜蜂)、Spiroplas-masp.M10(蜜蜂)关系较远,此外,3个淡水甲壳动物螺原体菌株与现今唯一报道的海水南美白对虾螺原体Spi-roplasma penaei系统发生关系也很远.因此,在螺原体属中,我国发现的淡水甲壳动物螺原体近缘种是非凡螺原体而不是我国陆生昆虫或植物螺原体及美洲的南美白对虾螺原体.

利用16S-23S rDNA RFLP及16S rRNA基因序列分析方法对湖北省饭豆(Vigna umbellata L.)根瘤菌系统发育的研究

采用16S-23S rDNA间隔区段(IGS)PCR-RFLP与16S rRNA基因部分序列分析的方法对饭豆根瘤菌进行了遗传多样性及系统发育分析.由16S-23S rDNA IGS PCR-RFLP分析可知,所有菌株在52%的相似性水平上聚在一起,形成了慢生型菌群与快生型菌群这两大菌群.群Ⅰ中,在79%相似性的水平上分为ⅠA与ⅠB两个分支.群Ⅱ中,在62%相似性的水平上分为ⅡA与ⅡB两个分支,分支ⅡA在72%的相似性水平上进一步分为ⅡA1、ⅡA2和ⅡA3三簇;分支ⅡB中的饭豆根瘤菌与标准菌株USDA205T聚在一起,表现的差异并不大.由16SrRNA基因部分序列分析结果可知,供试的4个代表菌株分别位于不同的系统发育分支中.CYR4243与Sinorhizobium fredii的模式菌株USDA205T的序列相似性达到了99.87%.HCY1101与Rhizobium leguminosarum中的三叶草生物型(bv.trifolii)和豌豆生物型(bv.viceae)这两个生物型的参比菌株亲缘关系最近,序列相似性为100%.HCY5202与R.galegae亲缘关系最近,序列相似性为99.86%.CYY3302与Bradyrhizobium elkanii的参比菌株USDA86有最近的亲缘关系,序列相似性近似于100%.

山羊奇异变形杆菌分离鉴定及其16S-23SrRNAISR序列RFLP分析

2012年初,山东菏泽某羊场的羊群发病,从发病羊器官分离到2株病原细菌。对病原细菌进行鉴定,并对其与已知同种异源菌株相似性差异进行分析。从患病山羊内脏器官分离细菌,经形态特征、培养特性、生化试验、血清学试验及致病性试验进行鉴定;再通过设计通用引物扩增16S-23SrRNA ISR(intergenic spacer region)序列,将PCR产物经HinfⅠ单酶切获得3条可视条带,同时对扩增条带中的主带测序并进行系统发育分析。结果表明,分离菌株为奇异变形杆菌;分离菌株同本实验室保存的兔源与鸡源奇异变形杆菌PCR-RFLP结果一致;分离菌株PCR产物同GenBank收录的HI4320株奇异变形杆菌及本实验室保存的兔源与鸡源奇异变形杆菌进行序列比较,分离羊源菌株与兔源菌株相似性为94.8%、与鸡源菌株相似性为96.0%～98.2%,与人源HI4320株相似性为96.9%。研究证实发病羊致病病原为奇异变形杆菌,其与鸡源、兔源和人源奇异变形杆菌的亲缘关系较近。

2株创伤弧菌的16S-23SrDNA间区的克隆、测序及分析(英文)

根据细菌的16S rDNA 3′端和23S rDNA 5′端的高度保守区设计引物,PCR扩增了2株创伤弧菌(Vibrio vulnificus)的16S-23S rDNA 间区(Intergenic spacer,IGS),克隆到pGEM-T载体上,测序。用BLAST和 DNAstar软件对16S-23S rDNA 间区序列及其内的 tRNA 基因进行比较分析。结果表明,2 株创伤弧菌共测出 9 条 16S-23S rDNA 间区序列, 其中ZSU006 测出 5 条, 间区类型分别为:IGSGLAV、IGSGLV、IGSIA 、IGSA和 IGSG。其中 IGSGLAV最大,包含 tRNAGlu、tRNALys、tRNAAla 和 tRNAVal基因;IGSGLV包含 tRNAGlu、tRNALys和 tRNAVal基因; IGSIA,则包含 tRNAIle和 tRNAAla基因;IGSG仅包含tRNAGlu基因;而IGSA仅包含tRNA Ala基因。菌株CG021测出的16S-23S rDNA IGS序列有4条,除缺少IGSA外,其余的IGS类型均与ZSU006的相同。与GenBank内的创伤弧菌ATCC27562 的IGS序列比较,发现创伤弧菌所有类型的IGS的tRNA基因两端的非编码区具有较高的种内同源性。16S-23S rDNA 间区结构的差异为建立一种新的创伤弧菌检测方法奠定了基础。

3株杂色鲍致病菌——副溶血弧菌的16S-23S rDNA间区序列的分析

以细菌的 1 6SrDNA 3′端和 2 3SrDNA 5′端的高度保守区为引物 ,扩增了 3株杂色鲍致病菌—副溶血弧菌(Vibrioparahaemolyticus)的 1 6S 2 3SrDNA间区 ,克隆到pGEM T载体上 ,测序。用BLAST和DNAstar软件对 1 6S 2 3SrDNA间区序列及其内的tRNA基因进行比较分析。结果表明副溶血弧菌ZSU0 0 8和ZSU0 0 9测出的 1 6S 2 3SrDNA间区均有 6条 ,间区类型也相同 ,分别为IGSGLAV 、IGSGLV、IGSAG、IGSIA、IGSG 和IGS0 。其中IGSGLAV最大 ,包含tRNAGlu、tR NALys、tRNAAla和tRNAVal基因 ;IGSGLV包含tRNAGlu、tRNALys和tRNAVal基因 ;IGSAG包含tRNAAla和tRNAGlu基因 ;IGSIA,则为tRNAIle和tRNAAla基因 ;IGSG 仅包含tRNAGlu基因 ;而IGS0 最小 ,未包含任何tRNA。菌株ZSU0 1 0测出的 1 6S 2 3SrDNAIGS序列有 5条 ,除缺少IGSAG 外 ,其余的IGS类型均与ZSU0 0 8和ZSU0 0 9相同。与GenBank内的副溶血弧菌IGS序列比较 ,发现副溶血弧菌所有类型的IGS的tRNA基因两端的非编码区具有较高的种内同源性。 1 6S 2 3SrDNA间区结构的差异为建立一种新的副溶血弧菌检测方法奠定了基础。

柑橘黄龙病菌亚洲种16S rDNA和16S-23S rDNA间隔区的PCR-RFLP及序列分析

为明确柑橘黄龙病菌的遗传多样性,PCR扩增了6个不同地区黄龙病菌的16SrDNA和16S-23S rDNA间隔区(intergenic spacer regions,ISR),分别通过4种内切酶对其进行了限制性片段长度多态性分析,发现不同分离物的16S rDNA和16S-23S rDNA间隔区各酶切产物的电泳谱带完全一致,未表现多态性。对16S-23SrDNA ISR进行了克隆和测序,经DNAman和NCBI Blast比对分析发现,6个分离物16S-23SrDNAISR序列之间不存在碱基差异,与数据库中柑橘黄龙病菌亚洲种(Candidatus Liberibacter asiaticus)同源性高达99.0%～100%。系统发育分析显示所有的Ca.L.asiaticus归为一个类群,而后与Ca.L.africanus、Ca.L.americanus和Ca.L.psyllaurous组成韧皮部杆菌属(Candidatus Liberibacter)一个大的类群。结果表明,同一种柑橘黄龙病菌不同分离物16S rDNA和16S-23S rDNAISR无分子变异或变异较小,不存在遗传多样性。

16S-23S rDNA间隔区在奶牛乳房炎诊断中的应用

以 16 S- 2 3S r DNA间隔区为扩增靶序列的 PCR技术是近年来发展的细菌分类和鉴定新方法 ,具有快速、敏感和特异性高的优点。作者综述了细菌 16 S- 2 3S r DNA间隔区序列的特性及其在奶牛乳房炎病原诊断中的应用等研究进展。

一株嗜水气单胞菌Aeromonas hydrophila的16S-23S rDNA间区序列分析及应用

根据细菌的16SrDNA3′端和23SrDNA5′端的高度保守区设计引物,扩增了一株中华鳖Trionyxsinensis"红板病"病原菌嗜水气单胞菌的16S-23SrDNA间区,克隆到pGEM＿T载体上,测序。用BLAST和DNAstar软件对16S-23SrDNA间区序列以及其内tRNA基因与已发表的嗜水气单胞菌和近缘种的IGSG序列进行比较分析,设计出对嗜水气单胞菌特异的PCR引物,建立了检测嗜水气单胞菌的PCR方法,进行了特异性、灵敏性检测,并用此方法检测了不同的水样。

分支杆菌临床分离株的16S-23S rRNA基因转录间隔区的序列分析

目的 建立鉴定分支杆菌分离株的 16S - 2 3SrDNA转录间隔区 (internaltranscribedspacer ,ITS)序列分析的方法 ,用该方法对临床分离株进行鉴定。方法 对从重庆某医院分离的 2 9株分支杆菌菌株分别进行了PCR扩增 ,得到它们的16S - 2 3SrDNAITS片段 ,并测定所得到片段的DNA序列。用DNA分析软件将所获得的序列与GenBank的分支杆菌序列相比较 ,计算种间相似性 ,并用序列构建分支杆菌菌株的系统发育树 ,对分离株进行鉴定。结果 在ITS序列分析中 ,有 10株的序列分别与结核分支杆菌复合群 (Mycobacteriumtuberculosiscomplex ,MTC)、戈登分支杆菌 ,脓肿分支杆菌的序列完全一致。依据完全一致的序列可以准确鉴定这些临床分离株为相应的种 ;4株 16SrDNA序列分析不能准确鉴定的分离株中其中 3株(M 4、M 5、M 12 )鉴定为戈登分支杆菌 ,1株 (M 2 3)鉴定为脓肿分支杆菌。部分分离株的的ITS序列在GenBank序列检索中无完全一致的匹配序列 ,这些不同的序列之间的相似程度为 2 7.1%～ 99.2 %。用临床分离株的ITS序列与其最相似的已知分支杆菌的ITS序列构建的系统发育树 ,菌株分群与 16SrDNA序列构建的系统发育树的分群基本一致。结论 分支杆菌的16S - 2 3SrDNAITS序列比 16SrDNA序列有更大的多样性 。

12种寄主来源的茄科雷尔氏菌16S-23S rDNA间隔区序列比较

应用PCR方法，获得了分离自广东番茄、茄子、辣椒、烟草、空心茱、沙姜、姜、马铃薯、花生、菊花、桑树和藿香等12种作物21个茄科雷尔氏菌菌株的16S-23SrDNA间隔区序列（ITS）。序列分析结果表明，除HZ-1菌株外，其余20个茄科雷尔氏菌菌株ITS序列长均为503bp，序列间相似性99．2％～100％，序列间差异仅1～4bp；而HZ-1菌株的ITS序列长为498bp，与其他菌株的ITS序列相似性为95．4％～95．6％。这些结果说明，这21株来源于12种不同寄主的茄科雷尔氏菌菌株的16S-23SrDNAITS序列比较保守。系统进化分析显示，仅菌株HZ-1聚类于茄科雷尔氏菌区组2中，其余20个菌株均聚类于茄科雷尔氏菌区组1中。

Q热立克次体中国株的16S-23SrDNA间区序列分析

用PCR扩增了 7株中国分离株 (七医、新桥、雅安、李、YS 8、YS 9和YH 1 1 )和2株国际参考株 (Henzerling和Grita)的 1 6S 2 3SrDNA基因间区 ,对扩增产物进行了序列分析。结果发现它们仅在少数几个碱基位上有不同。在第 6 0位上 3个云南分离株YS 8、YS 9、YH 1 1和Grita株与Stein等报道的序列 (包括九里、其它国际参考株和一些法国临床分离株 )的碱基序列一致 ,为“C” ;其他 5株为“A” ,此位点的不同可能与适应不同的地理环境相关。另外 ,YS 9株在第 8和 2 0 8位、新桥株在第 43 2位也分别出现缺失 ,可能与适应不同的动物宿主或在实验室传代情况不同有关。

基于16S-23S rRNA ITS AFLP对米酒发酵过程中原核微生物的演替分析

利用16S-23S rRNA ITS AFLP指纹图谱技术监控四川传统米酒发酵过程中原核微生物的演替,并结合米酒发酵过程中理化因子的动态变化对其演替过程进行了分析。研究结果表明,米酒发酵过程中,随着酒曲的接入,米酒醅中原核微生物伴随米酒理化因子的动态变化而发生群落演替。在适应期和发酵期,米酒醅中的原核微生物群落分别聚成群I和群II,二者相关系数为0.49。群II中,在相关系数0.638水平上又分为IIA和IIB两个分支。分支IIA又进一步分为IIA1和IIA2两簇,相关系数为0.73。簇IIA2中主要发生的是发酵旺盛期微生物的演替;簇IIA1中I,IA1-1和IIA1-2亚簇分别表示发酵前期、发酵后期米酒醅中的原核微生物群落演替,二者聚集于相关系数0.80。其中I,IA1-2中,发酵52 h和55 h的米酒醅中原核微生物群落几乎相似,二者群落相关系数为1.0。

中国布鲁氏菌16s-23s rRNA间隔区多态性研究

目的利用16 s-23 s rRNA间隔区(ITS)的多态性,对中国布鲁氏菌种间或种内生物型进行鉴别,评价ITS作为基因标识物的意义,寻找适合布鲁氏菌分型研究的基因标识物。方法应用聚合酶链反应-单链构象多态性(PCR-SSCP)分析技术,对中国120株布鲁氏菌的ITS进行分析和筛选,测序结果与Genbank中的布鲁氏菌ITS序列进行比较分析。结果对16 s-23 s rRNA间隔区的SSCP结果分析,得到4种不同的带型(ⅠI、I、Ⅲ、Ⅳ),测序序列有3个位点的差异,达到99.87%的一致性。结论中国布鲁氏菌的ITS序列高度保守,具有一定探讨其作为布鲁氏菌属种内分型的基因标识的价值。

以16S-23S rDNA间区序列为目的基因设计PCR引物鉴定多杀巴斯德氏菌(英文)

多杀巴斯德氏菌是养殖动物（鸡，猪，牛等）的重要致病菌．本研究以16S-23SrDNA间区序列为目的基因设计PCR引物鉴定多杀巴斯德氏菌．通过对多杀巴斯德氏菌ITS—IA（含有tDNA-Ile和tDNA-AIa的16S-23SrDNA间区序列）的测序和与GenBank中序列的BLAST，设计筛选了一对特异引物PS—F／PS—R．对引物的特异性和有效性，用PCR方法进行了验证．结果表明：所有的多杀巴斯德氏菌标准菌株和分离菌株都能被检出，而全部39株非多杀巴斯德氏菌都没有扩增出特异性条带．其检测灵敏度能达到10^2CFU／mL．研究结果表明，发展了的PCR鉴定方法是省时的和可靠的，整个过程只需要20h，而传统的鉴定方法需要至少5d的时间．

基于16S-23S rDNA间隔区序列(ITS)、REP序列的基因指纹图谱及UPGMA聚类法的拟诺卡菌属分类方法

拟诺卡菌属(Nocardiopsis)是拟诺卡菌科(Nocardiopsaceae)的唯一属.该属内进行物种鉴别时通常是在多相分类方法基础上,以全基因组杂交同源性在70%以下的为不同物种,此为国际公认的定种标准;但在进行大量菌株的比对时操作比较复杂,于是多种基于DNA的基因图谱技术发展起来.本实验利用适宜引物,对拟诺卡菌属15株基准株基因组DNA的16S-23S rDNA间隔区序列(ITS)和REP序列进行了扩增,获得了两种基因指纹图谱,同时根据UPGMA聚类法构建了相应的进化距离树图.结果表明,对于拟诺卡菌属中不同物种的区分,两种基因图谱技术的分辨力相当,均可以较好的呈现物种间差异,可以作为拟诺卡菌属菌株多相分类的组成部分,应用于物种水平的分类与鉴定.