粪便样品中大肠杆菌多态性分子研究

以粪便样品中分离到的大肠杆菌为研究对象,比较了3种不同方法在分离鉴定大肠杆菌过程中的应用。首先,通过传统方法从粪便样品中分离,筛选和确定了一批大肠杆菌疑似菌株,再用现代分子生物学方法对待鉴定的大肠杆菌疑似菌株,已知大肠杆菌MG1655以及几种其它细菌进行ARDRA(AmplifiedRibosomalDNARestrictionAnalysis)分析,最后利用ERIC-PCR技术在个体水平上分析菌株的多样性。结果表明,所有由传统方法确定的大肠杆菌疑似菌株和MG1655都属于同一ARDRA型,并与其它细菌的ARDRA条码型不同。这说明ARDRA分析得到的结果与传统分析方法的结果吻合,利用ARDRA分析可以区分大肠杆菌和其它肠道细菌。但是在本实验中ARDRA分析不能反映大肠杆菌中不同菌株之间的多样性,ERIC-PCR则可以区分它们。     

用指纹图谱评价环境样本DNA的提取效果

研究了DNA指纹图谱技术在评价环境样本DNA提取效果方面的应用。采用 3种DNA提取方法提取垃圾渗滤水和活性污泥中的微生物DNA ,并用ARDRA和RISA图谱加以评价。实验结果表明 ,RISA图谱分析法可以作为评估DNA提取效果的有效手段。     

RAPD技术在微生物生物多样鉴定中的应用

RAPD（随机放大多态性DNA）是1种新的DNA分子标记技术。与RFLp、AFLP及ARDRA相比,RAPD具有可在一次试验中同时观察到大量的DNA多态性片段,方法更具简单、敏感、花费少等优点。阐述了RAPD的原理方法,及目前在微生物分类鉴定研究中的应用,并分析了RAPD技术在共生固氮放线菌Frankia分类鉴定及系统发育研究中的应用前景。     

ARDRA联合RAPD对不动杆菌基因型鉴定的研究

收集多重耐药的不动杆菌10株,以标准参照株作对照,采用扩增核糖体DNA限制性酶切(ARDRA)DNA指纹技术联合随机扩增多态性DNA(RAPD)技术对其基因亚型进行分析;以非加权组间平均法(UPG-MA)进行聚类分析。该法可以有效地鉴定不动杆菌基因亚型;并从10株不动杆菌中鉴定出1株琼氏不动杆菌及9株鲍曼不动杆菌。ARDRA联合RAPD基因指纹分型技术有良好的互补性,可准确鉴定不动杆菌基因型。     

PCR技术在植物病原细菌研究中的应用*

利用rep-PCR、AFLP和RAPD等多种基因组指纹分析方法,指纹图谱结合计算机辅助分析,用于研究植物病原细菌群体遗传多样性;遗传多样性图谱有助于理解病原细菌的分类、群体结构,还有利于设计特异、灵敏、快速检测策略用于植物病原检测和病害诊断。已有许多以PCR为基础的检测技术如rDNA-PCR、ITS-PCR、ARDRA等,有很多特异性引物及检测程序,已在植物病原检测和病害诊断中广泛应用。PCR技术的应用和计算机的辅助分析,为植物病原细菌群体动态和生态学知识提供了基本框架,使植物病理学进入一个新时代。     

DNA分子标记技术在乳酸菌多态性研究中的应用

本文概述了常用于乳酸菌分离鉴定及多态性研究中的基于rDNA序列的分子标记技术和几种DNA指纹图谱技术(RAPD,ARDRA,AFLP,REP/ERIC-PCR),并对这些技术的原理、方法及其近几年在乳酸菌研究中的进展进行了介绍.同时本文还比较了各种方法的优缺点,不同的研究方法,其分辨率和检测限不同,必须根据研究目的,选择合适的分析方法.     

用于微生物多样性分析的棉田土壤总DNA的提取

目的：探讨适用于微生物多样性研究的棉田土壤微生物总DNA提取方法。方法：采用4种方法提取不同连作和轮作处理的棉田土壤微生物总DNA,比较其纯度、产率、片段大小,并应用ARDRA技术验证其质量。结果：其中3种方法均可获得23kb的DNA片段,但不同方法提取的DNA的产率和纯度上有明显差异。改良CTAB-SDS法提取的DNA完整性好,得率为24.20μg.g-1干土,纯化后A260/A280和A260/A230为分别为1.80和1.70,纯化回收率可达70.1%,完全适用于后续的PCR分析。结论：采用该法提取棉田土壤总DNA简便而高效。对该法提取获得的棉田土壤微生物总DNA进行ARDRA和DGGE分析,所得图谱能较全面地反映不同处理间微生物多样性及群落结构的差别,为不同栽培体系下棉田土壤微生物的分子生态学研究提供了基础。     

PCR技术在植物病原细菌研究中的应用

利用rep-PCR,AFLP和RAPD等多种基因组指纹分析方法,指纹图谱结合计算机辅助分析,用于研究植物病原细菌群体遗传多样性;遗传多样性图谱有助于理解病原细菌的分类,群体结构。还有利于设计特异,灵敏,快速检测策略用于植物病原检测和病害诊断。已有许多以PCR为基础的检测技术如rDNA-PCR,ITS-PCR,ARDRA等,有很多特异性引物及检测程序,已在植物病原检测和病害诊断中广泛应用,PCR技术的应用和计算机的辅助分析。为植物病原细菌群体动态和生态学知识提供了基本框架,使植物病理学进入一个新时代。     

DNA指纹图谱技术在土壤微生物多样性研究中的应用

土壤中的微生物多样性是十分丰富的,传统培养方法对土壤微生物多样性的研究有很大局限性。近年来,各种基于16S rDNA基因的指纹图谱分析技术取得了长足的进步,并广泛应用于土壤微生物多样性的研究。这些技术主要有变性梯度凝胶电泳(DGGE)/温度梯度凝胶电泳(TGGE)、单链构象多态性(SSCP)、随机引物扩增多态性DNA(RAPD)、限制性片段长度多态性(RFLP)和扩增核糖体DNA限制性分析(ARDRA)等。对这些技术近年来在土壤微生物多样性研究领域的应用予以简短综述,并初步探讨未来几年土壤微生物分子生态学发展的方向。     

蕙兰病株根部内生细菌种群变化

为了研究褐斑病与蕙兰根部内生细菌群落结构和多样性的关联,从野生蕙兰健株和褐斑病株根部分离出内生细菌112株,采用核糖体DNA扩增片段限制性酶切分析(ARDRA),研究了健株和病株内生细菌多样性与群落结构。将内生细菌纯培养物扩增近全长的16S rDNA,并用ARDRA (Amplified Ribosomal DNA Restriction Analysis) 对所分离的菌株进行分型,根据酶切图谱的差异,将健株中的内生细菌分成8个ARDRA型,病株分成13个ARDRA型。并选取代表性菌株进行16S rDNA序列测定。结果表明,健株分离出内生细菌6个属,优势菌群为Bacillus;病株分离出11个属,优势菌群为 Mitsuaria和Flavobacterium。通过回接兰花植物和初步拮抗实验发现,从病株分离出的H5号菌株 (Flavobacterium resistens)使兰花产生病症,而健株中的B02 (Bacillus cereus) 和B22号菌株 (Burkholderia stabilis) 对菌株H5有拮抗作用。     

Identification and differentiation of Lactobacillus, Streptococcus and Bifidobacterium species in fermented milk products with bifidobacteria

The aim of this study was to identify and discriminate bacteria contained in commercial fermented milks with bifidobacteria by the use of amplified ribosomal DNA restriction analysis (ARDRA) and randomly amplified polymorphic DNA (RAPD) techniques. ARDRA of the 16S rDNA gene and RAPD were performed on 13 Lactobacillus strains, 13 Streptococcus and 13 Bifidobacterium strains isolated from commercial fermented milk. Lactobacillus delbrueckii, Streptococcus thermophilus and Bifidobacterium animalis isolates were identified by genus- and species-PCR and also, they were differentiated at genus and species level by ARDRA using MwoI restriction enzyme. The ARDRA technique allowed for the discrimination among these three related genus with the use of only one restriction enzyme, since distinctive profiles were obtained for each genus. Therefore it can be a simple, rapid and useful method for routine identification. Also, RAPD technique allowed the discrimination of all bacteria contained in dairy products, at genus- and strain-level by the performance of one PCR reaction.     

Molecular differentiation of Bifidobacterium species with amplified ribosomal DNA restriction analysis and alignment of short regions of the ldh gene

The differentiation of Bifidobacterium species was performed with specific primers using the PCR technique, the amplified ribosomal DNA restriction analysis (ARDRA) technique based on reports on the sequence of the 16S rRNA gene and speciation based on a short region of the ldh gene. Four specific primer sets were developed for each of the Bifidobacterium species, B. animalis, B. infantis and B. longum. The use of the ARDRA method made it possible to discriminate between B. infantis, B. longum and B. animalis with the combination of BamHI, TaqI and Sau3AI restriction enzymes. The ldh gene sequences of 309-312 bp were determined for 19 Bifidobacterium strains. Alignment of these short regions of the ldh gene confirmed that it is possible to distinguish between B. longum and B. infantis but not between B. lactis and B. animalis.     

Combination of ARDRA and RAPD genotyping techniques in identification of Acinetobacter spp. genomic species

A total of 10 non-repetitive multi-drug-resist-ant Acinetobacter strains were collected. With reference to A. calcoaceticus (ATCC23055), A. baumannii (ATCC19606), A. lwoffii (ATCC17986), and A. junii (NCTC5866), DNA fingerprint technique, amplified ribo-somal DNA restriction analysis (ARDRA), and random amplified polymorphism DNA (RAPD) were carried out to identify the genomic species of Acinetobacter spp. The distances between them were calculated by the unweighted pair group method with arithmetic (UPGMA). Genotypes ofAcinetobacter spp. were effectively classified and an A. junii together with nine A. baumannii isolates was genomically identified. The combination of ARDRA and RAPD DNA-fingerprint technique shows high com-plementarity, and could be a useful tool in Acinetobacter genomic species identification.     

Rapid identification of marine bioluminescent bacteria by amplified 16S ribosomal RNA gene restriction analysis

To rapidly identify natural isolates of marine bioluminescent bacteria, we developed amplified ribosomal DNA restriction analysis (ARDRA) methods. ARDRA, which is based on the restriction patterns of 16S rRNA gene digested with five enzymes (EcoRI, DdeI, HhaI, HinfI, RsaI), clearly distinguished the 14 species of marine bioluminescent bacteria currently known, which belong to the genera Vibrio, Photobacterium, and Shewanella. When we applied ARDRA to 129 natural isolates from two cruises in Sagami Bay, Japan, 127 were grouped into six ARDRA types with distinctive restriction patterns; these isolates represented the bioluminescent species, P. angustum, P. leiognathi, P. phosphoreum, S. woodyi, V. fischeri, and V. harveyi. The other two isolates showing unexpected ARDRA patterns turned out to have 16S rRNA gene sequences similar to P. leiognathi and P. phosphoreum. Nevertheless, ARDRA provides a simple and fairly robust means for rapid identification of the natural isolates of marine bioluminescent bacteria, and is therefore useful in studying their diversity.     

Frequency and biodiversity of 2,4-diacetylphloroglucinol-producing bacteria isolated from the maize rhizosphere at different stages of plant growth

A Pseudomonas 2,4-diacetylphloroglucinol (DAPG)-producing population that occurred naturally on the roots, in rhizosphere soil of Zea mays and in the nonrhizosphere soil was investigated in order to assess the microbial diversity at five stages of plant growth. A total of 1,716 isolates were obtained, and 188 of these isolates were able to produce DAPG. DAPG producers were isolated at each stage of plant growth, indicating that the maize rhizosphere is colonized by natural DAPG producers throughout development. The frequency of DAPG producers was very low in the first stage of plant growth and increased over time. An analysis of the level of biodiversity of the DAPG producers at the species level was performed by comparing the AluI restriction patterns of the 16S ribosomal DNAs (rDNAs) amplified by PCR from 167 isolates. This comparison allowed us to cluster the isolates into four amplified rDNA restriction analysis (ARDRA) groups, and the main group (ARDRA group 1) contained 89.8% of the isolates. The diversity of the 150 isolates belonging to ARDRA group 1 was analyzed by the random amplified polymorphic DNA (RAPD) technique. An analysis of RAPD patterns by a molecular variance method revealed that there was a high level of genetic diversity in this population and that the genetic diversity was related to plant age. Finally, we found that some of the DAPG producers, which originated from all stages of plant growth, had the same genotype. These DAPG producers could be exploited in future screening programs for biocontrol agents.     

Frequency and Biodiversity of 2,4-Diacetylphloroglucinol-Producing Bacteria Isolated from the Maize Rhizosphere at Different Stages of Plant Growth

A Pseudomonas 2,4-diacetylphloroglucinol (DAPG)-producing population that occurred naturally on the roots, in rhizosphere soil of Zea mays and in the nonrhizosphere soil was investigated in order to assess the microbial diversity at five stages of plant growth. A total of 1,716 isolates were obtained, and 188 of these isolates were able to produce DAPG. DAPG producers were isolated at each stage of plant growth, indicating that the maize rhizosphere is colonized by natural DAPG producers throughout development. The frequency of DAPG producers was very low in the first stage of plant growth and increased over time. An analysis of the level of biodiversity of the DAPG producers at the species level was performed by comparing the AluI restriction patterns of the 16S ribosomal DNAs (rDNAs) amplified by PCR from 167 isolates. This comparison allowed us to cluster the isolates into four amplified rDNA restriction analysis (ARDRA) groups, and the main group (ARDRA group 1) contained 89.8% of the isolates. The diversity of the 150 isolates belonging to ARDRA group 1 was analyzed by the random amplified polymorphic DNA (RAPD) technique. An analysis of RAPD patterns by a molecular variance method revealed that there was a high level of genetic diversity in this population and that the genetic diversity was related to plant age. Finally, we found that some of the DAPG producers, which originated from all stages of plant growth, had the same genotype. These DAPG producers could be exploited in future screening programs for biocontrol agents.     

Fluctuation of endophytic bacteria and phytoplasmosis in elm trees

A total of 658 heterotrophic bacterial colonies isolated from phloem tissues of roots and branches in four months (April, June, September and December) from two elm plants, one of which affected by phytoplasmosis, were typed by means of ARDRA. This analysis revealed the existence of a high degree of variability within the community and was able to detect 84 different ARDRA groups. The Analysis of Molecular Variance was applied to ARDRA patterns to analyze the differentiation between communities isolated from the various samplings. Data obtained were compared with those from a previous work (Mocali et al. 2003). Results indicated that plants with symptoms of phytoplasmosis showed marked alterations in the extent of the fluctuations of the community along the seasons in the different plant organs.     

Effect of restriction endonucleases on assessment of biodiversity of cultivable polar marine planktonic bacteria by amplified ribosomal DNA restriction analysis

To choose a suitable restriction endonuclease for quick assessment of bacterial diversity in polar environments by ARDRA, we investigated the effect of restriction enzymes on ARDRA patterns of cultivable marine planktonic bacteria isolated from polar region. Thirty-three isolates were analyzed by ARDRA using five enzymes (HinfI, HaeIII, AluI, and the mix AfaI/MspI), respectively, resulting in different groups, each group corresponding to a particular genotype. A comparison of the ARDRA patterns was carried out, and phylogenetic position of all thirty-three bacteria was obtained by 16S rDNA sequencing. Consistent with phylogenetic analysis, ARDRA pattern comparison revealed that AluI, being sensitive and reliable enough to generate species-specific patterns, was a suitable restriction enzyme used for evaluating bacterial diversity, suggesting a combination of ARDRA with AluI and 16S rDNA sequencing can provide a simple, fast and reliable means for bacterial identification and diversity assessment in polar environments.