新疆特殊生境岩石内生细菌末端限制性片段长度多态性技术分析

【目的】了解新疆特殊生境不同类型岩石内生细菌的组成及多样性。【方法】采用末端限制性片段长度多态性技术(Terminal Restriction Fragment Length Polymorphism,T-RFLP),分析新疆乌苏花岗岩(1号样)、一号冰川和木垒变质岩(2,3号样)、裕民和托克逊岩石漆(4,5号样)内生细菌群落。【结果】样品间多样性指数变化不大;聚类分析表明岩石类型相同,其相似性较高,2号样和3号样聚为一支并与1号样再聚为一支,4号样与5号样聚为一支;各样品共有种群为厚壁菌门(Firmicutes)、放线菌门(Actinobacteria)、变形菌门(Proteobacteria)和拟杆菌门(Bacteroidetes),1号样存在酸杆菌门(Acidobacteria),2号样存在浮霉菌门(Planctomycetes);除5号样优势类群为放线菌门(29.3%),其它4个样品均为变形菌门,只是所占比例略有不同。【结论】生境不同的同类型岩石的内生细菌群落组成存在差异,各类岩石中可能存在大量未知细菌新种。     

末端限制性片段长度多态性技术分析硝化细菌微生物多样性

利用T_RFLP(末端限制性片段长度多态性)技术,分析硝化细菌富集反应器中的微生物群落结构,并对硝化细菌的丰度进行半定量研究。结果表明,培养48h后,硝化细菌富集效果最佳,多样性指数与初始培养相比下降了62.80%,富集出的硝化细菌主要为亚硝酸盐氧化菌(Nitrobacter)。同时对投加该硝化细菌前后的对虾养殖水体进行微生物多样性的动态研究,并推测了虾塘水中可能稳定存在的几种主要细菌种类,其中投加富集硝化细菌前后均存在的细菌种类包括短芽孢杆菌Brevibacillus brevis、微杆菌Microbacterium lactium、固氮弧菌Azoarcus indigens或者霍氏鲍特菌Bordetella holmesii。     

中国普通野生稻核糖体RNA基因限制性片段长度多态性

对９８份普通野生稻、亚洲栽培稻及稻进行了核糖体ＲＮＡ基因间间隔区的限制性片段长度多态性分析。共发现３０种长度变异类型,组成４５种表现型。广西普通野生稻的ｒＤＮＡ间隔序列长度多样性最丰富,２４份材料中长度变异类型,     

中国普通野生稻核糖体RNA墓因限制性片段长度多态性

对98份普通野生稻、亚洲栽培稻及稻进行了核糖体RNA基因间间隔区的限制性片段长度多态性（RFLP）分析。共发现30种长度变异类型,组成45种表现型。广西普通野生稻的rDNA间隔序列长度多样性最丰富,24份材料中检测到25种长度变异类型,共组成22种表现型。rDNA间隔区长度变异类型的地理分布与纬度相关,高纬度来源的普通野生稻的rDNA间隔区长度较短,与粳稻的长度变异类型相似;低纬度来源的材料rDNA间隔长度趋长,与籼稻的长度变异类型相似;稻的长度变异类型与粳稻相似。提出了华南是野生稻变异中心的观点,并指出对我国野生稻资源进行保护的重要性。     

山羊品种间线粒体DNA限制性片段长度多态性研究

本试验利用ＡｐａⅠ、ＢａｍＨⅠ、ＢｃｌⅠ、ＢｇｌⅠ、ＢｇｌⅡ、ＣｌａⅠ、ＥｃｏＲⅠ、ＥｃｏＲⅤ、ＨａｅⅡ、ＨｉｎｄⅢ、ＫｐｎⅠＰｓｔⅠ、ＰｖｕⅡ、ＳａｃⅠ、ＳａｌⅠ、ＳｍａⅠ和ＸｈｏⅠ计１８种限制性内切酶,研究了来自欧洲,非洲及国内的５个山羊品种共计３３只个体的ｍｔＤＮＡ,共检测了２７处限制性态型,可归结为８种单倍型。结果表明,国内２个百品种的基本单倍型为ＢａｍＨⅠ－Ａ,ＢｃｌⅠ－Ｂ、ＣｌａⅠ－Ａ     

T-RFLP技术在人肠道柔嫩梭菌类群的组成分析中的应用

目的建立能快速筛查和比较大规模人群肠道中柔嫩梭菌类群组成结构的T-RFLP（末端限制性片段长度多态性）。方法采用T-RFLP技术特异性地分析柔嫩梭菌类群的组成,考察该方法的重复性和灵敏度。用该方法对15个志愿者肠道中的柔嫩梭菌类群进行分析,并与DGGE方法分析的结果进行对比。结果T-RFLP方法重复性高,最低能检测到群落中1%的细菌,其结果与DGGE的分析结果具有较好的一致性。结论本研究建立的柔嫩梭菌类群特异性的T-RFLP方法能够对大量肠道样品中柔嫩梭菌类群的结构进行快速、有效的筛查和比较。     

限制性末端片段长度多态性分析技术及其在肠道微生物研究中的应用

限制性末端片段长度多态性分析技术(Terminal Restriction Fragment Length Polymorphism,T-RFLP)具有高通量,低成本,低劳动力等特点,是微生物生态学家在探索群落结构,功能及其动态变化中的一项实用方便的工具。自2012年至今,T-RFLP在肠道微生物领域研究方向不断拓宽,随后T-RFLP技术被更多的应用于人体相关疾病与肠道微生物关系的研究中。尽管T-RFLP技术仍存在不足,但随着16Sr RNA基因序列数据库和引物的改进,数据生成和分析统计工具的运用,T-RFLP最终将能在各个领域体现其价值,为人类疾病研究事业带来贡献。     

小鼠DNA的限制性片段长度多态性分析

用人类肌红蛋白基因内含子中３３ｂｐ的小卫星ＤＮＡ重复序列为探针,经ｐＢＲ３２２的ＥｃｏＲ Ｉ正向测序引物和α－３２Ｐ－ｄＣＴＰ在Ｔａｑ ＤＮＡ聚合酶作用下做合成标记,与６种小鼠的ＤＮＡ限制性片段杂交。结果显示,每个品系平均出现可分辨带纹在１３条以上,不同品系小鼠间的杂交带纹表现出高度的多态性。多态性带纹主要分布在６￣２３ｋｂ区段;同一近交系的不同个体间的带纹特点及分布完全一致;ＣＳ７与ＡＫＲ及二者     

裂解酶片段长度多态性分析的应用现状及发展

裂解酶片段长度多态性分析是近年来出现的一种新型分子生物学技术。它能裂解毒I对事先标记的待测DNA作特异性酶切,产生一组特异性DNA片段,经显影后形成一级结构依赖性的结构指纹图谱而检测DNA序列变化,其灵敏度,特异性和社会经济效益均等同于或优于SSCP、RFLP和DNA直接测序等方法,具有广阔的发展应用前景。本文介绍了该方法的技术原理,在遗传学基因突变筛查和基因分型等领域的应用现状以及近期取得的技术改进。     

The Use of Terminal Restriction Fragment Length Polymorphism (T-RFLP) for the Characterisation of Microbial Communities in Marine Sediments

Terminal Restriction Fragment Length Polymorphism (T-RFLP) of PCR amplified 16S rRNA genes was used to investigate microbial communities in the sediments of Ria Formosa, Portugal. Five replicates of surface sand sediments were collected at an artificial inlet to the sea, between June 2001 and July 2002. Restriction enzymes Msp1 and Hha1 provided 57 different terminal fragments (T-RFs). The sediments were essentially dominated by the same ribotypes throughout the year, with seasonal shifts attributed to minor ribotypes. Principal component analysis of the T-RFs profile revealed no consistent pattern of temporal variation and no consistent grouping of replicate sediment samples. The results suggest that the small-scale spatial variability outweighs the seasonal variability. Phylogenetic affiliations suggested that the dominant bacteria were representatives of the α-Proteobacteria group.     

Technicalities and Glitches of Terminal Restriction Fragment Length Polymorphism (T-RFLP)

Terminal restriction fragment length polymorphism (T-RFLP) is a rapid, robust, inexpensive and simple tool for microbial community profiling. Methods used for DNA extraction, PCR amplification and digestion of amplified products have a considerable impact on the results of T-RFLP. Pitfalls of the method skew the similarity analysis and compromise its high throughput ability. Despite a high throughput method of data generation, data analysis is still in its infancy and needs more attention. Current article highlights the limitations of the methods used for data generation and analysis. It also provides an overview of the recent methodological developments in T-RFLP which will assist the readers in obtaining real and authentic profiles of the microbial communities under consideration while eluding the inherent biases and technical difficulties.     

Comparison of Bacterial Communities in New England Sphagnum Bogs Using Terminal Restriction Fragment Length Polymorphism (T-RFLP)

Wetlands are major sources of carbon dioxide, methane, and other greenhouse gases released during microbial degradation. Despite the fact that decomposition is mainly driven by bacteria and fungi, little is known about the taxonomic diversity of bacterial communities in wetlands, particularly Sphagnum bogs. To explore bacterial community composition, 24 bogs in Vermont and Massachusetts were censused for bacterial diversity at the surface (oxic) and 1 m (anoxic) regions. Bacterial diversity was characterized by a terminal restriction fragment length (T-RFLP) fingerprinting technique and a cloning strategy that targeted the 16S rRNA gene. T-RFLP analysis revealed a high level of diversity, and a canonical correspondence analysis demonstrated marked similarity among bogs, but consistent differences between surface and subsurface assemblages. 16S rDNA sequences derived from one of the sites showed high numbers of clones belonging to the Deltaproteobacteria group. Several other phyla were represented, as well as two Candidate Division-level taxonomic groups. These data suggest that bog microbial communities are complex, possibly stratified, and similar among multiple sites.     

Terminal Restriction Fragment Length Polymorphism Data Analysis for Quantitative Comparison of Microbial Communities

Terminal restriction fragment length polymorphism (T-RFLP) is a culture-independent method of obtaining a genetic fingerprint of the composition of a microbial community. Comparisons of the utility of different methods of (i) including peaks, (ii) computing the difference (or distance) between profiles, and (iii) performing statistical analysis were made by using replicated profiles of eubacterial communities. These samples included soil collected from three regions of the United States, soil fractions derived from three agronomic field treatments, soil samples taken from within one meter of each other in an alfalfa field, and replicate laboratory bioreactors. Cluster analysis by Ward's method and by the unweighted-pair group method using arithmetic averages (UPGMA) were compared. Ward's method was more effective at differentiating major groups within sets of profiles; UPGMA had a slightly reduced error rate in clustering of replicate profiles and was more sensitive to outliers. Most replicate profiles were clustered together when relative peak height or Hellinger-transformed peak height was used, in contrast to raw peak height. Redundancy analysis was more effective than cluster analysis at detecting differences between similar samples. Redundancy analysis using Hellinger distance was more sensitive than that using Euclidean distance between relative peak height profiles. Analysis of Jaccard distance between profiles, which considers only the presence or absence of a terminal restriction fragment, was the most sensitive in redundancy analysis, and was equally sensitive in cluster analysis, if all profiles had cumulative peak heights greater than 10,000 fluorescence units. It is concluded that T-RFLP is a sensitive method of differentiating between microbial communities when the optimal statistical method is used for the situation at hand. It is recommended that hypothesis testing be performed by redundancy analysis of Hellinger-transformed data and that exploratory data analysis be performed by cluster analysis using Ward's method to find natural groups or by UPGMA to identify potential outliers. Analyses can also be based on Jaccard distance if all profiles have cumulative peak heights greater than 10,000 fluorescence units.     

Pros and Cons of Ion-Torrent Next Generation Sequencing versus Terminal Restriction Fragment Length Polymorphism T-RFLP for Studying the Rumen Bacterial Community

The development of next generation sequencing has challenged the use of other molecular fingerprinting methods used to study microbial diversity. We analysed the bacterial diversity in the rumen of defaunated sheep following the introduction of different protozoal populations, using both next generation sequencing (NGS: Ion Torrent PGM) and terminal restriction fragment length polymorphism (T-RFLP). Although absolute number differed, there was a high correlation between NGS and T-RFLP in terms of richness and diversity with R values of 0.836 and 0.781 for richness and Shannon-Wiener index, respectively. Dendrograms for both datasets were also highly correlated (Mantel test = 0.742). Eighteen OTUs and ten genera were significantly impacted by the addition of rumen protozoa, with an increase in the relative abundance of Prevotella, Bacteroides and Ruminobacter, related to an increase in free ammonia levels in the rumen. Our findings suggest that classic fingerprinting methods are still valuable tools to study microbial diversity and structure in complex environments but that NGS techniques now provide cost effect alternatives that provide a far greater level of information on the individual members of the microbial population.     

Characterization of Microbial Diversity in Hypersaline Environments by Melting Profiles and Reassociation Kinetics in Combination with Terminal Restriction Fragment Length Polymorphism (T-RFLP)

The diversity of prokaryotes inhabiting solar saltern ponds was determined by thermal melting and reassociation of community DNA. These measurements were compared with fingerprinting techniques such as terminal restriction fragment length polymorphisms (T-RFLP) analysis, denaturant gradient gel electrophoresis (DGGE), and cloning and sequencing approaches. Three ponds with salinities of 22, 32, and 37% (NaCl saturation) were studied. The combination of independent molecular techniques to estimate the total genetic diversity provided a realistic assessment to reveal the microbial diversity in these environments. The changes in the prokaryotic communities at different salinity (22, 32, and 37% salt) were significant and revealed that the total genetic diversity increased from 22% to 32% salinity. At 37% salinity the diversity was reduced again to nearly half that at 22% salinity. Our results revealed that the community genome had a DNA complexity that was 7 (in 22% salinity pond), 13 (in 32% salinity pond), and 4 (in 37% salinity pond) times the complexity of an Escherichia coli genome. The base composition profiles showed two abundant populations, which changed in relative amount between the three ponds. They indicated an uneven taxon distribution at 22% and 37% salinity and a more even distribution at 32% salinity. The results indicated a large predominating population at 37% salinity, which might correspond to the abundance of square archaea (SPhT) observed by transmission electron microscopy (TEM) and also indicated by the same T-RFLP fragment as the SPhT. The SPhT phylotype has also been reported to be the most frequently retrieved phylotype from this environment by culture independent techniques. In addition, two different operational taxonomic units (OTU) were detected at 37% salinity based on PCR with bacterial specific primers and T-RFLP. One of these predominant phylotypes is the extreme halophilic bacterium belonging to the bacteroidetes group, Salinibacter ruber.     

Terminal Restriction Fragment Length Polymorphism for Identification of Cryptosporidium Species in Human Feces

Effective management of human cryptosporidiosis requires efficient methods for detection and identification of the species of Cryptosporidium isolates. Identification of isolates to the species level is not routine for diagnostic assessment of cryptosporidiosis, which leads to uncertainty about the epidemiology of the Cryptosporidium species that cause human disease. We developed a rapid and reliable method for species identification of Cryptosporidium oocysts from human fecal samples using terminal restriction fragment polymorphism (T-RFLP) analysis of the 18S rRNA gene. This method generated diagnostic fragments unique to the species of interest. A panel of previously identified isolates of species was blind tested to validate the method, which determined the correct species identity in every case. The T-RFLP profiles obtained for samples spiked with known amounts of Cryptosporidium hominis and Cryptosporidium parvum oocysts generated the two expected diagnostic peaks. The detection limit for an individual species was 1% of the total DNA. This is the first application of T-RFLP to protozoa, and the method which we developed is a rapid, repeatable, and cost-effective method for species identification.