Rapid lactic acid bacteria identification in dairy products by high-resolution melt analysis of DGGE bands

Aim: To investigate the application of high‐resolution melt (HRM) analysis for rapid species‐level identification of lactic acid bacteria (LAB) communities in dairy products, as well as for bacterial community profiling and monitoring. Methods and Results: First, comparisons of HRM profiles of known reference strains of LAB and their denaturing gradient gel electrophoresis (DGGE) bands showed very good agreement, allowing species recognition and identification from DGGE bands by HRM. Second, samples of cheese, kefir grains and kefir were characterized by PCR‐DGGE, and melting profiles of DGGE bands were compared with known reference strains. Of the 13 DGGE bands, ten were identified by HRM by comparison with the reference strains and only three required sequencing for identification. Use of HRM profiling for comparison and monitoring of total LAB communities from dairy products or starter cultures was also evaluated, and good agreement was found when comparing clustering of DGGE band profiles with clustering of HRM melting profiles. Conclusion: Identification of DGGE bands is possible by comparison of HRM melting profiles with known reference strains. Significance and Impact of the Study: HRM profiling is suggested as an additional approach for identification of DGGE bands.     

Use of the rpoB gene as an alternative to the V3 gene for the identification of spoilage and pathogenic bacteria species in milk and milk products

Aim: To evaluate the rpoB gene as an alternative to the V3 gene for the identification of bacterial species in milk and milk products. Methods and Results: DNA obtained from different bacterial species strains was amplified by PCR using rpoB primers. PCR products of each bacterial species were then separated on a DGGE gel. The molecular fingerprints of the bacterial species tested were integrated into a database. The DGGE analysis shows a single band for the rpoB gene amplicons per each bacterial species. Comparison of electrophoretic profiles obtained from V3 16S rDNA amplification with those from this study obtained with rpoB showed that for some bacterial species that co‐migrated after amplification of the V3 region, distinct bands were observed on the gel with the amplification products of the rpoB region. Conclusions: The results obtained in this study show the discriminatory power of the rpoB gene, indicating that it can be used as an alternative to the V3 16S rRNA gene for the identification of bacterial species in milk and milk products. Significance and Impact of the Study: PCR‐DGGE targeting the rpoB gene is a way of discriminating the bacterial species that co‐migrated with the amplification of the V3 gene and so avoids the sequencing of the co‐migrating bands.     

Application of denaturant gradient gel electrophoresis for the analysis of the porcine gastrointestinal microbiota.

The porcine gastrointestinal tract (GIT) microbiota has been studied to increase production efficiency, improve product quality, and help attempt to reduce disease. During the developmental period from birth through weaning, the intestinal microbiota undergoes a rapid ecological succession. There is interest in developing a monitoring technique that allows for analysis of bacterial population levels and shifts within the pig intestine. The objective of this study was to determine if denaturant gradient gel electrophoresis (DGGE) could be effectively applied to measure changes in bacterial populations of the pig GIT, as influenced by age, diet or compartment. Bacterial genetic diversity was determined using DGGE analysis of the V3 region of 16S rDNA PCR products (approximately 200 bp) obtained from primers specific for the domain Bacteria. Protocol development included optimization of: DNA extraction procedures, PCR amplification, removal of PCR artifacts, and optimization of gel preparation and image capture. DGGE analysis revealed diverse bacterial populations between pigs of different ages and among individual gut compartments. Comparison of fecal DNA from different aged pigs revealed several unique PCR product bands indicating the presence of unique bacterial populations. Comparison of different gut compartments demonstrated that bacterial populations were most similar (C, value > 50%) within a single compartment and between adjacent ones. Thus, DGGE can be used to examine bacterial diversity and population shifts in the pig GIT.     

Genetic diversity of Desulfovibrio spp. in environmental samples analyzed by denaturing gradient gel electrophoresis of [NiFe] hydrogenase gene fragments.

The genetic diversity of Desulfovibrio species in environmental samples was determined by denaturing gradient gel electrophoresis (DGGE) of PCR-amplified [NiFe] hydrogenase gene fragments. Five different PCR primers were designed after comparative analysis of [NiFe] hydrogenase gene sequences from three Desulfovibrio species. These primers were tested in different combinations on the genomic DNAs of a variety of hydrogenase-containing and hydrogenase-lacking bacteria. One primer pair was found to be specific for Desulfovibrio species only, while the others gave positive results with other bacteria also. By using this specific primer pair, we were able to amplify the [NiFe] hydrogenase genes of DNAs isolated from environmental samples and to detect the presence of Desulfovibrio species in these samples. However, only after DGGE analysis of these PCR products could the number of different Desulfovibrio species within the samples be determined. DGGE analysis of PCR products from different bioreactors demonstrated up to two bands, while at least five distinguishable bands were detected in a microbial mat sample. Because these bands most likely represent as many Desulfovibrio species present in these samples, we conclude that the genetic diversity of Desulfovibrio species in the natural microbial mat is far greater than that in the experimental bioreactors.     

应用变性梯度凝胶电泳和16SrDNA序列分析对kefir粒中细菌多样性的研究

以开菲尔（Kefir）粒为材料,经过DNA抽提和16SrDNA V3区PCR扩增,扩增产物经变性梯度凝胶电泳（DGGE）分离并切割电泳条带进行序列测定,并与现有的数据库进行了比较,对Kefir粒的细菌多样性进行分析。结果表明,DGGE图谱中可检测到的8条带的16SrDNA基因序列中有7个基因序列与GenBank数据库登录的相关序列的相似性大于98％,余下的1个基因序列的相似性也大于96％。相似性大于98％的7个克隆中,有3个属于鞘氨醇杆菌属（Sphingobacterium）,2个属于乳杆菌属（Lactobacillus）,其它2个分别属于肠杆菌属（Errterobacter）和不动杆菌属（Acinetobacter）。首次报道了鞘氨醇杆菌作为优势菌群存在开菲尔Kefir粒中。     

应用变性梯度凝胶电泳和16S rDNA序列分析对kefir粒中细菌多样性的研究

以开菲尔(Kefir)粒为材料,经过DNA抽提和16S rDNA V3区PCR扩增,扩增产物经变性梯度凝胶电泳(DGGE)分离并切割电泳条带进行序列测定,并与现有的数据库进行了比较,对Kefir粒的细菌多样性进行分析。结果表明,DGGE图谱中可检测到的8条带的16S rDNA基因序列中有7个基因序列与GenBank数据库登录的相关序列的相似性大于98%,余下的1个基因序列的相似性也大于96%。相似性大于98%的7个克隆中,有3个属于鞘氨醇杆菌属(Sphingobacterium),2个属于乳杆菌属(Lactobacillus),其它2个分别属于肠杆菌属(Enterobacter)和不动杆菌属(Acinetobacter)。首次报道了鞘氨醇杆菌作为优势菌群存在开菲尔Kefir粒中。     

Characterization by denaturing gradient gel electrophoresis of bacterial communities in deep groundwater at the Kamaishi Mine,Japan

Bacterial communities in groundwater collected from five different sites at the Kamaishi Mine were investigated by using denaturing gradient gel electrophoresis (DGGE). The bacterial cells in groundwater were collected on Millipore filters, and their nucleic acid was extracted by freeze-thaw cycles. A partial 16S rRNA gene was amplified by using a universal primer set by PCR. The PCR products were analyzed by DGGE. The band pattern of DGGE was essentially identical between two samples obtained from different depths in the same borehole (KH-1). Samples from the other sites differed from one another. The partial sequences of 16S rRNA genes (about 350 base pairs) isolated from bands were determined and analyzed for phylogenetic position. Almost half the sequences from two samples of the KH-1 belonged to the cluster of spore-forming, gram-positive sulfate reducer, Desulfotomaculum. The other bands also were related to those of obligate anaerobes. This suggests that the environment in both sites of KH-1 was highly anaerobic. Although only a few sequences were retrieved from the other sites, they were phylogenetically distanced from known isolates.     

Detection and characterization of fungal infections of Ammophila arenaria (marram grass) roots by denaturing gradient gel electrophoresis of specifically amplified 18s rDNA.

Marram grass (Ammophila arenaria L.), a sand-stabilizing plant species in coastal dune areas, is affected by a specific pathosystem thought to include both plant-pathogenic fungi and nematodes. To study the fungal component of this pathosystem, we developed a method for the cultivation-independent detection and characterization of fungi infecting plant roots based on denaturing gradient gel electrophoresis (DGGE) of specifically amplified DNA fragments coding for 18S rRNA (rDNA). A nested PCR strategy was employed to amplify a 569-bp region of the 18S rRNA gene, with the addition of a 36-bp GC clamp, from fungal isolates, from roots of test plants infected in the laboratory, and from field samples of marram grass roots from both healthy and degenerating stands from coastal dunes in The Netherlands. PCR products from fungal isolates were subjected to DGGE to examine the variation seen both between different fungal taxa and within a single species. DGGE of the 18S rDNA fragments could resolve species differences from fungi used in this study yet was unable to discriminate between strains of a single species. The 18S rRNA genes from 20 isolates of fungal species previously recovered from A. arenaria roots were cloned and partially sequenced to aid in the interpretation of DGGE data. DGGE patterns recovered from laboratory plants showed that this technique could reliably identify known plant-infecting fungi. Amplification products from field A. arenaria roots also were analyzed by DGGE, and the major bands were excised, reamplified, sequenced, and subjected to phylogenetic analysis. Some recovered 18S rDNA sequences allowed for phylogenetic placement to the genus level, whereas other sequences were not closely related to known fungal 18S rDNA sequences. The molecular data presented here reveal fungal diversity not detected in previous culture-based surveys.     

Influence of petroleum contamination and biostimulation treatment on the diversity of Pseudomonas spp. in soil microcosms as evaluated by 16S rRNA based-PCR and DGGE

AIMS: The aim of this study was to apply a group specific PCR system followed by denaturing gradient gel electrophoresis (DGGE) analysis to evaluate the effect of oil contamination and the biostimulation process on the diversity of Pseudomonas populations in soil ecosystems. METHODS AND RESULTS: Direct DNA extraction from biostimulated- and oil-contaminated soil samples was performed. Primers specific for the genus Pseudomonas spp. were used to amplify 16S rRNA genes and then a semi-nested PCR reaction was applied to obtain smaller fragments for comparing the PCR products by DGGE. Whether in bulk, oil-contaminated or biostimulated soils, the DGGE profiles revealed little change in Pseudomonas community throughout the 270 days of experiment. The presence of a few additional bands observed only in treated samples indicated that a bacterial shift occurred with the addition of nutrients and with oil contamination. CONCLUSIONS, SIGNIFICANCE AND IMPACT OF THE STUDY: The combination of semi-nested PCR and DGGE was found to be a rapid and sensitive technique to study the diversity within the genus Pseudomonas and may be suitable for further studies concerning the role of this bacterial group in large-scale oil-contaminated areas.     

Nested PCR-denaturing gradient gel electrophoresis approach to determine the diversity of sulfate-reducing bacteria in complex microbial communities

Here, we describe a three-step nested-PCR-denaturing gradient gel electrophoresis (DGGE) strategy to detect sulfate-reducing bacteria (SRB) in complex microbial communities from industrial bioreactors. In the first step, the nearly complete 16S rRNA gene was amplified using bacterial primers. Subsequently, this product was used as a template in a second PCR with group-specific SRB primers. A third round of amplification was conducted to obtain fragments suitable for DGGE. The largest number of bands was observed in DGGE patterns of products obtained with primers specific for the Desulfovibrio-Desulfomicrobium group, indicating a large diversity of these SRBs. In addition, members of other phylogenetic SRB groups, i.e., Desulfotomaculum, Desulfobulbus, and Desulfococcus-Desulfonema-Desulfosarcina, were detected. Bands corresponding to Desulfobacterium and Desulfobacter were not detected in the bioreactor samples. Comparative sequence analysis of excised DGGE bands revealed the identity of the community members. The developed three-step PCR-DGGE strategy is a welcome tool for studying the diversity of sulfate-reducing bacteria.     

PCR-DGGE研究微生物种群中多条带产生原因分析

鸡肠道微生物菌群经PCR-DGGE分析,回收PCR-DGGE分析胶上的一条DNA片段,回收的DNA片段再重复进行2次PCR-DGGE分析,以及分别用PCR反复循环扩增和PCR高保真酶扩增后再进行DGGE分析等方法研究PCR-DGGE分析中多条带产生原因。结果显示PCR-DGGE分析中多条带产生原因可能是作PCR扩增模板的DNA混杂有少量其他DNA片段,多条带现象不易被消除。DGGE分析胶上的DNA片段测序时,将该DNA片段回收、PCR扩增后克隆,提取多个阳性克隆菌的质粒DNA片段,分别与其原目的DNA片段进行DGGE分析,在DGGE分析胶上选取与原目的DNA片段处于同一电泳位置的质粒DNA测序,提高测序的准确性。     

Screening of bacterial contamination during gelatine production by means of denaturing gradient gel electrophoresis, focussed on Bacillus and related endospore-forming genera

AIMS: To screen for bacterial contamination during gelatine production by means of denaturing gradient gel electrophoresis (DGGE). As members of Bacillus and related genera were found to persist in the final product, this study focussed on these taxa. METHODS AND RESULTS: Template DNA was extracted from gelatine samples at five crucial points of a gelatine production process. A primer specific for Bacillus and related genera was designed and used in a selective PCR, followed by a nested DGGE-PCR targeting the V9 region of the 16S rDNA. DGGE analysis of the resulting amplicons, and sequence analysis of selected bands, showed high sequence similarities of these bands with Bacillus fumarioli, B. licheniformis, B. coagulans and Clostridium perfringens. When the selective PCR was omitted, primarily Lactobacillus bands were retrieved. CONCLUSIONS: PCR-DGGE analysis of gelatine extracts can be used for tracing and screening of bacterial contamination during gelatine production. A selective PCR, nested with DGGE-PCR, gave much more accurate information about endospore-forming contaminants than did the direct DGGE procedure alone. Significance AND IMPACT OF THE STUDY: Use of this nested DGGE-PCR protocol may provide important information about possible hazards to the final microbiological quality and/or safety of gelatine, so allowing production parameters and/or remediation procedures may be adjusted on-line.     

Molecular characterization of Legionella populations present within slow sand filters used for fungal plant pathogen suppression in horticultural crops

The total bacterial community of an experimental slow sand filter (SSF) was analyzed by denaturing gradient gel electrophoresis (DGGE) of partial 16S rRNA gene PCR products. One dominant band had sequence homology to Legionella species, indicating that these bacteria were a large component of the SSF bacterial community. Populations within experimental and commercial SSF units were studied by using Legionella-specific PCR primers, and products were studied by DGGE and quantitative PCR analyses. In the experimental SSF unit, the DGGE profiles for sand column, reservoir, storage tank, and headwater tank samples each contained at least one intense band, indicating that a single Legionella strain was predominant in each sample. Greater numbers of DGGE bands of equal intensity were detected in the outflow water sample. Sequence analysis of these PCR products showed that several Legionella species were present and that the organisms exhibited similarity to strains isolated from environmental and clinical samples. Quantitative PCR analysis of the SSF samples showed that from the headwater sample through the sand column, the number of Legionella cells decreased, resulting in a lower number of cells in the outflow water. In the commercial SSF, legionellae were also detected in the sand column samples. Storing prefilter water or locating SSF units within greenhouses, which are often maintained at temperatures that are higher than the ambient temperature, increases the risk of growth of Legionella and should be avoided. Care should also be taken when used filter sand is handled or replaced, and regular monitoring of outflow water would be useful, especially if the water is used for misting or overhead irrigation.     

Recovery and phylogenetic analysis of nifH sequences from diazotrophic bacteria associated with dead aboveground biomass of Spartina alterniflora.

DNA was extracted from dry standing dead Spartina alterniflora stalks as well as dry Spartina wrack from the North Inlet (South Carolina) and Sapelo Island (Georgia) salt marshes. Partial nifH sequences were PCR amplified, the products were separated by denaturing gradient gel electrophoresis (DGGE), and the prominent DGGE bands were sequenced. Most sequences (109 of 121) clustered with those from alpha-Proteobacteria, and 4 were very similar (>99%) to that of Azospirillum brasilense. Seven sequences clustered with those from known gamma-Proteobacteria and five with those from known anaerobic diazotrophs. The diazotroph assemblages associated with dead Spartina biomass in these two salt marshes were very similar, and relatively few major lineages were represented.     

PCR-DGGE技术在农田土壤微生物多样性研究中的应用

变性梯度凝胶电泳技术(DGGE)在微生物生态学领域有着广泛的应用。研究采用化学裂解法直接提取出不同农田土壤微生物基因组DNA,并以此基因组DNA为模板,选择特异性引物F357GC和R515对16S rRNA基因的V3区进行扩增,长约230bp的PCR产物经变性梯度凝胶电泳(DGGE)进行分离后,得到不同数目且分离效果较好的电泳条带。结果说明,DGGE能够对土壤样品中的不同微生物的16S rRNA基因的V3区的DNA扩增片断进行分离,为这些DNA片断的定性和鉴定提供了条件。与传统的平板培养方法相比,变性梯度凝胶电泳(DGGE)技术能够更精确的反映出土壤微生物多样性,它是一种有效的微生物多样性研究技术。     

Optimization of the DGGE band identification method

Denaturant gradient gel electrophoresis (DGGE) enables insight into the diversity of the studied microbial communities on the basis of separation of PCR amplification products according to their nucleotide sequence composition. However, the success of the method is accompanied by the inherent appearance of various sequence artifacts that bias the impression of community structure by generating additional bands representing no virtual microbes. PCR-DGGE artifacts require optimization of the method when aiming at the phylogenetic identification of the selected DGGE bands. The aim of our study was to develop a procedure which will increase the reliability of the identification. Samples of rumen fluid were used for the optimization since they contain a complex microbial community that supports the generation of artifactual bands. An optimized procedure following band excision and elution of microbial DNA is proposed including nuclease treatment, selection of DNA polymerase with proofreading activity, and cloning prior to sequencing and identification analysis.     

应用DGGE法对青海相邻两盐湖中细菌多样性的快速检测

分别对青海相邻两盐湖柯柯盐湖、茶卡盐湖土样、泥样进行富集培养后,从中提取的DNA用两套不同的细菌通用引物进行扩增,分别得到包含V8和V9高变区的16SrDNA片断。经变性梯度凝胶电泳(DGGE)分析,结果显示这两个盐湖富集样品中细菌多样性具有较大的差异,而且同一盐湖不同性质样品中的细菌多样性差异也较大,两湖的泥样富集样品中均表现出了稍丰富的多样性。     

Increase of inheritable polymorphisms of arbitrary primed PCR products on DGGE gels

Summary Single 10-mer primers of arbitrary sequence were used to amplify, by polymerase chain reaction (PCR), random genomic regions of two closely related hexaploid wheat cultivars. Polymorphic bands between the two genomes were visualized on both agarose and denaturing gradient gel electrophoresis (DGGE) gels. There was approximately a four-fold increase in inheritable polymorphisms when the PCR fragments were separated on DGGE gels.     

A molecular approach to the characterization of the eukaryotic communities of an extreme acidic environment: methods for DNA extraction and denaturing gradient gel electrophoresis analysis

The diversity of the phytobenthonic community present in six acidophilic microbial mats from Río Tinto (Iberian Pyritic Belt, SW Spain) was analysed by optical microscopy and two molecular techniques, denaturing gradient gel electrophoresis (DGGE) and sequence analysis of 18S rDNA cloned gene fragments. Sixteen DNA isolation protocols as well as two commercial DNA extraction kits were tested and their efficiency compared. Purified DNA extracts were amplified by PCR using universal eukaryotic primers and the PCR products analysed by DGGE. Bead-mill homogenization was found to be superior to the other cell lysis methodologies assayed (sonication or freeze-thawing cycles) as it allowed efficiencies of cell disruption of over 95%. The methods combining bead-mill homogenization in the presence of SDS, treatment with chemical extractants (hexadecylmethylammonium bromide or guanidine isothiocyanate) and phenol extraction resulted in DNA preparations that amplified the same number of bands when analysed by DGGE as the two commercial kits assayed. The phylogenetic affiliations of the DGGE bands were determined by a BLAST search, and nine different species related to the Chlorophyta, Ciliophora, Kinetoplastida, Ascomycota, Streptophyta and Colcochaetales taxonomical groups were identified. Similar levels of diversity were found using cloning procedures. Although not all the species observed under the microscope were detected using molecular techniques, e.g. euglenas, heliozoan, or amoebae, DGGE fingerprints showed rather well the level of diversity present in the samples analysed, with limitations similar to cloning techniques.