New Group-Specific 16S rDNA Primers for Monitoring Foaming Mycolata During Saline Waste-Water Treatment

Newly designed group-specific PCR primers for denaturing gradient gel electrophoresis (DGGE) were used to investigate foaming mycolata from a bioreactor treating an industrial saline waste-water. Genetic profiles on DGGE gels were different with NaCl at 1.65 and 8.24 g l⁻¹, demonstrating that mycolata community was affected by salinity. A semi-nested PCR strategy resulted in more bands in community genetic profiles than direct amplification. DNA sequencing of bands confirmed the efficacy of the novel primers with sequences recovered being most similar to foam producing mycolata. The new group-specific primers/DGGE approach is a new step toward a more complete understanding of functionally important groups of bacteria involved in biological treatment of waste-water. Revisions requested 1 December 2005; Revisions received 19 December 2005     

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.     

PCR–DGGE method for analyzing the bacterial community in a high temperature petroleum reservoir

Different PCR–denaturing gradient gel electrophoresis (DGGE) protocols were employed to investigate bacterial communities in a high temperature and water flooded petroleum reservoir in Dagang oil field, China. Bacterial universal primers sets frequently used in PCR–DGGE were evaluated. Three primers sets P1 (341F-GC and 534R), P2 (341F-GC and 907R) and P3 (1055F and 1406R-GC) showed different DGGE patterns. Good separation and quality of patterns were obtained in DGGE analysis with the set P3. A total of 12 DNA fragments were excised from the DGGE gels and their sequences were determined. Clustering analysis of the DGGE profiles showed that bacteria in this petroleum reservoir belonged to four clusters. These results indicate that the procedure of DGGE analysis with the primer P3 (1055F and 1406R-GC) is suitable for investigating microbial community in petroleum reservoirs.     

Comparative analysis of denaturing gradient gel electrophoresis and temporal temperature gradient gel electrophoresis in separating Escherichia coli uidA amplicons differing in single base substitutions

A set of Escherichia coli freshwater isolates was chosen to compare the effectiveness of denaturing gradient gel electrophoresis (DGGE) vs temporal temperature gradient gel electrophoresis (TTGE) for separating homologous amplicons from the respective uidA region differing in one to seven single base substitutions. Both methods revealed congruent results but DGGE showed a five to eight times higher spatial separation of the uidA amplicons as compared with TTGE, although the experiments were performed at comparable denaturing gradients. In contrast to TTGE, DGGE displayed clear and focused bands. The results strongly indicated a significantly higher discrimination efficiency of the spatial chemical denaturing gradient as compared with the temporal temperature denaturing gradient for separating the uidA amplicons. Denaturing gradient gel electrophoresis proved to be highly efficient in the differentiation of E. coli uidA sequence types.     

Spatiotemporal variability in archaeal communities of tropical coastal waters

Spatiotemporal variations in the archaeal community structure from four locations along the central west coast of India were analyzed by denaturing gradient gel electrophoresis (DGGE) profiling and sequencing of prominent bands on the DGGE gels. A total of 36 water samples were collected during pre-monsoon, post-monsoon and monsoon seasons from three depths (surface, mid-depth , and close to bottom ～20 m). The community DNA extracts from these samples were subjected to DGGE analysis. The results of this study clearly indicate a significant difference in the community structure between sampling locations and seasons. Location-wise variation was more pronounced during pre-monsoon and post-monsoon seasons. During monsoon, however, the depth-wise variation was pronounced, suggesting monsoon influence on archaeal community structure. Sequencing of DGGE bands suggested the presence of marine group I and II archaea. Canonical correspondence analysis indicated that nitrate, nitrite and chlorophyll a were the significant explanatory variables responsible for > 60 % variation in archaeal community in these coastal waters.     

Assessment of differences in ascomycete communities in the rhizosphere of field-grown wheat and potato

To assess effects of plant crop species on rhizosphere ascomycete communities in the field, we compared a wheat monoculture and an alternating crop rotation of wheat and potato. Rhizosphere soil samples were taken at different time points during the growing season in four consecutive years (1999-2002). An ascomycete-specific primer pair (ITS5-ITS4A) was used to amplify internal transcribed spacer (ITS) sequences from total DNA extracts from rhizosphere soil. Amplified DNA was analyzed by denaturing gradient gel electrophoresis (DGGE). Individual bands from DGGE gels were sequenced and compared with known sequences from public databases. DGGE gels representing the ascomycete communities of the continuous wheat and the rotation site were compared and related to ascomycetes identified from the field. The effect of crop rotation exceeded that of the spatial heterogeneity in the field, which was evident after the first year. Significant differences between the ascomycete communities from the rhizospheres of wheat in monoculture and one year after a potato crop were found, indicating a long-term effect of potato. Sequencing of bands excised from the DGGE gels revealed the presence of ascomycetes that are common in agricultural soils.     

Separation of fluorescence-labelled terminal restriction fragment DNA on a two-dimensional gel (T-RFs-2D) - an efficient approach for microbial consortium characterization

Fingerprinting techniques provide access to understanding the ecology of uncultured microbial consortia. However, the application of current techniques such as terminal restriction fragment length polymorphism (T-RFLP) and denaturing gradient gel electrophoresis (DGGE) has been hindered due to their limitations in characterizing complex microbial communities. This is due to that different populations possibly share the same terminal restriction fragments (T-RFs) and DNA fragments may co-migrate on DGGE gels. To overcome these limitations, a new approach was developed to separate terminal restriction fragments (T-RFs) of 16S rRNA genes on a two-dimensional gel (T-RFs-2D). T-RFs-2D involves restriction digestion of terminal fluorescence-labelled PCR amplified 16S rRNA gene products and their high-resolution separation via a two-dimensional (2D) gel electrophoresis based on the T-RF fragment size (1(st) D) and its sequence composition on the denaturing gradient gel (2(nd) D). The sequence information of interested T-RFs on 2D gels can be obtained through serial poly(A) tailing reaction, PCR amplification and subsequent DNA sequencing. By employing the T-RFs-2D method, bacteria with MspI digested T-RF size of 436 (±1) bp and 514 (±1) bp were identified to be a Lysobacter sp. and a Dehalococcoides sp. in a polychlorinated biphenyl (PCB) dechlorinating culture. With the high resolution of 2D separation, T-RFs-2D separated 63 DNA fragments in a complex river-sediment microbial community, while traditional DGGE detected only 41 DNA fragments in the same sample. In all, T-RFs-2D has its advantage in obtaining sequence information of interested T-RFs and also in characterization of complex microbial communities.     

Detection of base mutations in genomic DNA using denaturing gradient gel electrophoresis (DGGE) followed by transfer and hybridization with gene-specific probes

It has been shown that minor differences, such as single-base-pair substitutions between otherwise identical DNA fragments can result in altered melting behavior detectable by denaturing gradient gel electrophoresis (DGGE). Sequence variations in only a small DNA region within one locus can be detected using the previously described procedures. We have developed a method for the efficient Southern transfer of genomic DNA fragments from the denaturing gradient gels in order to be able to analyze larger regions in several loci for variation. The gels were made using polyacrylamide containing 2% low-geling-temperature agarose (LGT). The polyacrylamide gel (PAG) was crosslinked with a reversible crosslinker, and after electrophoresis the crosslinks were cleaved, the structure of the gel being maintained by the agarose. After this treatment of the denaturing gels, more than 90% of the DNA fragments could be transferred to nylon membranes by alkaline transfer, while electroblotting transferred only 10% of the DNA. Hybridization with gene-specific probes was then performed. We have used this technique to identify an RFLP in the COL1A2 gene in a human genomic DNA sample. The transfer technique described should make the use of DGGE more widely applicable since the genomic DNA fragments separated on one gel can be screened with several different probes, both cDNA and genomic probes.     

Diversity of<Emphasis Type="Italic"> Mhc</Emphasis> class I and IIB genes in house sparrows (<Emphasis Type="Italic">Passer domesticus</Emphasis>)

In order to understand the expression and evolution of host resistance to pathogens, we need to examine the links between genetic variability at the major histocompatibility complex (Mhc), phenotypic expression of the immune response and parasite resistance in natural populations. To do so, we characterized the Mhc class I and IIB genes of house sparrows with the goal of designing a PCR-based genotyping method for the Mhc genes using denaturing gradient gel electrophoresis (DGGE). The incredible success of house sparrows in colonizing habitats worldwide allows us to assess the importance of the variability of Mhc genes in the face of various pathogenic pressures. Isolation and sequencing of Mhc class I and IIB alleles revealed that house sparrows have fewer loci and fewer alleles than great reed warblers. In addition, the Mhc class I genes divided in two distinct lineages with different levels of polymorphism, possibly indicating different functional roles for each gene family. This organization is reminiscent of the chicken B complex and Rfp-Y system. The house sparrow Mhc hence appears to be intermediate between the great reed warbler and the chicken Mhc, both in terms of numbers of alleles and existence of within-class lineages. We specifically amplified one Mhc class I gene family and ran the PCR products on DGGE gels. The individuals screened displayed between one and ten DGGE bands, indicating that this method can be used in future studies to explore the ecological impacts of Mhc diversity.     

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.     

凝胶条带内DNA回收测序评估DGGE可靠性

为了评估DGGE的可靠性,对DGGE条带中回收的DNA片段进行了测序比较分析,并引入了DGGE可靠性指数的概念评价其可靠性。结果显示同一条DGGE条带回收的DNA来自同一属的概率为64.7%,相同位置的DGGE条带可以被认为是同一OTU;不同的DGGE条带回收到类似的DNA序列（16S rDNA V3区差异小于4 bp）的概率为10.5%;DGGE可靠性指数为74.8%。以上结果表明尽管DGGE技术与理论预期存在一定的差距,但是DGGE技术基本能够反映微生物群落的多样性。       

Observation of bias associated with re-amplification of DNA isolated from denaturing gradient gels

DNA from environmental PCR products separated by denaturing gradient gel electrophoresis (DGGE) was isolated from the background smear rather than from discrete bands of the DGGE gel. The "interband" region was considered as a potential source of less dominant members of natural microbial communities. Surprisingly, instead of detecting new bands from the re-amplified PCR products, patterns very similar to the original ones were obtained regardless of the position of the "interband" region. The results suggest that the separation of amplicons by DGGE may not be perfect and band re-amplification based sequence analyses need careful interpretation.     

Mutation screening using fluorescence multiplex denaturing gradient gel electrophoresis (FMD): detecting mutations in the BRCA1 gene

Fluorescent multiplex denaturing gradient gel electrophoresis (FMD) is a mutation screening technique designed to detect unknown as well as previously identified mutations. FMD constitutes a recent modification of the standard denaturing gradient gel electrophoresis (DGGE) technique, which combines multiplex PCR amplification of target DNA using fluorescently labeled primers with DGGE separation of the amplicon mixture, allowing immediate identification of sequence variants by wet gel scanning. FMD permits the simultaneous detection of small insertions, deletions and single nucleotide substitutions among multiple DNA fragments (up to 480 fragments) from 96 samples in parallel for each run. It increases output and reduces cost dramatically compared with classical DGGE, without sacrificing sensitivity and accuracy in detecting mutations. This protocol details an accurate, fast, nonradioactive and cost-effective way to screen the BRCA1 gene for mutations with high sensitivity, providing easily interpreted results. It may also be adapted to screen other target genes and/or used in large-scale epidemiological studies.     

Analysis and frequency of bovine lymphocyte antigen (BoLA-DRB3) alleles in Iranian Holstein cattle

The bovine lymphocyte antigen (BoLA-DRB3) gene encodes cell surface glycoproteins that initiate immune response by presenting processed antigenic peptides to CD4 T helper cells. DRB3 is the most polymorphic bovine MHC class II gene which encodes the peptide-binding groove. DRB3 gene has been extensively evaluated as a candidate marker for association with various bovine diseases and immunological traits. This study describes genetic variability in the BoLA-DRB3 in Iranian Holstein cattle. This is the first study of the DNA polymorphism of the BoLA-DRB3 gene in Iranian Holstein cattle. Hemi-nested PCR-RFLP method is used for identification the frequency of BoLA-DRB3 alleles. The BoLA-DRB3 locus is highly polymorphic in the studied herd (26 alleles). Almost 67% of the alleles were accounted for four alleles (BoLA-DRB3.2*8, *24, *11 and *16) in Iranian Holstein cattle. The DRB3.2*8 allele frequency (26.6%) was higher than the others. The frequencies of the DRB3.2*54, *37, *36, *28, *25, *14, *13, *10, *1 alleles were lower than 1%. Significant distinctions have been found between Iranian Holstein cattle and other cattle breeds studied. In Iranian Holstein cattle the alleles (BoLA-DRB3.2*22, *2 and *16) associated with a lower risk of cystic ovarian disease in Holstein cattle are found. The alleles associated with the resistance to mastitis and to bovine leukemia virus infection BoLA-DRB3.2*11 and *23 are detected with the frequencies 10.4% and 4.4%, respectively. Thus in the Iranian Holstein cows studied are found alleles which are associated with resistance to various diseases. The method of DNA-typing of animals can be used in agricultural practice for BoLA-DRB3 allele genotyping of cattle in order to reduce spreading of alleles providing susceptibility to mastitis or leukemia in cattle herds.     

变性梯度凝胶电泳(DGGE)在微生物生态学中的应用

由于从环境样品中分离和培养细菌的困难,分子生物学方法已发展用来描述和鉴定微生物群落。近年来基于DNA方法的群落分析得到了迅速的发展,如PCR扩增技术,克隆文库法,荧光原位杂交法,限制性酶切片段长度多态性法,变性和温度梯度凝胶电泳法。DGGE已广泛用于分析自然环境中细菌、蓝细菌,古菌、微微型真核生物、真核生物和病毒群落的生物多样性。这一技术能够提供群落中优势种类信息和同时分析多个样品。具有可重复和容易操作等特点,适合于调查种群的时空变化,并且可通过对切下的带进行序列分析或与特异性探针杂交分析鉴定群落成员。DGGE分析微生物群落的一般步骤如下：一是核酸的提取,二是16S rRNA,18S rRNA或功能基因如可容性甲烷加单氧酶羟化酶基因(mmoX)和氨加单氧酶a一亚单位基因(amoA)片段的扩增,三是通过DGGE分析PCR产物。DGGE使用具有化学变性剂梯度的聚丙烯酰胺凝胶,该凝胶能够有区别的解链PCR扩增产物。由PCR产生的不同的DNA片段长度相同但核苷酸序列不同。因此不同的双链DNA片段由于沿着化学梯度的不同解链行为将在凝胶的不同位置上停止迁移。DNA解链行为的不同导致一个凝胶带图案,该图案是微生物群落中主要种类的一个轮廓。DGGE使用所有生物中保守的基因片段如细菌中的16S rRNA基因片段和真菌中的18S rRNA基因片段。然而同其他分子生物学方法一样,DGGE也有缺陷,其中之一是只能分离较小的片段,使用于系统发育分析比较和探针设计的序列信息量受到了限制。在某些情况下,由于所用基因的多拷贝导致一个种类多于一条带,因此不易鉴定群落结构到种的水平。此外,该技术具有内在的如单一细菌种类16S rDNA拷贝之间的异质性问题,可导致自然群落中微生物数量的过多估计。DGGE是分析微生物群落的一种有力的工具。不过为了减少DGGE和其它技术的缺陷,建议研究者结合DGGE和其它分子及微生物学方法以便更详细的观察微生物的群落结构和功能。     

Genetic markers of adaptive processes in the Far Eastern pink salmon <Emphasis Type="Italic">Oncorhynchus gorbuscha</Emphasis>: Allelic diversity at the locus of major histocompatibility complex MHC I-<Emphasis Type="Italic">A1</Emphasis>

To clarify allelic diversity at the locus of major histocompatibility complex MHC class I-A1 in the Far Eastern pink salmon Oncorhynchus gorbuscha, sequencing of the electrophoretic alleles isolated from the gel (DGGE alleles) was performed. In 47 individuals, the genotypes of which consisted of ten DGGE alleles, 18 MHC I-A1 nucleotide sequences were revealed, and thus, eight cryptic alleles not detected by electrophoresis were identified. Eleven of these alleles were identified earlier in pink salmon from Hokkaido, Alaska, and British Columbia, and seven, possibly, were unique to the populations from some Far Eastern regions. Six of the previously determined DGGE alleles corresponded to more than one nucleotide sequence. However, the sequences attributed to the same DGGE allele differed on average by less than 1 nucleotide. These findings point to sufficient sensitivity of the DGGE method, although the genetic diversity and differentiation estimates obtained with it will obviously be somewhat underestimated. Considerable predominance of nonsynonymous substitutions over the synonymous ones in the codons of the MHC I-A1 antigen-binding site confirms the presence of positive selection aimed at providing the population resistance to local spectrum of pathogens. Refinement of the allelic composition of the adaptively important MHC genetic marker will contribute to more complete understanding of the adaptive genetic structure of pink salmon as an important element of the overall population structure of the species.     

Changes in fecal microbiota of healthy dogs administered amoxicillin

The effect of oral amoxicillin treatment on fecal microbiota of seven healthy adult dogs was determined with a focus on the prevalence of bacterial antibiotic resistance and changes in predominant bacterial populations. After 4–7 days of exposure to amoxicillin, fecal Escherichia coli expressed resistance to multiple antibiotics when compared with the pre-exposure situation. Two weeks postexposure, the susceptibility pattern had returned to pre-exposure levels in most dogs. A shift in bacterial populations was confirmed by molecular fingerprinting of fecal bacterial populations using denaturing gradient gel electrophoresis (PCR-DGGE) of the 16S V3 rRNA gene region. Much of the variation in DGGE profiles could be attributed to dog-specific factors. However, permutation tests indicated that amoxicillin exposure significantly affected the DGGE profiles after controlling for the dog effect ( P =0.02), and pre-exposure samples were clearly separated from postexposure samples. Sequence analysis of DGGE bands and real-time PCR quantification indicated that amoxicillin exposure caused a shift in the intestinal ecological balance toward a Gram-negative microbiota including resistant species in the family Enterobacteriaceae .     

红树林土壤细菌群落16S rDNA V3片段PCR产物的DGGE分析

从土壤中抽提微生物总DNA ,直接扩增 16SrDNAV3片段 ,应用变性梯度凝胶电泳 (DGGE)和分子克隆技术分析 16SrDNAV3片段的多态性 ,发现地域因素和红树品种都是影响土壤细菌群落结构的因素。通过对杯萼海桑土壤 16SrDNAV3片段PCR产物两个DGGE条带进行分子克隆、序列测定和Blast分析 ,发现每个DGGE条带包含着许多不同的 16SrDNAV3片段 ,并且其中多数为NCBI未收录的序列。这表明DGGE和克隆技术相结合的方法是研究土壤微生物群落结构的一种可行方法。     

Detection of DNA sequence polymorphisms in human genomic DNA by using denaturing gradient gel blots.

Denaturing gradient gel electrophoresis can detect sequence differences outside restriction-enzyme recognition sites. DNA sequence polymorphisms can be detected as restriction-fragment melting polymorphisms (RFMPs) in genomic DNA by using blots made from denaturing gradient gels. In contrast to the use of Southern blots to find sequence differences, denaturing gradient gel blots can detect differences almost anywhere, not just at 4-6-bp restriction-enzyme recognition sites. Human genomic DNA was digested with one of several randomly selected 4-bp recognition-site restriction enzymes, electrophoresed in denaturing gradient gels, and transferred to nylon membranes. The blots were hybridized with radioactive probes prepared from the factor VIII, type II collagen, insulin receptor, beta 2-adrenergic receptor, and 21-hydroxylase genes; in unrelated individuals, several RFMPs were found in fragments from every locus tested. No restriction map or sequence information was used to detect RFMPs. RFMPs can be used as genetic markers, because their alleles segregate in a Mendelian manner. Unlike most other methods for detecting DNA sequence polymorphisms, a genomic DNA blot made from one gel can be hybridized consecutively with many (30 or more) different probes.     

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.