Cost-effective method to synthesize a fluorescent internal DNA standard for automated fragment sizing.

We describe a simple and cost-effective method for the synthesis of an internal fluorescently labeled DNA standard for fragment sizing using an automated DNA sequencer. A set of primer pairs labeled with ROX was developed to amplify 12 DNA fragments, 58-417 bp, derived from a conserved region of plant chloroplast DNA. These amplified fragments were mixed together, constituting a fluorescent internal DNA size marker. The precision of the size standard was evaluated by estimating the size of 20 alleles that were amplified at four dinucleotide microsatellite loci with the synthesized size standard and the commercial internal sizing standard, GeneScan Rox500. A number of intra-gel and inter-gel comparisons were run, and an analysis of variance was carried out. No significant difference was observed between the size estimates obtained with the synthesized DNA standard and the commercial standard. This facile and general PCR-based method for the synthesis of internal standards allows for significant savings in the implementation of large genotyping experiments using microsatellite or AFLP markers.     

Establishment of the Amplified Fragment Length Polymorphism (AFLP) technique for genotyping of pollen beetle (Meligethes aeneus) - a noxious insect pest on oilseed rape (Brassica napus)

In order to conduct studies concerning genetic variability of pollen beetles (Meligethes aeneus), a genotyping protocol was established. No genome information is available for pollen beetles so the amplified fragment length polymorphism (AFLP) technique was chosen since it does not depend on any prior sequence information of the samples and also is a sensitive and robust technique. However, several modifications were needed in order to adapt the method for analysis of pollen beetles. Basic modifications included (i) alterations of DNA purification, (ii) use of two six-cutter restriction enzymes, (iii) and modified PCR conditions. This protocol resulted in a favourable number of fragments of an appropriate size range for standard gel analysis by a DNA sequencer applicable to a single insect and even body parts enabling different assays to be conducted on a single specimen. Pollen beetles from different areas of Sweden were analysed to verify the reproducibility and efficacy of the protocol as well as for phenetic analysis. The high reproducibility of the modified AFLP protocol allows it to be used as a reliable tool for genotype analysis of pollen beetles.     

Development of a fluorophore-ribosomal DNA restriction typing method for monitoring structural shifts of microbial communities

DNA restriction fragment polymorphism technologies such as amplified ribosomal DNA restriction analysis (ARDRA) and terminal restriction fragment length polymorphism (T-RFLP) have been widely used in investigating microbial community structures. However, these methods are limited due to either the low resolution or sensitivity. In this study, a fluorophore-ribosomal DNA restriction typing (f-DRT) approach is developed for structural profiling of microbial communities. 16S rRNA genes are amplified from the community DNA and digested by a single restriction enzyme Msp I. All restriction fragments are end-labeled with a fluorescent nucleotide Cy5-dCTP via a one-step extension reaction and detected with an automated DNA sequencer. All 50 predicted restriction fragments between 100 and 600 bp were detected when twelve single 16S rRNA gene sequences were analyzed using f-DRT approach; 92% of these fragments were determined with accuracy of ±2 bp. In the defined model communities containing five components with different ratios, relative abundance of each component was correctly revealed by this method. The f-DRT analysis also showed structural shifts of intestinal microbiota in carcinogen-treated rats during the formation of precancerous lesions in the colon, as sensitive as multiple digestion-based T-RFLP analysis. This study provides a labor and cost-saving new method for monitoring structural shifts of microbial communities.     

PCR-based accurate synthesis of long DNA sequences

Here we describe a simple and rapid method for assembly and PCR-based accurate synthesis (PAS) of long DNA sequences. The PAS protocol involves the following five steps: (i) design of the DNA sequence to be synthesized and of 60-bp overlapping oligonucleotides to cover the entire DNA sequence; (ii) purification of the oligonucleotides by PAGE; (iii) first PCR, to synthesize DNA fragments of 400-500 bp in length using 10 inner (template) and two outer (primer) oligonucleotides; (iv) second PCR, to assemble the products of the first PCR into the full-length DNA sequence; and (v) cloning and verification of the synthetic DNA by sequencing and, if needed, error correction using an overlap-extension PCR technique. This method, which takes approximately 1 wk, is suitable for synthesizing diverse types of long DNA molecule. We have successfully synthesized DNA fragments from 0.5 to 12.0 kb, with high G+C content, repetitive sequences or complex secondary structures. The PAS protocol therefore provides a simple, rapid, reliable and relatively inexpensive method for synthesizing long, accurate DNA sequences.     

Analysis and purification of nucleic acids by ion-pair reversed-phase high-performance liquid chromatography

Sizing of DNA fragments is a routine analysis traditionally performed on agarose or polyacrylamide gels. Electrophoretic analysis is labor-intensive with only limited potential for automation. Recovery of DNA fragments from gels is cumbersome. We present data on automated, size-based separation of DNA fragments by ion-pair reversed-phase high performance liquid chromatography (IP RP HPLC) - DNA chromatography - on the WAVE DNA Fragment Analysis System with the DNASep cartridge. This system is suitable for accurate and rapid sizing of double-stranded (ds) DNA fragments from 50 to ca. 2000 base pairs (bp). Fluorescently labeled DNA fragments are compatible with the technology. Length-dependent separation of dsDNA fragments is sequence independent and retention times are highly reproducible. The resolving capabilities of DNA chromatography are illustrated by the analysis of multiple DNA size markers. Resolved dsDNA fragments are easily collected and are suitable for downstream applications such as sequencing and cloning. DNA chromatography under denaturing conditions with fluorescently labeled DNA fragments offers a means for the separation and purification of individual strands of dsDNA. Analysis of DNA fragments on the WAVE System is highly automated and requires minimal manual intervention. DNA chromatography offers a reliable and automated alternative to gel electrophoresis for the analysis of DNA fragments.     

微卫星复杂结构对分型的影响：以熊UamD116 和UamB1 为例

目的:微卫星是基因组上的短串联重复序列,具有高度多态性,表现为核心序列中重复单位的重复次数的变化,这种变化造成不同等位基因核心序列的长度不同。因此,其基因型主要依靠PCR扩增片段长度来判定。在各类研究中,人们更倾向于使用4碱基重复的微卫星以减少2碱基微卫星的stutter等问题的影响。但是4碱基微卫星核心序列结构复杂时,就会对分型的正确性产生影响,从而影响到下游分析的正确性。在很多野生动物的研究中,这一问题常常被忽略。本文以亚洲黑熊(Ursus thibetanus)的2个四碱基微卫星位点UamD116和UamB1为例,揭示内部结构对分型的影响。方法:我们选用96份亚洲黑熊样品(包括血液、肌肉组织和毛发等样品)进行微卫星分型研究,通过荧光标记的PCR扩增和毛细管电泳分型,比较了基于扩增片段长度的分型和基于序列核心结构的分型效果的差异。结果:UamD116核心序列结构除了含有多种不同的重复单位外,还在重复单位之间有碱基插入,出现单碱基T、二碱基TC和三碱基AAG插入;并在一类等位基因下游侧翼序列有1个GA缺失。基于序列结构的分型中可以将不同的等位基因分开,而在基于片段长度的分型中,容易将不同的等位基因合并为1个等位基因。在位点UamB1共发现两种类型的等位基因,在一类等位基因中出现一个3bp的插入,使等位基因之间的差异不再是4bp,而是1bp。在仅依据片段长度分型时,相差1bp的等位基因被认定为1个。此外,还有不同等位基因核心序列不同,但是二者长度完全一致。依据片段长度分型共发现8个等位基因,而经过序列分型确定的等位基因数为12个,相应地基因频率及其他遗传学参数都发生相应的改变。结论:对于核心序列结构复杂的微卫星必须通过等位基因测序来矫正片段长度分型的结果,才能得到可靠的群体遗传学结论。     

Multiplex-terminal restriction fragment length polymorphism

A novel method called "multiplex-terminal restriction fragment length polymorphism (M-TRFLP)" has been recently developed which can be used for simultaneous analysis of the community composition of two or more microbial taxa (up to four). This method can also be used for microbial diagnostic purposes. For M-TRFLP analysis, primers specific to different target genes are used for multiplex-PCR, with one primer for each target being labeled with a unique fluorescent dye at its 5' end. Restriction digestion of the amplified products followed by fragment size analysis on a DNA sequencer produces profiles for targeted genes, which can be distinguished from each other by the color of the terminal fragments imparted by the unique fluorescent dye used for primer labeling. In contrast to current protocols, M-TRFLP allows multiple communities or multiple targets (genes) data to be obtained in just one reaction and therefore saves time, cost and labor. This protocol can be completed in 5-8 h.     

Computer-aided high-throughput cloning of bacteria in liquid medium

Bacterial cloning was first introduced over a century ago and has since become one of the most useful procedures in biological research, perhaps paralleled in its ubiquity only by PCR and DNA sequencing. However, unlike PCR and sequencing, cloning has generally remained a manual, labor-intensive, low-throughput procedure. Here we address this issue by developing an automated, computer-aided bacterial cloning method using liquid medium that is based on the principles of (i) limiting dilution of bacteria, (ii) inference of colony forming units (CFUs) based on optical density (OD) readings, and (iii) verification of monoclonality using a mixture of differently colored fluorescently labeled bacteria for transformation. We demonstrate the high-throughput utility of this method by employing it as a cloning platform for a DNA synthesis process.     

Portable System for Microbial Sample Preparation and Oligonucleotide Microarray Analysis

We have developed a three-component system for microbial identification that consists of (i) a universal syringe-operated silica minicolumn for successive DNA and RNA isolation, fractionation, fragmentation, fluorescent labeling, and removal of excess free label and short oligonucleotides; (ii) microarrays of immobilized oligonucleotide probes for 16S rRNA identification; and (iii) a portable battery-powered device for imaging the hybridization of fluorescently labeled RNA fragments with the arrays. The minicolumn combines a guanidine thiocyanate method of nucleic acid isolation with a newly developed hydroxyl radical-based technique for DNA and RNA labeling and fragmentation. DNA and RNA can also be fractionated through differential binding of double- and single-stranded forms of nucleic acids to the silica. The procedure involves sequential washing of the column with different solutions. No vacuum filtration steps, phenol extraction, or centrifugation is required. After hybridization, the overall fluorescence pattern is captured as a digital image or as a Polaroid photo. This three-component system was used to discriminate Escherichia coli, Bacillus subtilis, Bacillus thuringiensis, and human HL60 cells. The procedure is rapid: beginning with whole cells, it takes approximately 25 min to obtain labeled DNA and RNA samples and an additional 25 min to hybridize and acquire the microarray image using a stationary image analysis system or the portable imager.     

Portable system for microbial sample preparation and oligonucleotide microarray analysis

We have developed a three-component system for microbial identification that consists of (i) a universal syringe-operated silica minicolumn for successive DNA and RNA isolation, fractionation, fragmentation, fluorescent labeling, and removal of excess free label and short oligonucleotides; (ii) microarrays of immobilized oligonucleotide probes for 16S rRNA identification; and (iii) a portable battery-powered device for imaging the hybridization of fluorescently labeled RNA fragments with the arrays. The minicolumn combines a guanidine thiocyanate method of nucleic acid isolation with a newly developed hydroxyl radical-based technique for DNA and RNA labeling and fragmentation. DNA and RNA can also be fractionated through differential binding of double- and single-stranded forms of nucleic acids to the silica. The procedure involves sequential washing of the column with different solutions. No vacuum filtration steps, phenol extraction, or centrifugation is required. After hybridization, the overall fluorescence pattern is captured as a digital image or as a Polaroid photo. This three-component system was used to discriminate Escherichia coli, Bacillus subtilis, Bacillus thuringiensis, and human HL60 cells. The procedure is rapid: beginning with whole cells, it takes approximately 25 min to obtain labeled DNA and RNA samples and an additional 25 min to hybridize and acquire the microarray image using a stationary image analysis system or the portable imager.     

Genomic typing of Escherichia coli O157:H7 by semi-automated fluorescent AFLP analysis

Escherichia coli serotype O157:H7 isolates were analyzed using a relatively new DNA fingerprinting method, amplified fragment length polymorphism (AFLP). Total genomic DNA was digested with two restriction endonucleases (EcoRI and MseI), and compatible oligonucleotide adapters were ligated to the ends of the resulting DNA fragments. Subsets of fragments from the total pool of cleaved DNA were then amplified by the polymerase chain reaction (PCR) using selective primers that extended beyond the adapter and restriction site sequences. One of the primers from each set was labeled with a fluorescent dye, which enabled amplified fragments to be detected and sized automatically on an automated DNA sequencer. Three AFLP primer sets generated a total of thirty-seven unique genotypes among the 48 E. coli O157:H7 isolates tested. Prior fingerprinting analysis of large restriction fragments from these same isolates by pulsed-field gel electrophoresis (PFGE) resulted in only 21 unique DNA profiles. Also, AFLP fingerprinting was successful for one DNA sample that was not typable by PFGE, presumably because of template degradation. AFLP analysis, therefore, provided greater genetic resolution and was less sensitive to DNA quality than PFGE. Consequently, this DNA typing technology should be very useful for genetic subtyping of bacterial pathogens in epidemiologic studies.     

Effect of DNA length on the nucleosome low salt transition.

The effect of DNA length on the low salt unfolding transition of nucleosomes has been studied by the use of fluorescently labeled histones. Nucleosomes were formed by the reconstitution of bulk DNA fragments averaging 173 and 250 base pairs in length. These nucleosomes exhibited a conformational change in a transition centered at about 7 mM ionic strength, very different from that observed for the standard 145 bp nucleosomes (1-3mM). In addition, the conformational change of the 173 and 250 bp nucleosomes involves twice as many ions as that of the 145 bp nucleosomes.     

A heteroduplex method for detection of targeted sub-populations of bacterial communities

We describe a simple method, based on heteroduplex mobility analysis of 16S rDNA fragments, for targeted detection of sub-populations of bacteria within diverse microbial communities. A small (ca. 200 bp) polymorphic fragment of the bacterial 16S rRNA gene was amplified from sample DNA using universal primers. Sample products were hybridised with a fluorescently labelled fragment amplified from a selected 'reporter' organism representing the target group. The resulting products were resolved and the labelled heteroduplex pairs detected on non-denaturing gels using automated DNA detection technology. A model, based on analysis of samples with known 16S rDNA sequences, demonstrates that heteroduplex mobility is inversely correlated with genetic distance and that beyond 26% genetic difference, heteroduplex products are not detected. The utility of the method was tested by field studies in which stream biofilms could be characterised by heteroduplex profiles generated with heterotrophic and autotrophic reporter organisms representing target groups.     

Multicolour fluorescent detection and mapping of AFLP markers in chicken (Gallus domesticus)

We describe the mapping of amplified restriction fragment polymorphism (AFLP) markers in chicken (Gallus domesticus) using a multi-colour fluorescent detection system. DNA was used from a population consisting of four families with a total of 183 F2 individuals. The enzyme combination EcoRI/TaqI was used for double digestion, and fluorescently labelled fragments were analysed on an ABI PRISM 377 DNA sequencer. Polymorphic signals in the range of 50-500 bp were genotyped with the ABI PRISM Genotyper 2.0 software, which enabled the analysis of both dominant and incomplete dominant markers (with respect to AFLP, often referred to as codominant). In 19 sets consisting of 3 EcoRI/TaqI primer pair combinations each, a total of 475 polymorphic markers was detected. From these polymorphisms 344 markers could be mapped on the Wageningen linkage map. Fourteen markers were length polymorphisms of the same fragment and 28 markers Z-linked and uniformative; 64 AFLP markers appeared to be unlinked and 25 AFLP markers could not be accurately mapped on the basis of the genotyping results. The resulting AFLP/microsatellite linkage map is comprised of 33 linkage groups with a total of 835 loci.     

Rapid DNA sequencing based upon single molecule detection

We are developing a laser-based technique for the rapid sequencing of 40-kb or larger fragments of DNA at a rate of 100 to 1000 bases per second. The approach relies on fluorescent labeling of the bases in a single fragment of DNA, attachment of this labeled DNA fragment to a support, movement of the supported DNA fragment into a flowing sample stream, and detection of individual fluorescently labeled bases as they are cleaved from the DNA fragment by an exonuclease. The ability to sequence large fragments of DNA will significantly reduce the amount of subcloning and the number of overlapping sequences required to assemble megabase segments of sequence information.     

Two-dimensional conformation-dependent electrophoresis (2D-CDE) to separate DNA fragments containing unmatched bulge from complex DNA samples

DNA fragments containing mispaired and modified bases, bulges, lesions and specific sequences have altered conformation. Methods for separating complex samples of DNA fragments based on conformation but independent of length have many applications, including (i) separation of mismatched or unmatched DNA fragments from those perfectly matched; (ii) simultaneous, diagnostic, mismatch scanning of multiple fragments; (iii) isolation of damaged DNA fragments from undamaged fragments; and (iv) estimation of reannealing efficiency of complex DNA samples. We developed a two-dimensional conformation-dependent electrophoresis (2D-CDE) method for separating DNA fragments based on length and conformation in the first dimension and only on length in the second dimension. Differences in migration velocity due to conformation were minimized during second dimension electrophoresis by introducing an intercalator. To test the method, we constructed 298 bp DNA fragments containing cytosine bulges ranging from 1 to 5 nt. Bulge-containing DNA fragments had reduced migration velocity in the first dimension due to altered conformation. After 2D-CDE, bulge-containing DNA fragments had migrated in front of an arc comprising heterogeneous fragments with regular conformation. This simple and robust method could be used in both analytical and preparative applications involving complex DNA samples.     

A method for evaluating the host range of bacteriophages using phages fluorescently labeled with 5-ethynyl-2′-deoxyuridine (EdU)

The evaluation of bacteriophage (phage) host range is a significant issue in understanding phage and prokaryotic community interactions. However, in conventional methods, such as plaque assay, target host strains must be isolated, although almost all environmental prokaryotes are recalcitrant to cultivation. Here, we introduce a novel phage host range evaluation method using fluorescently labeled phages (the FLP method), which consists of the following four steps: (i) Fluorescently labeled phages are added to a microbial consortium, and host cells are infected and fluorescently labeled. (ii) Fluorescent cells are sorted by fluorescence-activated cell sorting. (iii) 16S rRNA gene sequences retrieved from sorted cells are analyzed, and specific oligonucleotide probes for fluorescence in situ hybridization (FISH) are designed. (iv) Cells labeled with both fluorescently labeled phage and FISH probe are identified as host cells. To verify the feasibility of this method, we used T4 phage and Escherichia coli as a model. We first used nucleic acid stain reagents for phage labeling; however, the reagents also stained non-host cells. Next, we employed the Click-iT EdU (5-ethynyl-2'-deoxyuridine) assay kit from Invitrogen for phage labeling. Using EdU-labeled T4 phage, we could specifically detect E. coli cells in a complex microbial consortium from municipal sewage. We also confirmed that FISH could be applied to the infected E. coli cells. These results suggest that this FLP method using the EdU assay kit is a useful method for evaluating phage host range and may have a potential application for various types of phages, even if their prokaryotic hosts are currently unculturable.     

Identification of Salmonella abortusovis by PCR amplification of a serovar-specific IS200 element.

Field and collection isolates of Salmonella abortusovis carry one IS200 element in a distinct chromosome location. IS200 is not found in the corresponding region of the chromosome of other Salmonella serovars. Sequencing of the boundaries of the S. abortusovis-specific IS200 insertion permitted the design of primers for the amplification of this IS200 element by PCR. Isolates of S. abortusovis are identified by the amplification of a DNA fragment of about 900 bp or larger. PCR amplification of DNA from salmonellae other than S. abortusovis yields either a fragment of about 200 bp or no product. The high specificity of the assay is confirmed by the absence of cross-reactivity with the following templates: (i) sheep DNA, (ii) DNAs from abortion-causing agents other than S. abortusovis, and (iii) DNAs from microorganisms that do not cause abortion but are common in flocks.     

Multiple topological labeling for imaging single plasmids

Sequence-specific labeling methods for double-stranded DNA are required for mapping protein binding sites or specific DNA structures on circular DNA molecules by high-resolution imaging techniques such as electron and atomic force microscopies. Site-specific labeling can be achieved by ligating a DNA fragment to a stem-loop-triplex-forming oligonucleotide, thereby forming a topologically linked complex. The superhelicity of the plasmid is not altered and the process can be applied to two different target sites simultaneously, using DNA fragments of different sizes. Observation of the labeled plasmids by electron microscopy revealed that, under conditions where the triple helices were stable, the two labels were located at 339+/-34 bp from one another, in agreement with the distance between the two target sequences for triple helix formation (350 bp). Under conditions where the triple helices were not stable, the short DNA fragments could slide away from their target site. The concomitant attachment of two different stable labels makes it possible, for the first time to our knowledge, to label a circular DNA molecule and obtain information on its direction. In addition to its potential applications as a tool for structural investigations of single DNA molecules and their interactions with proteins, this DNA labeling method may also prove useful in biotechnology and gene therapy.