Sequential chemiluminescent detection of target DNAs without stripping and reprobing.

We present a simple method for sequential chemiluminescent detections of two different DNA loci on a single Southern blot. First, an enzyme-linked DNA probe for a unique sequence is detected with a horse-radish peroxidase (HRP) substrate followed by the detection of another enzyme-linked DNA probe for a different unique sequence with an alkaline phosphatase (AP) substrate that simultaneously inhibits the chemiluminescence generated by HRP. Such sequential detection steps eliminate the need to strip and reprobe blots and can be performed with no intervening steps.     

Transverse formamide gradients as a simple and easy way to optimise DNA single-strand conformation polymorphism analysis.

Although widely used, the detection of DNA mutations by the single-strand conformation polymorphism (SSCP) method is often hampered by the need to examine a large set of electrophoretic conditions in order to select the one suited to the DNA sequence under study. We show here that the use of transverse chemical gradient gels allows for a quick and easy optimisation of SSCP analysis, as exemplified on two mutations in exon 2 of the alpha-1-antitrypsin gene.     

Poly(A) cDNA-specific (PACS) RT-PCR: a quantitative method for the measurement of any poly(A)-containing mRNA not affected by contaminating genomic DNA

We present a simple and efficient RT-PCR method for the detection and quantitation of any poly(A)-containing mRNA that is not affected by contaminating genomic DNA and does not rely on exhaustive DNase digestion protocols. The technique described here requires the use of an antisense primer designed to contain 6-8 bp cDNA-specific sequence and an additional 17 Ts located on the 5' end to take advantage of the poly(A) tail. A second cDNA-specific sense primer can be used that does not need to be separated by intronic DNA sequence.     

小麦印度腥黑穗病菌和黑麦草腥黑粉菌检测标准分子构建

以小麦印度腥黑穗病菌和黑麦草腥黑粉菌为研究对象,采用分子克隆技术,分别构建了该两种真菌分子检测的标准分子。前者包括线粒体2297 bp的DNA序列以及rDNA710 bp的ITS序列,后者包括线粒体2.3kb的DNA序列以及rDNA710 bp的ITS序列。分别对该两个标准分子进行了性能评估试验,测试结果显示所构建的标准分子具有良好的特异性、均匀性和稳定性,能够满足小麦印度腥黑穗病菌和黑麦草腥黑粉菌分子检测需求。     

Direct DNA extraction for PCR-mediated assays of soil organisms.

By using the rDNA of a plant wilt pathogen (Verticillium dahliae) as the target sequence, a direct method for the extraction of DNA from soil samples which can be used for PCR-mediated diagnostics without a need for further DNA purification has been developed. The soil organisms are disrupted by grinding in liquid nitrogen with the natural abrasives in soil, and losses due to degradation and adsorption are largely eliminated by the addition of skim milk powder. The DNA from disrupted cells is extracted with sodium dodecyl sulfate-phenol and collected by ethanol precipitation. After suitable dilution, this DNA extract can be assayed directly by PCR amplification technologies. The method is rapid, cost efficient, and when combined with suitable internal controls can be applied to the detection and quantification of specific soil organisms or pathogens on a large-scale basis.     

A one-step electrochemical method for DNA detection that utilizes a peroxidase-mimicking DNAzyme amplified through PCR of target DNA

A novel one-step electrochemical method for DNA detection is described. The procedure utilizes a reaction catalyzed by a peroxidase-mimicking DNAzyme to produce a product, which forms an insoluble precipitation layer on the surface of an electrode. A rationally designed forward primer, conjugated with a peroxidase DNAzyme complementary sequence at its 5′-end, is used for PCR amplification of target DNA. As a result, the DNAzyme sequence is produced by amplification only when the target DNA is present in the sample. The PCR product is then subjected to the precipitation reaction on the electrode surface using an electrolyte assay buffer containing 4-chloronaphthol, hydrogen peroxide, ferrocenemethanol, hemin, and 5′-lambdaexonuclease. Finally, analysis is carried out using Faradaic impedance spectroscopy. The impedance value was found to greatly increase when target DNA is present owing to the formation of a precipitation layer on the electrode surface caused by the catalytic action of the DNAzyme. In contrast, no impedance increase is observed when a control sample not containing target DNA is utilized. By employing this strategy, target DNA from Chlamydia trachomatis was reliably detected within a 10 min period following precipitation without the need for complicated secondary procedures. This effort has led to the development of a highly convenient electrochemical one-step method for DNA detection that utilizes a peroxidase-mimicking DNAzyme, which is specifically designed to undergo amplification during PCR of target DNA.     

Mutation detection by pyrosequencing: sequencing of exons 5-8 of the p53 tumor suppressor gene

The ability to sequence a large number of DNA samples rapidly and accurately for detection of all possible mutations is a critical goal for the future application of DNA sequencing in routine medical diagnostics. Pyrosequencing() is a non-electrophoretic real-time DNA sequencing method that uses the luciferase-luciferin light release as the detection signal for nucleotide incorporation into target DNA. For pyrosequencing of the human p53 gene, a nested multiplex PCR method for amplification of exons 5-8 was prepared. In order to investigate the use of pyrosequencing in mutation detection, DNA samples from skin-cancer patients were used. Two forms of nucleotide dispensation strategy were used, cyclic and programmed. Bi-directional pyrosequencing was performed and the overlapping sequence data produced were assembled to determine the sequence of the gene. Reliable sequencing data were obtained with both dispensation strategies, but some advantages were obtained using the programmed nucleotide dispensation approach, such as longer and faster reads, and fewer out-of-phase problems. The accuracy of pyrosequencing for detection of p53 mutations and allele distribution was demonstrated.     

Molecular beacons for DNA biosensors with micrometer to submicrometer dimensions

Ultrasensitive molecular beacon (MB) DNA biosensors, with micrometer to submicrometer sizes, have been developed for DNA/RNA analysis. The fluorescence-based biosensors have been applied in DNA/ RNA detection without the need for a dye-labeled target molecule or an intercalation reagent in the testing solution. Molecular beacons are hairpin-shaped oligonucleotides that report the presence of specific nucleic acids. We have designed a surface-immobilizable biotinylated ssDNA molecular beacon for DNA hybridization at a liquid-solid interface. The MBs have been immobilized onto ultrasmall optical fiber probes through avidin-biotin binding. The MB DNA biosensor has been used directly to detect, in real time, its target DNA molecules without the need for a competitive assay. The biosensor is stable and reproducible. The MB DNA biosensor has selectivity with single base-pair mismatch identification capability. The concentration detection limits and mass detection limits are 0.3 nM and 15 amol for a 105-microm biosensor, and 10 nM and 0.27 amol for a submicrometer biosensor, respectively. We have also prepared molecular beacon DNA biosensor arrays for simultaneous analysis of multiple DNA sequences in the same solution. The newly developed DNA biosensors have been used for the precise quantification of a specific rat gamma-actin mRNA sequence amplified by the polymerase chain reaction.     

A universal platform for sensitive and selective colorimetric DNA detection based on Exo III assisted signal amplification

Rapid growth of available sequence data has made the detection of nucleic acids critical to the development of modern life sciences. Many amplification methods based on gold nanoparticles and endonuclease for sensitive DNA detection have been developed. However, these approaches require specific target sequence for endonuclease recognition, which cannot be fulfilled in all systems. Replacing the restriction enzyme with a nuclease that does not require any specific recognition sequence may offer a universally adaptable system. Here we have developed a novel homogeneous, colorimetric DNA detection method, which consists of Exo III, a linker DNA, and two DNA-modified gold nanoparticles. This system is simple, low-cost, sensitive and selective. By coupling cyclic enzymatic cleavage and gold nanoparticle for signal amplification, our system provides a colorimetric detection limit of 15 pM, which is 3 orders of magnitude more sensitive than that of a general three-component sandwich assay format. Due to the intrinsic property of Exo III, our method shows excellent detection selectivity for single-base discrimination. More importantly, superior to other methods based on nicking and FokI endonuclease, our target sequence-independent platform is generally applicable for DNA sensing. This new approach could be widely applied to sensitive nucleic acids detection.     

An autonomously self-assembling dendritic DNA nanostructure for target DNA detection

There is a growing need for sensitive and reliable nucleic acid detection methods that are convenient and inexpensive. Responsive and programmable DNA nanostructures have shown great promise as chemical detection systems. Here, we describe a DNA detection system employing the triggered self-assembly of a novel DNA dendritic nanostructure. The detection protocol is executed autonomously without external intervention. Detection begins when a specific, single-stranded target DNA strand (T) triggers a hybridization chain reaction (HCR) between two, distinct DNA hairpins (α and β). Each hairpin opens and hybridizes up to two copies of the other. In the absence of T, α and β are stable and remain in their poised, closed-hairpin form. In the presence of T, α hairpins are opened by toe-hold mediated strand-displacement, each of which then opens and hybridizes two β hairpins. Likewise, each opened β hairpin can open and hybridize two α hairpins. Hence, each layer of the growing dendritic nanostructure can in principle accommodate an exponentially increasing number of cognate molecules, generating a high molecular weight nanostructure. This HCR system has minimal sequence constraints, allowing reconfiguration for the detection of arbitrary target sequences. Here, we demonstrate detection of unique sequence identifiers of HIV and Chlamydia pathogens.     

An efficient strategy for broad-range detection of low abundance bacteria without DNA decontamination of PCR reagents

Background

Bacterial DNA contamination in PCR reagents has been a long standing problem that hampers the adoption of broad-range PCR in clinical and applied microbiology, particularly in detection of low abundance bacteria. Although several DNA decontamination protocols have been reported, they all suffer from compromised PCR efficiency or detection limits. To date, no satisfactory solution has been found.

Methodology/Principal Findings

We herein describe a method that solves this long standing problem by employing a broad-range primer extension-PCR (PE-PCR) strategy that obviates the need for DNA decontamination. In this method, we first devise a fusion probe having a 3′-end complementary to the template bacterial sequence and a 5′-end non-bacterial tag sequence. We then hybridize the probes to template DNA, carry out primer extension and remove the excess probes using an optimized enzyme mix of Klenow DNA polymerase and exonuclease I. This strategy allows the templates to be distinguished from the PCR reagent contaminants and selectively amplified by PCR. To prove the concept, we spiked the PCR reagents with Staphylococcus aureus genomic DNA and applied PE-PCR to amplify template bacterial DNA. The spiking DNA neither interfered with template DNA amplification nor caused false positive of the reaction. Broad-range PE-PCR amplification of the 16S rRNA gene was also validated and minute quantities of template DNA (10–100 fg) were detectable without false positives. When adapting to real-time and high-resolution melting (HRM) analytical platforms, the unique melting profiles for the PE-PCR product can be used as the molecular fingerprints to further identify individual bacterial species.

Conclusions/Significance

Broad-range PE-PCR is simple, efficient, and completely obviates the need to decontaminate PCR reagents. When coupling with real-time and HRM analyses, it offers a new avenue for bacterial species identification with a limited source of bacterial DNA, making it suitable for use in clinical and applied microbiology laboratories.     

Direct detection of point mutations by mismatch analysis: application to haemophilia B.

Rapid detection of point mutations in genomic DNA has been achieved by chemical mismatch analysis of heteroduplexes formed between amplified wild-type and target sequences in the human factor IX gene. Amplification and mismatch detection (AMD) analysis of DNA from relatives of haemophilia B patients permitted carrier diagnosis by direct identification of the presence or absence of the mutation in all cases, thus eliminating the need for the informative segregation of polymorphic markers. This extends diagnostic capability to virtually all haemophilia B families. AMD analysis permits detection of all sequence variations in genomic DNA and is therefore applicable to direct diagnosis of X-linked and autosomal diseases and for identification of new polymorphisms for genetic mapping.     

Comparison of Methods of Detection of Exceptional Sequences in Prokaryotic Genomes

Many proteins need recognition of specific DNA sequences for functioning. The number of recognition sites and their distribution along the DNA might be of biological importance. For example, the number of restriction sites is often reduced in prokaryotic and phage genomes to decrease the probability of DNA cleavage by restriction endonucleases. We call a sequence an exceptional one if its frequency in a genome significantly differs from one predicted by some mathematical model. An exceptional sequence could be either under- or over-represented, depending on its frequency in comparison with the predicted one. Exceptional sequences could be considered biologically meaningful, for example, as targets of DNA-binding proteins or as parts of abundant repetitive elements. Several methods to predict frequency of a short sequence in a genome, based on actual frequencies of certain its subsequences, are used. The most popular are methods based on Markov chain models. But any rigorous comparison of the methods has not previously been performed. We compared three methods for the prediction of short sequence frequencies: the maximum-order Markov chain model-based method, the method that uses geometric mean of extended Markovian estimates, and the method that utilizes frequencies of all subsequences including discontiguous ones. We applied them to restriction sites in complete genomes of 2500 prokaryotic species and demonstrated that the results depend greatly on the method used: lists of 5% of the most under-represented sites differed by up to 50%. The method designed by Burge and coauthors in 1992, which utilizes all subsequences of the sequence, showed a higher precision than the other two methods both on prokaryotic genomes and randomly generated sequences after computational imitation of selective pressure. We propose this method as the first choice for detection of exceptional sequences in prokaryotic genomes.     

Detection of Erwinia amylovora by novel chromosomal polymerase chain reaction primers

A new sensitive and specific method for the detection of Erwinia amylovora was developed. The method is based on the detection of a chromosomal DNA sequence specific for this bacterial species and enables the detection of E. amylovora pathogenic strains, including the recent isolates that lack plasmid pEA29 and thus cannot be detected by the previously popular PCR methods based on the detection of this plasmid. Species-specific random amplified polymorphic DNA (RAPD) marker was identified, cloned, and sequenced, and sequence characterized amplified region (SCAR) primers for specific PCR were developed. The E. amylovora specific sequence, 1269 bp long, was amplified in polymerase chain reaction and detected with electrophoresis in agarose gel stained with ethidium bromide. Amplification with other bacterial species did not produce any PCR product detectable by electrophoresis. Belonging of the E. amylovora specific sequence to chromosomal DNA was confirmed by computer analysis of the E. amylovora genome. A consistent sensitivity limit of the method was 3 CFU/reaction, and in some cases it was possible to detect 0.6 CFU/reaction. Due to its high sensitivity and specificity, our method of E. amylovora detection is currently the most reliable, taking into account that the reliability of PCR methods based on plasmid pEA29 has been compromised by the isolation of pathogenic E. amylovora strains that lack this plasmid.     

Tag/hybridization-based sensitive detection of polymerase chain reaction products

The polymerase chain reaction (PCR) is an important technology to amplify a single copy or a few copies of DNA segment in genomic DNAs, visualizing the segment as DNA fragment. Thus, PCR is frequently used in various examinations such as detection of bacteria and fungi in the food industry. Here, we report a simple and sensitive method for detection of PCR products using single-strand tag sequence and hybridization of the tag sequence to the complementary tag sequence immobilized on solid material (STH). The detection sensitivity was found to be at least 50 times higher than electrophoresis/ethidium bromide (EtBr) visualization for approximately a 500-bp fragment and higher than the ordinary hybridization, that is, hybridization of denatured PCR product to probe sequence immobilized on solid material.     

Identification of Salmonella enterica subspecies I, Salmonella enterica serovars Typhimurium, Enteritidis and Typhi using multiplex PCR

This study was designed to develop a multiplex PCR method with five specific primer pairs for the detection of Salmonella spp., Salmonella subspecies I, Salmonella enterica serovars Typhimurium, Typhi and Enteritidis. A multiplex PCR was constructed with five primer pairs for the detection of Salmonella and pathogenic Salmonella serovars, including a specific primer pair for Salmonella Typhi, based on the sequence comparison between genomic DNA sequences of 12 Salmonella strains. Each primer pair was specifically targeted to Salmonella spp., Salmonella subspecies I, Salmonella Typhimurium, Typhi and Enteritidis. This multiplex PCR was evaluated with various DNAs of Salmonella serovars that yielded high specificity for amplifying the expected PCR products of Salmonella serovars. Using this primer pair, a set of multiplex PCR was performed for the rapid identification of salmonellae and major pathogenic Salmonella serovars. Although this multiplex PCR method will need to be evaluated for a wide range of Salmonella serovars among multilaboratories, it should be useful for identifying clinically significant strains of Salmonella serovars rapidly and accurately without the need for serological testing.     

Probabilistic divergence measures for detecting interspecies recombination

This paper proposes a graphical method for detecting interspecies recombination in multiple alignments of DNA sequences. A fixed-size window is moved along a given DNA sequence alignment. For every position, the marginal posterior probability over tree topologies is determined by means of a Markov chain Monte Carlo simulation. Two probabilistic divergence measures are plotted along the alignment, and are used to identify recombinant regions. The method is compared with established detection methods on a set of synthetic benchmark sequences and two real-world DNA sequence alignments.     

Application of the fluorogenic probe technique (TaqMan PCR) to the detection of Enterococcus spp. and Escherichia coli in water samples

A recent PCR detection technique (TaqMan) based on the 5'-3'-exonuclease activity of the Taq DNA polymerase was applied to the detection of indicator organisms in water samples. In this technique, an increasing fluorescence signal is measured online which enables direct assessment of results after PCR without additional detection steps. The test is completed within about 5 h. Two sets of primers and probes were designed and tested: a genus-specific assay for the detection of Enterococcus spp. based on 23S rRNA sequence and an Escherichia coli-specific assay based on the uidA gene sequence. Specificity of the assays was confirmed by testing strains of target bacteria and potential interfering microorganisms. Application of the tests to 55 natural water samples showed the need of an overnight enrichment step to achieve compliance with detection limits of existing regulations. Compared with a parallel microbiological examination of the samples, agreement was 96% with the Enterococcus assay and 98% with the E. coli assay. The rapidity and feasibility of the method point to benefits in drinking water analysis, particularly in emergency situations and, thus, to improved public health management.