PCR amplification of tandemly repeated DNA: analysis of intra- and interchromosomal sequence variation and homologous unequal crossing-over in human alpha satellite DNA.

Tandemly repeated DNA can comprise several percent of total genomic DNA in complex organisms and, in some instances, may play a role in chromosome structure or function. Alpha satellite DNA is the major family of tandemly repeated DNA found at the centromeres of all human and primate chromosomes. Each centromere is characterized by a large contiguous array of up to several thousand kb which can contain several thousand highly homogeneous repeat units. By using a novel application of the polymerase chain reaction (repPCR), we are able to amplify a representative sampling of multiple repetitive units simultaneously, allowing rapid analysis of chromosomal subsets. Direct sequence analysis of repPCR amplified alpha satellite from chromosomes 17 and X reveals positions of sequence heterogeneity as two bands at a single nucleotide position on a sequencing ladder. The use of TdT in the sequencing reactions greatly reduces the background associated with polymerase pauses and stops, allowing visualization of heterogeneous bases found in as little as 10% of the repeat units. Confirmation of these heterogeneous positions was obtained by comparison to the sequence of multiple individual cloned copies obtained both by PCR and non-PCR based methods. PCR amplification of alpha satellite can also reveal multiple repeat units which differ in size. Analysis of repPCR products from chromosome 17 and X allows rapid determination of the molecular basis of these repeat unit length variants, which appear to be a result of unequal crossing-over. The application of repPCR to the study of tandemly repeated DNA should allow in-depth analysis of intra- and interchromosomal variation and unequal crossing-over, thus providing insight into the biology and genetics of these large families of DNA.     

Identification in human genomic DNA of the sequence homologous but not identical to either the histo-blood group ABH genes or alpha 1----3 galactosyltransferase pseudogene

Based on polymerase chain reaction (PCR) and sequencing of the cloned amplified fragments, we identified a homologous sequence to the histo-blood group ABH genes and alpha 1----3 galactosyltransferase pseudogene. The presence of this sequence in human genomic DNA was confirmed by Southern hybridization.     

Parallel tagged sequencing on the 454 platform

Parallel tagged sequencing (PTS) is a molecular barcoding method designed to adapt the recently developed high-throughput 454 parallel sequencing technology for use with multiple samples. Unlike other barcoding methods, PTS can be applied to any type of double-stranded DNA (dsDNA) sample, including shotgun DNA libraries and pools of PCR products, and requires no amplification or gel purification steps. The method relies on attaching sample-specific barcoding adapters, which include sequence tags and a restriction site, to blunt-end repaired DNA samples by ligation and strand-displacement. After pooling multiple barcoded samples, molecules without sequence tags are effectively excluded from sequencing by dephosphorylation and restriction digestion, and using the tag sequences, the source of each DNA sequence can be traced. This protocol allows for sequencing 300 or more complete mitochondrial genomes on a single 454 GS FLX run, or twenty-five 6-kb plasmid sequences on only one 16th plate region. Most of the reactions can be performed in a multichannel setup on 96-well reaction plates, allowing for processing up to several hundreds of samples in a few days.     

HPLC purification of polymerase chain reaction products for direct sequencing

Same day PCR amplification and sequencing is desired in situations where one needs to sequence a number of PCR products. The rapid, high-yield purification of PCR products via the use of high performance, anion-exchange chromatography yields sequencing results comparable to those obtained from techniques requiring subcloning of the PCR product. This can be achieved by standard dideoxynucleotide sequencing technology without the need to prepare prelabeled primers and additional internal primers or to gel purify the PCR product. In addition, this chromatographic technique offers the potential of isolating several PCR products from the same amplification mixture.     

Not all sequence tags are created equal: designing and validating sequence identification tags robust to indels

Ligating adapters with unique synthetic oligonucleotide sequences (sequence tags) onto individual DNA samples before massively parallel sequencing is a popular and efficient way to obtain sequence data from many individual samples. Tag sequences should be numerous and sufficiently different to ensure sequencing, replication, and oligonucleotide synthesis errors do not cause tags to be unrecoverable or confused. However, many design approaches only protect against substitution errors during sequencing and extant tag sets contain too few tag sequences. We developed an open-source software package to validate sequence tags for conformance to two distance metrics and design sequence tags robust to indel and substitution errors. We use this software package to evaluate several commercial and non-commercial sequence tag sets, design several large sets (max_count = 7,198) of edit metric sequence tags having different lengths and degrees of error correction, and integrate a subset of these edit metric tags to polymerase chain reaction (PCR) primers and sequencing adapters. We validate a subset of these edit metric tagged PCR primers and sequencing adapters by sequencing on several platforms and subsequent comparison to commercially available alternatives. We find that several commonly used sets of sequence tags or design methodologies used to produce sequence tags do not meet the minimum expectations of their underlying distance metric, and we find that PCR primers and sequencing adapters incorporating edit metric sequence tags designed by our software package perform as well as their commercial counterparts. We suggest that researchers evaluate sequence tags prior to use or evaluate tags that they have been using. The sequence tag sets we design improve on extant sets because they are large, valid across the set, and robust to the suite of substitution, insertion, and deletion errors affecting massively parallel sequencing workflows on all currently used platforms.     

Efficient production of single-stranded DNA as long as 2 kb for sequencing of PCR-amplified DNA.

A modification of the asymmetric PCR method is described, which reliably facilitates sequencing of PCR-amplified DNA. This procedure produces single-stranded DNA fragments as long as two kilobases that are suitable for dideoxy DNA sequencing. First, a PCR for double-stranded DNA is preformed under optimal conditions (double-stranded PCR). Then, a 5-10-microliters fraction of the double-stranded PCR and a single primer are used to generate single-stranded DNA in a separate PCR (single-stranded PCR). The concentration of the single primer are used to generate single-stranded DNA in a separate PCR (single-stranded PCR). The concentration of the single primer is approximately 0.4 microM. Usually 15 to 25 cycles of single-stranded PCR are optimal to produce single-stranded DNA for four to eight sequencing reactions. The single-stranded DNA is purified by centrifugal ultrafiltration and used directly in dideoxy sequencing. This method was employed to produce high-quality single-stranded DNA templates from a variety of organisms for efficient DNA sequencing of PCR-amplified DNA.     

Direct PCR sequencing of dystrophin polymorphic CACA alleles after purification to remove shadow bands.

A method is described that allows the sequencing of polymerase chain reaction (PCR) products containing CACA repeats. The method was tested using a DNA polymorphism that exists at the 3' end of the dystrophin gene. This polymorphism consists of a variation in the length of a CACA dinucleotide repeat. Four alleles from a total of 16 individuals were sequenced at this locus after the DNA sequence had been amplified by the PCR. Five examples of each of the common alleles were sequenced. For each allele all five sequences were the same. The only example of a rare allele was also sequenced. The PCR products of DNA sequences containing dinucleotide repeats consist of a number of bands differing by 2 bp below the most intense main band. Previously, direct sequencing of the PCR products lead to ambiguities and smearing at and above the CACA repeat. In this paper, the main PCR band was cut out of a sequencing gel and directly sequenced to give a clear DNA sequence. Our results indicate that for a particular allele, all individuals had exactly the same DNA sequence. This implies that with the appropriate choice of oligonucleotide primers, polymorphisms could be detected without electrophoresis.     

Analysis of any point mutation in DNA. The amplification refractory mutation system (ARMS).

We have improved the "polymerase chain reaction" (PCR) to permit rapid analysis of any known mutation in genomic DNA. We demonstrate a system, ARMS (Amplification Refractory Mutation System), that allows genotyping solely by inspection of reaction mixtures after agarose gel electrophoresis. The system is simple, reliable and non-isotopic. It will clearly distinguish heterozygotes at a locus from homozygotes for either allele. The system requires neither restriction enzyme digestion, allele-specific oligonucleotides as conventionally applied, nor the sequence analysis of PCR products. The basis of the invention is that unexpectedly, oligonucleotides with a mismatched 3'-residue will not function as primers in the PCR under appropriate conditions. We have analysed DNA from patients with alpha 1-antitrypsin (AAT) deficiency, from carriers of the disease and from normal individuals. Our findings are in complete agreement with allele assignments derived by direct sequencing of PCR products.     

Diagnosis of alpha 1-antitrypsin deficiency by enzymatic amplification of human genomic DNA and direct sequencing of polymerase chain reaction products.

We have compared sequencing of cloned "polymerase chain reaction" (PCR) products and the direct sequencing of PCR products in the examination of individuals from six families affected with alpha 1-antitrypsin (AAT) deficiency. In families where paternity was in question we confirmed consanguinity by DNA fingerprinting using a panel of locus-specific minisatellite probes. We demonstrate that direct sequencing of PCR amplification products is the method of choice for the absolutely specific diagnosis of AAT deficiency and can distinguish normals, heterozygotes and homozygotes in a single, rapid and facile assay. Furthermore, we demonstrate the reproducibility of the PCR and a rapid DNA isolation procedure. We have also shown that two loci can be simultaneously amplified and that the PCR product from each locus can be independently examined by direct DNA sequencing.     

A method for clone sequence confirmation using a mismatch-specific DNA endonuclease

Site-directed mutagenesis and polymerase chain reaction (PCR)-based cloning are well-established methods carried out routinely in most modern molecular biology laboratories. Application of these methods requires confirmation of the DNA sequence of the target gene by sequencing of DNA purified from multiple colonies, a laborious process. We have developed an alternative approach to screen DNA amplified directly from colony DNA for both desired and undesired mutations. This approach is based on the use of a plant mismatch DNA endonuclease, Surveyor Nuclease, to directly screen clones derived by site-directed mutagenesis. We have also used this approach to identify error-free clones of three genes from celery cDNA produced by PCR and TOPO cloning. Sequence confirmation using Surveyor Nuclease provides a fast and simple approach to obtain desired clones from site-directed mutagenesis and PCR-based cloning methods without the necessity of sequencing DNAs purified from multiple clones.     

Re-usable DNA template for the polymerase chain reaction.

DNA covalently bound to an uncharged nylon membrane was used for consecutive amplifications of several different genes by PCR. Successful PCR amplifications were obtained for membrane-bound genomic and plasmid DNA. Membrane-bound genomic DNA templates were re-used at least 15 times for PCR with specific amplification of the desired gene each time. PCR amplifications of specific sequences of p53, p16, CYP1A1, CYP2D6, GSTM1 and GSTM3 were performed independently on the same strips of uncharged nylon membrane containing genomic DNA. PCR products were subjected to restriction fragment length polymorphism analysis, single-strand conformational polymorphism analysis and/or dideoxy sequencing to confirm PCR-amplified gene sequences. We found that PCR fragments obtained by amplification from bound genomic DNA as template were identical in sequence to those of PCR products obtained from free genomic DNA in solution. PCR was performed using as little as 5 ng genomic or 4 fg plasmid DNA bound to membrane. These results suggest that DNA covalently bound to membrane can be re-used for sample-specific PCR amplifications, providing a potentially unlimited source of DNA for PCR.     

Nucleotide sequence analysis of 95 kb near the 3' end of the murine T-cell receptor alpha/delta chain locus: strategy and methodology.

The nucleotide sequence of a region at the 3' terminus of the murine T-cell receptor alpha/delta chain locus is presented. This region, which encodes the constant region genes for alpha and delta chain polypeptides and all 50 joining gene segments for the alpha chain polypeptide, spans 94,647 bp and includes more than 50 noncoding sequence elements important for T-cell receptor gene rearrangement and expression. DNA sequencing of this region included complete analysis of two cosmid clones and five additional restriction fragments using a random subcloning approach with various manual and automated sequencing strategies. The automated sequencing strategies hold considerable promise for future large-scale DNA sequencing efforts.     

The determination of the sequences present in the shadow bands of a dinucleotide repeat PCR.

A Polymerase Chain Reaction (PCR) of a DNA sequence containing a CA repeat produces a main band but also several shadow bands that differ by 2 base pairs below the main band. In the experiments described in this paper, these shadow bands were excised from a DNA sequencing gel and directly sequenced. It was found that the sequence in the CA repeat was ambiguous. However, the sequence 5' and 3' to the CA repeat was clear and unambiguous. It is proposed that the shadow bands are generated by 2 base pair random deletions in the CA repeat region. During this process the sequence becomes 'scrambled' only in the CA repeat region. The shadow bands were shown to occur during the PCR since the genomic DNA template did not contain the shadow bands. It is probable that the shadow bands arise by slippage during the PCR. It is predicted that a thermostable DNA polymerase with a high processivity would greatly reduce the occurrence of shadow bands.     

Evaluating Bias of Illumina-Based Bacterial 16S rRNA Gene Profiles

Massively parallel sequencing of 16S rRNA genes enables the comparison of terrestrial, aquatic, and host-associated microbial communities with sufficient sequencing depth for robust assessments of both alpha and beta diversity. Establishing standardized protocols for the analysis of microbial communities is dependent on increasing the reproducibility of PCR-based molecular surveys by minimizing sources of methodological bias. In this study, we tested the effects of template concentration, pooling of PCR amplicons, and sample preparation/interlane sequencing on the reproducibility associated with paired-end Illumina sequencing of bacterial 16S rRNA genes. Using DNA extracts from soil and fecal samples as templates, we sequenced pooled amplicons and individual reactions for both high (5- to 10-ng) and low (0.1-ng) template concentrations. In addition, all experimental manipulations were repeated on two separate days and sequenced on two different Illumina MiSeq lanes. Although within-sample sequence profiles were highly consistent, template concentration had a significant impact on sample profile variability for most samples. Pooling of multiple PCR amplicons, sample preparation, and interlane variability did not influence sample sequence data significantly. This systematic analysis underlines the importance of optimizing template concentration in order to minimize variability in microbial-community surveys and indicates that the practice of pooling multiple PCR amplicons prior to sequencing contributes proportionally less to reducing bias in 16S rRNA gene surveys with next-generation sequencing.     

Integrated method for single-cell DNA extraction, PCR amplification, and sequencing of ribosomal DNA from harmful dinoflagellates Cochlodinium polykrikoides and Alexandrium catenella

A simplified technique was developed for DNA sequence-based diagnosis of harmful dinoflagellate species. This protocol integrates procedures for DNA extraction and polymerase chain reaction (PCR) amplification into a single tube. DNA sequencing reactions were performed directly, using unpurified PCR products as the DNA template for subsequent sequencing reactions. PCR reactions using DNA extracted from single cells of Cocodinium polykrikoides and Alexandrium catenella successfully amplified the target ribosomal DNA regions. DNA sequencing of the unpurified PCR products showed that DNA sequences corresponded to the expected locus of ribosomal DNA regions of both A. catenella and C. polykrikoides (each zero genetic distance and 100% sequence similarity). Using the protocol described in this article, there was little DNA loss during the purification step, and the technique was found to be rapid and inexpensive. This protocol clearly resolves the taxonomic ambiguities of closely related algal species (such as Alexandrium and Cochlodinium), and it constitutes a significant breakthrough for the molecular analysis of nonculturable dinoflagellate species.     

Revisiting the effect of PCR replication and sequencing depth on biodiversity metrics in environmental DNA metabarcoding

Environmental DNA (eDNA) metabarcoding is an increasingly popular tool for measuring and cataloguing biodiversity. Because the environments and substrates in which DNA is preserved differ considerably, eDNA research often requires bespoke approaches to generating eDNA data. Here, we explore how two experimental choices in eDNA study design—the number of PCR replicates and the depth of sequencing of PCR replicates—influence the composition and consistency of taxa recovered from eDNA extracts. We perform 24 PCR replicates from each of six soil samples using two of the most common metabarcodes for Fungi and Viridiplantae (ITS1 and ITS2), and sequence each replicate to an average depth of ~84,000 reads. We find that PCR replicates are broadly consistent in composition and relative abundance of dominant taxa, but that low abundance taxa are often unique to one or a few PCR replicates. Taxa observed in one out of 24 PCR replicates make up 21–29% of the total taxa detected. We also observe that sequencing depth or rarefaction influences alpha diversity and beta diversity estimates. Read sampling depth influences local contribution to beta diversity, placement in ordinations, and beta dispersion in ordinations. Our results suggest that, because common taxa drive some alpha diversity estimates, few PCR replicates and low read sampling depths may be sufficient for many biological applications of eDNA metabarcoding. However, because rare taxa are recovered stochastically, eDNA metabarcoding may never fully recover the true amplifiable alpha diversity in an eDNA extract. Rare taxa drive PCR replicate outliers of alpha and beta diversity and lead to dispersion differences at different read sampling depths. We conclude that researchers should consider the complexity and unevenness of a community when choosing analytical approaches, read sampling depths, and filtering thresholds to arrive at stable estimates.     

Optimization strategies for the polymerase chain reaction

The GeneAmp polymerase chain reaction (PCR) process has now become a key procedure in molecular biology research laboratories. The PCR technique is an in vitro method in which genomic or cloned target sequences are specifically enzymatically amplified as directed by a pair of oligonucleotide primers. This technique has been quite robust in the hands of the majority of researchers and is extremely flexible, as evidenced by the increasing number of related PCR formats (i.e., inverse PCR, anchored PCR, asymmetric PCR, labeled primer PCR and RNA-PCR). Today's applications include direct sequencing, genomic cloning, DNA typing, detection of infectious microorganisms, site-directed mutagenesis, prenatal genetic disease research, and analysis of allelic sequence variations. Scientists at Cetus and Perkin-Elmer have collaborated for several years to better understand the interacting biochemical and biophysical parameters which affect PCR optimization. Following are many of the current recommendations, offered with the caveat that our understanding of the PCR process is continually evolving.     

金黄色葡萄球菌肠毒素B基因的克隆和在大肠杆菌中高效表达

利用PCR方法从金黄色葡萄球菌TSTw基因组DNA中扩增出约700bp的DNA片段,将之克隆到pGEM7Zf(+)载体上并转化大肠杆菌 DH5α菌株。重组质粒的测序结果表明克隆到了seb基因,它含有717bp（不包括N端81bp的信号肽编码区）,其核苷酸序列与文献报道完全一致。将其连接于表达载体7ZTS上,转化到大肠杆菌JM109（DE3）内。表达的SEB占总蛋白33.5%。      

Cloning of Taiwan water buffalo male-specific DNA sequence for sexing

Random amplified polymorphic DNA (RAPD) fingerprinting was carried out to investigate the sex-specific DNA sequence for sexing in Taiwan water buffalos. One hundred and forty random primers were used for RAPD-PCR (polymerase chain reaction). One of these primers, OPC-16, produced a 321 bp fragment found only in tested males. This male-specific fragment was isolated and constructed into plasmids for nucleotide sequencing, a novel male-specific sequence was obtained. Two primers (BuSexOPC16-F and -R) were designed according to the cloned male-specific sequence to amplify the male-specific fragment using PCR for sexing. Sex-specific bands in the gel were represented in the males but none were found in the females when the Taiwan water buffalo genomic DNA samples were amplified with these two primers using PCR. The same results were also obtained from Taiwan yellow, Holstein, Angus, and Hereford cattle samples. This showed that the sex of these five breeds could be easily and effectively determined using the PCR technique.     

Palaeogenomics

In many ways, palaeogenomics began when the first ancient DNA sequence was reported. This first sequence was derived from a stuffed museum specimen of the quagga, an extinct mammal related to the zebra. Unspecified and unselected DNA was extracted from the quagga specimen, cloned into a bacterial library, and then sequenced. It took another 17 years and the development of PCR before two independent groups successfully sequenced the complete mitochondrial genomes from several extinct moa species. Only 4 years later, using the original approach of cloning nonspecific ancient DNA extract and shotgun sequencing, the first ancient nuclear DNA sequences were determined, this time from the extinct cave bear. Since these early successes, palaeogenomics has rapidly expanded, because of both technological development and increasing interest in ancient DNA research. New methods, developed since the cave bear sequence was reported, have produced nuclear DNA on a megabase scale from two extinct species, the mammoth and the Neanderthal, our closest relative. For both species, low-coverage genome-sequencing projects have been proposed. It is likely that these will be successful, given the rapid technical development in sequencing techniques. This review carefully examines both the promise and the current limitations of palaeogenomic analyses for both mitochondrial and nuclear DNA.