Locked nucleic acids in PCR primers increase sensitivity and performance

The incorporation of locked nucleic acids (LNAs) into oligonucleotide primers has been shown to increase template binding strength and specificity for DNA amplification. Real-time PCR and DNA sequencing have been shown to be significantly enhanced by the use of LNAs. Theoretically, increasing primers' binding strength may also increase the sensitivity of conventional PCR, reducing minimum template requirements. We compared LNA-modified PCR primers with their standard DNA counterparts for amplification sensitivity with template amounts as low as 5 pg. Although the results are highly dependent on the design of the LNA primers, large increases in peak height can be achieved from as little as 75 pg, as well as clearer and more complete profiles. Increased amplification success with lower template amounts may also be seen. Additionally, the use of LNAs can enhance multiplexing. Thus, incorporating LNAs into PCR primers can increase amplification success, sensitivity, and performance under a wide range of conditions.     

A method for counting PCR template molecules with application to next-generation sequencing

Amplification by polymerase chain reaction is often used in the preparation of template DNA molecules for next-generation sequencing. Amplification increases the number of available molecules for sequencing but changes the representation of the template molecules in the amplified product and introduces random errors. Such changes in representation hinder applications requiring accurate quantification of template molecules, such as allele calling or estimation of microbial diversity. We present a simple method to count the number of template molecules using degenerate bases and show that it improves genotyping accuracy and removes noise from PCR amplification. This method can be easily added to existing DNA library preparation techniques and can improve the accuracy of variant calling.     

Amplification of bacterial genomic DNA by the polymerase chain reaction and direct sequencing after asymmetric amplification: application to the study of periplasmic permeases.

The polymerase chain reaction (PCR) has been used to amplify DNA fragments by using eucaryotic genomic DNA as a template. We show that bacterial genomic DNA can be used as a template for PCR amplification. We demonstrate that DNA fragments at least as large as 4,400 base pairs can be amplified with fidelity and that the amplified DNA can be used as a substrate for most operations involving DNA. We discuss problems inherent in the direct sequencing of the amplified product, one of the important exploitations of this methodology. We have solved the problems by developing an "asymmetric amplification" method in which one of the oligonucleotide primers is used in limiting amounts, thus allowing the accumulation of single-stranded copies of only one of the DNA strands. As an illustration of the use of PCR in bacteria, we have amplified, sequenced, and subcloned several DNA fragments carrying mutations in genes of the histidine permease operon. These mutations are part of a preliminary approach to studying protein-protein interactions in transport, and their nature is discussed.     

On the causes,consequences, and avoidance of PCR duplicates: Towards a theory of library complexity

Library preparation protocols for most sequencing technologies involve PCR amplification of the template DNA, which open the possibility that a given template DNA molecule is sequenced multiple times. Reads arising from this phenomenon, known as PCR duplicates, inflate the cost of sequencing and can jeopardize the reliability of affected experiments. Despite the pervasiveness of this artefact, our understanding of its causes and of its impact on downstream statistical analyses remains essentially empirical. Here, we develop a general quantitative model of amplification distortions in sequencing data sets, which we leverage to investigate the factors controlling the occurrence of PCR duplicates. We show that the PCR duplicate rate is determined primarily by the ratio between library complexity and sequencing depth, and that amplification noise (including in its dependence on the number of PCR cycles) only plays a secondary role for this artefact. We confirm our predictions using new and published RAD-seq libraries and provide a method to estimate library complexity and amplification noise in any data set containing PCR duplicates. We discuss how amplification-related artefacts impact downstream analyses, and in particular genotyping accuracy. The proposed framework unites the numerous observations made on PCR duplicates and will be useful to experimenters of all sequencing technologies where DNA availability is a concern.     

Length and GC-biases during sequencing library amplification: a comparison of various polymerase-buffer systems with ancient and modern DNA sequencing libraries

High-throughput sequencing technologies frequently necessitate the use of PCR for sequencing library amplification. PCR is a sometimes enigmatic process and is known to introduce biases. Here we perform a simple amplification-sequencing assay using 10 commercially available polymerase-buffer systems to amplify libraries prepared from both modern and ancient DNA. We compare the performance of the polymerases with respect to a previously uncharacterized template length bias, as well as GC-content bias, and find that simply avoiding certain polymerase can dramatically decrease the occurrence of both. For amplification of ancient DNA, we found that some commonly used polymerases strongly bias against amplification of endogenous DNA in favor of GC-rich microbial contamination, in our case reducing the fraction of endogenous sequences to almost half.     

Sources of PCR-induced distortions in high-throughput sequencing data sets

PCR permits the exponential and sequence-specific amplification of DNA, even from minute starting quantities. PCR is a fundamental step in preparing DNA samples for high-throughput sequencing. However, there are errors associated with PCR-mediated amplification. Here we examine the effects of four important sources of error—bias, stochasticity, template switches and polymerase errors—on sequence representation in low-input next-generation sequencing libraries. We designed a pool of diverse PCR amplicons with a defined structure, and then used Illumina sequencing to search for signatures of each process. We further developed quantitative models for each process, and compared predictions of these models to our experimental data. We find that PCR stochasticity is the major force skewing sequence representation after amplification of a pool of unique DNA amplicons. Polymerase errors become very common in later cycles of PCR but have little impact on the overall sequence distribution as they are confined to small copy numbers. PCR template switches are rare and confined to low copy numbers. Our results provide a theoretical basis for removing distortions from high-throughput sequencing data. In addition, our findings on PCR stochasticity will have particular relevance to quantification of results from single cell sequencing, in which sequences are represented by only one or a few molecules.     

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.     

Automated sequencing of complete mitochondrial genomes from laser-capture microdissected samples

Mitochondrial DNA mutations have been related to both aging and a variety of diseases such as cancer. Due to the relatively small size of the genome (16 kb) and with the use of automated DNA sequencing, the entire genome can be sequenced from clinical specimens in days. We present a reliable approach to complete mitochondrial genome sequencing from laser-capture microdissected human clinical cancer specimens that overcome the inherent limitations of relatively small tissue samples and partial DNA degradation, which are unavoidable when laser-capture microdissection is used to attain pure populations of cells from heterogeneous tissues obtained from surgical procedures. The acquisition of sufficient template combined with a standard set of 18 pairs of PCR primers allows for the efficient amplification of the genome. Subsequent single-stranded amplification is performed using 36 sequencing primers, and samples are run on an ABI PRISM 3100 Genetic Analyzer. The use of this procedure should allow even investigators with little experience sequencing from clinical specimens success in complete mitochondrial genome sequencing.     

2'-modified oligonucleotides from methoxyoxalamido and succinimido precursors: synthesis, properties, and applications

Synthesis of 2'-modified oligonucleotides from 2'-methoxyoxalamido (MOX) and 2'-succinimido (SUC) precursors is described. Their physical and biochemical properties were assessed. Synthesized oligonucleotides were used as primers in advanced DNA sequencing protocols. An example of sequencing directly off genomic DNA template without prior cloning or PCR amplification is presented.     

2′-MODIFIED OLIGONUCLEOTIDES FROM METHOXYOXALAMIDO AND SUCCINIMIDO PRECURSORS: SYNTHESIS,PROPERTIES, AND APPLICATIONS

Synthesis of 2′-modified oligonucleotides from 2′-methoxyoxalamido (MOX) and 2′-succinimido (SUC) precursors is described. Their physical and biochemical properties were assessed. Synthesized oligonucleotides were used as primers in advanced DNA sequencing protocols. An example of sequencing directly off genomic DNA template without prior cloning or PCR amplification is presented.     

Barcoded primers used in multiplex amplicon pyrosequencing bias amplification

"Barcode-tagged" PCR primers used for multiplex amplicon sequencing generate a thus-far-overlooked amplification bias that produces variable terminal restriction fragment length polymorphism (T-RFLP) and pyrosequencing data from the same environmental DNA template. We propose a simple two-step PCR approach that increases reproducibility and consistently recovers higher genetic diversity in pyrosequencing libraries.     

Molecular barcodes detect redundancy and contamination in hairpin-bisulfite PCR

PCR amplification of limited amounts of DNA template carries an increased risk of product redundancy and contamination. We use molecular barcoding to label each genomic DNA template with an individual sequence tag prior to PCR amplification. In addition, we include molecular ‘batch-stamps’ that effectively label each genomic template with a sample ID and analysis date. This highly sensitive method identifies redundant and contaminant sequences and serves as a reliable method for positive identification of desired sequences; we can therefore capture accurately the genomic template diversity in the sample analyzed. Although our application described here involves the use of hairpin-bisulfite PCR for amplification of double-stranded DNA, the method can readily be adapted to single-strand PCR. Useful applications will include analyses of limited template DNA for biomedical, ancient DNA and forensic purposes.     

Overcoming a barrier for DNA polymerization in triplex-forming sequences.

Folded structures in the DNA template, such as hairpins and multi-stranded structures, often serve as pause and arrest sites for DNA polymerases. DNA polymerization is particularly difficult on mirror-repeated homopurine.homopyrimidine templates where triple-stranded (triplex) structures may form between the nascent and folded template strands. In order to use a linear PCR amplification approach for the structural analysis of DNA in mirror-repeated sequences we modified a conventional protocol. The barrier for DNA synthesis can be eliminated using an oligonucleotide that hybridizes with the template to prevent its folding and is subsequently displaced by the progressing polymerase. The described approach is potentially useful for sequencing and analysis of chemical adducts and point mutations in a variety of sequences prone to the formation of folded structures, such as long hairpins and quadruplexes.     

Mung Bean Nuclease Treatment Increases Capture Specificity of Microdroplet-PCR Based Targeted DNA Enrichment

Targeted DNA enrichment coupled with next generation sequencing has been increasingly used for interrogation of select sub-genomic regions at high depth of coverage in a cost effective manner. Specificity measured by on-target efficiency is a key performance metric for target enrichment. Non-specific capture leads to off-target reads, resulting in waste of sequencing throughput on irrelevant regions. Microdroplet-PCR allows simultaneous amplification of up to thousands of regions in the genome and is among the most commonly used strategies for target enrichment. Here we show that carryover of single-stranded template genomic DNA from microdroplet-PCR constitutes a major contributing factor for off-target reads in the resultant libraries. Moreover, treatment of microdroplet-PCR enrichment products with a nuclease specific to single-stranded DNA alleviates off-target load and improves enrichment specificity. We propose that nuclease treatment of enrichment products should be incorporated in the workflow of targeted sequencing using microdroplet-PCR for target capture. These findings may have a broad impact on other PCR based applications for which removal of template DNA is beneficial.     

DNA extraction method for screening yeast clones by PCR

A simple procedure for isolating yeast DNA suitable for use as a template for PCR amplification is described. SDS treatment alone is sufficient for extraction of chromosomal DNA from yeast cells. Cells of a yeast colony are suspended in a small volume (about 20 microL) of a 0.25% SDS solution, mixed vigorously and centrifuged. The supernatant can be directly used as a template after dilution to give an SDS concentration of less than 0.01% in the final PCR mixture.     

Chelex-100快速提取放线菌DNA作为PCR扩增模板

旨在建立有效扩增16S rRNA基因序列的放线菌DNA快速提取的方法。采用Chelex-100法提取放线菌DNA,使用PCR扩增16S rRNA基因序列评价提取核酸的质量。结果显示,Chelex-100法能够在10 min之内从放线菌中快速提取DNA,所提取的DNA可以直接用于PCR扩增反应,PCR扩增产物电泳条带清晰,符合理论预期结果。因此,Chelex-100法提取放线菌DNA可以作为16S rRNA基因序列PCR扩增的模板,该方法具有经济、简便、快速的特点,适合于放线菌菌株大规模地筛选和分类鉴定。     

水稻OsNCED3基因的RNAi载体构建

水稻OsNCED3基因是水稻抗逆过程中重要的基因之一.以水稻中花10号幼苗为材料,提取基因组DNA.设计引物扩增区段cDNA并引入相应的酶切位点,以基因组DNA作为模板,进行RNAi-OsNCED3顺式和反式目的片段的PCR扩增.将PCR产物连接到pMD19-T载体上,经酶切和PCR检测后进行测序.测序结果表明:RNAi-OsNCED3顺式和反式目的片段均已正确的连接到pMD19-T载体上.然后将RNAi-OsNCED3顺式和反式目的片段通过酶切和连接,连接到含有发夹结构的质粒pFGC5941上.PCR及双酶切结果显示,构建的pFGC5941-OsNCED3即RNAi-OsNCED3载体结构完整.     

Dideoxy linear PCR on a commercial fluorescent automated DNA sequencer.

The use of automated fluorescent DNA sequencer systems and PCR-based DNA sequencing methods play an important role in the actual effort to improve the efficiency of large-scale DNA analysis. Here we show the application of the linear PCR using a single fluorescent primer and dideoxynucleotide terminators in four separate sequencing reactions on the EMBL/Pharmacia's fluorescent automated DNA sequencer. We have used dideoxy/deoxynucleoside triphosphate ratios and linear amplification cycle conditions to obtain an accurate sequencing response of up to, and over, 500 bases from just 400 ng of double-stranded DNA template without chemical denaturation. The sequencing protocol described in this paper is effectively suited for enhancement of sensitivity and performance of the automated DNA sequencing system.