Optimization of long-distance PCR using a transposon-based model system

Isoenzyme and molecular approach for authenticating and monitoring of animal cell lines

Authentication of cell lines is of paramount importance to validate the results from their use in biomedical research. Although isoenzyme polymorphism is the standard method, molecular methods based on mitochondrial DNA (mtDNA) have been developed to replace it. The aim of this study was the improvement of our isoenzyme electrophoretic analysis and the validation of one molecular technique targeted at mtDNA for the authentication of our animal cell lines. The combined method of cellular lysing through osmotic shock, followed by freezing-thawing in N2 to obtain isoenzyme extracts, and with 42 × 106 cells maintained the best efficiency. The superior electrophoretic conditions were PAGE run at 200 V. All cell lines had isoenzymatic mobility corresponding to their species to lactate dehydrogenase, malate-dehydrogenase, and glucose-6-phosphate dehydrogenase isoenzymes, and could be distinguished from each other. Two molecular techniques based on mtDNA were tested, one on the cytochrome b gene and other on cytochrome c oxidase I subunit gene. Due to difficulties in distinguishing all cell lines using only one these techniques, we merged the primers of two methods in such a way that there was a sufficient differentiation of all DNA fragments. The sequencing of these PCR products was also performed to validate these data.

Long and Accurate Polymerase Chain Reaction (LA PCR)

The standard polymerase chain reaction (PCR) is easily capable of amplifying segments of DNA smaller than ∼3 kb in length-sufficient for most purposes, but not enough to amplify an entire mammalian gene, nor even a cDNA of average dimensions. Instead of full-length products, standard PCR amplification of longer templates generates variously sized truncated molecules that appear as unattractive smears on a gel. Long and accurate PCR (LA PCR) addresses the issue in part by using a mixture of two different thermostable DNA polymerases to catalyze the amplification reaction. The first polymerase is an efficient but error-prone workhorse (e.g., Taq), whereas the second, used in much smaller amounts, provides a proofreading 3' → 5' exonuclease function that resects mismatched 3' ends. These improvements generate high yields and accurate copies of long targets.

Properties of targeted preamplification in DNA and cDNA quantification

Objective: Quantification of small molecule numbers often requires preamplification to generate enough copies for accurate downstream enumerations. Here, we studied experimental parameters in targeted preamplification and their effects on downstream quantitative real-time PCR (qPCR). Methods: To evaluate different strategies, we monitored the preamplification reaction in real-time using SYBR Green detection chemistry followed by melting curve analysis. Furthermore, individual targets were evaluated by qPCR. Result: The preamplification reaction performed best when a large number of primer pairs was included in the primer pool. In addition, preamplification efficiency, reproducibility and specificity were found to depend on the number of template molecules present, primer concentration, annealing time and annealing temperature. The amount of nonspecific PCR products could also be reduced about 1000-fold using bovine serum albumin, glycerol and formamide in the preamplification. Conclusion: On the basis of our findings, we provide recommendations how to perform robust and highly accurate targeted preamplification in combination with qPCR or next-generation sequencing.

Long-Range PCR Amplification of DNA by DNA Polymerase III Holoenzyme from Thermus thermophilus

DNA replication in bacteria is accomplished by a multicomponent replicase, the DNA polymerase III holoenzyme (pol III HE). The three essential components of the pol III HE are the α polymerase, the β sliding clamp processivity factor, and the DnaX clamp-loader complex. We report here the assembly of the functional holoenzyme from Thermus thermophilus (Tth), an extreme thermophile. The minimal holoenzyme capable of DNA synthesis consists of α, β and DnaX (τ and γ), δ and δ′ components of the clamp-loader complex. The proteins were each cloned and expressed in a native form. Each component of the system was purified extensively. The minimum holoenzyme from these five purified subunits reassembled is sufficient for rapid and processive DNA synthesis. In an isolated form the α polymerase was found to be unstable at temperatures above 65°C. We were able to increase the thermostability of the pol III HE to 98°C by addition and optimization of various buffers and cosolvents. In the optimized buffer system we show that a replicative polymerase apparatus, Tth pol III HE, is capable of rapid amplification of regions of DNA up to 15,000 base pairs in PCR reactions.

Polymorphic Alu insertions within the Major Histocompatibility Complex class I genomic region: a brief review

Most polymorphic Alu insertions (POALINs) belong to a subgroup of the Alu multicopy retrotransposon family of short interspersed nucleotide elements (SINEs) that are categorized as AluYb8 and AluYa5. The number of AluYb8/AluYa5 members (approximately 4,492 copies) is significantly less than the approximately one million fixed Alu copies per human genome. We have studied the presence of POALINs within the Major Histocompatibility Complex (MHC) class I region on the short arm of chromosome 6 (6p21.3) because this region has a high gene density, many genes with immune system functions, large sequence variations and diversity, duplications and redundancy, and a strong association with more than 100 different diseases. Since little is known about POALINs within the MHC genomic region, we undertook to identify some of the members of the AluYb8/AluYa5 subfamily and to study their frequency of distribution and genetic characteristics in different populations. As a result of our comparative genomic analyses, we identified the insertion sites for five POALINs distributed within the MHC class I region. This brief review outlines the locations of the insertions and sequence features of the five MHC POALINs, their single site and haplotype frequencies in different geographic populations, and their association with different HLA class I genes and disease. We show that the MHC POALINs have a potential value as lineage and linkage markers for the study of human population genetics, disease associations, genomic diversity and evolution.

Development of long PCR techniques to analyze deletion mutations of the human hprt gene

DNA primers and reaction conditions for long polymerase chain reaction amplification (PCR) of portions of the human hprt gene are presented. Use of these primers with DNA from previously defined hprt deletion mutants demonstrated production of the expected smaller size products as compared to DNA from wild type cells. These primers will be of value in the rapid analysis and subsequent sequencing of hprt deletion mutations in human cells.

Substitution of Asn for Ser543 in the large fragment of Taq DNA polymerase increases the efficiency of synthesis of long DNA molecules

Substitution of Asn for Ser543 in the large fragment of Taq DNA polymerase (Klentaq) increases several times the efficiency of synthesis of long (over 2 kbp) DNA molecules. The difference in the DNA synthesis efficiencies by the mutant and native enzymes increased with the increase in the DNA fragment length.

Human papillomavirus type 16 variant lineages in United States populations characterized by nucleotide sequence analysis of the E6, L2, and L1 coding segments

Human papillomavirus type 16 (HPV16) nucleotide sequence variations in the E6 (nucleotide positions [nt] 104 to 559), L2 (nt 4272 to 5657), and L1 (nt 5665 to 7148) open reading frames (ORFs), and the long control region (nt 7479 to 7842), were examined in 29 selected United States isolates. Of 3,690 nucleotide positions, 129 (3.5%) varied. The maximum pairwise distance was 66 nucleotide differences, or 1.8%. Nucleotide variations within different genome segments were phylogenetically compatible, and nucleotide changes within E6, L2, and L1 contained phylogenetic information beyond that provided in the long control region. Most isolates were classified as members of HPV16 lineages that have been described previously. However, two novel phylogenetic branches were identified. The L2 ORF was the most variable coding segment. L2 synonymous and nonsynonymous nucleotide changes were distributed asymmetrically. The amino-terminal half of the L2 protein was remarkably conserved among all isolates, suggesting that the region is under evolutionary constraint. The amino-terminal region of the E6 ORF was relatively varied, especially at E6 amino acid positions 10 and 14. Several amino acid difference in the L1 ORF were observed between lineages. Forty-nine amino acid variations across all sequenced coding regions were observed. These amino acid differences may be relevant to differences in the generation of humoral or cell-mediated immune responses to HPV16 variants. Our data form a basis for considering HPV16 sequence variation in the rational design of vaccine strategies and as an epidemiologic correlate of cervical cancer risk.

Amplification of complete insect mitochondrial genome in two easy pieces

The entire insect mitochondrial genome has been amplified in just two PCR reactions. 'Universal' insect primers and techniques to optimize amplification of long PCR products were used to obtain segments of the mitochondrial genomes of Helicoverpa zea and Heliothis virescens (Lepidoptera) ranging in size from 3.7 kb to 14 kb or about 25% to over 85% of a typical 16 kb mtDNA. Overlapping pairs of fragments contain the complete mtDNA sequence.

MAAP: a versatile and universal tool for genome analysis

Multiple arbitrary amplicon profiling (MAAP) uses one or more oligonucleotide primers (> or = 5 nt) of arbitrary sequence to initiate DNA amplification and generate characteristic fingerprints from anonymous genomes or DNA templates. MAAP markers can be used in general fingerprinting as well as in mapping applications, either directly or as sequence-characterized amplified regions (SCARs). MAAP profiles can be tailored in the number of monomorphic and/or polymorphic products. For example, multiple endonuclease digestion of template DNA or the use of mini-hairpin primers can enhance detection of polymorphic DNA. Comparison of the expected and actual number of amplification products produced with primers differing in length, sequence and GC content from templates of varying complexity reveal severe departures from theoretical formulations with interesting implications in primer-template interaction. Extensive primer-template mismatching can occur when using templates of low complexity or long primers. Primer annealing and extension appears directed by an 8 nt 3'-terminal primer domain, requires sites with perfect homology to the first 5-6 nt fom the 3' terminus, and involves direct physical interaction between amplicon annealing sites.

Effective amplification of long targets from cloned inserts and human genomic DNA

We have used the polymerase chain reaction (PCR) to amplify up to 22 kb of the beta-globin gene cluster from human genomic DNA and up to 42 kb from phaga lambda DNA. We have also amplified 91 human genomic inserts of 9-23 kb directly from recombinant lambda plaques. To do this, we increased pH, added glycerol and dimethyl sulfoxide, decreased denaturation times, increased extension times, and used a secondary thermostable DNA polymerase that possesses a 3'-to 5'-exonuclease, or "proofreading," activity. Our "long PCR" protocols maintain the specificity required for targets in genomic DNA by using lower levels of polymerase and temperature and salt conditions for specific primer annealing. The ability to amplify DNA sequences of 10-40 kb will bring the speed and simplicity of PCR to genomic mapping and sequencing and facilitate studies in molecular genetics.

PCR amplification of up to 35-kb DNA with high fidelity and high yield from lambda bacteriophage templates

A target length limitation to PCR amplification of DNA has been identified and addressed. Concomitantly, the base-pair fidelity, the ability to use PCR products as primers, and the maximum yield of target fragment were increased. These improvements were achieved by the combination of a high level of an exonuclease-free, N-terminal deletion mutant of Taq DNA polymerase, Klentaq1, with a very low level of a thermostable DNA polymerase exhibiting a 3'-exonuclease activity (Pfu, Vent, or Deep Vent). At least 35 kb can be amplified to high yields from 1 ng of lambda DNA template.

Use of a sensitive fluorescent intercalating dye to detect PCR products of low copy number and high molecular weight

The ability to routinely and specifically amplify and detect PCR products ranging in size from < 1 to > 10 kb, regardless of target template sequence or structure, would facilitate several tasks in human genome research. Generation of a wide size range of PCR products would potentially expedite isolation of uncloned DNA (gaps) represented in physical maps and provide a means for maintaining order and orientation of closely linked loci during analysis. Long-range PCR offers an alternative to isolation of genomic or cDNA clones from tissues or species where appropriate libraries are unavailable. This methodology also provides a powerful strategy to pursue directed transposon-based mapping and sequencing of templates of 100 kb or greater. Further development of basic PCR technology has been necessary in order to make it feasible to use large DNA targets as primary templates for genome analysis. Application of these extended PCR capacities would potentially save time, materials, and cost.

A simple and efficient method for constructing high resolution physical maps

This paper describes a simple and efficient walking method for constructing high resolution physical maps and discusses its applications to genome analysis. The method is an integration of three strategies: (1) use of a highly redundant library of 3Kb-long subclones; (2) construction of a multidimensional pool from the library; (3) direct application of a PCR (polymerase chain reaction)-based screening technique to the pooled library, with two PCR primers, one from the end of the subcloning vector and the other from the leading edge of the walk. This technique allows not only detection of each overlapping subclone but simultaneous determination of its orientation and the size of its overlap. The end of the subclone with the smallest overlap is sequenced and a primer is designed for the next step in the walk. Iteration of the screening procedure with minimum overlapping subclones results in completion of the high resolution map. Using this method, a 3Kb-resolution map was constructed from an 80Kb region of the bithorax complex of Drosophila melanogaster. The method is general enough to be applicable to DNA from other species, and simple enough to be automated.