Truncated amplification: a method for high-fidelity template-driven nucleic acid amplification

The error rate of conventional PCR is problematic when amplifying from single cells or amplifying segments for protein functional analysis by in vitro translation. We describe truncated amplification, a method for high-fidelity amplification in which DNA polymerase errors are not propagated efficiently and original DNA templates exert greater influence on the amplification process. Truncated amplification utilizes pairs of oligonucleotides and thermal cycling, but it differs from PCR. Truncated amplification amplifies non-exponentially with one or two chimeric oligonucleotides and produces truncated terminal products that are no more than three rounds of replication from the original template. Exon 6 of the p53 gene was utilized as a model system to demonstrate proof of principle. Chimeric oligonucleotides containing three 3'-->5' reversed-deoxynucleotides or 2'-OMe-ribonucleotides at 6-8 nucleotides from the 3 'terminus retained sequence specificity and primer extension activity. With PfuTurbo but not with Taq or Vent (exo-) DNA polymerases, the modified nucleotides completely truncated the DNA polymerase elongation. The resulting truncated terminal products are not templates for further amplification because of the short length of the 3' complementary region. Truncated amplific ation can amplify quadratically or geometrically depending on whether two or one chimeric oligonucleotides are used. Truncated amplification is a promising approach when template-driven amplification is desired to increase thefrequency of error-free products.     

Semiautomated clone verification by real-time PCR using molecular beacons

Conventional, high-throughput PCR analysis of common elements utilizing numerous primer sets and template DNA requires multiple rounds of PCR to ensure optimal conditions. Laborious gel electrophoresis and staining is then necessary to visualize amplification products. We propose novel multicolor molecular beacons, to establish a high-throughput, PCR-based sequence tagged site (STS) detection system that swiftly and accurately confirms marker content in template containing common repeat elements. A simple, one-tube, real-time PCR assay system was developed to specifically detect regions containing CA and GATA repeats. Ninety-six samples can be confirmed for marker content in a closed-tube format in 3 h, eliminating product confirmation on agarose gels and avoiding crossover contamination. Multiple STSs can be detected simultaneously in the same reaction tube by utilizing molecular beacons labeled with multicolor fluorophores. Template DNA from 260 RPCI-11 bacterial artificial chromosome (BAC) clones was examined for the presence of CA and/or GATA repeats using molecular beacon PCR and compared with conventional PCR results of the same clones. Of the 205 clones containing CA and GATA repeats, we were able to identify 129 clones (CA, n = 99; GATA, n = 30) by using molecular beacons and only 121 clones (CA, n = 92; GATA, n = 29) by conventional PCR amplification. As anticipated, 55 clones that contained sequences other than CA or GATA failed molecular beacon detection. Molecular beacon PCR, employing beacons specific for tandem repeat elements, provides a fast, accurate, and sensitive multiplex detection assay that will expedite verification of marker content in a multitude of template containing these repeats.     

PCR amplification of Tetrahymena rDNA segments starting with individual cells.

To facilitate studies of rDNA molecular genetics in Tetrahymena thermophila, we attempted the detection of polymorphisms in the nontranscribed spacers (NTSs) using polymerase chain reaction (PCR), starting with minute amounts of DNA. The targeted polymorphic regions are 85% adenine-thymine (AT). We found conditions of efficient and specific in vitro amplification of targeted segments in the replication domain of the 5'NTS and in the subtelomeric segment of the 3'NTS. The identity of the amplified segments was confirmed by restriction enzyme digestion and DNA sequence analysis. Digestion of the template DNA at restriction sites upstream and downstream of the targeted region increased the efficiency of amplification, presumably because the targeted segments are in a palindromic molecule. Starting from total cell DNA corresponding to as little as 0.03 picogram (equivalent to the DNA content of 0.003 cells or about 30 rDNA molecules), we observed the amplified band after agarose gel electrophoresis and ethidium bromide staining. The yield indicated more than 10-billion-fold amplification. Amplification of the subtelomeric fragment yielded homogeneous product of minimum possible length even though the telomeric-specific primer can bind, at least initially, at a multiplicity of GGGGTT repeats. Amplified 5'NTS product also was detected in an ethidium-bromide-stained gel when PCR was started with a single cell.     

PCR bias in amplification of androgen receptor alleles, a trinucleotide repeat marker used in clonality studies.

Trinucleotide CAG repeats in the X-linked human androgen receptor gene (HUMARA) have proved a useful means of determining X chromosome haplotypes, and when combined with methylation analysis of nearby cytosine residues permits identification of non-random X inactivation in tumors of women. Co-amplification of two alleles in a heterozygote generates PCR products which differ in the number of CAG units, and thus their melting and secondary structure characteristics. We have shown that under optimal conditions amplification efficiency of two HUMARA alleles is near-equivalent, generating PCR products in a ratio proportional to that of the genomic template. In contrast, reduction of template quantity, damage of template by ultraviolet irradiation or addition of monovalent salts (sodium chloride, sodium acetate or ammonium acetate) produces highly variable imbalances of allelic PCR products, with a strong tendency to preferentially amplify lower molecular weight alleles. Variability and biasing was diminished by substitution of 7-deaza-2'-dGTP for dGTP during amplification, an intervention which reduces stability of intramolecular and intermolecular GC base pairing. We conclude that DNA which is scanty, damaged or salt contaminated may display amplification bias of GC-rich PCR targets, potentially confounding accurate interpretation or reproducibility of assays which require co-amplification of alleles.     

DNA ligase I competes with FEN1 to expand repetitive DNA sequences in vitro

Repeat sequences in various genomes undergo expansion by poorly understood mechanisms. By using an oligonucleotide system containing such repeats, we recapitulated the last steps in Okazaki fragment processing, which have been implicated in sequence expansion. A template containing either triplet or tandem repeats was annealed to a downstream primer containing complementary repeats at its 5'-end. Overlapping upstream primers, designed to strand-displace varying numbers of repeats in the downstream primer, were annealed. Human DNA ligase I joined overlapping segments of repeats generating an expansion product from the primer strands. Joining efficiency decreased with repeat length. Flap endonuclease 1 (FEN1) cleaved the displaced downstream strand and together with DNA ligase I produced non-expanded products. However, both expanded and non-expanded products formed irrespective of relative nuclease and ligase concentrations tested or enzyme addition order, suggesting the pre-existence and persistence of intermediates leading to both outcomes. FEN1 activity decreased with the length of repeat segment displaced presumably because the flap forms structures that inhibit cleavage. Increased MgCl(2) disfavored ligation of substrate intermediates that result in expansion products. Examination of expansion in vitro enables dissection of substrate and replication enzyme dynamics on repeat sequences.     

The human neutrophil elastase gene. Analysis of the nucleotide sequence reveals three distinct classes of repetitive DNA

DNA sequence analysis reveals the gene encoding human neutrophil elastase to be contained on a 6-kb EcoRI fragment. The gene contains five exons and closely resembles rat mast cell proteinase II and mouse adipsin in its exon structure and intron splice phase. Non-coding regions are very rich in repetitive DNA, containing seven Alu-like segments, three distinct clustered direct repeats with monomer lengths of 53 (six repeats), 23 (three repeats) and 41 (ten repeats) nucleotides, and a 200-nucleotide AT-rich region. Protein sequence analysis, inferred from the coding regions of the gene, indicates that neutrophil elastase may contain an unusual activation peptide similar to that found in the other major neutrophil serine proteinase, cathepsin G.     

PCR Amplification of Tetrahymena rDNA Segments Starting with Individual Cells

To facilitate studies of rDNA molecular genetics in Tetrahymena thermophila , we attempted the detection of polymorphisms in the nontranscribed spacers (NTSs) using polymerase chain reaction (PCR), starting with minute amounts of DNA. The targeted polymorphic regions are 85% adenine-thymine (AT). We found conditions of efficient and specific in vitro amplification of targeted segments in the replication domain of the 5'NTS and in the subtelomeric segment of the 3'NTS. The identity of the amplified segments was confirmed by restriction enzyme digestion and DNA sequence analysis. Digestion of the template DNA at restriction sites upstream and downstream of the targeted region increased the efficiency of amplification, presumably because the targeted segments are in a palindromic molecule. Starting from total cell DNA corresponding to as little as 0.03 picogram (equivalent to the DNA content of 0.003 cells or about 30 rDNA molecules), we observed the amplified band after agarose gel electrophoresis and ethidium bromide staining. The yield indicated more than 10-billion-fold amplification. Amplification of the subtelomeric fragment yielded homogeneous product of minimum possible length even though the telomeric-specific primer can bind, at least initially, at a multiplicity of GGGGTT repeats. Amplified 5'NTS product also was detected in an ethidium-bromide-stained gel when PCR was started with a single cell.     

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.     

Uracil DNA glycosylase-mediated cloning of polymerase chain reaction-amplified DNA: application to genomic and cDNA cloning.

A simple and rapid method for cloning of amplification products directly from the polymerase chain reaction (PCR) has been developed. The method is based on the addition of a 12-base dUMP-containing sequence (CUACUACUACUA) to the 5' end of PCR primers. Incorporation of these primers during PCR results in the selective placement of dUMP residues into the 5' end of amplification products. Selective degradation of the dUMP residues in the PCR products with uracil DNA glycosylase (UDG) disrupts base pairing at the termini and generates 3' overhangs. Annealing of 3' protruding termini to vector DNA containing complementary 3' ends results in chimeric molecules which can be transformed, with high efficiency, without in vitro ligation. Directional cloning of PCR products has also been accomplished by incorporating different dU-containing sequences at the end of each PCR primer. Substitution of all dT residues in PCR primers with dU eliminates cloning of aberrant "primer dimer" products and enriches cloning of genuine PCR products. The method has been applied to cloning of inter-Alu DNA sequences from human placental DNA. Using a single primer, DNA sequences between appropriately oriented Alu sequences were amplified and cloned. Cloning of cDNA for the glyceraldehyde-3'-phosphate dehydrogenase gene from rat brain RNA was also demonstrated. The 3' end region of this gene was amplified by the 3' RACE method and the amplified DNA was cloned after UDG digestion. Characterization of cloned DNAs by sequence analysis showed accurate repair of the cloning junctions. The ligase-free cloning method with UDG should prove to be a widely applicable procedure for rapid cloning of PCR-amplified DNA.     

Artificial DNA splicing using directed ligation]

An approach to the directed genetic recombination in vitro has been devised, which allows for joining, in a predetermined chemical-enzymatic way, a series of DNA segments to give a precisely spliced polynucleotide sequence (DNA Splicing by Directed Ligation, SDL). The approach makes use of amplification, by several polymerase chain reactions (PCR), of the chosen DNA segments. The corresponding primers contain recognition sites of the class IIS restriction endonucleases, yielding protruding ends of unique primary structures. The protruding ends of the segments to be joined together are structurally predetermined to make them mutually complementary. Ligation of the mixture of the segments so synthesized gives the desired sequence in an unambiguous way. The suggested approach has been exemplified by the synthesis of a totally processed (intronless) gene encoding human mature interleukin-1 alpha.     

Nucleotide sequence determination of point mutations at the mouse HPRT locus using in vitro amplification of HPRT mRNA sequences

Cloning of genomic and cDNA sequences of mammalian genes has made it possible to analyze at the molecular level mutations induced by radiation and chemical mutagens. The X-linked HPRT gene is very suitable for these investigations because in addition to the availability of cell culture systems, HPRT mutants can also be obtained directly from the lymphocytes of mouse and man. Recently a new technique has been introduced by Saiki and co-workers which allows the cloning and sequencing of small specific DNA segments from total genomic DNA after in vitro amplification of those segments up to 200,000-fold (Saiki et al., 1985). We have adapted this so-called polymerase chain reaction (PCR) procedure in such a way that the entire mouse HPRT-coding region could be amplified, cloned and sequenced. Instead of genomic DNA, we have used RNA as template in the PCR reactions. This allows us to detect point mutations in HPRT exon sequences in a very efficient way, since the DNA sequence of all 9 exons, which are scattered over 34 kb of DNA, can be obtained from only one amplification experiment. We studied the nature of 3 N-ethyl-N-nitrosourea (ENU)-induced HPRT mutants from cultured mouse lymphoma cells. One contains an A:T----G:C transition, the second an A:T----T:A transversion, whereas the third mutant is the result of abnormal splicing events, probably due to a mutation in the 3' splice site of the first intron.     

DNA binding specificity of proteins derived from alternatively spliced mouse p53 mRNAs.

The mouse p53 gene generates two alternative splice products encoding p53 protein and a naturally occurring protein (p53as) with changes at the C-terminus. In p53as the negative regulatory region for DNA binding and PAb421 antibody binding site are replaced, and p53as is constitutively active for sequence-specific DNA binding. Using the technique of randomized synthetic oligonucleotide in cyclic amplification and selection of targets, we have found that p53as and p53 proteins have the same DNA binding specificities but that these specificities frequently diverge from the consensus of two copies of PuPuPuCATGPyPyPy. The importance of tetranucleotide CATG was confirmed but there was a less rigorous requirement for patterns of flanking or intervening sequences. In particular, the three purines upstream and three pyrimidines downstream of CATG are not required for p53 or p53as binding, 29 or more intervening nucleotides are tolerated, and one CATG is sufficient where adjacent nucleotides contain a region of homology with certain previously reported non-consensus p53 binding sequences. These results suggested further definition of the non-consensus motifs, and database searches with these uncovered additional candidate genes for p53 protein binding. We conclude that p53as and perhaps other activated forms of p53 exert their effects on the same genes and that differential activities of p53 protein forms are not due to inherently different sequence selectivities of DNA binding.     

Total synthesis of a tyrosine suppressor tRNA gene. XV. Synthesis of the promoter region.

By use of polynucleotide kinase and polynucleotide ligase, the 10 deoxyoligonucleotide segments, whose syntheses have been described in accompanying papers, have been joined to form the 62-nucleotide-long DNA corresponding to the promoter region of an Escherichia coli suppressor tRNA gene. The following sequence in the joining reactions was used to obtain error-free and optimal yields of the products: 1) joining of Segment P-1 to P-3 in the presence of Segment P-2; 2) joining of Segments P-4 to P-7 to form Duplex [P4-7]; 3) joining of Segments P-8 to P-10 to Duplex [P4-7] to form Duplex [P4-10]; and finally, 4) joining of P-(1 + 3) and P-2 to Duplex [P4-10] to form the total promoter Duplex [P].     

Chromosome micro‐dissection and region‐specific libraries from pachytene chromosomes of maize (Zea mays L.)

For the first time, pachytene chromosomes have been used for micro-dissection, amplification and cloning using the short arm of maize chromosome 6. For this purpose, methods for the preparation of unstained pachytene chromosomes were developed. In two separate experiments, 10 and 12 segments of the satellite region were isolated utilizing glass needles and DNA was amplified by linker-adaptor-PCR. After amplification, maize-specific DNA was verified by genomic Southern hybridizations. Chromosomal in situ suppression hybridization confirmed that the adaptor PCR products originated from the micro-dissected 6S region. The adaptor PCR products were cloned into a plasmid vector and the chromosome region-specific libraries were characterized.     

Single primer-mediated polymerase chain reaction: application in cloning of two different 5'-untranslated sequences of acidic fibroblast growth factor mRNA.

Polymerase chain reactions (PCR) are used to generate specific DNA sequences from minute amounts of DNA templates using a pair of oligonucleotide primers. To amplify regions of unknown sequence, methods such as inverted PCR, Alu PCR, and rapid amplification of cDNA ends (RACE) have been developed. These methods require several enzymatic manipulations of DNA which are either tedious or only suitable for certain special conditions. We have explored the possibility of PCR using a single primer. This method takes advantage of the fact that partial complementarity provides sufficient affinity for the oligonucleotide primer to anneal to a secondary, imperfect binding site. Thus, no modification of DNA template was required for the single primer-mediated PCR. We have used this method to generate two different aFGF cDNA clones containing different 5'-untranslated sequences.     

Diverse organization of immunoglobulin VH gene loci in a primitive vertebrate.

The immunoglobulin (Ig) heavy chain variable (VH) gene family of Heterodontus francisci (horned shark), a phylogenetically distant vertebrate, is unique in that VH, diversity (DH), joining (JH) and constant region (CH) gene segments are linked closely, in multiple individual clusters. The V regions of 12 genomic (liver and gonad) DNA clones have been sequenced completely and three organization patterns are evident: (i) VH-D1-D2-JH-CH with unique 12/22 and 12/12 spacers in the respective D recombination signal sequences (RSSs); VH and JH segments have 23 nucleotide (nt) spacers, (ii) VHDH-JH-CH, an unusual germline configuration with joined VH and DH segments and (iii) VHDHJH-CH, with all segmental elements being joined. The latter two configurations do not appear to be pseudogenes. Another VH-D1-D2-JH-CH gene possesses a D1 segment that is flanked by RSSs with 12 nt spacers and a D2 segment with 22/12 spacers. Based on the comparison of spleen, VH+ cDNA sequences to a germline consensus, it is evident that both DH segments as well as junctional and N-type diversity account for Ig variability. In this early vertebrate, the Ig genes share unique properties with higher vertebrate T-cell receptor as well as with Ig and may reflect the structure of a common ancestral antigen binding receptor gene.