Optimization of the polymerase chain reaction with regard to fidelity: modified T7, Taq, and vent DNA polymerases

Genotypic selection methods for the direct analysis of point mutations

Genotypic selection enriches a particular DNA sequence relative to another closely-related DNA sequence based only on a change of one or a few bases. This review is a survey of the genotypic selection methods that have the sensitivity to detect rare point mutations. These methods are primarily being used to study mutations caused by environmental mutagens; however, the ability to detect and measure very minor DNA sequence populations is likely to further research efforts in many fields. The approaches for allele-selection have intrinsic strengths and weaknesses, and vary greatly in sensitivity. The most sensitive method is Restriction Fragment Length Polymorphism/Polymerase Chain Reaction (RFLP/PCR) by which mutant fractions as low as 1 mutant allele in 10(8) wild-type alleles can be detected. The RFLP/PCR approach is presented as a prototype genotypic selection method. Genotypic selection methods are categorized in terms of those that (1) selectively destroy the abundant or wild-type allele, (2) selectively amplify the rare or mutant allele, or (3) spatially separate the alleles. Issues relevant to the further development of genotypic selection methods include initial DNA pool size, strategies to eliminate the bulk of extraneous DNA, the use of an internal copy number standard in quantitative PCR, the fidelity of thermostable DNA polymerases, and the effective use of PCR in linking two or more genotypic selection techniques. We conclude that proficient genotypic selection requires more than one allele-enrichment technique with at least one of these preceding a high-fidelity PCR amplification step.

Fidelity and mutational spectrum of Pfu DNA polymerase on a human mitochondrial DNA sequence

The study of rare genetic changes in human tissues requires specialized techniques. Point mutations at fractions at or below 10(-6) must be observed to discover even the most prominent features of the point mutational spectrum. PCR permits the increase in number of mutant copies but does so at the expense of creating many additional mutations or "PCR noise". Thus, each DNA sequence studied must be characterized with regard to the DNA polymerase and conditions used to avoid interpreting a PCR-generated mutation as one arising in human tissue. The thermostable DNA polymerase derived from Pyrococcus furiosus designated Pfu has the highest fidelity of any DNA thermostable polymerase studied to date, and this property recommends it for analyses of tissue mutational spectra. Here, we apply constant denaturant capillary electrophoresis (CDCE) to separate and isolate the products of DNA amplification. This new strategy permitted direct enumeration and identification of point mutations created by Pfu DNA polymerase in a 96-bp low melting domain of a human mitochondrial sequence despite the very low mutant fractions generated in the PCR process. This sequence, containing part of the tRNA glycine and NADH dehydrogenase subunit 3 genes, is the target of our studies of mitochondrial mutagenesis in human cells and tissues. Incorrectly synthesized sequences were separated from the wild type as mutant/wild-type heteroduplexes by sequential enrichment on CDCE. An artificially constructed mutant was used as an internal standard to permit calculation of the mutant fraction. Our study found that the average error rate (mutations per base pair duplication) of Pfu was 6.5 x 10(-7), and five of its more frequent mutations (hot spots) consisted of three transversions (GC-->TA, AT-->TA, and AT-->CG), one transition (AT-->GC), and one 1-bp deletion (in an AAAAAA sequence). To achieve an even higher sensitivity, the amount of Pfu-induced mutants must be reduced.

PCR fidelity of pfu DNA polymerase and other thermostable DNA polymerases

The replication fidelities of Pfu, Taq, Vent, Deep Vent and UlTma DNA polymerases were compared using a PCR-based forward mutation assay. Average error rates (mutation frequency/bp/duplication) increased as follows: Pfu (1.3 x 10(-6)) < Deep Vent (2.7 x 10(-6)) < Vent (2.8 x 10(-6)) < Taq (8.0 x 10(-6)) < < exo- Pfu and UlTma (approximately 5 x 10(-5)). Buffer optimization experiments indicated that Pfu fidelity was highest in the presence of 2-3 mM MgSO4 and 100-300 microM each dNTP and at pH 8.5-9.1. Under these conditions, the error rate of exo- Pfu was approximately 40-fold higher (5 x 10(-5)) than the error rate of Pfu. As the reaction pH was raised from pH 8 to 9, the error rate of Pfu decreased approximately 2-fold, while the error rate of exo- Pfu increased approximately 9-fold. An increase in error rate with pH has also been noted for the exonuclease-deficient DNA polymerases Taq and exo- Klenow, suggesting that the parameters which influence replication error rates may be similar in pol l- and alpha-like polymerases. Finally, the fidelity of 'long PCR' DNA polymerase mixtures was examined. The error rates of a Taq/Pfu DNA polymerase mixture and a Klentaq/Pfu DNA polymerase mixture were found to be less than the error rate of Taq DNA polymerase, but approximately 3-4-fold higher than the error rate of Pfu DNA polymerase.

Fidelity and predominant mutations produced by deep vent wild-type and exonuclease-deficient DNA polymerases during in vitro DNA amplification

Denaturing gradient gel electrophoresis (DGGE) was used to examine error rates and mutations induced by native (wt) and exonuclease-deficient (exo-) Deep Vent DNA polymerases during DNA amplification by polymerase chain reaction (PCR), in the presence or absence of the T4 bacteriophage gene 32 protein (gp32).gp32 was found to decrease the error rate of the wt, but not that of the exo-, Deep Vent. The average errors per base duplication for the native form were 8.0 x 10(-5) and 6.0 x 10(-5) in the absence and presence of gp32, respectively. For the exo- form, the error rates were 2.0 x 10(-4) and 2.2 x 10(-4) errors per base duplication in the absence and presence of gp32, respectively. Examination of mutations produced by native Deep Vent showed that A/T to G/C transition predominated, consistent with the results of our earlier studies with DNA polymerases derived from other thermophilic bacteria. These results indicate that PCR with high fidelity can be achieved by using wt Deep Vent in combination with gp32.

Conservation of the sporozoite p67 vaccine antigen in cattle-derived Theileria parva stocks with different cross-immunity profiles

Immunity to Theileria parva infection in cattle is often parasite stock specific. The antigenic diversity which is expressed at the schizont stage of the parasite together with a wild reservoir of the organism in buffalo has complicated the development of effective disease control by immunization. We have previously shown that about 70% of cattle inoculated with recombinant forms of p67, a sporozoite stage-specific surface antigen from the cattle-derived Muguga stock of the parasite, are immune to a homologous challenge. Thus, immune responses to p67 can play a role in immunity. The genes encoding this protein in five other parasite stocks have been sequenced. Here, we report that the p67 molecule encoded by four cattle-derived parasite stocks (Boleni, Uganda, Mariakani, and Marikebuni) that fall into different cross-immunity groups is identical in sequence to Muguga p67. The protein encoded by a buffalo-derived parasite exhibits 95% sequence identity with Muguga p67, the major difference being the presence of a 43-residue peptide insert. As predicted by these data, cattle inoculated with recombinant p67 can resist a heterologous cattle-derived parasite challenge. Seven of 12 cattle receiving a homologous Muguga challenge and 6 of 11 cattle receiving a heterologous Marikebuni challenge were immune to East Coast fever. These results extend earlier data suggesting that p67 is a conserved molecule and confirm its potential as a broad-spectrum vaccine antigen for the control of T. parva infection.

Synthesis of a modified gene encoding human ornithine transcarbamylase for expression in mammalian mitochondrial and universal translation systems: a novel approach towards correction of a genetic defect

The mitochondrial (MT) genome is a potential means of gene delivery to human cells for therapeutic expression. As a first step towards this, we have synthesized a gene coding for mature human ornithine transcarbamylase (OTC) by recursive PCR using 18 oligodeoxyribonucleotides, each 70-80 nucleotides in length, using codons which should allow translation in accordance with both mammalian mt and universal codon usage. Flanking mt DNA sequences were incorporated which are designed to facilitate site-specific cloning into the mt genome. Expression of this human gene in Escherichia coli leads to an immunoreactive OTC product of the correct size and N-terminal amino-acid sequence, but which forms inclusion bodies and lacks enzymatic activity.

The polymerase chain reaction: applications for the detection of foodborne pathogens

Faster methods for the detection of foodborne microbial pathogens are needed. The polymerase chain reaction (PCR) can amplify specific segments of DNA and is used to detect and identify bacterial genes responsible for causing diseases in humans. The major features and requirements for the PCR are described along with a number of important variations. A considerable number of PCR-based assays have been developed, but they have been applied most often to clinical and environmental samples and more rarely for the detection of foodborne microorganisms. Much of the difficulty in implementing PCR for the analysis of food samples lies in the problems encountered during the preparation of template DNAs from food matrices; a variety of approaches and considerations are examined. PCR methods developed for the detection and identification of particular bacteria, viruses, and parasites found in foods are described and discussed, and the major features of these reactions are summarized.

Fetal VDJ gene repertoire in rabbit: evidence for preferential rearrangement of VH1

B cells in rabbit preferentially utilize the 3'-most VH gene, VH1, in VDJ genes. To determine whether the preferential utilization of VH1 results from preferential rearrangement, we examined VH gene usage in nonproductive VDJ gene rearrangements, genes that would not be influenced by antigen selection. Since nonproductive VDJ gene rearrangements are found infrequently in neonatal and adult rabbits, we examined the VDJ gene rearrangements during early fetal development. According to nested-primer polymerase chain reaction analyses, VDJ genes in fetal liver appeared around day 14 of gestation and nucleotide sequence analyses of VDJ genes cloned from 14- to 28-day-old fetuses showed that many of the genes were nonproductive. We found that most of these nonproductive genes had utilized VH1 indicating to us that the preferential utilization of VH1 is due to preferential rearrangement. We compared the nucleotide sequence of the promoter region of VH1 with sequences of several other unutilized and infrequently utilized VH genes and found that the core transcriptional factor motifs were similar in all VH promoters examined. We suggest that transcriptional activity of the VH1 promoter region does not explain the preferential rearrangement of VH1.

The cardiovirulent phenotype of coxsackievirus B3 is determined at a single site in the genomic 5' nontranslated region

We report the construction of chimeric coxsackievirus B3 (CVB3) strains in which sequences of an infectious cDNA copy of a noncardiovirulent CVB3 genome were replaced by the homologous sequences from a cardiovirulent CVB3 genome to identify which of 10 predicted genetic sites determine cardiovirulence. Cardiovirulent phenotype expression was consistently linked to nucleotide 234 (U in cardiovirulent CVB3 and C in avirulent CVB3) in the 5' nontranslated region. Reconstructions of the parental noncardiovirulent CVB3 genome from chimeras restored the noncardiovirulent phenotype when tested in mice. Inoculation of severe combined immunodeficient (scid) mice with the noncardiovirulent CVB3 strain resulted in massive cardiomyocyte necrosis in all animals. Sequence analysis of viral genomes isolated from twelve scid mouse hearts showed that only nucleotide position 234 was different (a C-->U transition) from that in the input parental noncardiovirulent CVB3 genome. Higher-order RNA structures predicted by two different algorithms did not demonstrate an obvious local effect caused by the C-->U change at nucleotide 234. Initial studies of parental and chimeric CVB3 replication in primary cultures of fetal murine heart fibroblasts and in adult murine cardiac myocytes demonstrated that viral RNA transcriptional efficiency is approximately 10-fold lower for noncardiovirulent CVB3 than for cardiovirulent CVB3. CVB3 did not shut off protein synthesis in murine cardiac fibroblasts, nor were levels of viral protein synthesis significantly different as a function of viral phenotype. Taken together, these data support a significant role for determination of the CVB3 cardiovirulence phenotype by nucleotide 234 in the 5' nontranslated region, possibly via a transcriptional mechanism.

Evolutionary trail of the mitochondrial genome as based on human 16S rDNA pseudogenes

In the course of studies on mutations in human mitochondrial (mt) DNA, we have uncovered and sequenced four new nuclear pseudogenes corresponding to bp 2457-2657 of the mt 16S rDNA. The four genes and their homologies with human mtDNA are E2 (62.4%), K10 (74.4%), E1 (84.6%) and LE6 (93.2%). When these five pseudogene sequences and another previously reported pseudogene sequence are compared with each other, they display what appears to be an ordered series of steps from a hypothetical common ancestor. The sequence of the hypothetical ancestor closely resembles that found in a wide variety of present-day mammalian mt genomes. The pseudogene sequences suggest an evolutionary trail of mt mutation dominated by base pair transitions punctuated by integration into the nuclear genome. Once integrated into the nuclear genome, the pseudogenes appear to follow the distinctive nuclear mutational pathway in which GC to AT transitions predominate and CpG sequences are preferentially eliminated.

Effects of the T4 bacteriophage gene 32 product on the efficiency and fidelity of DNA amplification using T4 DNA polymerase

Two bacteriophage DNA polymerases (Pol), T4 Pol and modified T7 Pol, were used to catalyze DNA amplification in vitro by PCR, and their efficiency and fidelity in DNA amplification were examined in the presence and absence of the T4 bacteriophage gene 32-encoded protein (SSB32). The SSB32 protein significantly improved the efficiency of amplification by T4 Pol. Examination of the amplified DNA by denaturing gradient gel electrophoresis (DGGE) revealed that the protein also reduced the rates of error produced by T4 Pol during PCR, from 6.3 x 10(-6) to 2.0 x 10(-6) errors per base duplication after 10(11)-fold amplification. This protein also improved, but to a lesser extent, the fidelity of modified T7 Pol, from 1.80 x 10(-5) to 1.15 x 10(-5) errors per base duplication. High fidelity polymerase chain reaction (hifi-PCR) is needed for studies requiring isolation of mutant sequences present as only a small fraction of the wild type in the amplified DNA. Although several thermostable Pol are currently available for use in automated PCR, their fidelity was found to be significantly lower than that of the thermosensitive T4 Pol. Therefore, T4 Pol is useful for studies requiring hifi-PCR, although this enzyme needs to be added in the reaction mixture during every cycle of PCR.

Improved polymerase fidelity in PCR-SSCPA

Polymerase fidelity is important in any application of the polymerase chain reaction (PCR). In single-strand conformation polymorphism analysis (SSCPA) where one may be looking for a small number of altered DNA strands in the presence of thousands of unchanged strands it is critical. We have examined the effect of PCR conditions, product purification and SSCP analysis on the measured error rates with 4 thermostable polymerases (Taq, Vent, Pyrostase and Pfu). Error rates have been calculated by densitometric scanning of SSCPA gel images. Using PCR conditions which maximize fidelity and eliminating products which include large additions or deletions we have achieved error rates of 10(-5) to 10(-6). Such low rates heighten the probability that relatively infrequent mutations will be identified. Further, the densitometric scanning of gel images provides a useful modification of conventional SSCPA which facilitates such identification.

Molecular cloning and bacterial expression of cDNA for rat calpain II 80 kDa subunit

The complete cDNA of 3.2 kb for rat calpain II large subunit has been constructed from library- and polymerase chain reaction-derived fragments, and sequenced. The cDNA encodes a protein of 700 amino acids having 93% sequence identity with human calpain II, and 61% identity with human calpain I. The gene possesses 21 exons, of which exons 3-21 have been mapped over 33 kb of the rat genome. A new phagemid expression vector was created from pT7-7 by insertion of the f1 origin and mutation of an NdeI to an NcoI site. Rat calpain II cDNA ligated into this vector expressed in Escherichia coli an 80 kDa protein identical in size to highly purified rat calpain II; this protein was specifically recognized on immunoblots by an affinity-purified anti-rat calpain II antibody. This is the second mammalian calpain II large subunit to be fully sequenced, and the first to be artificially expressed.

Amplification and sequencing of variable regions in bacterial 23S ribosomal RNA genes with conserved primer sequences

Published bacterial 23S ribosomal RNA sequences were aligned, and universally conserved regions flanking highly variable regions were looked for. In strategically positioned conserved regions, six oligonucleotides suitable for polymerase chain reaction (PCR) and sequencing were designed, allowing fast sequencing of four of the most variable 23S rRNA regions. Two other primers were designed for PCR amplification of nearly complete 23S rRNA genes. All these primers successfully amplified fragments of 23S rRNA genes from seven unrelated bacteria. Four primers were used to determine 938 bp of sequence for Campylobacter jejuni subsp. jejuni. These results indicate that the oligonucleotide sequences presented here are useful for PCR amplification and sequence determination of variable 23S rRNA regions for a broad variety of eubacterial species.

Methods used for analyses of "environmentally" damaged nucleic acids

In this review, we present various techniques, currently applied in many laboratories, which are useful in the detection of "environmentally"-induced damage to DNA. These techniques include: (a) chromatographic methods, which allow determination of chemical changes within DNA, be they formation of adducts with or oxidation of bases in DNA; (b) electrophoretic methods, which facilitate finding the site(s) in DNA where that chemical modification occurred; and (c) immunological assays, which help to detect DNA damage using externally produced antibodies that recognize the specific chemical changes in DNA or its fragments, as well as by detection of autoantibodies that develop in response to environmental exposures of animals and humans.

Mutational analysis using denaturing gradient gel electrophoresis and PCR

Denaturing gradient gel electrophoresis (DGGE) separates (DNA) molecules based on their sequence. Using the proper conditions, all base-pair substitutions can be resolved from the wild-type sequence using DGGE. Polymerase chain reaction (PCR) permits rapid amplification of a given region of the genome. In this paper, we demonstrate the utility of DGGE combined with PCR for mutation analysis by presenting different examples: (i) analysis of mouse p53 cDNA for mutations, (ii) simultaneous analysis of thousands of 4NQO-induced mutants for mutations in HPRT exon 3, (iii) examination of the fidelity of the thermostable DNA polymerase isolated from Pyrococcus furiosus (Pfu), (iv) purification of mutant DNA from contaminating wild-type DNA from mouse spleenic T-cell clones.

Analysis of a protein-binding domain of p53

The tumor suppressor protein p53 was first isolated as a simian virus 40 large T antigen-associated protein and subsequently was found to function in cell proliferation control. Tumor-derived mutations in p53 occur predominantly in four evolutionarily conserved regions spanning approximately 50% of the polypeptide. Previously, three of these regions were identified as essential for T-antigen binding. We have examined the interaction between p53 and T antigen by using Escherichia coli-expressed human p53. By a combination of deletion analysis and antibody inhibition studies, a region of p53 that is both necessary and sufficient for binding to T antigen has been localized. This function is contained within residues 94 to 293, which include the four conserved regions affected by mutation in tumors. Residues 94 to 293 of p53 were expressed in both wild-type and mutant forms. T-antigen binding was unaffected by tumor-derived mutations which have been associated with the wild-type conformation of p53 but was greatly reduced by mutations which were previously shown to alter p53 conformation. Our results show that, like T-antigen binding to the Rb tumor suppressor protein, T antigen appears to interact with the domain of p53 that is commonly mutated in human tumors.

Analysis of a protein-binding domain of p53

The tumor suppressor protein p53 was first isolated as a simian virus 40 large T antigen-associated protein and subsequently was found to function in cell proliferation control. Tumor-derived mutations in p53 occur predominantly in four evolutionarily conserved regions spanning approximately 50% of the polypeptide. Previously, three of these regions were identified as essential for T-antigen binding. We have examined the interaction between p53 and T antigen by using Escherichia coli-expressed human p53. By a combination of deletion analysis and antibody inhibition studies, a region of p53 that is both necessary and sufficient for binding to T antigen has been localized. This function is contained within residues 94 to 293, which include the four conserved regions affected by mutation in tumors. Residues 94 to 293 of p53 were expressed in both wild-type and mutant forms. T-antigen binding was unaffected by tumor-derived mutations which have been associated with the wild-type conformation of p53 but was greatly reduced by mutations which were previously shown to alter p53 conformation. Our results show that, like T-antigen binding to the Rb tumor suppressor protein, T antigen appears to interact with the domain of p53 that is commonly mutated in human tumors.

Rapid characterization of HIV-1 sequence diversity using denaturing gradient gel electrophoresis and direct automated DNA sequencing of PCR products

A direct method for visualization and isolation of sequence variants of human immunodeficiency virus type 1 (HIV-1) utilizing denaturing gradient gel electrophoresis (DGGE) combined with automated direct DNA sequencing was developed. Two fragments from the env gene and one from the nef gene of HIV-1, which together constitute approximately 1.0 kb of sequence, were amplified by PCR and analyzed. HIV-1 variants from each region were resolved and excised from the gel; this was followed by direct sequencing of different viral variants. In 9 infected patients, a limited number of dominant sequence variants could be seen in the three regions, together with a faint background of minor variants. The use of DGGE makes it possible to obtain a direct estimate of overall HIV-1 sequence diversity within patient samples without an intermediate DNA cloning step.

Induction of cell differentiation by human immunodeficiency virus 1 vpr

Cell lines from rhabdomyosarcomas, which are tumors of muscle origin, have been used as models of CD4-independent HIV infection. These cell lines can be induced to differentiate in vitro. We report here that the vpr gene of HIV1 is sufficient for the differentiation of the human rhabdomyosarcoma cell line TE671. Differentiated cells are characterized by great enlargement, altered morphology, lack of replication, and high level expression of the muscle-specific protein myosin. We have also observed the morphological differentiation and inhibition of proliferation of two other transformed cell lines. vpr-transfected cells remain fully viable in culture for extended periods. These observations elucidate a potential role for vpr in the virus life cycle and raise the possibility that some aspects of HIV-induced pathologies may be caused by a disturbance of cells by vpr.

Mismatch amplification mutation assay (MAMA): application to the c-H-ras gene

We have found that under appropriate conditions, an allele-specific polymerase chain reaction (PCR) can achieve a sensitivity suitable for measuring specific, infrequent mutations in single cell systems or in animal tissues. Using the 12th codon GC-to-AT mutation in the rat c-Ha-ras gene as a model system, we have defined conditions that allow for measurement of mutations present at frequencies as low as one in 10(5) gene copies. Our approach involved the use of PCR primers that created a single mismatch with the mutated allele (GAA) but created a double mismatch with the wild-type allele (GGA). Five out of the six such double-mismatch primers we tested permitted amplification of the mutant allele (GAA) with a high degree of specificity. The specificity of the assay was further enhanced by using a two-step PCR cycle consisting of a denaturation step (1 min incubation at 94 degrees C) and an annealing/extension step (1 min incubation at 50 degrees C) in the presence of 10% (vol/vol) glycerol. Reconstruction experiments using genomic DNA demonstrate that this procedure cna measure the presence of 30 copies of the transforming ras allele present amongst 3 x 10(6) copies of the wild-type allele.

Randomization of genes by PCR mutagenesis

A modified polymerase chain reaction (PCR) was developed to introduce random point mutations into cloned genes. The modifications were made to decrease the fidelity of Taq polymerase during DNA synthesis without significantly decreasing the level of amplification achieved in the PCR. The resulting PCR products can be cloned to produce random mutant libraries or transcribed directly if a T7 promoter is incorporated within the appropriate PCR primer. We used this method to mutagenize the gene that encodes the Tetrahymena ribozyme with a mutation rate of 0.66% +/- 0.13% (95% C.I.) per position per PCR, as determined by sequence analysis. There are no strong preferneces with respect to the type of base substituion. The number of mutations per DNA sequence follows a Poisson distribution and the mutations are randomly distributed throughout the amplified sequence.

Immunoglobulin heavy chain gene expression in peripheral blood B lymphocytes

cDNA libraries for IgM heavy chain variable regions were prepared from unmanipulated peripheral blood lymphocytes of two healthy people. Partial sequencing of 103 clones revealed VH gene family use and complete CDR3 and JH sequences. The libraries differed in the two subjects. In one person's cDNA the VH5 family was overexpressed and the VH3 family underexpressed relative to genomic complexity. In the second person's cDNA, VH3 was most frequently expressed. In both libraries, JH4 was most frequent. VH segments of several clones were closely related to those in fetal repertoires. However, there was also evidence of mutation in many cDNAs. Three clones differed from the single nonpolymorphic VH6 germline gene by 7-13 bases. Clones with several differences from VH5 germline gene VH251 were identified. CDR3 segments were highly diverse. JH portions of several CDR3's differed from germline JH sequences. 44% of the clones had DH genes related to the DLR and DXP families, most with differences from germline sequences. In 11 DLR2-related sequences, several base substitutions could not be accounted for by polymorphism. Thus, circulating IgM-producing B cell populations include selected clones, some of which are encoded by variable region gene segments that have mutated from the germline form.

The fidelity of Taq polymerase catalyzing PCR is improved by an N-terminal deletion

KlenTaq DNA polymerase is an N-terminally truncated Thermus aquaticus (Taq) DNA polymerase I. As expressed from a gene construct in Escherichia coli, translation initiates at Met236, bypassing the 5'----3' exonuclease domain of the DNA polymerase-encoding gene. A sensitive forward mutation assay was used to measure the relative number of mutations introduced into the entire lacZ gene by the polymerase chain reaction (PCR) under various conditions which allow the amplification of such a large DNA span. Two selectable markers, one at each end of the test lacZ fragment, were employed to avoid the plating and scoring of PCR artefacts such as primer initiation in the midst of the lacZ gene, and cloning artefacts such as empty vector plasmid. The measured relative mutation rate was twofold lower for KlenTaq as compared to the full-length Taq DNA polymerase.

Molecular cloning and expression of the bacteriophage T7 0.7(protein kinase) gene

The bacteriophage T7 0.7 gene encodes a protein which supports viral reproduction under specific suboptimal growth conditions. The 0.7 protein (gp0.7) shuts off host RNA polymerase-catalyzed transcription and also expresses a serine/threonine-specific, cAMP-independent protein kinase (PK) activity. To determine the role of the gp0.7 PK in viral reproduction, the 0.7 gene of the T7(JS78) mutant phage--whose gp0.7 expresses only the PK activity--was cloned in the plasmid expression vector pET-11a. Cells containing the recombinant plasmid were viable, and upon IPTG induction produced a 30-kDa polypeptide, similar in size to the gp0.7-related polypeptide seen in T7(JS78)-infected cells. Extracts of cells containing this polypeptide can phosphorylate the exogenous substrate lysozyme. Expression of plasmid-encoded gp0.7(JS78) in vivo results in phosphorylation of the same proteins which are phosphorylated in T7(JS78)-infected cells; moreover, the plasmid-encoded gp0.7(JS78) is itself phosphorylated. The JS78 mutation changes Gln243 in gp0.7 to an amber codon, which explains the production of the truncated, 30-kDa gp0.7-related polypeptide, and implicates the 11-kDa C-terminal domain in host transcription shut-off. The T7(A23) 0.7 point mutant fails to express PK activity in infected cells. However, the truncated T7(A23)-related polypeptide, expressed from a plasmid, exhibits PK activity in vivo and in vitro, but with an altered specificity. Thus, the A23 mutation, which changes Asp100 to Asn, may identify a substrate recognition determinant.

Ha-ras oncogene activation in mammary glands of N-methyl-N-nitrosourea-treated rats genetically resistant to mammary adenocarcinogenesis

A single dose of N-methyl-N-nitrosourea given to sexually immature female Buf/N rats produces a high incidence of mammary adenocarcinomas. A large percentage of these tumors contain the Ha-ras oncogene, activated by a G----A transition at the second nucleotide of codon 12. Copenhagen rats, on the other hand, are completely resistant to mammary tumor induction by a number of carcinogens, including N-methyl-N-nitrosourea. Here we show, using a sensitive method involving PCR, that codon 12 Ha-ras mutations occur in the mammary glands of both Buf/N and Copenhagen rats 30 days after N-methyl-N-nitrosourea treatment. These mutations were evenly distributed among individual mammary glands and were present in purified mammary epithelial cells. In Buf/N rats, the fraction of cells containing a mutated Ha-ras allele increased by a factor of 10-100 between 30 and 60 days, whereas in Copenhagen rats, there was no such increase during this time period. We conclude that the resistance of the Copenhagen rat to mammary carcinogenesis is not due to a defect in initiation but rather appears to be due to the inability of cells containing a mutated ras allele to undergo sustained clonal expansion.

Construction of synthetic genes using PCR after automated DNA synthesis of their entire top and bottom strands

A new method is described for the direct construction of synthetic genes by applying a modified version of the polymerase chain reaction (PCR) to crude oligonucleotide mixtures made by automated solid phase DNA synthesis. Construction of the HIV-1 393 bp rev gene and the 655 bp nef gene by this method is illustrated. The sequences for the entire top and bottom strands of rev were each programmed into an automated DNA synthesizer. Following DNA synthesis, the two crude oligonucleotide solutions were mixed together, specific primers were added, and the target gene was amplified by a modified PCR technique. Although the longer (greater than 200 bases) strands comprise a very small percentage of the total DNA after solid phase synthesis, this method uses PCR to 'find' and amplify such strands to create the target gene. The rev gene constructed by this method was found to contain 4 sequence errors, which were subsequently corrected by site-directed mutagenesis. In order to evaluate the source of sequence errors, several nef genes were made from the top and bottom strand DNA synthesis solutions using independent PCR's. Results suggest that sequence errors arose from both DNA synthesis and PCR. The utility of this method in producing a functional gene is demonstrated by expression of rev in E.coli.

DNA polymerase fidelity and the polymerase chain reaction

High-fidelity DNA synthesis conditions are those that exploit the inherent ability of polymerases to discriminate against errors. This review has described several experimental approaches for controlling the fidelity of enzymatic DNA amplification. One of the most important parameters to consider is the choice of which polymerase to use in PCR. As demonstrated by the data in Tables 2 and 3, high-fidelity DNA amplification will be best achieved by using a polymerase with an active 3'-->5' proofreading exonuclease activity (Fig. 1E). For those enzymes that are proofreading-deficient, the in vitro reaction conditions can significantly influence the polymerase error rates. To maximize fidelity at the dNTP insertion step (Fig. 1A,B), any type of deoxynucleoside triphosphate pool imbalance should be avoided. Similarly, stabilization of errors by polymerase extension from mispaired or misaligned primer-termini (Fig. 1D) can be minimized by reactions using short synthesis times, low dNTP concentrations, and low enzyme concentrations. Additional improvements in fidelity can be made by further manipulating the reaction conditions. To perform high-fidelity PCR with Taq polymerase, reactions should contain a low MgCl2 concentration, not in large excess over the total concentration of dNTP substrates, and be buffered to approximately pH 6 (70 degrees C) using Bis-Tris Propane or PIPES (Table 2). These buffers have a pKa between pH 6 and pH 7 and a small temperature coefficient (delta pKa/degree C), allowing the pH to be maintained stably throughout the PCR cycle. For amplifications in which fidelity is the critical issue, one should avoid the concept that conditions generating more DNA product are the better conditions.(ABSTRACT TRUNCATED AT 250 WORDS)