Influence of neighboring base sequence on mutagenesis induced by in vitro misincorporation in the lacI gene of Escherichia coli.

Genetic and electrophoretic assays of misincorporation were used to assess the effect of DNA sequence on mutagenesis arising from in vitro DNA synthesis within the lacI gene of Escherichia coli. The viral strand of a derivative of phage M13 containing the entire lacI gene was annealed with a series of synthetic oligonucleotides complementary to the N-terminal region of the lacI gene. Each primer-template was incubated with E. coli DNA polymerase I (Klenow fragment) under conditions favoring misincorporation, wherein one of the 4 dNTPs was lacking ('minus' reaction) or present at very low concentration ('micro' reaction). The extent of elongation of each primer was assessed by gel electrophoresis, and lacI mutants arising during the misincorporation reactions were detected by a transfection assay in which i- base substitutions within the in vitro synthesized strand were selectively recovered by the use of uracil-containing templates. Direct dideoxy sequencing of the '-A' reaction products and sequence analysis of i- mutant progeny revealed a vast predominance of single and non-tandem multiple base transitions. The addition of small quantities of dATP to a '-A' reaction increased the mutation yield and broadened the distribution of base substitutions along the template. We detected a general bias towards increased base substitution at template positions flanked by G.C base pairs or 5'-pyrimidine, 3'-purine nearest neighbors, although considerable site-to-site variation in the occurrence of base substitutions was seen, even within identical nearest neighbor contexts.     

DNA Sequence Effects on Single Base Deletions Arising during DNA Polymerization in Vitro by Escherichia Coli Klenow Fragment Polymerase

Most single base deletions detected after DNA polymerization in vitro directed by either Escherichia coli DNA polymerase I or its Klenow fragment are opposite Pu in the template. The most frequent study, were previously found to be associated with the consensus template context 5'-PyTPu-3'. In this study, the predictive power of the consensus sequence on single base deletion frequencies was directly tested by parallel comparison of mutations arising in four related DNAs differing by a single base. G, a deletion hotspot within the template context 5'-TTGA-3', was substituted by each of the 3 other bases. Previous studies had shown that deletions opposite the G were frequent but that deletions opposite its neighboring A were never detected. Based on the predictions of the consensus, the substitution of T for G should produce frequent deletions opposite the neighboring A due to its new 5'-TTTA-3' template context. This prediction was fulfilled; no deletions of this A were detected in the other templates. The consensus further predicted that deletions opposite template C would be lower than those opposite either A or G at the same site and this prediction was also fulfilled. The C substitution also produced a new hotspot for 1 bp deletions 14 bp away. The new hotspot depends on quasi-palindromic misalignment of the newly synthesized DNA strand during polymerization; accurate, but ectopically templated synthesis is responsible for this mutagenesis. Mutations templated by quasi-palindromic misalignments have previously been recognized when they produced complex sequence changes; here we show that this mechanism can produce frequent single base deletions. The unique stimulation of misalignment mutagenesis by the C substitution in the template is consistent with the singular ability of C at that site to contribute to extended complementary pairing during the DNA misalignment that precedes mutagenesis.     

A simple and rapid method for the selection of oligodeoxynucleotide-directed mutants

We describe an in vitro selection procedure for oligodeoxynucleotide-directed mutagenesis, which produces mutants at frequencies of greater than 90%, facilitating the identification of mutants directly by nucleotide sequencing. The method is based on the selective methylation of the mutant strand by the incorporation of 5-methyl-dCTP. Restriction endonuclease digestion of the resulting hemimethylated DNA with MspI results in the nicking of only the nonmethylated-parental strand. The parental strand is removed by treatment with exonuclease III. The mutants are recovered by transformation of a mcrAB strain of Escherichia coli with the nascent strand.     

Primer extension mutagenesis powered by selective rolling circle amplification

Primer extension mutagenesis is a popular tool to create libraries for in vitro evolution experiments. Here we describe a further improvement of the method described by T.A. Kunkel using uracil-containing single-stranded DNA as the template for the primer extension by additional uracil-DNA glycosylase treatment and rolling circle amplification (RCA) steps. It is shown that removal of uracil bases from the template leads to selective amplification of the nascently synthesized circular DNA strand carrying the desired mutations by phi29 DNA polymerase. Selective RCA (sRCA) of the DNA heteroduplex formed in Kunkel's mutagenesis increases the mutagenesis efficiency from 50% close to 100% and the number of transformants 300-fold without notable diversity bias. We also observed that both the mutated and the wild-type DNA were present in at least one third of the cells transformed directly with Kunkel's heteroduplex. In contrast, the cells transformed with sRCA product contained only mutated DNA. In sRCA, the complex cell-based selection for the mutant strand is replaced with the more controllable enzyme-based selection and less DNA is needed for library creation. Construction of a gene library of ten billion members is demonstrated with the described method with 240 nanograms of DNA as starting material.     

Loss of DNA polymerase beta stacking interactions with templating purines, but not pyrimidines, alters catalytic efficiency and fidelity.

Structures of DNA polymerases bound with DNA reveal that the 5'-trajectory of the template strand is dramatically altered as it exits the polymerase active site. This distortion provides the polymerase access to the nascent base pair to interrogate proper Watson-Crick geometry. Upon binding a correct deoxynucleoside triphosphate, alpha-helix N of DNA polymerase beta is observed to form one face of the binding pocket for the new base pair. Asp-276 and Lys-280 stack with the bases of the incoming nucleotide and template, respectively. To determine the role of Lys-280, site-directed mutants were constructed at this position, and the proteins were expressed and purified, and their catalytic efficiency and fidelity were assessed. The catalytic efficiency for single-nucleotide gap filling with the glycine mutant (K280G) was strongly diminished relative to wild type for templating purines (>15-fold) due to a decreased binding affinity for the incoming nucleotide. In contrast, catalytic efficiency was hardly affected by glycine substitution for templating pyrimidines (<4-fold). The fidelity of the glycine mutant was identical to the wild type enzyme for misinsertion opposite a template thymidine, whereas the fidelity of misinsertion opposite a template guanine was modestly altered. The nature of the Lys-280 side-chain substitution for thymidine triphosphate insertion (templating adenine) indicates that Lys-280 "stabilizes" templating purines through van der Waals interactions.     

Leading strand synthesis of R1 plasmid replication in vitro is primed by primase alone at a specific site downstream of oriR

By using an in vitro system for R1 plasmid replication dependent on a plasmid-encoded repA protein and host dnaA protein, 5' ends of the nascent leading strand were located at positions 1986-1992, some 380 base pair downstream of oriR. Analyses of early replication intermediates generated in vitro in the presence of dideoxy TTP also indicated that replication initiates about 400 base pair downstream of oriR and proceeds unidirectionally. When a 418-base single-stranded DNA from position 1778 to 2195, derived from the leading strand template, was cloned onto an M13 vector, the chimeric single-stranded phage could be replicated in vitro with only single-stranded DNA binding protein, primase (dnaG gene product), and DNA polymerase III holoenzyme. Furthermore, the priming occurred at a site identical to leading strand initiation. These results strongly suggest that the leading strand synthesis is primed by primase alone. The lagging strand synthesis is specifically terminated at position 1515 or 1516 within oriR, preventing further leftward fork movement. Based on these results, a scheme of R1 plasmid replication is presented.     

A new method for random mutagenesis of complete genes: enzymatic generation of mutant libraries in vitro

A new efficient in vitro mutagenesis method for the generation of complete random mutant libraries, containing all possible single base substitution mutations in a cloned gene is described. The method is based on controlled use of polymerases. Four populations of DNA molecules are first generated by primer elongation so that they terminate randomly, but always just before a known type of base (before A, C, G or T respectively). Each of the four populations is then mutagenized in a separate misincorporation reaction, where the correct base can now be omitted. The regeneration of wild-type sequences can thus be efficiently avoided. Also, the misincorporating nucleotide concentrations can be optimized to give the three possible single mutations in close to equal ratio. The mutagenesis can be precisely localized within a predetermined target region of any size, and vector sequences remain intact. We have mutagenized the DNA coding for the alpha-fragment of Escherichia coli beta-galactosidase, and identified 176 different base substitution mutations by sequencing. The present method gives mutant yields of 40-60%, when the mutants contain about one amino acid change per protein molecule. All types of base substitution mutations can be generated and deletions are rare. The efficiency of this method permits the use of relatively elaborate screening systems to isolate mutants of either structural genes or regulatory regions.     

A gradient PCR-based screen for use in site-directed mutagenesis

Site-directed mutagenesis is widely used to study protein and nucleic acid structure and function. Despite recent advancements in the efficiency of procedures for site-directed mutagenesis, the fraction of site-directed mutants by most procedures rarely exceeds 50% on a routine basis and is never 100%. Hence it is typically necessary to sequence two or three clones each time a site-directed mutant is constructed. We describe a simple and robust gradient-PCR-based screen for distinguishing site-directed mutants from the starting, unmutated plasmid. The procedure can use either purified plasmid DNA or colony PCR, starting from a single colony. The screen utilizes the primer used for mutagenesis and a common outside primer that can be used for all other mutants constructed with the same template. Over 30 site-specific mutants in a variety of templates were successfully screened and all of the mutations detected were subsequently confirmed by DNA sequencing. A single base pair mismatch could be detected in an oligonucleotide of 36 bases. Detection efficiency was relatively independent of starting template concentration and the nature of the outside primer used.     

Structural basis for uracil recognition by archaeal family B DNA polymerases

Deamination of cytosine to uracil in a G-C base pair is a major promutagenic event, generating G-C-->A-T mutations if not repaired before DNA replication. Archaeal family B DNA polymerases are uniquely able to recognize unrepaired uracil in a template strand and stall polymerization upstream of the lesion, thereby preventing the irreversible fixation of an A-T mutation. We have now identified a 'pocket' in the N-terminal domains of archaeal DNA polymerases that is positioned to interact with the template strand and provide this ability. The structure of this pocket provides interacting groups that discriminate uracil from the four normal DNA bases (including thymine). These groups are conserved in archaeal polymerases but absent from homologous viral polymerases that are unable to recognize uracil. Using site-directed mutagenesis, we have confirmed the biological role of this pocket and have engineered specific mutations in the Pfu polymerase that confer the ability to read through template-strand uracils and carry out PCR with dUTP in place of dTTP.     

Site-specific forced misincorporation mutagenesis using modified T7 DNA polymerase

A new method for forced misincorporation site-specific mutagenesis is described. The method uses an exonuclease-deficient modified version of T7 DNA polymerase in the presence of one dNTP to force a misincorporation. Analysis by PAGE is used to monitor the efficiency of such misincorporation reactions. Brief extension of the terminally mismatched primer/template using the same enzyme in the presence of all four dNTPs is followed by chase/ligation using unmodified T7 DNA polymerase and T4 DNA ligase to give heteroduplex DNA. We have applied the method to mutagenesis of the Lac Z region of M13 and found that, using strand selection, efficiencies of mutagenesis at one site are greater than 50%. When the mutating dNTP is complementary to a neighbouring homopolymeric tract on the template, multiple mutation is observed and efficiences are lower. The method is more general than internal mismatch mutagenesis and, because of its rapidity, is more expedient than existing methods of forced misincorporation mutagenesis.     

Misalignment-mediated DNA polymerase beta mutations: comparison of microsatellite and frame-shift error rates using a forward mutation assay

Mutations arising in microsatellite DNA are associated with neurological diseases and cancer. To elucidate the molecular basis of microsatellite mutation, we have determined the in vitro polymerase error frequencies at microsatellite sequences representative of those found in the human genome: [GT/CA](10), [TC/AG](11), and [TTCC/AAGG](9). DNA templates contained the microsatellites inserted in-frame into the 5' region of the herpes simplex virus thymidine kinase (HSV-tk) gene. Polymerase beta (polbeta) error frequencies were quantitated in microsatellite sequences, relative to frame-shift error frequencies in coding sequences, from the same DNA synthesis reaction. The polbeta error frequencies within the dinucleotide sequences were (2-9) x 10(-3), 14-72-fold higher than the ssDNA template frequencies. The polbeta error frequencies within the tetranucleotide sequences were (4-6) x 10(-3), a 4-13-fold increase over background. Strand biases were observed for the [TC/AG](11) and [TTCC/AAGG](9) alleles, in which more errors were produced when the purine strand served as a template. Mutations within each microsatellite included noncanonical base substitution events and single nucleotide deletions as well as the expected unit length changes. An exponential relationship was observed between the polymerase error frequency per site and both the number of repetitive units and total length of the allele. Our observations are consistent with the strand slippage model of microsatellite mutagenesis and demonstrate that DNA sequence and/or structural differences result in mutational strand biases. To our knowledge, this is the first direct quantitation of DNA polymerase errors in vitro using template microsatellite sequences.     

DNA strand biases and the mutational resilience of genes

This paper quantifies the resilience of a gene to each class of base substitution. The resilience of a gene is defined as the set of probabilities of synonymous base substitution (one for each type of base substitution on each DNA strand), and is derived from the fraction of all possible substitutions which result in no change of encoded amino acids. We discuss the resilience of the common mutational target genes, lacI and hypoxanthine-guanine phosphoribosyltransferase (hprt), and the p53 tumour suppressor gene. There are inherent strand biases to mutation in terms of the resilience differences between the non-template and template DNA strands. The ability to quantify resilience differences between the two DNA strands contributes to our understanding of strand bias to mutation.     

Development and use of an in vitro HSV-tk forward mutation assay to study eukaryotic DNA polymerase processing of DNA alkyl lesions.

We have developed an in vitro DNA polymerase forward mutation assay using damaged DNA templates that contain the herpes simplex virus type 1 thymidine kinase (HSV-tk) gene. The quantitative method uses complementary strand hybridization to gapped duplex DNA molecules and chloramphenicol selection. This design ensures exclusive analysis of mutations derived from the DNA strand produced during in vitro synthesis. We have examined the accuracy of DNA synthesis catalyzed by calf thymus polymerase alpha-primase, polymerase beta and exonuclease-deficient Klenow polymerase. Using unmodified DNA templates, polymerase beta displays a unique specificity for the loss of two bases in a dinucleotide repeat sequence within the HSV-tk locus. Treatment of the DNA template with N-ethyl-N-nitrosourea resulted in a dose-dependent inhibition of DNA synthesis concomitant with an increased mutation frequency. Similar dose-response curves were measured for the three polymerases examined; thus the identity of the DNA polymerase does not appear to affect the mutagenic potency of ethyl lesions. The HSV-tk system is unique in that damage-induced mutagenesis can be analyzed both quantitatively and qualitatively in human cells, in bacterial cells and in in vitro DNA synthesis reactions at a single target sequence.     

Efficient site directed in vitro mutagenesis using ampicillin selection.

A novel plasmid vector pSELECT-1 is described which can be used for highly efficient site-directed in vitro mutagenesis. The mutagenesis method is based on the use of single-stranded DNA and two primers, one mutagenic primer and a second correction primer which corrects a defect in the ampicillin resistance gene on the vector and reverts the vector to ampicillin resistance. Using T4 DNA polymerase and T4 DNA ligase the two primers are physically linked on the template. The non-mutant DNA strand is selected against by growth in the presence of ampicillin. In tests of the vector, highly efficient (60-90%) mutagenesis was obtained.     

DNA strand specificity for UV-induced mutations in mammalian cells.

The influence of DNA repair on the molecular nature of mutations induced by UV light (254 nm) was investigated in UV-induced hprt mutants from UV-sensitive Chinese hamster cells (V-H1) and the parental line (V79). The nature of point mutations in hprt exon sequences was determined for 19 hprt mutants of V79 and for 17 hprt mutants of V-H1 cells by sequence analysis of in vitro-amplified hprt cDNA. The mutation spectrum in V79 cells consisted of single- and tandem double-base pair changes, while in V-H1 cells three frameshift mutations were also detected. All base pair changes in V-H1 mutants were due to GC----AT transitions. In contrast, in V79 all possible classes of base pair changes except the GC----CG transversion were present. In this group, 70% of the mutations were transversions. Since all mutations except one did occur at dipyrimidine sites, the assumption was made that they were caused by UV-induced photoproducts at these sites. In V79 cells, 11 out of 17 base pair changes were caused by photoproducts in the nontranscribed strand of the hprt gene. However, in V-H1 cells, which are completely deficient in the removal of pyrimidine dimers from the hprt gene and which show a UV-induced mutation frequency enhanced seven times, 10 out of 11 base pair changes were caused by photoproducts in the transcribed strand of the hprt gene. We hypothesize that this extreme strand specificity in V-H1 cells is due to differences in fidelity of DNA replication of the leading and the lagging strand. Furthermore, we propose that in normal V79 cells two processes determine the strand specificity of UV-induced mutations in the hprt gene, namely preferential repair of the transcribed strand of the hprt gene and a higher fidelity of DNA replication of the nontranscribed strand compared with the transcribed strand.     

寡聚核苷酸诱导突变法改造φ×174噬菌体A基因蛋白的DNA识别序列

 为了进一步研究φX174噬菌体A基因蛋白的复制功能与其所识别的30核苷酸保守序列的关系,我们采用寡聚核苷酸诱导的定点突变法成功地改造了这30核苷酸保守序列。将此保守序列重组到M_(13)mp9噬菌体后,以其单链为模板,在14或16寡聚核苷酸的诱导下,合成共价闭环DNA。经转化到E.coli JM103菌株,用点印迹(Dot blot)杂交法筛选,得到两种重组突变株。一种突变株其30核苷酸保守序列正链的第22碱基由A改为G。另一突变株为其第10碱基A改为C,第11碱基T改为A。突变效率约为5％。制备了此突变株单链及双链DNA,分别做了双脱氧末端终止法及Maxam和Gilbert法序列分析鉴定。     

Mutagenesis by single site-specific arylamine-DNA adducts. Induction of mutations at multiple sites

Two related carcinogen adducts, N-(deoxyguanosin-8-yl)-2-aminofluorene (AF) or N-(deoxyguanosin-8-yl)-N-acetyl-2-aminofluorene (AAF), were introduced into the lacZ' gene at base position 6253 of the minus strand of M13mp9 viral DNA. The construction of this site-specifically modified DNA was accomplished by first preparing a gapped heteroduplex missing 7 nucleotides at position 6251-6257 followed by ligation with an unmodified heptamer or with a heptamer containing either an AF or AAF adduct. These site-specifically modified templates were transfected into competent wild-type Escherichia coli cells (JM103) and a uvrA strain (SMH12). The mutation spectrum was determined by phenotypic selection of colorless plaques indicating a defective beta-galactosidase marker enzyme and by an in situ hybridization procedure to detect single base pair mismatches in the adduct region. DNA sequencing was used to characterize 179 of the mutants obtained. We found that both adducts were capable of inducing base substitution mutations at the adduct site and in the local region of the adduct. A specific frameshift (+1G) was also observed at a displaced site. All of the frameshift mutations occurred at the ligation site of the modified oligonucleotide. Control experiments with an unmodified oligonucleotide did not show an enhancement of mutations at this site, indicating that the adducts may have been responsible for these frameshifts. The mutations spectra induced by these adducts suggest that mutagenesis depends not only on adduct structure but also the sequence in which the adduct is located and the host cell type used for mutation expression.     

Theory of misrepair mutagenesis

On the basis of experimental data a model of induced mutagenesis is proposed that takes into account the repair of DNA damage by the Rec system. The peculiar feature of the Rec system is the cleavage and resynthesis of long sequences near the recognized DNA damage. Up to 1000–2000 nucleotides are replaced in one act. Therefore a definite probability exists of finding a damaged point on the second strand serving as template. It is believed that at this point no requirements of complementarity exist and that a random substitution can take place. This is the origin of a point mutation (transition, transversion or frameshift).From this model a general formula for the dose-response curve of mutagenesis is deduced which also takes into account the possibility of simultaneously initiated repair on both complementary strands of DNA. The latter leads to a lethal event when the points are situated proximally. This formula fits the observations in different cases studied. Some fundamantal observations such as the absence of mutants from predominant single-strand breaks of DNA chains are readily explained.