Escherichia coli DNA polymerase I. Construction of a polA plasmid for amplification and an improved purification scheme

Previous attempts to clone the Escherichia coli polA+ gene onto a high copy number plasmid were unsuccessful. The apparent lethality of unregulated overproduction of DNA polymerase I can be eliminated by cutting at a BglII site 100 nucleotides upstream from the ATG start codon of the polA gene. This permitted the construction of plasmid pMP5 which contains both the coding sequence for DNA polymerase I and the lambda pL promoter for conditional control of polA gene expression. BglII cutting only damages but does not eliminate the polA promoter activity; the BglII site thus lies within the polA promoter region. Leakiness of the damaged polA promoter results in overproduction of DNA polymerase I even under conditions where pL is fully repressed. This overproduction is inhibitory of cell growth, as reflected in both growth rate and in the frequency of appearance of mutant plasmids which are nonproducers of DNA polymerase I. Transformation of plasmid pMP5 into E. coli N4830 yields strain ATL100 which under inducing conditions provides 138-fold amplification of DNA polymerase I. Optimization of growth and expression conditions are presented together with an optimized rapid polymerase purification scheme. In addition to providing a convenient source for preparation of DNA polymerase I, this work serves as the basis for a future detailed molecular genetic analysis of the polA gene product.     

Isolation of Haemophilus influenzae genes that suppress Escherichia coli polA mutations

Haemophilus influenzae was found to produce a DNA polymerase that was similar to polymerase I of Escherichia coli. E. coli polA mutants were used as backgrounds for the selection of H. influenzae polA suppressor genes. Six different H. influenzae fragments were isolated that could suppress E. coli polA mutations. None of the suppressors appeared to encode the H. influenzae equivalent of the E. coli polA gene. One type of clone, represented by pGW41, caused a polymerase I activity to appear in a suppressed polA1 mutant. Plasmids from the pGW41 class contained two genes (pol-2 and pol-3) that were both required for polA suppression. Mutated nonsuppressing derivatives of the pGW41 class were used to create H. influenzae mutants that were deficient in polymerase I.     

Genetic mapping and DNA sequence analysis of mutations in the polA gene of Escherichia coli

DNA polymerase I of Escherichia coli provides an excellent model for the study of template-directed enzymatic synthesis of DNA because it is a single subunit enzyme, it can be obtained in large quantities and the three-dimensional structure of the polymerizing domain (the Klenow fragment) has recently been determined (Ollis et al., 1985). One approach to assigning functions to particular portions of the structure is to correlate the altered enzymatic behavior of mutant forms of DNA polymerase I with the change in the primary sequence of the protein. Towards this end we have developed a rapid procedure for mapping any polA mutation to a region no larger than 300 base-pairs within the polA gene. Two series of polA deletion mutants with defined end-points were constructed in vitro and cloned into bacteriophage lambda. These phages can then be used to map precisely E. coli polA mutants. Twelve polA- alleles have been mapped in this way and for nine of them the nature of the mutational change has been determined by DNA sequence analysis. Two of the mutations, polA5 and polA6, which affect the enzyme-DNA interaction, provide evidence for the location of the DNA binding region on the polymerase three-dimensional structure.     

Complementation of Bacillus subtilis polA mutants by DNA polymerase I from Streptococcus pneumoniae

Summary The polA gene of Streptococcus pneumoniae cloned in the recombinant plasmid pSM22 is expressed in Bacillus subtilis. Extracts of B. subtilis polA mutants containing pSM22 showed 6 times more DNA polymerase activity than extracts of wild-type cells without the plasmid. Complete complementation of the B. subtilis polA5 and polA59 mutations with respect to in vivo resistance to UV irradiation and methyl methanesulfonate was observed when four copies of the pneumococcal polA gene were present in each cell. Ectopic integration of the polA gene together with a cat marker into the chromosome of B. subtilis gave chromosomal insertions containing single and double doses of the pneumococcal polA gene. Correlation with gene dosage was observed for both chloramphenicol acetyltransferase and DNA polymerase activities measured in vitro. Depending on the number of copies of the S. pneumoniae polA gene present, restoration of DNA repair functions in polA mutants of B. subtilis was either partial or complete.     

Role of DNA polymerase I in postreplication repair: a reexamination with Escherichia coli delta polA.

Using strains of Escherichia coli K-12 that are deleted for the polA gene, we have reexamined the role of DNA polymerase I (encoded by polA) in postreplication repair after UV irradiation. The polA deletion (in contrast to the polA1 mutation) made uvrA cells very sensitive to UV radiation; the UV radiation sensitivity of a uvrA delta polA strain was about the same as that of a uvrA recF strain, a strain known to be grossly deficient in postreplication repair. The delta polA mutation interacted synergistically with a recF mutation in UV radiation sensitization, suggesting that the polA gene functions in pathways of postreplication repair that are largely independent of the recF gene. When compared to a uvrA strain, a uvrA delta polA strain was deficient in the repair of DNA daughter strand gaps, but not as deficient as a uvrA recF strain. Introduction of the delta polA mutation into uvrA recF cells made them deficient in the repair of DNA double-strand breaks after UV irradiation. The UV radiation sensitivity of a uvrA polA546(Ts) strain (defective in the 5'----3' exonuclease of DNA polymerase I) determined at the restrictive temperature was very close to that of a uvrA delta polA strain. These results suggest a major role for the 5'----3' exonuclease activity of DNA polymerase I in postreplication repair, in the repair of both DNA daughter strand gaps and double-strand breaks.     

fcsA29 mutation is an allele of polA gene of Escherichia coli

The cold-sensitive fcsA29 mutation of Escherichia coli was found to be a new type of cold-sensitive allele of the polA gene encoding DNA polymerase I, caused by an Asp(116)-->Asn change in the 5'-->3' exonuclease domain. The fcsA29 mutant showed typical polA mutant phenotypes such as UV sensitivity and unacceptability of recA mutation. Cold-sensitive growth of the mutant was suppressed by introduction of a sulA mutation, indicating that cell filamentation was due to the SOS response.     

Intergeneric conjugational crossing of Escherichia coli with Salmonella typhimurium. II. Transfer of a polA1 mutation from Escherichia coli to Salmonella typhimurium and its phenotypic expression in the salmonella genome]

The Escherichia coli structural gene for DNA polymerase I was inserted into Salmonella typhimurium chromosome by conjugal transfer. The genetic analysis of P1-mediated transduction of obtained hybrid showed that polA gene is located in it between metE and rha loci and is cotransduced with metE (about 50%) and rha (12%). The phenotypic properties of polA1 hybrid E. coliXS. typhimurium concerning UV-MMS-NG and gamma-ray sensitivity are similar to the polA1 mutants of E. coli.     

Nucleotide sequence of the Escherichia coli polA gene and primary structure of DNA polymerase I

We report the nucleotide sequence of 3.2 kilobase pair region of the Escherichia coli polA gene, comprising the coding region for DNA polymerase I with about 400 base pairs of flanking sequence. The amino acid sequence for DNA polymerase I derived from our DNA sequence is largely consistent with previous protein chemical data. In the following paper, Brown et al. (Brown, W. E., Stump, K. H., and Kelley, W. S. (1982) J. Biol. Chem. 257, 1965-1972) present additional protein chemistry experiments that further confirm our sequence. Mild proteolysis of DNA polymerase I is known to produce two enzymatically active fragments (Brutlag, D., Atkinson, M. R., Setlow, P., and Kornberg, A. (1969) Biochem. Biophys. Res. Commun. 37, 982-989; Klenow, H., and Henningsen, I. (1970) Proc. Natl. Acad. Sci. U. S. A. 74, 5632-5636). We have located the site of this cleavage between residues 323 and 324 of the 928 amino acid polymerase molecule. By sequence comparison of the polA1 and wild type alleles, we have identified the polA1 mutation as a change from Trp (TGG) to amber (TAG) at residue 342.     

Method for determining whether a gene of Escherichia coli is essential: application to the polA gene

We have developed a general method for determining whether a gene of Escherichia coli is essential for viability. The method requires cloned DNA spanning the gene in question and a reasonably detailed genetic and physical map of the cloned segment. Using this information, one constructs a deletion of the target gene in vitro. For convenience, the deletion can be marked by an antibiotic resistance gene. A DNA segment containing the deletion is then cloned onto an att delta phage lambda vector. Integration of this phage, by homologous recombination at the target locus, and subsequent excision provide an efficient route for crossing the marked deletion onto the bacterial chromosome. Failure to delete the target gene indicates either that the resulting deletion was not viable or that the desired recombinational event did not take place. The use of prophage excision to generate the deletion allows one to estimate the fraction of deletion-producing events by analysis of the other product of the excision, the phage produced on induction of the prophage. In this way one can determine whether failure to recover a particular chromosomal deletion was due to its never having been formed, or, once formed, to its failure to survive. Applying this method to the polA gene, we found that polA is required for growth on rich medium but not on minimal medium. We repeated the experiment in the presence of plasmids carrying functional fragments of the polA gene, corresponding to the 5'-3' exonuclease and the polymerase-3'-5' exonuclease portions of DNA polymerase I. Surprisingly, either of these fragments, in the absence of the other, was sufficient to allow growth on rich medium.     

The polymerase domain of Streptococcus pneumoniae DNA polymerase I. High expression, purification and characterization

The 3'-terminal two-thirds of the Streptococcus pneumoniae polA gene was cloned in an Escherichia coli genefusion vector with inducible expression. The resulting recombinant plasmid (pSM10) directs the hyperproduction of a polypeptide of 70.6 kDa corresponding to the C-terminal fragment of pneumococcal DNA polymerase I. Induced cells synthesized catalytically active protein to the extent of 7% of the total soluble protein in the cells. The polymerase fragment was purified to greater than 90% homogeneity with a yield of 1.5 mg pure protein/l culture. The protein has DNA polymerase activity, but no exonuclease activity. The enzyme requires a divalent cation (MgCl2 or MnCl2) for polymerization of DNA. Comparison of the mutant and wild-type pneumococcal polymerases shows that the construction did not affect the enzymatic affinity for the various substrates. The mutant protein, like its parent DNA polymerase I, exhibited an intermediate level of activity with primed single-stranded DNA. At high molar ratio of enzyme/DNA substrate, the polymerase fragment catalyzes strand displacement and switching after completing the replication of a primed single-stranded M13 DNA molecule.     

Streptococcus pneumoniae DNA polymerase I lacks 3''-to-5'' exonuclease activity: localization of the 5''-to-3'' exonucleolytic domain.

The Streptococcus pneumoniae polA gene was altered at various positions by deletions and insertions. The polypeptides encoded by these mutant polA genes were identified in S. pneumoniae. Three of them were enzymatically active. One was a fused protein containing the first 11 amino acid residues of gene 10 from coliphage T7 and the carboxyl-terminal two-thirds of pneumococcal DNA polymerase I; it possessed only polymerase activity. The other two enzymatically active proteins, which contained 620 and 351 amino acid residues from the amino terminus, respectively, lacked polymerase activity and showed only exonuclease activity. These two polymerase-deficient proteins and the wild-type protein were hyperproduced in Escherichia coli and purified. In contrast to the DNA polymerase I of Escherichia coli but similar to the corresponding enzyme of Thermus aquaticus, the pneumococcal enzyme appeared to lack 3'-to-5' exonuclease activity. The 5'-to-3' exonuclease domain was located in the amino-terminal region of the wild-type pneumococcal protein. This exonuclease activity excised deoxyribonucleoside 5'-monophosphate from both double- and single-stranded DNAs. It degraded oligonucleotide substrates to a decameric final product.     

Anaerobic incubation enhances the colony formation of a polA recB strain of Escherichia coli K-12.

Escherichia coli strain E247 (polA1 recB21) has reduced colony formation (even at the permissive temperature of 30 degrees C) because of a poor suppressor mutation (sup-126). The colony formation was enhanced in the absence of oxygen about 3-fold at 30 degrees C and 10(6)-fold at 43 degrees C, suggesting that a polA recB strain was inviable due to oxygen toxicity. Colony formation was also increased by incubation in an agar medium containing the reducing agent thioglycolate and incubation in the presence of chloroform-killed Saccharomyces cerevisiae pet+ cells, but not pet cells. Since the E247 strain viability was inversely dependent on the oxygen pressure and since the strain was more sensitive to superoxide radical than either the polA or the recB mutant, it seems likely that the polA and recB genes play a role in repairing DNA damage during respiration.     

Suppression of ColE1 high-copy-number mutants by mutations in the polA gene of Escherichia coli.

We isolated three Escherichia coli suppressor strains that reduce the copy number of a mutant ColE1 high-copy-number plasmid. These mutations lower the copy number of the mutant plasmid in vivo up to 15-fold; the wild-type plasmid copy number is reduced by two- to threefold. The suppressor strains do not affect the copy numbers of non-ColE1-type plasmids tested, suggesting that their effects are specific for ColE1-type plasmids. Two of the suppressor strains show ColE1 allele-specific suppression; i.e., certain plasmid copy number mutations are suppressed more efficiently than others, suggesting specificity in the interaction between the suppressor gene product and plasmid replication component(s). All of the mutations were genetically mapped to the chromosomal polA gene, which encodes DNA polymerase I. The suppressor mutational changes were identified by DNA sequencing and found to alter single nucleotides in the region encoding the Klenow fragment of DNA polymerase I. Two mutations map in the DNA-binding cleft of the polymerase region and are suggested to affect specific interactions of the enzyme with the replication primer RNA encoded by the plasmid. The third suppressor alters a residue in the 3'-5' exonuclease domain of the enzyme. Implications for the interaction of DNA polymerase I with the ColE1 primer RNA are discussed.     

The 5'' to 3'' exonuclease activity of DNA polymerase I is essential for Streptococcus pneumoniae

Three different mutations were introduced in the polA gene of Streptococcus pneumoniae by chromosomal transformation. One mutant gene encodes a truncated protein that possesses 5' to 3' exonuclease but has lost polymerase activity. This mutation does not affect cell viability. Other mutated forms of polA that encode proteins with only polymerase activity or with no enzymatic activity could not substitute for the wild-type polA gene in the chromosome unless the 5' to 3' exonuclease domain was encoded elsewhere in the chromosome. Thus, it appears that the 5' to 3' exonuclease activity of the DNA polymerase I is essential for cell viability in S. pneumoniae. Absence of the polymerase domain of DNA polymerase I slightly diminished the ability of S. pneumoniae to repair DNA lesions after ultraviolet irradiation. However, the polymerase domain of the pneumococcal DNA polymerase I gave almost complete complementation of the polA5 mutation in Escherichia coli with respect to resistance to ultraviolet irradiation.     

Either bacteriophage T4 RNase H or Escherichia coli DNA polymerase I is essential for phage replication.

Bacteriophage T4 rnh encodes an RNase H that removes ribopentamer primers from nascent DNA chains during synthesis by the T4 multienzyme replication system in vitro (H. C. Hollingsworth and N. G. Nossal, J. Biol. Chem. 266:1888-1897, 1991). This paper demonstrates that either T4 RNase HI or Escherichia coli DNA polymerase I (Pol I) is essential for phage replication. Wild-type T4 phage production was not diminished by the polA12 mutation, which disrupts coordination between the polymerase and the 5'-to-3' nuclease activities of E. coli DNA Pol I, or by an interruption in the gene for E. coli RNase HI. Deleting the C-terminal amino acids 118 to 305 from T4 RNase H reduced phage production to 47% of that of wild-type T4 on a wild-type E. coli host, 10% on an isogenic host defective in RNase H, and less than 0.1% on a polA12 host. The T4 rnh(delta118-305) mutant synthesized DNA at about half the rate of wild-type T4 in the polA12 host. More than 50% of pulse-labelled mutant DNA was in short chains characteristic of Okazaki fragments. Phage production was restored in the nonpermissive host by providing the T4 rnh gene on a plasmid. Thus, T4 RNase H was sufficient to sustain the high rate of T4 DNA synthesis, but E. coli RNase HI and the 5'-to-3' exonuclease of Pol I could substitute to some extent for the T4 enzyme. However, replication was less accurate in the absence of the T4 RNase H, as judged by the increased frequency of acriflavine-resistant mutations after infection of a wild-type host with the T4 rnh (delta118-305) mutant.     

Repair of near-ultraviolet (365 nm)-induced strand breaks in Escherichia coli DNA. The role of the polA and recA gene products.

The action of near-ultraviolet (UV-365 nm) radiation in cellular inactivation (biological measurements) and induction and repair of DNA strand breaks (physical measurements) were studied in a repair-proficient strain and in polA-, recA-, uvrA-, and polA uvrA-deficient strains of Escherichia coli K-12. The induction of breaks in the polA and polA uvrA strains was linear with dose (4.0 and 3.7 X 10(-5) breaks/2.5 X 10(9) daltons/Jm-2, respectively). However, in the recA-, uvrA-, and repair-proficient strains, there was an initial lag in break induction at low doses and then a linear induction of breaks at higher doses with rates of 4.6, 2.8, and 3.2 X 10(-5) breaks/2.5 X 10(9) daltons/Jm-2, respectively. We interpret these strain differences as indicating simultaneous induction and repair of breaks in polymerase 1 (polA)-proficient strains under the 0 degrees C, M9 buffer irradiation conditions that, for maximum efficiency, require both the polA and recA gene products. Strand-break rejoining also occurred at 30 degrees C in complete growth medium. We propose that at least three (and possibly four) distinct types of pathways can act to reduce the levels of 365-nm radiation-induced strand breaks. A quantitative comparison of the number of breaks remaining with the number of lethal events remaining after repair in complete medium at 30 degrees C showed that between one and three breaks remain per lethal event in the wild-type and recA strains, whereas in the polA strain one order of magnitude more breaks were induced.     

Conditional lethality of the recA441 and recA730 mutants of Escherichia coli deficient in DNA polymerase I

E. coli strains bearing the recA441 mutation and various mutations in the polA gene resulting in enzymatically well-defined deficiencies of DNA polymerase I have been constructed. It was found that the recA441 strains bearing either the polA1 or polA12 mutation causing deficiency of the polymerase activity of pol I are unable to grow at 42 degrees C on minimal medium supplemented with adenine, i.e., when the SOS response is continuously induced in strains bearing the recA441 mutation. Under these conditions the inhibition of DNA synthesis is followed in recA441 polA12 by DNA degradation and loss of cell viability. A similar lethal effect is observed with the recA730 polA12 mutant. The recA441 strain bearing the polA107 mutation resulting in the deficiency of the 5'-3' exonuclease activity of pol I shows normal growth under conditions of continuous SOS response. We postulate that constitutive expression of the SOS response leads to an altered requirement for the polymerase activity of pol I.