DNA degradation in an amber mutant of Escherichia coli K12 affecting DNA ligase and viability

Isolation of an amber mutant lig-321 (or dnaL321) if Escherichia coli K12 with a defect in DNA ligase activity was previously reported (Nagata & Horiuchi, 1974). This was the first demonstration that, in E. coli, conditionally lethal nonsense mutants can be isolated selectively. Unlike the hitherto available E. coli K12 DNA ligase-deficient (lig) mutants, the DNA of this mutant is degraded under lethal conditions. This paper describes its further characterization. The DNA degradation was found to be an energy-requiring process, in which endonuclease I did not seem to participate. Kinetic analyses of prelabeled DNA indicated that the parental strands were degraded. The sedimentation profile of prelabeled DNA in an alkaline sucrose gradient showed that the extensive degradation was preceded by a step in which the parental strands were broken into relatively large pieces. At least in the early phase of degradation, which we examined by alkaline sucrose gradient centrifugation of pulse-labeled DNA, synthesis of discontinuous daughter chains (Okazaki fragments, Okazaki et al., 1968) was confirmed. Joining of the nascent chains, however, was completely inhibited. Genetic analyses revealed that the mutant allele is recessive to the wild type. This agrees with in vitro studies in which the mutant crude extract was found not to inhibit DNA ligase activity of the wild type extract. These and other properties of the lig-321 mutant were compared with the other DNA ligase-deficient mutants of E. coli. The role of this enzyme in DNA replication, repair and recombination is discussed.     

The reversion of trp frameshift mutations in mut,polA, lig and dnaE mutant strains of Escherichia coli

Mutator mutations mutL25, mutR34, and mutU4 had similar effects on the reversion of 4 trp frameshift mutations of known sequence. The mutation trpE9777, which resulted from the addition of an A–T base-pair to a run of 5 A–T base-pairs, was most strongly reverted by the 4 mutators. Reversion of trpE9777 was also increased by mutation polA1 (DNA polymerase I) and dnaE486 and dnaE511 (DNA polymerase III). No effect was found with the ligase mutations, lig-4 or lig-ts7. Mutations polAex1 and polA107, both deficient in the 5′ → 3′ exonuclease activity of DNA polymerase I, had different mutator effects; the factor increase in reversion of trpE9777 was 28-fold for polAex1, 6-fold for polA107, and 21-fold for polA1. The trpE9777 mutation is a useful indicator of frameshift mutator activity.     

Functional Interactions between the DNA Ligase of ESCHERICHIA COLI and Components of the DNA Metabolic Apparatus of T4 Bacteriophage

T4 phage completely defective in both gene 30 (DNA ligase) and the rII gene (function unknown) require at least normal levels of host-derived DNA ligase (E. coli lig gene) for growth. Viable E. coli mutant strains that harbor less than 5% of the wild-type level of bacterial ligase do not support growth of T4 doubly defective in genes 30 and rII (T4 30- rII- mutants). We describe here two classes of secondary phage mutations that permit the growth of T4 30- rII- phage on ligase-defective hosts. One class mapped in T4 gene su30 (Krylov 1972) and improved T4 30- rII- phage growth on all E. coli strains, but to varying degrees that depended on levels of residual host ligase. Another class mapped in T4 gene 32 (helix-destabilizing protein) and improved growth specifically on a host carrying the lig2 mutation, but not on a host carrying another lig- lesion (lig4). Two conclusions are drawn from the work: (1) the role of DNA ligase in essential DNA metabolic processes in T4-infected E. coli is catalytic rather than stoichiometric, and (2) the E. coli DNA ligase is capable of specific functional interactions with components of the T4 DNA replication and/or repair apparatus.     

Suppression of a Mutation in Gene 3 of Bacteriophage T7 (T7 Endonuclease I) by Mutations in Phage and Host Polynucleotide Ligase

Bacteriophage T7 bearing amber mutations in both gene 1.3 (T7 DNA ligase) and gene 3 (T7 endonuclease I) are viable when grown in suppressor-negative, ligase-negative hosts. This is evidenced by a high plating efficiency and a large burst size compared to the single mutants. These findings may be explained by a limited destruction of cellular DNA by the double mutant.     

On the fidelity of DNA replication. The accuracy of T4 DNA polymerases in copying phi X174 DNA in vitro

The fidelity with which wild type T4 DNA polymerase copies phi X174 amber 3 plus strand DNA at position 587 in vitro has been measured. Synthesis is initiated by hybridizing to the template a HaeIII restriction fragment whose 3'-OH terminus is 83 nucleotides from the amber 3 site. Based on gel electrophoresis of product DNA molecules and genetic marker rescue data, T4 DNA polymerase copies significantly beyond the mutant site. Transfection analysis shows that the A X T leads to G X C mutation at position 587 occurs 10- to 100-fold less frequently with T4 DNA polymerase than with E. coli DNA polymerase I. The aberrant incorporation of cytosine opposite adenine at position 587 by the T4 polymerase alone is occurring at a frequency not greater than about 10(-7) which, for this particular locus, may be similar to the fidelity exhibited by the T4 accessory proteins plus the polymerase comprising the replication complex. A comparison of the accuracy of mutator L56 and antimutator L141 T4 DNA polymerases relative to wild type shows at most a 2- to 4-fold decrease and increase, respectively, in fidelity. When compared to 10- to 1000-fold effects on mutation frequencies that these same mutant alleles have in vivo, these results suggest that the wide range in expression of mutator and antimutator phenotypes in vivo may be dependent on an abnormal interaction of the aberrant DNA polymerases with other protein components of the replication complex.     

DNA replication in dnaB mutants of Escherichia coli: Gene product interaction and synthesis of 4 S pieces

The DNA produced by several dnaB mutants has been examined both in vivo and in vitro. The alleles chosen for study had previously been shown to differ over a wide range in the apparent severity of their effects on DNA replication.Comparison of DNA replication between dnaB heteroallelic diploids and the constituent haploid strains indicates interaction between the dnaB products in the heteroallelic diploids. The data are consistent with a functional multimeric aggregate of dnaB gene products that is at least a tetramer.Alkaline sucrose gradient profiles of pulse-labeled DNA, synthesized by some of the mutants in vivo and by mutant lysates in vitro, exhibit a peak at about 4 S. The 4 S DNA is most apparent in those mutants in which replication is most severely restricted by temperature.This 4 S material can be chased in vitro into DNA larger than Okazaki pieces, and density transfer experiments indicate that these pieces are formed at the replication fork. Conversion of the 4 S material to large DNA is not altered by inhibition of polynucleotide ligase either by the presence of the lig-4 polA1 mutations in vivo or by the addition of nicotinamide mononucleotide in vitro. The in vitro observations suggest that 4 S pieces are formed on only one side of the replication fork.     

Plasmid models for bacteriophage T4 DNA replication: requirements for fork proteins.

Bacteriophage T4 DNA replication initiates from origins at early times of infection and from recombinational intermediates as the infection progresses. Plasmids containing cloned T4 origins replicate during T4 infection, providing a model system for studying origin-dependent replication. In addition, recombination-dependent replication can be analyzed by using cloned nonorigin fragments of T4 DNA, which direct plasmid replication that requires phage-encoded recombination proteins. We have tested in vivo requirements for both plasmid replication model systems by infecting plasmid-containing cells with mutant phage. Replication of origin and nonorigin plasmids strictly required components of the T4 DNA polymerase holoenzyme complex. Recombination-dependent plasmid replication also strictly required the T4 single-stranded DNA-binding protein (gene product 32 [gp32]), and replication of origin-containing plasmids was greatly reduced by 32 amber mutations. gp32 is therefore important in both modes of replication. An amber mutation in gene 41, which encodes the replicative helicase of T4, reduced but did not eliminate both recombination- and origin-dependent plasmid replication. Therefore, gp41 may normally be utilized for replication of both plasmids but is apparently not required for either. An amber mutation in gene 61, which encodes the T4 RNA primase, did not eliminate either recombination- or origin-dependent plasmid replication. However, plasmid replication was severely delayed by the 61 amber mutation, suggesting that the protein may normally play an important, though nonessential, role in replication. We deleted gene 61 from the T4 genome to test whether the observed replication was due to residual gp61 in the amber mutant infection. The replication phenotype of the deletion mutant was identical to that of the amber mutant. Therefore, gp61 is not required for in vivo T4 replication. Furthermore, the deletion mutant is viable, demonstrating that the gp61 primase is not an essential T4 protein.     

Discontinuous DNA replication in a lig-7 strain of Escherichia coli is not the result of mismatch repair, nucleotide-excision repair, or the base-excision repair of DNA uracil

After pulse-labeling with 3H-thymidine for 30 s at 42 degrees C, the newly-synthesized DNA from uvrB5 lig-7, uvrB5 lig-7 ung-1 (or ung152), uvrB5 lig-7 mutL218 (or mutS215), and uvrB5 lig-7 ung-1 mutL218 (or mutS215) cells sedimented very slowly in alkaline sucrose gradients. The bulk of these DNA molecules were smaller than 2,000 nucleotides long (i.e., about the size of Okazaki fragments), and none of the 3H-radioactivity was found to sediment as high-molecular-weight DNA. These results indicate that the apparent discontinuous DNA replication observed in lig-7 strains is not the result of mismatch repair, nucleotide-excision repair, or the base-excision repair of DNA uracil.     

Sequence and cloning of bacteriophage T4 gene 63 encoding RNA ligase and tail fibre attachment activities

The sequence of gene 63 of bacteriophage T4 was determined by a shotgun approach. Small DNA fragments, derived by sonication of a restriction fragment that encompasses the region of gene 63, were cloned in M13 vectors and sequenced by the 'dideoxy' method. The position of the gene was established by comparison with the sequence of a gene 63 amber mutant. Knowledge of the DNA sequence of gene 63 and surrounding regions has allowed the construction of a clone of gene 63 in which RNA ligase production is under the control of the lac promoter of bacteriophage M13mp8. Infected E. coli cells can be induced to produce a protein indistinguishable from commercially available RNA ligase.     

Physical mapping and complete nucleotide sequence of the denV gene of bacteriophage T4.

Phage T4 deletion mutants that are folate analog resistant (far) and contain deletions in the region of the T4 genome near denV have been isolated previously. We showed that one of these mutants (T4farP12) expressed normal denV gene activity, whereas another mutant (T4farP13) was defective in the denV gene. The rII-distal (right) physical endpoints of these deletions defined the limits of the interval in which the rII-proximal (left) endpoint of the denV gene should be located. The deletion endpoints were identified by restriction and Southern hybridization analyses of phage derivatives containing deoxycytidine instead of hydroxymethyldeoxycytidine in their DNAs. The results of these analyses localized the rII-proximal (left) end of the denV gene to a region between 62.4 and 64.3 kilobases on the T4 physical map. denV+ phage resulted from marker rescue with two of five denV- alleles tested, using plasmids containing a 1.8-kilobase fragment from this region or a 179-base-pair terminal fragment derived from it. Sequencing of the 179-base-pair fragment from wild-type DNA showed a 130-base-pair open reading frame with its termination codon at the rII-proximal end. Confirmation that this open reading frame is part of the denV coding sequence was obtained by identifying a TAG amber codon in the homologous DNA derived from a denV amber mutant strain. This mutant strain rescued the denV+ allele from plasmids containing the wild-type sequence. An adjacent overlapping restriction fragment was also cloned, permitting determination of the remaining denV gene sequence. Based on these results, the 3' end of the coding region of the denV locus was mapped to kilobase position 64.07 on the T4 physical map, and the 5' end was mapped to position 64.48.     

Nonsense mutation in open reading frame E2 of bovine papillomavirus DNA.

Oligonucleotide-directed mutagenesis was used to construct a nonsense mutation in open reading frame (ORF) E2 of bovine papillomavirus DNA. A single base substitution mutation was constructed which converted a TAC codon into a TAG amber stop codon at a position in the ORF that did not overlap with any other viral ORFs. Full-length viral DNA containing the mutation induced only approximately 2% of the transformed foci of mouse C127 cells that were induced by wild-type DNA. In a different transformation assay, approximately one-half of the C127 cells which had acquired the mutant DNA gave rise to colonies containing at least some cells with transformed morphology. The constructed mutation was maintained in cell lines derived from cells which had acquired the mutant viral DNA, but the viral DNA appeared to be integrated into the host cell genome. Genetic mapping experiments proved that the constructed amber mutation caused the decrease in focus-forming activity and the integration of the mutant viral DNA. These results suggest that ORF E2 encodes a protein which is involved either directly or indirectly in some aspects of oncogenic transformation by bovine papillomavirus and in maintaining the viral DNA as a plasmid in transformed cells.     

Temperature-sensitive lethal mutants in the structural gene for dna ligase in the yeast schizosaccharomyces pombe

cdc 17-K42 was isolated as a temperature-sensitive cdc^? mutant of the fission yeast Schizosaccharomyces pombe after nitrosoguanidine mutagenesis. The temperature-sensitive phenotype segregrates 2:2 in tetrad analyses, and it is recessive to the wild-type allele. The pattern of cell division in this mutant on temperature shift implies that its defective function is usually completed by the end of S phase. Cells of cdc 17-K42 enter S phase and undergo a complete round of DNA synthesis at the restrictive temperature, but mitosis does not follow. The nascent DNA accumulated at the restrictive temperature is exclusively composed of short (Okazaki) fragments. After a 20 min pulse label, the main peak of labeled DNA is from 70–450 nucleotides long. DNA ligase assays, involving the formation of covalently closed λ DNA circles, show that the mutant has low levels of DNA ligase activity (<20%) when assayed at the permissive temperature and none detectable when assayed at the restrictive temperature. This implies that the cdc 17 locus codes for the structural gene for DNA ligase. cdc 17-K42 also has a temperature-enhanced ultraviolet sensitivity, suggesting that the same enzyme is involved in DNA repair. Two other independent mutant alleles in the same gene have also been isolated (M75 and L16). They share many of the above properties.     

Vaccinia DNA ligase complements Saccharomyces cerevisiae cdc9, localizes in cytoplasmic factories and affects virulence and virus sensitivity to DNA damaging agents.

The functional compatibility of vaccinia virus DNA ligase with eukaryotic counterparts was demonstrated by its ability to complement Saccharomyces cerevisiae cdc9. The vaccinia DNA ligase is a 63 kDa protein expressed early during infection that is non-essential for virus DNA replication and recombination in cultured cells. This implies complementation by a mammalian DNA ligase, yet no obvious recruitment of host DNA ligase I from the nucleus to the cytoplasm was observed during infection. An antiserum raised against a peptide conserved in eukaryotic DNA ligases identified the virus enzyme in discrete cytoplasmic 'factories', the sites of virus DNA synthesis, demonstrating immunological cross-reactivity between host DNA ligase I and the vaccinia enzyme. DNA ligase was not detected in the factories of a mutant virus lacking the ligase gene. Despite this, no difference in growth between wild-type (WT) and mutant virus was detectable even in Bloom's syndrome cells which have reduced DNA ligase I activity. However, DNA ligase negative virus showed an increased sensitivity to UV or bleomycin in cultured cells, and the importance of DNA ligase for virus virulence in vivo was demonstrated by the attenuated phenotype of the deletion mutant in intranasally infected mice.     

Aberrant DNA repair and DNA replication due to an inherited enzymatic defect in human DNA ligase I.

Two missense mutations in different alleles of the DNA ligase I gene have been described in a patient (46BR) with immunodeficiencies and cellular hypersensitivity to DNA-damaging agents. One of the mutant alleles produces an inactive protein, while the other encodes an enzyme with some residual activity. A subline of identical phenotype that is homozygous (or hemizygous) for the mutant allele encoding this partially active enzyme has facilitated characterization of the enzymatic defect in 46BR. This subline retains only 3 to 5% of normal DNA ligase I activity. The intermediates in the ligation reaction, DNA ligase I-AMP and nicked DNA-AMP, accumulate in vitro and in vivo. The defect of the 46BR enzyme lies primarily in conversion of nicked DNA-AMP into the final ligated DNA product. Assays of DNA repair in 46BR cell extracts and of DNA replication in permeabilized cells have clarified functional roles of DNA ligase I. The initial rate of ligation of Okazaki fragments during DNA replication is apparently normal in 46BR cells, but 25 to 30% of the fragments remain in low-molecular-weight form for prolonged times. DNA base excision repair by 46BR cell extracts shows a delay in ligation and an anomalously long repair patch size that is reduced upon addition of purified normal DNA ligase I.     

Reduced repair of DNA double-strand breaks by homologous recombination in a DNA ligase I-deficient human cell line

Genetic and biochemical studies of mammalian DNA ligase I indicate that this multifunctional enzyme plays a key role in the completion of DNA replication and certain DNA excision repair pathways. However, the involvement of DNA ligase I in DNA double-strand break repair has not been examined. Here we have determined the effect of DNA ligase I-deficiency on the frequency of homologous recombination initiated by a site-specific DNA double-strand break. We found that expression of wild-type DNA ligase I in a human DNA ligase I mutant cell line significantly increased the frequency of homologous recombination. Notably, the ability of DNA ligase I to promote the recombinational repair of DNA double-strand breaks was dependent upon its interaction with proliferating cell nuclear antigen. Thus, our results demonstrate that DNA ligase I-deficiency reduces recombinational repair of DNA double-strand breaks.     

Topoisomerase II and other DNA-delay and DNA-arrest mutations impair bacteriophage T4 DNA packaging in vivo and in vitro.

A survey of DNA packaging in vivo and in vitro during infections caused by T4 DNA-delay and DNA-arrest amber mutants revealed a common DNA packaging-deficient phenotype. Electron microscopy revealed high proportions of proheads partially filled with DNA in vivo, indicating normal initiation but incomplete encapsidation. In contrast, exogenous mature T4 DNA was packaged in vitro by several early-gene mutant extracts. Detailed analysis of gene ts39 mutants (subunit of topoisomerase II) showed that in vivo packaging is defective, yet expression of late proteins appeared normal and the concatemeric DNA was not abnormally short or nicked. Although g39 amber mutant extracts packaged DNA in vitro, two of three ts39 mutant extracts prevented encapsidation of the exogenous DNA. The temperature-sensitive (ts) gp39 in a mutant topoisomerase II complex may have interfered with packaging in vivo and in vitro by interacting with DNA in an anomalous fashion, rendering it unfit for encapsidation. These results support the hypothesis that T4 DNA packaging is sensitive to DNA structure and discriminates against encapsidation of some types of defective DNA.     

Drosophila Nonsense Suppressors: Functional Analysis in Saccharomyces Cerevisiae, Drosophila Tissue Culture Cells and Drosophila Melanogaster

Amber (UAG) and opal (UGA) nonsense suppressors were constructed by oligonucleotide site-directed mutagenesis of two Drosophila melanogaster leucine-tRNA genes and tested in yeast, Drosophila tissue culture cells and transformed flies. Suppression of a variety of amber and opal alleles occurs in yeast. In Drosophila tissue culture cells, the mutant tRNAs suppress hsp70:Adh (alcohol dehydrogenase) amber and opal alleles as well as an hsp70:β-gal (β-galactosidase) amber allele. The mutant tRNAs were also introduced into the Drosophila genome by P element-mediated transformation. No measurable suppression was seen in histochemical assays for Adh(n4) (amber), Adh(nB) (opal), or an amber allele of β-galactosidase. Low levels of suppression (approximately 0.1-0.5% of wild type) were detected using an hsp70:cat (chloramphenicol acetyltransferase) amber mutation. Dominant male sterility was consistently associated with the presence of the amber suppressors.     

Loss of DNA ligase IV prevents recognition of DNA by double-strand break repair proteins XRCC4 and XLF

The repair of DNA double-strand breaks by nonhomologous end-joining (NHEJ) is essential for maintenance of genomic integrity and cell viability. Central to the molecular mechanism of NHEJ is DNA ligase IV/XRCC4/XLF complex, which rejoins the DNA. During adenovirus (Ad5) infection, ligase IV is targeted for degradation in a process that requires expression of the viral E1B 55k and E4 34k proteins while XRCC4 and XLF protein levels remain unchanged. We show that in Ad5-infected cells, loss of ligase IV is accompanied by loss of DNA binding by XRCC4. Expression of E1B 55k and E4 34k was sufficient to cause loss of ligase IV and loss of XRCC4 DNA binding. Using ligase IV mutant human cell lines, we determined that the absence of ligase IV, and not expression of viral proteins, coincided with inhibition of DNA binding by XRCC4. In ligase IV mutant human cell lines, DNA binding by XLF was also inhibited. Expression of both wild-type and adenylation-mutant ligase IV in ligase IV-deficient cells restored DNA binding by XRCC4. These data suggest that the intrinsic DNA-binding activities of XRCC4 and XLF may be subject to regulation and are down regulated in human cells that lack ligase IV.     

An amber dna mutant of Escherichia coli K12 affecting DNA ligase

We have isolated an amber mutant (dnaL321) of Escherichia coli K12, which affects DNA ligase and which is lethal unless it is suppressed. DNA is degraded under the restrictive conditions. The mutation also affects the sensitivity of the cell to ultraviolet light irradiation, and the capacity to support the growth of phage λ that is deficient in general recombination. This pleiotropy is considered to be due to a single mutation, and is suppressed by supD^?_Isu+ and by supF^?su_III⁺). The mutation is cotransducible with dapE(2%), and with ptsI(85%), by phage Plvir.     

Characterization of transposon-generated protease mutant of xanthomonas campestris pathovar glycine 8ra

Protease negative mutant of Xanthomonas campestris pathovar glycine 8ra (prt-mutant) was constructed by mutagenesis employing artificial transposon Omegon-Km. Transposon delivery was conducted through diparental conjugation using X. campestris pathovar glycine 8ra as recipient and Escherichia coli S17-1 carrying pJFF 3500 plasmid as the donor. The frequency of transconjugation was found 1.9 x 10(-7) per recipient. Enzyme analysis indicated the presence of mutant with lower protease activity than that of the wild-type. Genetic analysis employing pulsed-field gel electrophoresis (PFGE) of the genomic DNA digested with AseI or SpeI restriction endonuclease could significantly differentiate X. campestris pathovar glycine 8ra prt from the wild-type parent. The 9.85 kb pLR omega 6 plasmid was constructed from the genomic DNA of the prt mutant after being digested with KpnI restriction endonuclease and ligated with T4 DNA ligase.