Non-targeted mutagenesis of unirradiated lambda phage in Escherichia coli host cells irradiated with ultraviolet light

Non-targeted mutagenesis of lambda phage by ultraviolet light is the increase over background mutagenesis when non-irradiated phage are grown in irradiated Escherichia coli host cells. Such mutagenesis is caused by different processes from targeted mutagenesis, in which mutations in irradiated phage are correlated with photoproducts in the phage DNA. Non-irradiated phage grown in heavily irradiated uvr+ host cells showed non-targeted mutations, which were 3/4 frameshifts, whereas targeted mutations were 2/3 transitions. For non-targeted mutagenesis in heavily irradiated host cells, there were one to two mutant phage per mutant burst. From this and the pathways of lambda DNA synthesis, it can be argued that non-targeted mutagenesis involves a loss of fidelity in semiconservative DNA replication. A series of experiments with various mutant host cells showed a major pathway of non-targeted mutagenesis by ultraviolet light, which acts in addition to "SOS induction" (where cleavage of the LexA repressor by RecA protease leads to din gene induction): (1) the induction of mutants has the same dependence on irradiation for wild-type and for umuC host cells; (2) a strain in which the SOS pathway is constitutively induced requires irradiation to the same level as wild-type cells in order to fully activate non-targeted mutagenesis; (3) non-targeted mutagenesis occurs to some extent in irradiated recA recB cells. In cells with very low levels of PolI, the induction of non-targeted mutagenesis by ultraviolet light is enhanced. We propose that the major pathway for non-targeted mutagenesis in irradiated host cells involves binding of the enzyme DNA polymerase I to damaged genomic DNA, and that the low polymerase activity leads to frameshift mutations during semiconservative DNA replication. The data suggest that this process will play a much smaller role in ultraviolet mutagenesis of the bacterial genome than it does in the mutagenesis of lambda phage.     

Replication of M13 oriC bacteriophages in Escherichia coli rep mutant is dependent on the cloned Escherichia coli replication origin.

The involvement of the Escherichia coli rep protein in the replication of M13 chimeric deoxyribonucleic acids (DNAs) carrying the E. coli chromosomal DNA replication origin (oriC) has been examined. Previous studies indicate that the cloning of a 3,550-base-pair sequence of chromosomal DNA containing oriC into an M13 vector allows extensive replication of the M13 oriC chimeric DNA in an E. coli rep-3 mutant. We have extended these studies by preparing a 330-base-pair deletion that specifically deletes the oriC sequence in the M13 oriC DNAs, to demonstrate that the replication observed in the rep-3 host is dependent on the cloned origin. Thus, a DNA-unwinding enzyme other than the rep protein may be involved in the strand separation process accompanying replication which initiates at oriC in the M13 oriC chimeric DNAs and in the E. coli chromosome. The rep assay used for assessing the functionality of the cloned oriC is useful for analysis of any rep-independent origin of replication functional in E. coli. A direct selection for a cloned origin of replication is possible in the rep-3 recA56 host. Since the cloned origin is nonessential for propagation of the M13 chimeric phage in a rep+ host, mutations in the cloned origin may be constructed, and the mutant phage may be examined by a simple transductional analysis of the rep-3 recA56 mutant strain.     

Evidence for Escherichia coli polymerase II mutagenic bypass of intrastrand DNA crosslinks

The mutagenic potentials of DNAs containing site- and stereospecific intrastrand DNA crosslinks were evaluated in Escherichia coli cells that contained a full complement of DNA polymerases or were deficient in either polymerases II, IV, or V. Crosslinks were made between adjacent N(6)-N(6) adenines and consisted of R,R- and S,S-butadiene crosslinks and unfunctionalized 2-, 3-, and 4-carbon tethers. Although replication of single-stranded DNAs containing the unfunctionalized 3- and 4-carbon tethers were non-mutagenic in all strains tested, replication past all the other intrastrand crosslinks was mutagenic in all E. coli strains, except the one deficient in polymerase II in which no mutations were ever detected. However, when mutagenesis was analyzed in cells induced for SOS, mutations were not detected, suggesting a possible change in the overall fidelity of polymerase II under SOS conditions. These data suggest that DNA polymerase II is responsible for the in vivo mutagenic bypass of these lesions in wild-type E. coli.     

A Bacillus subtilis plasmid that can be packaged as single-stranded DNA in Escherichia coli: use for oligodeoxynucleotide-directed mutagenesis

A Bacillus subtilis/Escherichia coli shuttle vector was modified to contain the origin of DNA replication of the E. coli filamentous phage f1, in both orientations. Upon superinfection with and f1-related phage of an E. coli strain containing either of the modified vectors, the single-stranded (ss) form of the plasmid was packaged in virions and released to the culture medium. Each of these ss DNAs has been purified from the virions and used as a template for oligodeoxynucleotide-directed mutagenesis. The resulting mutations were demonstrated by DNA sequencing. The capacity of these vectors to be isolated as phage ss DNA from E. coli and to replicate as plasmids in B. subtilis makes them convenient substrates for the production of oligodeoxynucleotide-directed mutations for studies in B. subtilis.     

Separation of the SOS-dependent and SOS-independent components of alkylating-agent mutagenesis.

Escherichia coli plasmids containing the rpsL+ gene (Strs phenotype) as the target for mutation were treated in vitro with N-methyl-N-nitrosourea. Following fixation of mutations in E. coli MM294A cells (recA+ Strs), an unselected population of mutant and wild-type plasmids was isolated and transferred into a second host, E. coli 6451 (recA Strr). Strains carrying plasmid-encoded forward mutations were then selected as Strr isolates, while rpsL+ plasmids conferred the dominant Strs phenotype in the second host. Mutation induction and reduced survival of N-methyl-N-nitrosourea-treated plasmids were shown to be dose dependent. Because this system permitted analysis and manipulation of the levels of certain methylated bases produced in vitro by N-methyl-N-nitrosourea, it afforded the opportunity to assess directly the relative roles of these bases and of SOS functions in mutagenesis. The methylated plasmid DNA gave a mutation frequency of 6 X 10(-5) (a 40-fold increase over background) in physiologically normal cells. When the same methylated plasmid was repaired in vitro by using purified O6-methylguanine DNA methyltransferase (to correct O6-methylguanine and O4-methylthymine), no mutations were detected above background levels. In contrast, when the methylated plasmid DNA was introduced into host cells induced by UV light for the SOS functions, rpsL mutagenesis was enhanced eightfold over the level seen without SOS induction. This enhancement of mutagenesis by SOS was unaffected by prior treatment of the DNA with O6-methylguanine DNA methyltransferase. These results demonstrate a predominant mutagenic role for alkylation lesions other than O6-methylguanine or O4-methylthymine when SOS functions are induced. The mutation spectrum of N-methyl-N-nitrosourea under conditions of induced SOS functions revealed a majority of mutagenic events at A . T base pairs.     

Role of the E. coli umuC gene product in the repair of single-stranded DNA phage

The umuC product of Escherichia coli has been suggested to have a central role in SOS induced error prone replication of DNA (Kato and Shinoura 1977). To investigate this possibility, we examined the effect of umuC mutations on error prone repair of single and double-stranded DNA phages. No Weigle reactivation of M13 phage was detected in a umuC mutant. Reactivation of lambda phage was reduced but still evident. However mutagenesis occurred in both cases. These results suggest that induced error prone replication of phage DNA can occur via umuC dependent (transdimer synthesis) and umuC independent mechanisms.     

Comparative study of mutagenesis by O6-methylguanine in the human Ha-ras oncogene in E. coli and in vitro.

Single residues of O6-methylguanine (O6-meG) were introduced into the first or second position of codon 12 (GGC; positions 12G1 or 12G2, respectively) or the first position of codon 13 (GGT; position 13G1) of the human Ha-ras oncogene in phage M13-based vectors. After transformation of E.coli, higher mutant plaque frequencies (MPF) were observed at 12G1 and 13G1 than at 12G2 if O6-alkylguanine-DNA alkyltransferase (AGT) had been depleted, while similar MPF were observed at all three positions in the presence of active AGT. Taken together, these observations suggest reduced AGT repair at 12G2. Kinetic analysis of in vitro DNA replication in the same sequences using E. coli DNA polymerase I (Klenow fragment) indicated that variation in polymerase fidelity may contribute to the overall sequence specificity of mutagenesis. By constructing vectors which direct methyl-directed mismatch repair to the (+) or the (-) strand and comparing the MPF values in bacteria proficient or deficient in mismatch repair and/or AGT, it was concluded that, while mutS-mediated mismatch repair did not remove O6-meG from O6-meG:C pairs, this repair mechanism can affect O6-meG mutagenesis by repairing G:T pairs generated through AGT-induced demethylation of O6-meG:T replication intermediates.     

Oxidative damage in DNA. Lack of mutagenicity by thymine glycol lesions

Thymine glycol (5,6-dihydroxy-5,6-dihydrothymine) is a base damage common to oxidative mutagens and the major stable radiolysis product of thymine in DNA. We assessed the mutagenic potential of thymine glycols in single-stranded bacteriophage DNA during transfection of Escherichia coli wild-type and umuC strains. cis-Thymine glycols were induced in DNA by reaction with the chemical oxidant, osmium tetroxide (OsO4); modification of thymines was quantitated by using anti-thymine glycol antibody. Inactivation of transfecting molecules showed that one lethal hit corresponded to 1.5 to 2.1 thymine glycols per phage DNA in normal cells, whereas conditions of W-reactivation (SOS induction) reversed 60 to 80% of inactivating events. Forward mutations in the lacI and lacZ' (alpha) genes of f1 and M13 hybrid phage DNAs were induced in OsO4-treated DNA in a dose-dependent manner, in both wild-type and umuC cells. Sequence analysis of hybrid phage mutants revealed that mutations occurred preferentially at cytosine sites rather than thymine sites, indicating that thymine glycols were not the principal pre-mutagenic lesions in the single-stranded DNA. A mutagenic specificity for C----T transitions was confirmed by OsO4-induced reversion of mutant lac phage. Pathways for mutagenesis at derivatives of oxidized cytosine are discussed.     

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.     

O6-methylguanine mutation and repair is nonuniform. Selection for DNA most interactive with O6-methylguanine

Mutations were induced in the ampicillinase gene of a bacteriophage f1/pBR322 chimera both by incorporation of O6-methyl-dGTP opposite T during DNA replication in vitro and by site-directed mutagenesis using O6-methylguanine-containing oligonucleotides. After passage of the DNA through Escherichia coli, analysis of 151 O6-methyl-dGTP-induced mutations indicated a significantly greater number of unmutated mutation sites than expected, whereas the mutated sites generally fit a Poisson distribution. The unmutated sites are assumed to be caused by the inability of some sequences to tolerate the presence of a tetrahedral methyl group within the confines of a Watson-Crick helix (Toorchen, D., and Topal, M.D. (1983) Carcinogenesis 4, 1591-1597). A consensus of the DNA sequences surrounding unmutated mutation sites was derived. The consensus sequence had significant similarity to the region of the rat Harvey ras oncogene containing the N-methyl-N-nitrosourea activated site for transformation (Zarbl, H., Sukumar, S., Arthur, A. V., Dionisio, M.-Z., and Barbacid, M. (1985) Nature 315, 382-385). We propose that direct alkylation at O6 of a guanine present within the consensus sequence may produce a DNA conformation less subject to repair. Mutation by O6-methylguanine-containing oligonucleotides demonstrated that repair of the O6-methylguanine lesions varied at least 3-4-fold with position of the lesion.     

Spectrum of N4-aminocytidine mutagenesis

N4-Aminocytidine, a nucleoside analog, is a potent mutagen towards phages, bacteria, Drosophila and mammalian cells in culture. In vitro, biochemical studies indicate that this reagent acts by being incorporated into DNA. To elucidate the mechanism of N4-aminocytidine mutagenesis, it is essential to identify the nature of DNA sequence alterations taking place during the mutagenesis. We have analyzed the nucleotide sequence changes in the lac promoter-lacZ alpha region of M13mp2 phage induced by treatment of phage-infected Escherichia coli with N4-aminocytidine. The sequence alterations of DNA samples from 89 mutants of the phage were determined. These mutants had single point mutations, except one mutant, in which a double point mutation was detected. Several hot spots were found: however, there are no apparent relations to particular DNA sequences regarding the locations of these spots. All the mutations are transitions; neither transversions nor deletions/insertions were found. A feature in these transitions is that the A/T to G/C and G/C to A/T changes occur at approximately equal rates. The overall picture of the mutagenesis is consistent with a scheme in which misincorporation and misreplication caused by the modified cytosine structure are the key steps in the DNA replication leading to transitions. Similar nucleotide alterations were found for the mutagenesis induced by an alkylated derivative, N'-methyl-N4-aminocytidine. N4-Aminocytidine also induced reversions of these mutants; both A/T to G/C and G/C to A/T transitions again took place.     

Fidelity of replication of the leading and the lagging DNA strands opposite N-methyl-N-nitrosourea-induced DNA damage in human cells.

Semi-conservative replication of double-stranded DNA in eukaryotic cells is an asymmetric process involving leading and lagging strand synthesis and different DNA polymerases. We report a study to analyze the effect of these asymmetries when the replication machinery encounters alkylation-induced DNA adducts. The model system is an EBV-derived shuttle vector which replicates in synchrony with the host human cells and carries as marker gene the bacterial gpt gene. A preferential distribution of N-methyl-N-nitrosourea (MNU)-induced mutations in the non transcribed DNA strand of the shuttle vector pF1-EBV was previously reported. The hypermutated strand was the leading strand. To test whether the different fidelity of DNA polymerases synthesizing the leading and the lagging strands might contribute to MNU-induced mutation distribution the mutagenesis study was repeated on the shuttle vector pTF-EBV which contains the gpt gene in the inverted orientation. We show that the base substitution error rates on an alkylated substrate are similar for the replication of the leading and lagging strands. Moreover, we present evidence that the fidelity of replication opposite O6-methylguanine adducts of both the leading and lagging strands is not affected by the 3' flanking base. The preferential targeting of mutations after replication of alkylated DNA is mainly driven by the base at the 5' side of the G residues.     

Correlated genetic and EcoRI cleavage map of Bacillus subtilis bacteriophage phi105 DNA.

The seven previously identified EcoRI cleavage fragments of phi 105 DNA were ordered with respect to their sites of origin on the phage genome by marker rescue. One fragment, H, did not carry any determinants essential for replication. This fragment was totally missing in a deletion mutant which exhibited a lysogenization-defective phenotype. There is a nonessential region on the phi 105 genome which begins in fragment B, spans fragment H, and ends in fragment F. The size of the nonessential region, as estimated by alterations observed in the fragmentation patterns of deletion mutant DNAs, is approximately 2.7 X 10(6) daltons. Two new EcoRI cleavage fragments with molecular weights of approximately 0.2 X 10(6) were detected by autoradiography of 32P-labeled DNA. These small fragments were not located on the cleavage map.     

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.     

Induction of direct mutations of intracellular phage cd exposed to O-methylhydroxylamine]

Intracellular development of DNA-containing cd phage in the presence of O-methylhydroxylamine (in vivo mutagenesis) results in 50-fold increase of mutants in the phage progeny. The main effect is due to the mutagen presence during replication of phage DNA (within 10-20 min after the infection). The presence of the mutagen both before and after DNA replication does not produce any considerable mutagenic effect. Comparison of the data obtained with kinetic reaction of O-methylhydroxylamine with nucleic acid components is due to enzymatic formation of modified precursors, N4-metoxycytidine and/or N6-metoxyadenosine derivatives, which have dual functional specificity, and to their incorporation into genome under DNA replication. The presence of O-methylhydroxylamine increases not only the number of mixed clones with a high content of mutants, but also the number of pure mutant clones. Recombinogenic activity of O-methylhydroxylamine is considered to be a possible cause of this effect.     

Mechanism of replication of bacteriophage phi X174. XXII. Site-specific mutagenesis of the A* gene reveals that A* protein is not essential for phi X174 DNA replication

The A and A* proteins of phage phi X174 are encoded in the same reading frame in the viral genome; the smaller A protein is the result of a translational start signal with the A gene. To differentiate their respective functions, oligonucleotide-directed site-specific mutagenesis was used to change the ATG start codon of the phi X 174 A* gene, previously cloned into pCQV2 under lambda repressor control, into a TAG stop codon. The altered A gene was then inserted back into phi X replicative form DNA to produce an amber mutant, phi XamA*. Two different Escherichia coli amber suppressor strains infected with this mutant produced viable progeny phage with only a slight reduction in yield. In Su+ cells infected with phi XamA*, phi X gene A protein, altered at one amino acid, was synthesized at normal levels; A* protein was not detectable. These observations indicate that the A* protein increases the replicative efficiency of the phage, perhaps by shutting down host DNA replication, but is not required for replication of phi X174 DNA or the packaging of the viral strand under the conditions tested.     

Damaged-site independent mutagenesis of phage lambda produced by inducible error-prone repair

The existence of damaged-site independent mutagenesis is confirmed here by scoring the appearance of clear-plaque (c-) or virulent (vir) forward mutations on intact (non-irradiated) phage lambda grown on UV-irradiated E. coli K12 hosts. The mutation frequency was measured as a function of the incubation time between the occurrence of host DNA lesions and phage infection. The time course of mutagenesis of intact phage followed the induction pattern observed upon UV-reactivation of UV-damaged phage by Defais et al. (1976). Intact phage did not mutate in UV-irradiated hosts carrying the uvm-25 mutation known to prevent the occurrence of UV-reactivation. These findings suggest that damaged-site independent mutagenesis results from inducible error-prone repair. Clear-plaque mutations arising on intact phage were mostly found in phage bursts consisting of clear and turbid plaque formers whereas UV-damaged phage gave rise to mostly clear-plaque formers. Contrarily to damaged-site dependent mutagenesis, damaged-site independent mutagenesis can arise even at late times during the phage replication cycle. Our data indicate that about half of the phage mutations that arise upon UV-reactivation are damaged-site independent mutations. Replication of intact phage DNA in a host during induction of SOS functions provides a sensitive assay for the detection of damaged-site independent mutagenesis.     

Nucleotide excision repair and recombination are engaged in repair of trans-4-hydroxy-2-nonenal adducts to DNA bases in Escherichia coli

One of the major products of lipid peroxidation is trans-4-hydroxy-2-nonenal (HNE). HNE forms highly mutagenic and genotoxic adducts to all DNA bases. Using M13 phage lacZ system, we studied the mutagenesis and repair of HNE treated phage DNA in E. coli wild-type or uvrA, recA, and mutL mutants. These studies revealed that: (i) nucleotide excision and recombination, but not mismatch repair, are engaged in repair of HNE adducts when present in phage DNA replicating in E. coli strains; (ii) in the single uvrA mutant, phage survival was drastically decreased while mutation frequency increased, and recombination events constituted 48 % of all mutations; (iii) in the single recA mutant, the survival and mutation frequency of HNE-modified M13 phage was slightly elevated in comparison to that in the wild-type bacteria. The majority of mutations in recA^- strain were G:C → T:A transversions, occurring within the sequence which in recA⁺ strains underwent RecA-mediated recombination, and the entire sequence was deleted; (iv) in the double uvrA recA mutant, phage survival was the same as in the wild-type although the mutation frequency was higher than in the wild-type and recA single mutant, but lower than in the single uvrA mutant. The majority of mutations found in the latter strain were base substitutions, with G:C → A:T transitions prevailing. These transitions could have resulted from high reactivity of HNE with G and C, and induction of SOS-independent mutations.     

Molecular mechanisms of substitution mutagenesis. An experimental test of the Watson-Crick and topal-fresco models of base mispairings

The proteins coded by bacteriophate T4 replication genes 32, 41, 43, 44, 45, 61, and 62 together can replicate phi X174 DNA templates very efficiently. The fidelity of this in vitro replication reaction has been measured using an infectivity assay. The product molecules have the same specific infectivity as the template DNA. When an amber mutant DNA template is used, no increase in the frequency of revertants is seen even after more than 60 duplications in vitro. By using imbalances in the concentrations of deoxynucleotide substrates, the error rate during DNA replication in vitro can be greatly increased. Control experiments indicate that the increased mutagenesis is not due to the presence of dITP or dUTP as contaminants in the deoxynucleotide substrates used. The increase in the frequency of revertants is linearly related to the ratio of the correct and the incorrect deoxynucleotides. Determination of the DNA sequence of the revertants induced shows that a change in DNA sequence of the amber site predicted from the nucleotide bias occurs. DNA synthesis in vitro resembles in vivo replication in that the error rate depends not only upon the base change required for reversion but also upon the neighboring DNA sequences. The error rate is estimated to be 5 X 10(-6) at am3 site, 6.4 X 10(-7) at am86 site, and less than 2.9 X 10(-7) at am9 site. Comparison of the frequency of G-T and A-C mispairs reveals that most AT leads to GC transition mutations occur through G-T mispairs. Measurement of the frequency of the mispairs required to induce transversion mutations reveals that these occur primarily through purine-purine mispairs. Transition mutations are more frequent than transversion mutations at both the am3 and the am86 sites. These observations support the models for base pairing errors proposed by Watson and Crick ((1953) Nature 171, 964-967) and Topal and Fresco ((1976) Nature 263, 285-289).     

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.