The DNA-Delay Mutants of Bacteriophage T4

Mutants of phage T4 defective in genes 39, 52, 58-61, and 60 (the DNA delay or DD genes) are characterized by a delay in phage DNA synthesis during infection of a nonpermissive Escherichia coli host. Amber (am) mutants defective in these genes yield burst sizes varying from 30 to 110 at 37 C in E. coli lacking an am suppressor. It was found that when DD am mutants are grown on a non-permissive host at 25 C, rather than at 37 C, phage yield is reduced on the average 61-fold. At 25 C incorporation of labeled thymidine into phage DNA is also reduced to 3 to 10% of wild-type levels. Mutants defective in the DD genes were found to promote increased recombination as well as increased base substitution and addition-deletion mutation. These observations indicate that the products of the DD genes are necessary for normal DNA synthesis. The multiplication of the DD am mutants on an Su⁻ host at 37 C is about 50-fold inhibited if prior to infection the host cells were grown at 25 C. This suggests that a compensating host function allows multiplication of DD am mutants at 37 C in the Su⁻ host, and that this function is active in cells grown at 37 C prior to infection, but is inactive when the prior growth is at 25 C. Further results are described which suggest that the products of genes 52, 60, and 39 as well as a host product interact with each other.     

Gyrase-dependent initiation of bacteriophage T4 DNA replication: interactions of Escherichia coli gyrase with novobiocin, coumermycin and phage DNA-delay gene products.

Wild-type bacteriophage T4 and DNA-delay am mutants defective in genes 39, 52, 60 and 58–61 were tested for intracellular sensitivity to the antibiotics coumermycin and novobiocin, drugs which inhibit the DNA gyrase of Escherichia coli. Treatment with these antibiotics drastically reduced the characteristic growth of gene 39, 52 and 60 DNA-delay am mutants in E. coli lacking an amber suppressor (su^?). Wild-type phage-infected cells were unaffected by the drugs while the burst size of a gene 58–61 mutant was affected to an intermediate extent. A su^?E. coli strain which is resistant to coumermycin due to an altered gyrase permitted growth of the DNA-delay am mutants in the presence of the drug. Thus, the characteristic growth of the DNA-delay am mutants in an su^? host apparently depends on the host gyrase. An E. coli himB mutant is defective in the coumermycin-sensitive subunit of gyrase (H. I. Miller, personal communication). Growth of the gene 39, 52 and 60 am mutants was inhibited in the himB mutant while the gene 58–61 mutant and wild-type T4 showed small reductions in burst size in this host. Experiments with nalidixic acid-sensitive and resistant strains of E. coli show that wild-type phage T4 requires a functional nalA protein for growth.Novobiocin and coumermycin inhibit phage DNA synthesis in DNA-delay mutant-infected su^?E. coli if added during the early logarithmic phase of phage DNA synthesis. The gene 58–61 mutant showed the smallest inhibition of DNA synthesis in the presence of the drugs. Addition of the drugs during the late linear phase of phage DNA synthesis had no effect on further synthesis in DNA-delay mutant-infected cells. Coumermycin and novobiocin had no effect on DNA synthesis in wild-type-infected cells regardless of the time of addition of the antibiotics. Models are considered in which the DNA-delay gene products either form an autonomous phage gyrase or interact with the host gyrase and adapt it for proper initiation of phage DNA replication.     

φX-174 Bacteriophage Structural Mutants Which Affect Deoxyribonucleic Acid Synthesis

Seven cistrons in X-174 were identified and one in particular was studied intensively: cistron A, which is assigned a protein in the mature phage. Amber mutants in this cistron synthesize a new deoxyribonucleic acid (DNA) form in addition to circular phage DNA upon infection of the restrictive host. This DNA is linear, non-infectious, and single-stranded; it is formed from the phage strand of replicative form X-174 DNA. These mutants produce two different defective particles in the restrictive host. One particle contains circular phage DNA but is not infectious; the other contains the new DNA form and is similar to the 70S particles found in wild-type phage lysates. The mutant A gene product acts independently of normal A protein upon mixed infection of the restrictive host with an A mutant and a mutant from any other cistron or wild type.     

Lambda-repressed mutants of bacteriophage T5. II. Physiological characterization.

Physiological properties of bacteriophage T5 gene A1 mutants, whose growth is inhibited in λ lysogens, and designated T5 lr, have been studied. In the presence of λ gene rex, which is responsible for lr growth inhibition, gene A1 product is synthesized and functional. However, several physiological defects were observed: phage DNA synthesis is inhibited; late phage-induced proteins are synthesized in markedly decreased amounts after a delay of about 15 minutes; phage DNA transfer into the host goes beyond the first-step transfer fragment but, in most bacteria, is interrupted after penetration of about 55% of the genome. Relationships between these different defects are discussed.     

A Mutant of E. COLI That Restricts Growth of Bacteriophage T4 at Elevated Temperatures

After nitrosoguanidine mutagenesis, a Phage Host Defective (phd) mutant of E. coli HfrH was isolated that supported the growth of T4D wild-type bacteriophage at 30°, but not at 40° or higher. Eleven independent spontaneous mutants of T4 (go mutants) were isolated that overcame the growth restriction at high temperature. All of these mutants were located within three percent recombination of a gene 39 amber mutation in the clockwise direction on the standard map. In mixed infections, the representative go mutant chosen for further study seems to be recessive to its wild-type allele. Temperature-shift experiments suggested that the mutated host function involved in phage growth is a "late" function, beginning in mid-eclipse.—Electrophoresis of phage proteins labelled early and late in infection showed that under restrictive conditions early protein synthesis was normal, but that certain late proteins were absent. However, measurements of DNA synthesis showed that under restrictive conditions the amount of phage DNA synthesized, and especially the amount of DNA sedimenting as high molecular weight replicative intermediate, was reduced. Pulse-chase experiments showed that the phage DNA made under restrictive conditions was not rapidly degraded.     

High-frequency transduction of pBR322 by cytosine-substituted T4 bacteriophage: evidence for encapsulation and transfer of head-to-tail plasmid concatemers

Transduction of plasmid pBR322 by cytosine-substituted T4 phages has been studied. Three T4 phage mutants which substitute cytosine for all of hydroxymethylcytosine residues in the DNA, were shown to transduce pBR322 at frequencies of 2 × 10^?2 to 4 × 10^?3 transductants per singly infected cell. Also, three T4 phage strains which partially substitute cytosine for hydroxymethylcytosine, transduced pBR322 at frequencies of 2 × 10^?3 to 2 × 10^?4. The transduction frequencies of pBR322 we attained are at least 10-fold higher than those reported by G. G. Wilson, K. Young, and G. J. Edlin (1979, Nature (London)280, 80–82). We found that multiplicity of infection in preparation of the transducing phage is the most important factor affecting the frequency of pBR322 transduction. When a lysate made at a multiplicity of infection ranging from 0.5 to 0.05 was used as the donor phage, transduction frequency of pBR322 was 10- to 40-fold higher than that of high-m.o.i. lysate. The transduction frequency was not affected by either restriction systems or amber suppressors of the recipient cells. However, no pBR322-containing transductant was obtained when either recA or polA mutants were used as the recipients. DNA from T4dC phage containing pBR322-transducing particles was analyzed on agarose gel electrophoresis after cleavage with restriction endonucleases. It was suggested that the pBR322 DNA in the T4dC phage particles exists as head-to-tail concatemers.     

Bacteriophage T4 mutants deficient in alteration and modification of the Escherichia coli RNA polymerase

An extensive screening of coliphage T4 mutants has revealed two distinct classes defective, respectively, in the two sequential phage-induced phosphorylations of the host RNA polymerase, alteration and modification. The existence of these mutants proves that T4-specified functions are involved in both processes. The viabilities of these mutants demonstrate that neither alteration nor modification is essential for growth in Escherichia coli B/r. Physiological studies after infection of E. coli B/r have failed to reveal any abnormalities of phage deficient in alteration or modification. Both mutants normally inhibit host protein and stable RNA synthesis and normally express all classes of T4 genes. Thus, these specific phage-induced structural changes in the host RNA polymerase are not fundamental to the control of gene expression during T4 development. Alteration and modification may be required for growth in some strains of E. coli and hence be selectively advantageous because they extend the normal host range of the phage.Alteration appears to be catalyzed by a T4 function injected with the DNA. A polypeptide of molecular weight 61,000, which is probably cleaved during morphogenesis from a precursor of molecular weight 79,000, is missing in phage particles of alteration-deficient strains and may be the phage activity so injected. The T4 gene involved in alteration is named alt.Modification is controlled by a T4-replicative gene that has been mapped into a region of about 500 base-pairs between genes 39 and 56. These mapping data show that the defect in α modification defines a new T4 gene, named mod.     

Genome structures in a lysogenic Rhizobium meliloti system

Summary The genome structure of the temperateRhizobium meliloti phage and the attachment site of this phage on the host chromosome were examined by genetic means. The heat-sensitive mutants used in 2 and 3 point crosses gave a linear chromosome map. There was no evidence for map circularity. The immunity region has a distal position on the phage chromosome. The functional grouping of the used 23 phage mutants was made byin vivo andin vitro complementation tests and 20 cistrons were obtained. The cistrons, near to the immunity region, were identified as early genes, the remaining ones as morphogenetic cistrons. The latter inin vitro complementation tests gave two complementing groups, presumably as head and tail donors. The attachment site of the prophage on the host chromosome was localized by pulse mutagen treatments in synchronously replicating cultures. The sequence of markers are O-str — hs — att ¹⁶⁻³ — T.     

Integration of the plasmid prophages P1 and P7 into the chromosome of Escherichia coli.

The prophages of the related temperate bacteriophages P1 and P7, which normally exist as plasmids, suppress Escherichia coli dnaA (ts) mutants by integrating into the host chromosome. The locations of the sites on the prophage used for integrative recombination were identified by restriction nuclease analysis and DNA-DNA hybridization techniques. The integration of P1 and P7 often involves a specific site on the host DNA and a specific site on the phage DNA; the latter is probably the end of the phage genetic map. When this site is utilized, the host Rec⁺ function is not required. In Rec⁺ strains, P1 and P7 may also recombine with homologous regions on the host chromosome; at least one of these regions is an IS1 element. In some integration events, prophage deletions are observed which are often associated with inverted repeat structures on the phage DNA. Thus, P1 and P7 may employ one of several different mechanisms for integration.     

Inadequate inhibition of host RNA polymerase restricts T7 bacteriophage growth on hosts overexpressing udk

Overexpression of udk, an Escherichia coli gene encoding a uridine/cytidine kinase, interferes with T7 bacteriophage growth. We show here that inhibition of T7 phage growth by udk overexpression can be overcome by inhibition of host RNA polymerase. Overexpression of gene 2, whose product inhibits host RNA polymerase, restores T7 phage growth on hosts overexpressing udk. In addition, rifampicin, an inhibitor of host RNA polymerase, restores the burst size of T7 phage on udk-overexpressing hosts to normal. In agreement with these findings, suppressor mutants that overcome the inhibition arising from udk overexpression gain the ability to grow on hosts that are resistant to inhibition of RNA polymerase by gene 2 protein, and suppressor mutants that overcome a lack of gene 2 protein gain the ability to grow on hosts that overexpress udk. Mutations that eliminate or weaken strong promoters for host RNA polymerase in T7 DNA, and mutations in T7 gene 3.5 that affect its interaction with T7 RNA polymerase, also reduce the interference with T7 growth by host RNA polymerase. We propose a general model for the requirement of host RNA polymerase inhibition.     

Genetic and Immunological Studies of Bacteriophage T4 Thymidylate Synthetase

Thymidylate synthetase, which appears after infection of Escherichia coli with bacteriophage T4, has been partially purified. The phage enzyme is immunologically distinct from the host enzyme and has a molecular weight of 50,000 in comparison to 68,000 for the host enzyme. A system has been developed to characterize T4 td mutants previously known to have impaired expression of phage thymidylate synthetase. For this system, an E. coli host lacking thymidylate synthetase was isolated. Known genetic suppressors were transduced into this host. The resulting isogenic hosts were infected with phage T4 td mutants. The specific activities and amounts of cross-reacting material induced by several different types of phage mutants under conditions of suppression or non-suppression have been examined. The results show that the phage carries the structural gene specifying the thymidylate synthetase which appears after phage infection, and that the combination of plaque morphology, enzyme activity assays, and an assay for immunologically cross-reacting material provides a means for identifying true amber mutants of the phage gene.     

Characterization of new regulatory mutants of bacteriophage T4. II. New class of mutants.

Amber mutants of bacteriophage T4 have been isolated that induce thymidine kinase activity only after infection of a strain of Escherichia coli carrying a suppressor mutation. The activity induced when one of these mutants infected this suppressor strain is much more heat sensitive than the activity induced by wild-type T4. This indicates that this amber mutation lies within the structural gene for thymidine kinase. This gene is between fI and v on the standard T4 genetic map. A mutant of tt4 that is unable to induce thymidine kinase activity incorporates only about one-eighth as much thymidine into its DNA as phage that do induce thymidine kinase. This contrasts to the findings that the total thymidine kinase activity in extracts prepared from cells infected with phage able to induce thymidine kinase in only twice as great as the activity in cells infected with the mutant unable to induce the enzyme.     

Isolation of mutants of bacteriophage T4 unable to induce thymidine kinase activity. II. Location of the structural gene for thymidine kinase.

Amber mutants of bacteriophage T4 have been isolated that induce thymidine kinase activity only after infection of a strain of Escherichia coli carrying a suppressor mutation. The activity induced when one of these mutants infected this suppressor strain is much more heat sensitive than the activity induced by wild-type T4. This indicates that this amber mutation lies within the structural gene for thymidine kinase. This gene is between fI and v on the standard T4 genetic map. A mutant of tt4 that is unable to induce thymidine kinase activity incorporates only about one-eighth as much thymidine into its DNA as phage that do induce thymidine kinase. This contrasts to the findings that the total thymidine kinase activity in extracts prepared from cells infected with phage able to induce thymidine kinase in only twice as great as the activity in cells infected with the mutant unable to induce the enzyme.     

DNA base sequence changes induced by bromouracil mutagenesis of lambda phage

The base sequence changes induced by bromouracil mutagenesis in the cI gene of phage lambda have been determined by direct sequence analysis. Phage DNA mutagenized during prophage replication or during phage lytic growth showed predominantly A · T → G · C transitions. The frequency of this mutation was strongly sequence-dependent: 5′ A-C-G-C 3′ > A-C(A.C or T) > A(A.G or T). The difference in mutability of bases in the gene is not the result of specificity in mutL-dependent mismatch repair, since phage grown in mutL host cells showed the same distribution of bromouracil mutations. The observations made in phage mutagenized with bromouracil in the prophage state should be representative of bromouracil mutagenesis in the Escherichia coli chromosome.     

A functional requirement for modification of the wobble nucleotide in the anticodon of a T4 suppressor tRNA

Temperature-sensitive mutants of E. coli have been isolated which restrict the growth of strains of bacteriophage T4 which are dependent upon the function of a T4-coded amber or ochre suppressor transfer RNA. One such mutant restricts the growth of certain ochre but not amber suppressor-requiring phage. Analysis of the T4 tRNAs synthesized in this host revealed that many nucleotide modifications are significantly reduced. The modifications most strongly affected are located in the anticodon regions of the tRNAs. The T4 ochre suppressor tRNAs normally contain a modified U residue in the wobble position of the anticodon; it has been possible to correlate the absence of this specific modification in the mutant host with the restriction of suppressor activity. Furthermore, the extent of this restriction varies dramatically with the site of the nonsense codon, indicating that the modification requirement is strongly influenced by the local context of the mRNA. An analysis of spontaneous revertants of the E. coli ts mutant indicates that temperature sensitivity, restriction of phage suppressor function, and undermodification of tRNA are the consequences of a single genetic lesion. The isolation of a class of partial revertants to temperature insensitivity which have simultaneously become sensitive to streptomycin suggests that the translational requirement for the anticodon modification can be partially overcome by a change in the structure of the ribosome.     

Fate of thymine-containing dimers in the deoxyribonucleic acid of ultraviolet-irradiated mutator T1 Escherichia coli transfuctants

In order to determine whether a relationship generally exists between the mutator property (mutT1) and repair of ultraviolet (UV) irradiation damaged DNA, we performed spontaneous mutation rate and UV-survival determinations without and with acriflavin (4 μg/ml) in P1 phage mediated mut T1 Escherichia coli transductants. The strains constructed were assumed to be cosigenic except for the mutator factor. The mutT1 uvrA, uvrB or exrA transdunctants had mutation rates similar to the donor strain. Double mutants containing mutT1 and uvrB or exrA had the same level of UV survival as the parent with the same mutator phenotype. Mutator strains were normal for host-cell reactivation of UV-irradiated phage T1, and phage lambda was UV-inducible. The fate of UV-induced thymine-containing dimers in the deoxyribonucleic acid (DNA) of mutT1 transductants was investigated. Dark repair of pyrimidine dimers is equally sensitive in the nonmutator and mutator Hcr⁺. During incubation in the dark, dimers were excised to the same extent from the DNA of the Hcr⁺ mutator and nonmutator transductants but remained in the DNA of the Hcr^? mutant.     

Fate of Donor Deoxyribonucleic Acid in a Highly Transformation-Deficient Strain of Haemophilus influenzae

A transformation-deficient strain of Haemophilus influenzae (efficiency of transformation 10⁴-fold less than that of the wild type), designated TD24, was isolated by selection for sensitivity to mitomycin C. In its properties the mutant was equivalent to recA type mutants of Escherichia coli. The TD24 mutation was linked with the str-r marker (about 30%) and only weakly linked with the nov-r2.5 marker. The uptake of donor deoxyribonucleic acid (DNA) was normal in the TD24 strain, but no molecules with recombinant-type activity (molecules carrying both the donor and the resident marker) were formed. In the mutant the intracellular presynaptic fate of the donor DNA was the same as that in the transformation-proficient (wild-type) strain, and the radioactive label of the donor DNA associated covalently with the recipient chromosome in about the same quantity as in the wild type. However, many fewer donor atoms were associated with segments of the mutant's recipient chromosome as compared with segments of the wild-type chromosome. In the mutant the association was accompanied by complete loss of donor marker activity. The lack of donor marker activity of the donor-recipient complex of DNA isolated from the mutant was not due to lack of uptake of the complex by the second recipient and its inability to associate with the second recipient's chromosome. Because the number of donor-atom-carrying resident molecules was higher than could be accounted for by the lengths of presynaptic donor molecules, we favor the idea that the association of donor DNA atoms with the mutant chromosome results from local DNA synthesis rather than from dispersive integration of donor DNA by recombination.     

On the lack of host-cell reactivation of UV-irradiated phage T5. I. Interference of T5 infection with the host-cell reactivation of phage T1

UV-irradiated phage T5, in contrast to T1, T3 and T7, fail to display hostcell reactivation (HCR) when infecting excision-repair proficient Escherichia coli cells. Possible causes of this lack of HCR (which T5 shares with the T-even phages) have been investigated by studying HCR of T1 under conditions of superinfection by T5. Repair-proficient B/r cells were infected at low multiplicity with UV-irradiated phage T1 in the presence of 1.8 mg/ml caffeine and were superinfected after 15 min with heavily UV-irradiated T5 amber mutants at high multiplicity. The caffeine, which is later diluted out, prevents any T1 repair prior to T5 superinfection, and UV (254 nm) irradiation of T5 with 144 J/m² reduces the ability of this phage to exclude T1, thus permitting a reasonable fraction of the mixedly infected complexes to produce T1 progeny.Under these conditions, T5 superinfection causes loss of HCR in about 90% of the T1-producing complexes. Superinfection with unirradiated T5 likewise inhibits HCR of T1, but superinfection with irradiated T3 (a host-cell-reactivable phage) does not. This indicates that the observed HCR inhibition of T1 results from T5 infection rather than from competition of irradiated foreign DNA for the excision-repair enzymes of the bacterial host. Employment of apropriate T5 amber mutants has shown that “first-step transfer” (FST) of T5 DNA (involving only 8% of the T5 genome) is sufficient for HCR inhibition, but that transfer of the remainder DNA in addition inhibits a previously described minor T1 recovery process. HCR inhibition of T1, and thus presumably lack of HCR in T5 itself, is ascribed to a substance which is produced either post infection by a gene located in the FST segment of the T5 genome, or which is transferred from extracellular T5 together with the FST DNA.