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.     

Involvement of bacteriophage T4 genes in radiation repair

One interpretation of Ebisuzaki's (1966) observation that the functional survival of certain early phage T4 genes is identical in v⁺ and v -infected cells is that the product of the early gene being studied is essential for the successful completion of excision repair (which is known to be mediated by the v gene). An experiment designed to test this hypothesis is described, with results which fully support the idea. Assuming then that this interpretation is valid, it became possible to determine the involvement in excision repair of a much wider range of early genes by establishing whether or not the v allele affects their functional survival. In addition a comparable series of experiments was performed with phages carrying the u.v.-sensitive y mutation which is known to mediate a quite different type of repair in T4-infected cells.The results indicate that genes 1, 30, 42, 43 and 56 are involved in excision repair, but not genes 32, 41, 43 or 44. All these genes are however involved in y-mediated repair. It appears therefore that this latter repair system (which bears some resemblance to that controlled by the rec genes in bacteria) depends on normal phage DNA synthesis for its completion. However the repair synthesis following the excision of pyrimidine dimers in u.v.-irradiated T4 DNA seems distinct from normal DNA synthesis in that it does not involve certain of the early phage genes, and in particular does not utilize the DNA polymerase coded by gene 43. It is suggested that the polymerase activity associated with this repair synthesis is provided by the bacterial Kornberg polymerase pol I.     

Cloned genes for bacteriophage T4 late functions are expressed in Escherichia coli

We have constructed derivatives of plasmid pMB9 carrying EcoRI digestion fragments of bacteriophage T4 DNA that code for late gene functions. When Escherichia coli strains carrying these plasmids are infected with T4 amber mutants, burst sizes up to 30% of the wild-type level are obtained. Single burst experiments imply that the phage progeny result from complementation and do not depend on marker rescue. By electrophoretic and immunological techniques, we have established that the cloned T4 late genes are transcribed and translated in uninfected cells. A serum blocking assay has been used to quantitate the levels of one of the T4 gene products, gp11, before and after T4 infection. Uninfected cells containing the cloned T4 gene 11 DNA have 0.1% and mini cells have 1% of the gp11 levels per unit protein found in cells late after T4 wild-type infection. There is little or no additional gp10 and gp11 formed from the cloned genes after T4 infection.     

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.     

Construction and properties of a recombinant plasmid containing gene 32 of bacteriophage T4D

This paper describes the construction and characterization of a chimeric plasmid that encodes the single-stranded DNA-binding protein of bacteriophage T4D (the product of gene 32). The plasmid contains a 2·6 × 10³ base HindIII segment of T4 DNA that includes genes 59 and 32 as well as a portion of gene 33. Isolation of bacteria carrying the recombinant plasmid became possible when the segment of phage DNA contained an amber mutation in gene 32. This suggests that a functional gene 32 is deleterious to the cell. Using antibody to gene 32 protein, we have been able to demonstrate expression of the plasmid-borne gene 32 in uninfected bacteria. Deletion variants of the gene 32 plasmid have been constructed in vitro. These have been used to align the genetic map of the region with the restriction map and to study phage gene expression from the plasmid in both infected and uninfected cells. In phage-infected cells the level of functional gene 32 product regulates the efficiency of translation of its own messenger RNA. We also observe such self-regulation for gene 32 present on the plasmid.     

Maturation of the head of bacteriophage T4. II. Head-related, aberrant tau-particles

Three somewhat different types of particle accumulate in cells infected with a phage carrying a mutation in gene 21 (in addition to the tubular variant (polyhead) of the head). The major type is the so-called τ-particle. These particles are very fragile, associated with the cell membrane, and have a sedimentation coefficient of about 420 S. They possess no DNA if isolated, and contain predominantly the precursor proteins P23, P24, P22 and the internal protein IP III, in addition to protein P20 and several proteins of unknown genetic origin.The remainder of the particles are partially or completely filled with DNA. The ratio of τ-particles to these partially or completely filled particles depends upon the particular mutant (in gene 21) phage used. In cells infected with a phage carrying the amber mutation (N90) in gene 21, about 10% of the precursor head protein P23 is cleaved to P231, and correspondingly about 10% of the particles are partially or completely filled with DNA. In cells infected with the temperature-sensitive mutant (N8) in gene 21, about 1% of the particles are fully or partially filled, and correspondingly about 1% of the P23 is cleaved to P231. In either case, the DNA-associated particles contain predominantly the cleaved proteins P231 and IP III1, and have none of the P22 and IP III found in τ-particles. This observation, and the correlation of the amount of partially or completely filled particles with the extent of the cleavage of P23 in the lysates, strongly suggest that cleavage of the head proteins is required for DNA packaging to occur.The τ-particles have properties similar to the so-called prohead I particles which we have isolated as intermediates in wild-type head assembly (preceding paper). However, temperature shift-down experiments, using several different phage carrying temperature-sensitive mutations in gene 21, indicate that the bulk of the τ-particles cannot be used for normal phage production.     

Host DNA Degradation after Infection of Escherichia coli with Bacteriophage T4: Dependence of the Alternate Pathway of Degradation Which Occurs in the Absence of Both T4 Endonuclease II and Nuclear Disruption on T4 Endonuclease IV

Escherichia coli cells infected with T4 phage which are deficient in both nuclear disruption and endonuclease II exhibit a pathway of host DNA degradation which does not occur in cells infected with phage deficient only in endonuclease II. This alternate pathway of host DNA degradation requires T4 endonuclease IV.     

The relation between hairpin formation by mitochondrial WANCY tRNAs and the occurrence of the light strand replication origin in Lepidosauria

Mitochondrial light strand DNA replication is initiated at light strand replication origins (OLs), short stem-loop hairpins formed by the heavy strand DNA. OL-like secondary structures are also formed by heavy strand DNA templating for the five tRNAs adjacent to OLs, the WANCY tRNA cluster. We tested whether natural OL absence associates with greater capacities for formation of OL-like structures by WANCY tRNA genes. Using lepidosaurian taxa (Sphenodon, lizards and amphisbaenids), we compared WANCY tRNA capacities to form OL-like structures between 248 taxa possessing an OL with 131 taxa without OL (from different families). On average, WANCY tRNA genes form more OL-like structures in the absence of a regular OL than in its presence. Formation of OL-like structures by WANCY tRNAs follows hierarchical patterns that may reduce competition between the tRNA's translational function and its secondary OL function: the rarer the tRNA's cognate amino acid, the greater the capacity to form OL-like structures. High OL-forming capacities for neighboring tRNAs are avoided. Because OL absence usually occurs in taxa with reduced genomes, increased formation of OL-like structures by WANCY tRNAs might result from selection for greater metabolic efficiency. Further analyses suggest that OL loss is one of the latest steps in genome reduction, and promotes the increase in formation of OL-like structures by WANCY tRNA genes in Lepidosauria.     

Cloning of linear DNAs in vivo by overexpressed T4 DNA ligase: construction of a T4 phage hoc gene display vector.

A method was developed to clone linear DNAs by overexpressing T4 phage DNA ligase in vivo, based upon recombination deficient E. coli derivatives that carry a plasmid containing an inducible T4 DNA ligase gene. Integration of this ligase-plasmid into the chromosome of such E. coli allows standard plasmid isolation following linear DNA transformation of the strains containing high levels of T4 DNA ligase. Intramolecular ligation allows high efficiency recircularization of cohesive and blunt-end terminated linear plasmid DNAs following transformation. Recombinant plasmids could be constructed in vivo by co-transformation with linearized vector plus insert DNAs, followed by intermolecular ligation in the T4 ligase strains to yield clones without deletions or rearrangements. Thus, in vitro packaged lox-site terminated plasmid DNAs injected from phage T4 were recircularized by T4 ligase in vivo with an efficiency comparable to CRE recombinase. Clones that expressed a capsid-binding 14-aa N-terminal peptide extension derivative of the HOC (highly antigenic outer capsid) protein for T4 phage hoc gene display were constructed by co-transformation with a linearized vector and a PCR-synthesized hoc gene. Therefore, the T4 DNA ligase strains are useful for cloning linear DNAs in vivo by transformation or transduction of DNAs with nonsequence-specific but compatible DNA ends.     

Genetic and Physiological Studies of Bacteriophage T5 III. Patterns of Deoxyribonucleic Acid Synthesis Induced by Mutants of T5 and the Identification of Genes Influencing the Appearance of Phage-Induced Dihydrofolate Reductase and Deoxyribonuclease

Patterns of deoxyribonucleic acid (DNA) metabolism in nonpermissive cells infected with amber mutants representing 29 genes of T5 are reported. A group of 7 contiguous genes are essential for the synthesis of phage DNA, whereas 20 other genes, when defective, permit varying degrees of phage DNA synthesis. Two further genes are essential for complete transfer of phage DNA to host cells, and therefore indirectly do not permit the synthesis of phage DNA. The structural genes for an early T5 deoxyribonuclease and for T5 DNA polymerase, as well as a gene that affects the synthesis of dihydrofolate reductase, have been identified in the genetic map of T5.     

Assembly of the tail of bacteriophage T4

The protein products of at least 21 phage genes are needed for the formation of the tail of bacteriophage T4. Cells infected with amber mutants defective in these genes are blocked in the assembly process. By characterizing the intermediate structures and unassembled proteins accumulating in mutant-infected cells, we have been able to delineate most of the gene-controlled steps in tail assembly. Both the organized structures and unassembled proteins serve as precursors for in vitro tail assembly. We review here studies on the initiation, polymerization, and termination of the tail tube and contractile sheath and the genetic control of these processes. These studies make clear the importance of the baseplate; if baseplate formation is blocked (by mutation) the tube and sheath subunits remain essentially unaggregated, in the form of soluble subunits. Seventeen of the 21 tail genes specify proteins involved in baseplate assembly. The genes map contiguously in two separate clusters, one of nine genes and the other of eight genes. Recent studies show that the hexagonal baseplate is the end-product of two independent subassembly pathways. The proteins of the first gene cluster interact to form a structure which probably represents one-sixth of the outer radius. The products of the other gene cluster interact to form the central part of the baseplate. Most of the phage tail precursor proteins appear to be synthesized in a non-aggregating form; they are converted to a reactive form upon incorporation into preformed substrate complexes, without proteolytic cleavage. Thus reactive sites are limited to growing structures.     

Topoisomerase Involvement in Multiplicity Reactivation of Phage T4

The products of phage T4 genes 39, 52 and probably 60 have been previously characterized as forming a type II DNA topoisomerase. Other evidence suggested that this topoisomerase promotes normal initiation of DNA replication, and that when it is defective its loss is partially compensated for by the host gyrase. We present evidence here that mutants defective in genes 39, 52 and 60 have reduced ability to carry out multiplicity reactivation (MR, a form of recombinational repair) of phage DNA damaged either by mitomycin C (MMC) or psoralen plus near-UV light (PUVA). We also observed that there is not extensive superhelicity in the intracellular phage DNA either in the presence or absence of the phage topoisomerase. This tends to rule out the possibility that the topoisomerase influences MR by controlling the general superhelicity of the phage DNA. The dependence of MR on topoisomerase could occur in several possible ways. However, we favor the explanation that the lesions are bypassed by a postreplication recombinational repair process that is influenced by the topoisomerase through its role in initiating replication.     

Mutation to Overproduction of Bacteriophage T4 Gene Products

R9 was isolated as one of several mutations that enhanced the growth of a leaky amber (am) mutant of bacteriophage T4 gene 62 (product required for phage DNA synthesis) under conditions of partial suppression by ribosomal ambiguity. R9 also enhanced the growth of leaky am mutants of some, but not all, other T4 “early” gene functions. R9 mapped between mutations in genes 43 and 62. By using assays involving polyacrylamide slab gel electrophoresis in the presence of sodium dodecyl sulfate, we observed the following. (i) R9 resulted in an overproduction of many T4 “early” proteins in infected cells. The most pronounced effects of R9 were observed when phage DNA synthesis and/or the functions of maturation genes 55 and 33 were not expressed. (ii) In rifampintreated infected cells, the capacity to synthesize T4 “early” proteins decayed more slowly in the presence of the R9 mutation than in the presence of the wild-type counterpart of R9. R9 appeared to have no effect on the rates of RNA synthesis either during early or late times after infection. The results suggest that the R9 mutation leads to increased functional stability of T4 “early” messengers.     

Role of Gene 52 in Bacteriophage T4 DNA Synthesis

In an attempt to elucidate the mechanism of delayed DNA synthesis in phage T4, Escherichia coli B cells were infected with H17 (an amber mutant defective in gene 52 possessing a "DNA-delay" phenotype). The fate of (14)C-labeled H17 parental DNA after infection was followed: we could show that this DNA sediments more slowly in neutral sucrose than wild-type DNA 3 min postinfection. In pulse-chase experiments progeny DNA was found to undergo detachment from the membrane at 12 min postinfection. Reattachment to the membrane was found to be related to an increase in rate of DNA synthesis. A nucleolytic activity that is absent from cells infected by wild-type phage and from uninfected cells could be detected in extracts prepared from mutant-infected cells. In contrast, degradation of host DNA was found to be less extensive in am H17 compared with wild-type infected cells. Addition of chloramphenicol to mutant-infected cells 10 min postinfection inhibited the appearance of a nuclease activity on one hand and suppressed the "DNA-delay" phenotype on the other hand. We conclude that the gene 52 product controls the activity of a nuclease in infected cells whose main function may be specific strand nicking in association with DNA replication. This gene product might directly attack both E. coli and phage T4 DNA, or indirectly determine their sensitivity to degradation by another nuclease.     

Regulation of Expression of Cloned Bacteriophage T4 Late Gene 23

The parameters governing the activity of the cloned T4 gene 23, which codes for the major T4 head protein, were analyzed. Suppressor-negative bacteria carrying wild-type T4 gene 23 cloned into plasmid pCR1 or pBR322 were infected with T4 gene 23 amber phage also carrying mutations in the following genes: (i) denA and denB (to prevent breakdown of plasmid DNA after infection) and (ii) denA, denB, and, in addition, 56 (to generate newly replicated DNA containing dCMP) and alc/unf (because mutations in this last gene allow late genes to be expressed in cytosine-containing T4 DNA). Bacteria infected with these phage were labeled with (14)C-amino acids at various times after infection, and the labeled proteins were separated by one-dimensional gel electrophoresis so that the synthesis of plasmid-coded gp23 could be compared with the synthesis of other, chromosome-coded T4 late proteins. We analyzed the effects of additional mutations that inactivate DNA replication proteins (genes 32 and 43), an RNA polymerase-binding protein (gene 55), type II topoisomerase (gene 52), and an exonuclease function involved in recombination (gene 46) on the synthesis of plasmid-coded gp23 in relation to chromosome-coded T4 late proteins. In the denA:denB:56:alc/unf genetic background, the phage chromosome-borne late genes followed the same regulatory rules (with respect to DNA replication and gp55 action) as in the denA:denB genetic background. The plasmid-carried gene 23 was also under gp55 control, but was less sensitive than the chromosomal late genes to perturbations of DNA replication. Synthesis of plasmid-coded gp23 was greatly inhibited when both the type II T4 topoisomerase and the host's DNA gyrase are inactivated. Synthesis of gp23 was also substantially affected by a mutation in gene 46, but less strongly than in the denA:denB genetic background. These observations are interpreted as follows. The plasmid-borne T4 gene 23 is primarily expressed from a late promoter. Expression of gene 23 from this late promoter responds to an activation event which involves some structural alteration of DNA. In these respects, the requirements for expressing the plasmid-borne gene 23 and chromosomal late genes are very similar (although in the denA:denB:56:alc/unf genetic background, there are significant quantitative differences). For the plasmid-borne gene 23, activation involves the T4 gp46, a protein which is required for DNA recombination. However, for the reasons presented in the accompanying paper (Jacobs et al., J. Virol. 39:31-45, 1981), we conclude that the activation of gene 23 does not require a complete breakage-reunion event which transposes that gene to a later promoter on the phage chromosome. Ways in which gp46 may actually be involved in late promoter activation on the plasmid are discussed.     

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.