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.     

Replication and Recombination of Gene 59 Mutant of Bacteriophage T4D

After infection of Escherichia coli B with phage T4D carrying an amber mutation in gene 59, recombination between two rII markers is reduced two- to three-fold. This level of recombination deficiency persists even when burst size similar to wild type is induced by the suppression of the mutant DNA-arrest phenotype. In the background of two other DNA-arrest mutants in genes 46 and 47, a 10- to 11-fold reduction in recombination is observed. The cumulative effect of gene 59 mutation on gene 46-47 mutant suggests that complicated interactions must occur in the production of genetic recombinants. The DNA-arrest phenotype of gene 59 mutant can be suppressed by inhibiting the synthesis of late phage proteins. Under these conditions, DNA replicative intermediates similar to those associated with wild-type infection are induced. Synthesis of late phage proteins, however, results in the degradation of mutant 200S replicative intermediate into 63S DNA molecules even in the absence of capsid assembly. Although these 63S molecules are associated with membrane, they do not replicate. These results suggest a role for gene 59 product, in addition to a possible requirement of concatemeric DNA in late replication of phage T4 DNA.     

T4 DNA replication and viral gene expression

The normal dependence of “late” T4 gene expression on concurrent viral DNA replication is circumvented in cells infected with a triple mutant in which viral DNA polymerase, DNA ligase, and the exonuclease functions of genes 46 or 47 are defective. Acrylamide gel electrophoresis of labeled proteins from infected cells has made possible an extension of the analysis of replication-uncoupled T4 protein synthesis. We find a number of late T4 proteins synthesized: the products of genes 34, 37, 18, 23 and 24. Processing of the gene 23 product, normally headassembly dependent, occurs, but with considerably diminished efficiency compared to wild-type infection. Late T4 protein synthesis in replication-uncoupled infection retains a requirement for T4 gene 33 and gene 55 function. Finally, a number of “early” T4 gene products, normally shut off late in wildtype infection, continue to be synthesized late in replication-uncoupled infection, concurrently with the late proteins.     

Gene 68, a new bacteriophage T4 gene which codes for the 17K prohead core protein is involved in head size determination

We have identified the gene for a major component of the prohead core of bacteriophage T4, the 17K protein. The gene, which we call gene 68, lies between genes 67 and 21 in the major cluster of T4 head genes. All of the genes in this region of the T4 genome have overlapping initiation and termination codons with the sequence T-A-A-T-G. We present the DNA sequence of the gene and show that it codes for a protein containing 141 amino acids with an acidic amino-terminal half and a basic carboxyl terminus. Antibodies prepared against the 17K protein were used to show that it is cleaved by the phage-coded gp21 protease during head maturation and that most of the protein leaves the head after cleavage. A frameshift mutation of the gene was constructed in vitro and recombined back into the phage genome. The mutated phages had a drastically reduced burst size and about half of the particles produced were morphologically abnormal, having isometric rather than prolate heads. Thus, the 17K protein is involved in head shape determination but is only semi-essential for T4 growth.     

55.2, a Phage T4 ORFan Gene,Encodes an Inhibitor of Escherichia coli Topoisomerase I and Increases Phage Fitness

Topoisomerases are enzymes that alter the topological properties of DNA. Phage T4 encodes its own topoisomerase but it can also utilize host-encoded topoisomerases. Here we characterized 55.2, a phage T4 predicted ORF of unknown function. High levels of expression of the cloned 55.2 gene are toxic in E. coli. This toxicity is suppressed either by increased topoisomerase I expression or by partial inactivation of the ATPase subunit of the DNA gyrase. Interestingly, very low-level expression of 55.2, which is non-lethal to wild type E. coli, prevents the growth of a deletion mutant of the topoisomerase I (topA) gene. In vitro, gp55.2 binds DNA and blocks specifically the relaxation of negatively supercoiled DNA by topoisomerase I. In vivo, expression of gp55.2 at low non-toxic levels alters the steady state DNA supercoiling of a reporter plasmid. Although 55.2 is not an essential gene, competition experiments indicate that it is required for optimal phage growth. We propose that the role of gp55.2 is to subtly modulate host topoisomerase I activity during infection to insure optimal T4 phage yield.     

Genetic complementation by cloned bacteriophage T4 late genes.

Bacteriophage T4 containing nonsense mutations in late genes was found to be genetically complemented by four conjugate T4 genes (7, 11, 23, or 24) located on plasmid or phage vectors. Complementation was at a very low level unless the infecting phage carried a denB mutation (which abolishes T4 DNA endonuclease IV activity). In most experiments, the infecting phage also had a denA mutation, which abolishes T4 DNA endonuclease II activity. Mutations in the alc/unf gene (which allow dCMP-containing T4 late genes to be expressed) further increased complementation efficiency. Most of the alc/unf mutant phage strains used for these experiments were constructed to incorporate a gene 56 mutation, which blocks dCTP breakdown and allows replication to generate dCMP-containing T4 DNA. Effects of the alc/unf:56 mutant combination on complementation efficiency varied among the different T4 late genes. Despite regions of homology, ranging from 2 to 14 kilobase pairs, between cloned T4 genes and infecting genomes, the rate of formation of recombinants after T4 den:alc phage infection was generally low (higher for two mutants in gene 23, lower for mutants in gene 7 and 11). More significantly, when gene 23 complementation had to be preceded by recombination, the complementation efficiency was drastically reduced. We conclude that high complementation efficiency of cloned T4 late genes need not depend on prior complete breakage-reunion events which transpose those genes from the resident plasmid to a late promoter on the infecting T4 genome. The presence of the intact gene 23 on plasmids reduced the yield of T4 phage. The magnitude of this negative complementation effect varied in different plasmids; in the extreme case (plasmid pLA3), an almost 10-fold reduction of yield was observed. The cells can thus be said to have been made partly nonpermissive for this lytic virus by incorporating a part of the viral genome.     

New Late Gene, dar, Involved in DNA Replication of Bacteriophage T4 I. Isolation, Characterization, and Genetic Location

Suppressors of gene 59-defective mutants were isolated by screening spontaneous, temperature-sensitive (ts) revertants of the amber mutant, amC5, in gene 59. Six ts revertants were isolated. No gene 59-defective ts recombinant was obtained by crossing each ts revertant with the wild type, T4D. However, suppressors of gene 59-defective mutants were obtained from two of these ts revertants. These suppressor mutants are referred to as dar (DNA arrested restoration). dar mutants specifically restored the abnormalities, both in DNA synthesis and burst size, caused by gene 59-defective mutants to normal levels. It is unlikely that dar mutants are nonsense suppressors since theý failed to suppress amber mutations in 11 other genes investigated. The genetic expression of dar is controlled by gene 55; therefore, dar is a late gene. The genetic location of dar has been mapped between genes 24 and 25, a region contiguous to late genes. dar appears to be another nonessential gene of T4 since burst sizes of dar were almost identical to those of the wild type. Mutations in dar did not affect genetic recombination and repair of UV-damaged DNA, but caused a sensitivity to hydroxyurea in progeny formation. The effect of the dar mutation on host DNA degradation cannot account for its hydroxyurea sensitivity. dar mutant alleles were recessive to the wild-type allele as judged by restoration of arrested DNA synthesis. The possible mechanisms for the suppression of defects in gene 59 are discussed.     

Purification and some of the functions of the products of bacteriophage T4 recombination genes, uvsX and uvsY

The nonessential T4 genes uvsX and uvsY are involved in DNA repair and general recombination. Using newly isolated amber mutants of these genes, we have identified the gene products (gp) by sodium dodecyl sulfate (SDS)/polyacrylamide gel electrophoresis. Their relative molecular masses are 39 000 and 16 000, respectively. In the normal wild-type infection process they are produced early but not late in infection. Their synthesis continues for a longer period when DNA synthesis is blocked. We have developed procedures to isolate these gene products at a purity of more than 95% for gpuvsX and at 70% for gpuvsY, as judged by SDS/polyacrylamide gel electrophoresis and staining with Coomassie brilliant blue dye. The purification procedures suggest that these products may be membrane proteins. Using both an agarose gel assay and electron microscopy, we find that the product of the gene uvsX catalyzes the assimilation of a linear single-stranded fd DNA fragment into superhelical double-stranded fd DNA (RFI). The reaction requires ATP and Mg2+ besides substrate DNAs and uvsX protein. The T4 uvsX protein therefore is similar to the Escherichia coli recA protein in molecular size and function, but differs in antigenic property.     

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.     

Efficiency and Frequency of Translational Coupling between the Bacteriophage T4 Clamp Loader Genes

The bacteriophage T4 DNA polymerase holoenzyme is composed of the core polymerase, gene product 43 (gp43), in association with the “sliding clamp” of the T4 system, gp45. Sliding clamps are the processivity factors of DNA replication systems. The T4 sliding clamp comes to encircle DNA via the “clamp loader” activity inherent in two other T4 proteins: 44 and 62. These proteins assemble into a pentameric complex with a precise 4:1 stoichiometry of proteins 44 and 62. Previous work established that T4 genes 44 and 62, which are directly adjacent on polycistronic mRNA molecules, are—to some degree—translationally coupled. In the present study, measurement of the levels (monomers/cell) of the clamp loader subunits during the course of various T4 infections in different host cell backgrounds was accomplished by quantitative immunoblotting. The efficiency of translational coupling was obtained by determining the in vivo levels of gp62 that were synthesized when its translation was either coupled to or uncoupled from the upstream translation of gene 44. Levels of gp44 were also measured to determine the relative stoichiometry of synthesis and the percentage of gp44 translation that was transmitted across the intercistronic junction (coupling frequency). The results indicated a coupling efficiency of ~85% and a coupling frequency of ~25% between the 44-62 gene pair during the course of infection. Thus, translational coupling is the major factor in maintaining the 4:1 stoichiometry of synthesis of the clamp loader subunits. However, coupling does not appear to be an absolute requirement for the synthesis of gp62.     

Deoxycytidylate hydroxymethylase gene of bacteriophage T4. Nucleotide sequence determination and over-expression of the gene

We describe two approaches to cloning and over-expressing gene 42 of bacteriophage T4, which encodes the early enzyme deoxycytidylate hydroxymethylase. In Bochum a library of sonicated fragments of wild-type phage DNA cloned into M13mp18 was screened with clones known to contain parts of gene 42. Two overlapping fragments, each of which contained one end of the gene, were cleaved at a HincII site and joined, to give a fragment containing the entire gene. In Corvallis a 1.8-kb fragment of cytosine-substituted DNA, believed to contain the entire gene, was cloned into pUC18 and shown to express the enzyme at low level. The cloned fragment bore an amber mutation in gene 42. From the DNA sequence of gene 42, the cloned gene was converted to the wild-type allele by site-directed mutagenesis. Both gene-42-containing fragments were cloned into the pT7 expression system and found to be substantially overexpressed. dCMP hydroxymethylase purified from one of the over-expressing strains had a turnover number similar to that of the enzyme isolated earlier from infected cells. In addition, the N-terminal 20 amino acid residues matched precisely the sequence predicted from the gene sequence. The amino acid sequence of gp42 bears considerable homology with that of thymidylate synthase of either host or T4 origin. The gene 42 nucleotide sequences of bacteriophages T2 and T6 were determined and found to code for amino acid sequences nearly identical to that of T4 gp42.     

A phage-encoded nucleoid associated protein compacts both host and phage DNA and derepresses H-NS silencing

Nucleoid Associated Proteins (NAPs) organize the bacterial chromosome within the nucleoid. The interaction of the NAP H-NS with DNA also represses specific host and xenogeneic genes. Previously, we showed that the bacteriophage T4 early protein MotB binds to DNA, co-purifies with H-NS/DNA, and improves phage fitness. Here we demonstrate using atomic force microscopy that MotB compacts the DNA with multiple MotB proteins at the center of the complex. These complexes differ from those observed with H-NS and other NAPs, but resemble those formed by the NAP-like proteins CbpA/Dps and yeast condensin. Fluorescent microscopy indicates that expression of motB in vivo, at levels like that during T4 infection, yields a significantly compacted nucleoid containing MotB and H-NS. motB overexpression dysregulates hundreds of host genes; ∼70% are within the hns regulon. In infected cells overexpressing motB, 33 T4 late genes are expressed early, and the T4 early gene repEB, involved in replication initiation, is up ∼5-fold. We postulate that MotB represents a phage-encoded NAP that aids infection in a previously unrecognized way. We speculate that MotB-induced compaction may generate more room for T4 replication/assembly and/or leads to beneficial global changes in host gene expression, including derepression of much of the hns regulon.