Properties of Bacteriophage T4 Baseplate Protein Encoded by Gene 8

Gene product 8 (gp8, 344 amino acids per monomer) of bacteriophage T4 is one of the baseplate structural proteins. We constructed an expression vector of gp8 and developed a method for purification of recombinant protein. CD spectroscopy showed that gp8 is an / type structural protein. Its polypeptide chain consists of nearly 40% -structure and 15% -helix. These data agree with results of prediction of secondary structure based on the amino acid sequence of the protein. The sedimentation coefficient under standard conditions (S_20,w) is 4.6S. Analytical ultracentrifugation results demonstrated that gp8 in solution has two types of oligomers—dimer and tetramer. The tetramer of gp8 may be included in the wedge (1/6 of the baseplate), and the dimer may be an intermediate product of association.     

Degradation of Escherichia coli Chromosome After Infection by Bacteriophage T4: Role of Bacteriophage Gene D2a

Mutations in the D2a gene of bacteriophage T4 have recently been shown to result in the stabilization of cytosine-containing phage deoxyribonucleic acid (DNA) made after infection by phage gene 56 (deoxycytidine triphosphatase) mutants. In the experiments reported here, we investigate the role of the D2a gene in the degradation of the host chromosome. We find that if T4 endonuclease II, a product of the phage gene denA, is active, host chromosome degradation appears normal, regardless of the presence of the D2a gene product. However, if T4 endonuclease II is absent, a small amount of host chromosome degradation occurs, but only if the D2a product is present. These results are interpreted in terms of the hypothesis that D2a controls a nuclease which degrades cytosine-containing DNA. Neither D2a nor denA mutations affect the shut-off of host DNA synthesis.     

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.     

Involvement of Gene 49 in Recombination of Bacteriophage T4

The role of T4 gene 49 in recombination was investigated using its conditional-lethal amber (am) and temperature-sensitive (ts) mutants. When measured in genetic tests, defects in gene 49 produced a recombination-deficient phenotype. However, DNA synthesized in cells infected with a ts mutant (tsC9) at a nonpermissive temperature appeared to be in a recombinogenic state: after restitution of gene function by shifting to a permissive temperature, the recombinant frequency among progeny increased rapidly even when DNA replication was blocked by an inhibitor. Growth of a gene 49-defective mutant was suppressed by an additional mutation in gene uvsX, but recombination between rII markers was not.     

Role of Gene 46 in Bacteriophage T4 Deoxyribonucleic Acid Synthesis

In an attempt to establish whether Escherichia coli B infected with N130 (an amber mutant defective in gene 46) is recombination-deficient, the postinfection fate of (14)C-labeled N130 parental deoxyribonucleic acid (DNA) was followed, its amount in complex with the host cell membrane being determined in sucrose gradients after mild lysis of the infected cells. The parental DNA was found to undergo gradual detachment from the membrane during infection. Pulse-chase experiments similarly showed that newly synthesized DNA is normally attached to the host cell membrane and is detached by endonucleolytic breakage at a late stage of infection. The conclusion is that only attached DNA molecules are replicated by membrane-bound replicase, whereas those detached by endonucleolytic breakage are not. It thus seems that the gene 46 product controls the activity of a nuclease whose main function is recombination of DNA nicked by endonuclease, thereby attaching it to the host cell membrane. The rate of T4 DNA synthesis is apparently governed by the efficiency of recombination. Supporting evidence was found in experiments with the double mutant N130 x N134 (genes 46, 33).     

Immediate-Early Expression of the Gene Causing Superinfection Breakdown in Bacteriophage T4B

Superinfection breakdown appears to belong to the "immediate-early" functions induced by T4 phage.     

Mutator Mutations in Bacteriophage T4 Gene 42 (Dhmc Hydroxymethylase)

Temperature-sensitive mutations of bacteriophage T4 gene 42 produce diverse effects upon spontaneous mutation rates. G:C → A:T transition rates are increased, often strongly; frameshift mutation rates are weakly increased; A:T → G:C transition rates (and perhaps also A:T → Py:Pu transversion rates) are decreased; and one G:C → Py:Pu transversion rate is also decreased. These results, together with certain interactions between gene-42 mutator effects and both base analogue mutagenesis and the viral error-prone repair system, suggest that the dHMC hydroxymethylase coded by gene 42 affects mutation rates in a more complex manner than by the simple regulation of the concentration of the DNA precursor dHMCTP.     

Suppressors of Mutations in the rII Gene of Bacteriophage T4 Affect Promoter Utilization

Homyk, Rodriguez and Weil (1976) have described T4 mutants, called sip, that partially suppress the inability of T4rII mutants to grow in λ lysogens. We have found that mutants sip1 and sip2 are resistant to folate analogs and overproduce FH₂ reductase. The results of recombination and complementation studies indicate that sip mutations are in the mot gene. Like other mot mutations (Mattson, Richardson and Goodin 1974; Chace and Hall 1975; Sauerbier, Hercules and Hall 1976), the sip2 mutation affects the expression of many genes and appears to affect promoter utilization. The mot gene function is not required for T4 growth on most hosts, but we have found that it is required for good growth on E. coli CTr5X. Homyk, Rodriguez and Weil (1976) also described L mutations that reverse the effects of sip mutations. L₂ decreases the folate analog resistance and the inability of sip2 to grow on CTr5X. L₂ itself is partially resistant to a folate analog, and appears to reverse the effects of sip2 on gene expression. These results suggest that L₂ affects another regulatory gene related to the mot gene.     

Control of Early Gene Expression of Bacteriophage T4: Involvement of the Host rho Factor and the mot Gene of the Bacteriophage

Many early mRNA species of bacteriophage T4 are not synthesized after infection of Escherichia coli in the presence of chloramphenicol. This has been interpreted as a need for T4 protein(s) to be synthesized to allow expression of some early genes, e.g., those for deoxycytidinetriphosphatase, deoxynucleosidemonophosphate kinase and UDP-glucose-DNA beta-glucosyltransferase. In the experiments described here, early mRNA of bacteriophage T4 was allowed to accumulate during chloramphenicol treatment. After the addition of rifampin to inhibit further RNA synthesis, and subsequent removal of chloramphenicol, the accumulated mRNA was permitted to express itself into measured enzyme activities. It was shown that the early mRNA species coding for deoxycytidinetriphosphatase and UDP-glucose-DNA beta-glucosyltransferase could be formed in the presence of chloramphenicol if the E. coli host cell carried a mutation in the structural gene for the RNA chain termination factor rho. This was interpreted to mean that T4 protein(s) with anti-rho activity is normally required for the expression of these two early genes. An altered rho-factor could not, however, relieve the need of phage protein synthesis for the formation of another early mRNA, that coding for deoxynucleosidemonophosphate kinase. In this case the mot gene of T4 seemed to be involved, since the primary infection of E. coli cells with the mot gene mutant tsG1 did not allow subsequent deoxynucleoside monophosphate kinase mRNA synthesis after wild-type phage infection in the presence of chloramphenicol. In control experiments, deoxynucleoside monophosphate kinase mRNA synthesis induced by wild-type phage superinfecting in the presence of chloramphenicol was facilitated by the primary infection with T4 phage containing an unmutated mot gene.     

Revised Location of the rIII Gene on the Genetic Map of Bacteriophage T4

Two- and three-factor crosses showed that the T4 rIII gene is located between genes 31 and 30 rather than between genes 31 and 63.     

ESCHERICHIA COLI Rho Factor Is Involved in Lysis of Bacteriophage T4-Infected Cells

A Rid (Rho interaction deficient) phenotype of bacteriophage T4 mutants was defined by cold-sensitive restriction (lack of plaque formation) on rho+ hosts carrying additional polar mutations in unrelated genes, coupled to suppression (plaque formation) in otherwise isogenic strains carrying either a polarity-suppressing rho or a multicopy plasmid expressing the rho+ allele. This suggests that the restriction may be due to lower levels of Rho than what is available to T4 in the suppressing strains.--Rid394 X 4 was isolated upon hydroxylamine mutagenesis and mapped in the t gene; other t mutants (and mot, as well as dda dexA double mutants) also showed a Rid phenotype. In liquid culture in strains that restricted plaque formation Rid394 X 4 showed strong lysis inhibition (a known t- phenotype) but no prolonged phage production (another well-known t- phenotype). This implies that when Rho is limiting the t mutant shuts off phage production at the normal time. Lysis inhibition was partially relieved, and phage production prolonged to varying extents depending on growth conditions in strains that allowed plaque formation. No significant effect on early gene expression were found. Apparently, both mutant (polarity-suppressing) and wild-type Rho can function in prolonging phage production and partially relieving lysis inhibition of Rid394 X 4 when present at a sufficiently high level, and Rho may play other role(s) in T4 development than in early gene regulation.