Bacteriophage-induced functions in Escherichia coli K (lambda) infected with rII mutants of bacteriophage T4

Rutberg, Blanka (Karolinska Institutet, Stockholm, Sweden), and Lars Rutberg. Bacteriophage-induced functions in Escherichia coli K(lambda) infected with rII mutants of bacteriophage T4. J. Bacteriol. 91:76-80. 1966.-When Escherichia coli K(lambda) was infected with rII mutants of phage T4, deoxycytidine triphosphatase, one of the phage-induced early enzymes, was produced at initially the same rate as in r(+)-infected cells. Deoxyribonuclease activity was one-third to one-half of that of r(+)-infected cells. This lower deoxyribonuclease activity was observed also in other hosts or when infection was made with rI or rIII mutants. Presence of chloramphenicol did not allow a continued synthesis of phage deoxyribonucleic acid in rII-infected K(lambda). No phage lysozyme was detected nor was any antiphage serum-blocking antigen found in rII-infected K(lambda). It is suggested that the rII gene is of significance for the expression of phage-induced late functions in the host K(lambda).     

Properties of Bacteriophage T4 Mutants Defective in Gene 30 (Deoxyribonucleic Acid Ligase) and the rII Gene

In Escherichia coli K-12 strains infected with phage T4 which is defective in gene 30 [deoxyribonucleic acid (DNA) ligase] and in the rII gene (product unknown), near normal levels of DNA and viable phage were produced. Growth of such T4 ligase-rII double mutants was less efficient in E. coli B strains which show the "rapidlysis" phenotype of rII mutations. In pulse-chase experiments coupled with temperature shifts and with inhibition of DNA synthesis, it was observed that DNA synthesized by gene 30-defective phage is more susceptible to breakdown in vivo when the phage is carrying a wild-type rII gene. Breakdown was delayed or inhibited by continued DNA synthesis. Mutations of the rII gene decreased but did not completely abolish the breakdown. T4 ligase-rII double mutants had normal sensitivity to ultraviolet irradiation.     

Analysis of expression of the rII gene function of bacteriophage T4.

Temperature-sensitive (ts) mutants of the T4 phage rII gene were islated and used in temperature shift experiments that revelaed two different expressions for the normal rII (rII+) gene function in vivo: (i) an early expression (0 to 12 min postinfection at 30 C) that prevents restriction of T4 growth in Escherichia coli hosts lysogenic for gamma phage, and (ii) a later expression (12 to 18 min postinfection at 30 C) that results in restriction of T4 growth when the phage DNA ligase (gene 30) is missing. The earlier expression appeared to coincide with the period of synthesis of the protein product of the T4 rIIA cistron, whereas the later expression occurred after rIIA protein synthesis had stopped. The synthesis of the protein product of the rIIB cistron continues for several minutes after rIIA protein synthesis ceases (O'Farrell and Gold, 1973). The two rII+ gene expressions might require different molar ratios of the rIIA and rIIB proteins. It is possible that the separate expressions of rII+ gene function are manifestations of different associations between the two rII proteins and other T4-induced proteins that are synthesized or activated at different times after phage infection.     

Initiation of Bacillus subtilis Ribonucleic Acid Polymerase on Deoxyribonucleic Acid from Bacteriophages 2C, φ29, T4, and Lambda

Ribonucleic acid (RNA) synthesis primed by bacteriophage T4 or lambda deoxyribonucleic acid (DNA) with Bacillus subtilis RNA polymerase is severely inhibited by high ionic strength. In contrast, RNA synthesis on B. subtilis bacteriophage 2C, SPO1, or phi29 DNA is only moderately affected under similar conditions. The basis of this inhibition lies in the inability of the enzyme to initiate RNA chains with adenosine triphosphate or guanosine triphosphate (ATP, GTP). Binding to templates and the rate of catalysis in high salt after initiation do not seem to be affected. Incorporation of gamma-(32)P-ATP and GTP under a variety of conditions suggests that the specificity of B. subtilis RNA polymerase is different from that of the Escherichia coli enzyme and that it recognizes few promoters on T4 and lambda DNA. Although B. subtilis RNA polymerase initiates RNA chains primarily with ATP or GTP, initiations with pyrimidines can occur on DNA molecules in which hydroxymethyluracil replaces thymine. RNA synthesis on denatured DNA does not seem to be inhibited by high ionic strength, and on native T4 or lambda DNA the inhibition of initiation at constant ionic strength is inversely but not linearly proportional to the ionic radii of cations used to stabilize bihelical DNA to denaturation.     

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.     

Replication of T4rII Bacteriophage in Escherichia coli K-12 (λ)

The defect of T4rII replication in Escherichia coli K-12 (lambda) can be phenotypically reversed by various supplements to the growth medium. Arginine, lysine, spermidine, and a number of diamines allowed varying levels of rII replication. The best reversion was obtained with 0.4 m sucrose in 0.002 to 0.005 m Ca(++). Monovalent cations severely inhibited reversion. A cell surface site of polyamine action is consistent with the fact that spermidine inhibits phage ghost-induced cell lysis and with the finding that sufficient polyamine is available within the cells to allow normal patterns of neutralization of phage deoxyribonucleic acid, as detected by the polyamine content of progeny phage. In the absence of effective supplements, rII-infected cells swelled and lost refractility. The data indicate that a leaky cell envelop is involved. No difference in mucopeptides of uninfected K-12 (lambda) and K-12 was detected and, because the mucopeptide in r(+) infected cells was found to be at least partially hydrolyzed midway through the lytic cycle, it did not appear that the rII defect concerned mucopeptide synthesis. The pattern of cell phospholipid synthesis changes after phage infection, but no difference was detected between r(+) and rII with regard to biosynthesis of phosphatidylethanolamine and phosphatidylglycerol.     

A mutation of the wobble nucleotide of a bacteriophage T4 transfer RNA.

Wild-type bacteriophage T7 is not subject to restriction by the Escherichia coli B and K restriction systems, but T7 mutants that are susceptible to such restriction have been isolated. These mutants are all defective in gene 0.3, the first T7 gene to be expressed after infection. The gene 0.3 protein apparently acts to prevent modification as well as restriction, suggesting that it may interact with a component of the host restriction-modification system that is required for both processes. Mutants in which gene 0.3 is completely deleted are only partially modified by growth on hosts with an active restriction-modification system, presumably because the conditions of T7 infection overload the modifying capacity of the cells. This is in contrast to phages such as lambda that are completely modified during growth. Since gene 0.3 is not essential for growth in non-restricting hosts, it has been possible to isolate deletions which extend to the left of gene 0.3 into the region where E. coli RNA polymerase initiates the synthesis of T7 early RNA. Two of the three strong initiators from which E. coli RNA polymerase transcribes the early region can be deleted.In the course of searching for T7 mutants that are unable to overcome restriction, it was discovered that mutants defective in gene 2 are able to plate on E. coli C with essentially normal efficiency, and most gene 7 mutants are able to plate on both C and K strains. It has not been determined why genes 2 and 7 seem to be needed for growth in some E. coli strains but not in others.