Phospholipase activity in bacteriophage-infected Escherichia coli. III. Phopholipase A involvement in lysis of T4-infected cells.

Bacteriophage studies with Escherichia coli K-12 (gamma)DR-DS-, a mutant lacking the major known fatty acyl hydrolases (phospholipases), and its wild-type parent showed equivalent phage infection with regard to phage production and time of phage release. Further examination of the DR-DS- mutant, however, revealed that the progeny bacteriophage were released without complete dissolution of the host cell. Prolonged cell integrity of the infected mutant was noted by spectrophotometry and supported by direct microscope examination. The phage release occurred at normal "lysis" time with phage yields comparable to that of the wild-type bacteria. Inner membrane degradation was indicated by the release of beta-galactosidase, a cytoplasmic enzyme, and of trichloracetic acid-precipitable RNA. Thus, outer membrane degradation is required for dissolution of phage-infected cells, and this degradation is at least partly dependent on activation of host phospholipases.     

Phospholipase Activity in Bacteriophage-Infected Escherichia coli I. Demonstration of a T4 Bacteriophage-Associated phospholipase

Phospholipase activity has been found to be associated with T4 phage and T4 ghost particles. The attachment of the phospholipase to the phage persists during purification through cesium chloride gradients and dialysis, indicating that it is firmly bound. The presence of the enzymatic activity on T4 ghosts suggests that it is not normally packaged within the head of the virus. The enzyme has specificity for phosphatidylglycerol and its activity is stimulated by 0.1% Triton X-100 and 20% methanol. It does not have a requirement for Ca²⁺ and is inactivated at temperatures above 60 C. The association of the phospholipase with T4 phage grown in a phospholipase-deficient host and its absence on unsuppressed T4amtA3 suggests that it may be phage gene specific.     

Zinc uptake and incorporation into proteins in T4D bacteriophage-infected Escherichia coli.

The metabolism of Zn2+ in Escherichia coli infected with T4D bacteriophage and various T4D mutants has been examined. E. coli B infected with T4D, and all T4D mutants except T4D 12-, took up zinc ions at a rate identical to that of uninfected cells. E. coli B infected with T4D 12- had a markedly decreased rate of zinc uptake. The incorporation of zinc into proteins of infected cells has also been studied. T4D phage infection was found to shut off the synthesis of all bacterial host zinc metalloproteins while allowing the formation of viral-induced zinc proteins. The amount of zinc incorporated into viral proteins was affected by the absence of various T4D gene products. Cells infected with T4D 12-, and to a much less extent those infected with T4D 29-, incorporated the least amount of zinc into proteins, while cells infected with T4D 11- and T4D 51- incorporated increased amounts of zinc into the zinc metalloproteins. In cells infected with T4D 11- and 51- most of the zinc protein was found to be the product of gene 12. The marked effect of infection of E. coli with T4D 12- on both zinc uptake and zinc incorporation into protein supports the conclusion that T4D gene 12 protein is a zinc metalloprotein. Additionally, these observations have indicated that this metalloprotein interacts with host cell membrane.     

Absence of phospholipase activity in bacteriophage T4.

We assayed phospholipase activity in T4Dt+ and in t mutant phage grown under permissive and restrictive conditions. There was no correlation between the presence of the t+ gene product and phospholipase activity. Phospholipase activity in phage lysates could be attributed to the presence of bacterial debris or to the use of commercial DNase which contains phospholipase.     

Early events after infection of Escherichia coli by bacteriophage T5. II. Control of the bacteriophage-induced 5'-nucleotidase activity.

The control of activity of the bacteriophage T5-induced 5'-nucleotidase is dependent upon the amount of T5 parental DNA injected into the cell and expressed. When only the first-step transfer DNA is injected and expressed the amount of 5'-nucleotidase activity observed is two to three times the maximum amount observed after normal T5 infection, and inactivation of the enzyme does not occur. Enzyme inactivation occurs only after the remaining DNA is injected, but only limited expression of this DNA is required. The control of the nucleotidase inactivation process is similar to that for the repair of the nicks in parental DNA, and is probably mediated by a class IIa protein.     

Postinfection control by bacteriophage T4 of Escherichia coli recBC nuclease activity.

Infection by bacteriophage T4 has previously been shown to cause a rapid inhibition of the host recBC DNase, an ATP-dependent DNase that is required for genetic recombination in Escherichia coli. We report here the partial purification of a protein ("T4 rec inhibitor") from extracts of T4-infected cells and some characteristics of the in vitro inhibition reaction with purified inhibitor and recBC nuclease. This inhibitory activity could not be purified from extracts of uninfected E. coli. Both the ATP-dependent exonuclease and DNA-dependent ATPase activities of recBC DNase are inhibited by T4 rec inhibitor. Experiments suggest that the inhibitor interacts with the nuclease in a stoichiometric manner. The biological significance of this inhibition is discussed with respect to control reactions in phage-infected cells.     

DNA injection during bacteriophage T4 infection of Escherichia coli.

The process of phage T4 DNA injection into the host cell was studied under a fluorescent microscope, using 4',6-diamidino-2-phenylindole as a DNA-specific fluorochrome. The phage DNA injection was observed when spheroplasts were infected with the artificially contracted phage particles having a protruding core. The DNA injection was mediated by the interaction of the core tip with the cytoplasmic membrane of the spheroplast. A membrane potential was not required for the process of DNA injection. On the other hand, DNA injection upon infection by intact noncontracted phage of the intact host cell was inhibited by an energy poison. Based on these observations, together with results from previous work, a model for the T4 infection process is presented, and the role of the membrane potential in the infection process is discussed.     

Stimulation of cell division by T4 infection in Escherichia coli dnaEts at nonpermissive temperature.

Summary Filamentous cells resulting from growth of a dnaEts mutant of Escherichia coli at high temperature were stimulated to divide by infection with bacteriophage T4. This effect appears to be related to T4 DNA synthesis; no increase in cell number took place in chloramphenicol-treated, T4-infected cells nor in cells infected with DNA synthesis-less mutants of T4. The ability of cells to divide after T4 infection was dependent on the length of time that the cells had been grown at 42°C, indicating that a potential for cell division accumulates during preincubation.     

Bacterial ice nucleation activity after T4 bacteriophage infection.

The changes in ice nucleation activity of transformed Ina+ Escherichia coli K12 after infection with T4D bacteriophage have been examined. Within 2 min after infection class A nucleation activity (measured at -4 degrees C) fell about 100-1000-fold whilst class B (measured at -5.5 degrees C) and class C (measured at -9 degrees C) nucleation activities increased 50-100-fold and then rapidly decreased. These changes also occurred after interaction with T4D ghost particles or T4D 11-/12- particles. Since ghost particles lack DNA and 11-/12- particles lack short tail fibres, the T4D particles appear to be exerting their effect by the attachment of the phage long tail fibres to the cell. The changes were not influenced by the addition of chloramphenicol.     

Biological activity of T4 DNA synthesized in toluene-treated Escherichia coli cells.

T4 DNA synthesized in a toluene-treated cell system can act as the genetic donor in a DNA transformation assay. This material transforms a variety of markers at high efficiency. We present evidence that the genetic activity is due to newly synthesized, double-stranded DNA.     

Bacteriophage T4 Inhibits Colicin E2-Induced Degradation of Escherichia coli Deoxyribonucleic Acid II. Inhibition by T4 Ghosts and by T4 in the Absence of Protein Synthesis

The deoxyribonucleic acid (DNA) of Escherichia coli B is converted by colicin E2 to products soluble in cold trichloroacetic acid; we showed previously that this DNA degradation (hereafter termed solubilization) is subject to inhibition by infection with phage T4 and that at least two modes of inhibition can be differentiated on the basis of their sensitivity to chloramphenicol (CM). This report deals exclusively with the inhibition of E2 produced by T4, or T4 ghosts, in the absence of protein synthesis. The following observations are described. (i) The stage of T4 infection that inhibits E2 occurs after reversible adsorption of the phage to the bacterial surface, but probably prior to injection of T4 DNA into the cell's interior. (ii) The extent of inhibition increases as the T4 multiplicity is increased; however, the fraction of bacterial DNA that eventually is solubilized is virtually independent of the phage multiplicity. (iii) Phage ghosts (DNA-less phage particles) possess an approximately 15-fold greater inhibitory capacity toward E2 than do intact phage; however, because highly purified T4 (completely freed of ghost contamination) still inhibit E2, we discount the possibility that preparations of "intact phage" inhibit exclusively by virtue of contaminating ghosts. (iv) T4 infection does not liberate an extracellular inactivator of E2. In fact, infection with sufficiently high multiplicities of T4 produces a supernatant factor that protects E2 from nonspecific inactivation at 37 C. This protective factor does not interfere with the colicin's ability to induce DNA solubilization. (v) Inhibition of E2 occurs even when phage are added well after initiation of DNA solubilization by E2, suggesting that a late stage of E2 action is the target of inhibition by T4 infection. (vi) Increasing the CM concentration from 50 mug/ml to 200 mug/ml appears to reduce the inhibition appreciably; however, this can be attributed to an enhancement by CM of the rate of E2-induced DNA solubilization. (vii) The same degree of inhibition of E2 by T4 seen in CM is observed when CM is replaced by puromycin or rifampin. (viii) Others have shown that raising the multiplicity of E2 increases the rate of DNA solubilization. We find that the fractional inhibition (i), [i = (1 - y(i)/y(o)), where y(i) and y(o) represent the inhibited and uninhibited rates of solubilization of DNA, respectively], produced by a given T4 multiplicity is independent of the multiplicity of E2 and hence is independent of the rate of DNA solubilization induced by E2.