T-related Bacteriophages Isolated from Shigella sonnei

The properties of three T-related phages-35, 55, and 3201-isolated from Shigella sonnei were studied. They were similar with respect to morphology of plaques, duration of the latent periods, lysis inhibition effect, and serological characteristics. These phages closely resembled the T-even phages. Phages 3201, 35, and 55 had the same host range and receptor specificity as phage T2.     

Lysis and lysis inhibition in bacteriophage T4: rV mutations reside in the holin t gene.

Upon infecting populations of susceptible host cells, T-even bacteriophages maximize their yield by switching from lysis at about 25 to 35 min at 37 degrees C after infection by a single phage particle to long-delayed lysis (lysis inhibition) under conditions of sequential infection occurring when free phages outnumber host cells. The timing of lysis depends upon gene t and upon one or more rapid-lysis (r) genes whose inactivation prevents lysis inhibition. t encodes a holin that mediates the movement of the T4 endolysin though the inner cell membrane to its target, the cell wall. The rI protein has been proposed to sense superinfection. Of the five reasonably well characterized r genes, only two, rI and rV, are clearly obligatory for lysis inhibition. We show here that rV mutations are alleles of t that probably render the t protein unable to respond to the lysis inhibition signal. The tr alleles cluster in the 5' third of t and produce a strong r phenotype, whereas conditional-lethal t alleles produce the classical t phenotype (inability to lyse) and other t alleles produce additional, still poorly understood phenotypes. tr mutations are dominant to t+, a result that suggests specific ways to probe T4 holin function.     

The first recognized epigenetic signal: DNA glucosylation of T-even bacteriophages.

Host-induced modification of phage T2 to T*2 was discovered in 1952. This phenomenon, a reversible alteration in viral host range resulting from a single growth cycle in certain bacterial hosts, is an ‘epigenetic’ change. In 1963 the chemical basis for the T* modification was shown to be the loss of DNA glucosylation, which resulted from T-even phage growth in cells lacking the glucosyl donor UDPG. Thus, DNA glucosylation of T-even phages was the first recognized epigenetic signal.     

Partial Exclusion between T-Even Bacteriophages; an Incipient Genetic Isolation Mechanism

Conditional lethal mutant systems developed in T-even bacteriophages T2, T4 and T6 have been used to study the partial exclusion which characterizes mixed infections of these phages. In bacteria mixedly infected with T2 and T4, the dominant phage (T4) acts against localized exclusion sensitivity determinants in the genome of the excluded phage (T2). These determinants are clustered near genes controlling early functions; the determinants themselves do not appear among the progeny, but markers located close to them appear infrequently, by recombination. The excluding action of T4 does not depend on the action of any gene so far identified by conditional lethal mutations, nor does it depend on differences in DNA glucosylation between infecting phages. Regardless of mechanism, the genetic consequence of this partial exclusion is to limit genetic exchange between T2 and T4 in the region of the genome controlling early functions, while retaining the capacity for extensive exchange in other regions; in short, partial exclusion constitutes a localized genetic isolating mechanism. Related forms of partial exclusion characterize mixed infections of other T-even phages, including those of some phages newly isolated from nature.     

Early Abortive Lysis by Phage BF23 in Escherichia coli K-12 Carrying the Colicin Ib Factor

Growth of phage BF23 was restricted in Escherichia coli K-12 strains carrying a colicin I factor (ColIb); most infected cells lysed early without producing progeny phages. Either addition of chloramphenicol before phage infection or ultraviolet irradiation of phage prevented early abortive lysis, an indication that certain phage functions are required for this phenomenon. Very little or no phage-induced lysozyme was synthesized in the infected ColI(+) cells. This result suggests that early abortive lysis was not due to the lysozyme action. A small fraction (0.05) of BF23-infected ColI(+) cells showed normal phage growth. This "escaped growth" may reflect the physiological state of the host bacteria rather than the heterogeneity of the infecting phage. Host-controlled modification was not observed. A phage mutant, BF23hI, able to grow on ColI(+) cells, was isolated and was characterized to be recessive to the wild-type BF23 in its ability to undergo early abortive lysis. Among the T series phages, T5 induced early abortive lysis, and growth of T5 was restricted upon infection to ColI(+) cells. These results and the other observations, including the occurrence of phenotypic mixing between BF23 and T5, suggest that these two phages are related to each other even though the receptor sites for BF23 and T5 are apparently different.     

Ambivalent bacteriophages of different species active on Escherichia coli K12 and Salmonella sps. strains

A study was made of several bacteriophages (including phages U2 and LB related to T-even phages of Escherichia coli) that grow both on E. coli K12 and on some Salmonella strains. Such phages were termed ambivalent. T-even ambivalent phages (U2 and LB) are rare and have a limited number of hosts among Salmonella strains. U2 and LB are similar to canonical E. coli-specific T-even phages in morphological type and size of the phage particle and in reaction with specific anti-T4 serum. Phages U2 and LB have identical sets of structural proteins, some of which are similar in size to structural proteins of phages T2 and T4. DNA restriction patterns of phages U2 and LB differ from each other and from those of T2 and T4. Still, DNAs of all four phages have considerable homology. Unexpectedly, phages U2 and LB grown on Salmonella bungori were unstable during centrifugation in a CsCl gradient. Ambivalent bacteriophages were found in species other than T-even phages and were similar in morphotype to lambdoid and other E. coli phages. One of the ambivalent phages was highly similar to well-known Felix01, which is specific for Salmonella. Ambivalent phages can be used to develop a new set for phage typing in Salmonella. An obvious advantage is that ambivalent phages can be reproduced in the E. coli K12 laboratory strain, which does not produce active temperate phages. Consequently, the resulting typing phage preparation is devoid of an admixture of temperate phages, which are common in Salmonella. The presence of temperate phages in phage-typing preparations may cause false-positive results in identifying specific Salmonella strains isolated from the environment or salmonellosis patients. Ambivalent phages are potentially useful for phage therapy and prevention of salmonellosis in humans and animals.     

Lysis of lysis-inhibited bacteriophage T4-infected cells.

T4 bacteriophage (phage)-infected cells show a marked increase in latent-period length, called lysis inhibition, upon adsorption of additional T4 phages (secondary adsorption). Lysis inhibition is a complex phenotype requiring the activity of at least six T4 genes. Two basic mysteries surround our understanding of the expression of lysis inhibition: (i) the mechanism of initiation (i.e., how secondary adsorption leads to the expression of lysis inhibition) and (ii) the mechanism of lysis (i.e., how this signal not to lyse is reversed). This study first covers the basic biology of the expression of lysis inhibition and lysis of T4-infected cells at high culture densities. Then evidence is presented which implies that, as with the initiation of lysis inhibition, sudden, lysis-associated clearing of these cultures is likely caused by T4 secondary adsorption. For example, such clearing is often observed for lysis-inhibited T4-infected cells grown in batch culture during T4 stock preparation. The significance of this secondary adsorption-induced lysis to wild T4 populations is discussed. The study concludes with a logical argument suggesting that the lytic nature of the T4 phage particle evolved as a novel mechanism of phage-induced lysis.     

Amino Acid Control over Deoxyribonucleic Acid Synthesis in Escherichia coli Infected With T-Even Bacteriophage

Starvation for a required amino acid of normal or RC(str)Escherichia coli infected with T-even phages arrests further synthesis of phage deoxyribonucleic acid (DNA). This amino acid control over phage DNA synthesis does not occur in RC(rel)E. coli mutants. Heat inactivation of a temperature-sensitive aminoacyl-transfer ribonucleic acid (RNA) synthetase similarly causes an arrest of phage DNA synthesis in infected cells of RC(str) phenotype but not in cells of RC(rel) phenotype. Inhibition of phage DNA synthesis in amino acid-starved RC(str) host cells can be reversed by addition of chloramphenicol to the culture. Thus, the general features of amino acid control over T-even phage DNA synthesis are entirely analogous to those known for amino acid control over net RNA synthesis of uninfected bacteria. This analogy shows that the bacterial rel locus controls a wider range of macromolecular syntheses than had been previously thought.     

T-Even Bacteriophage-Tolerant Mutants of Escherichia coli B II. Nucleic Acid Metabolism

T-even bacteriophage-tolerant mutants are strains of Escherichia coli which can adsorb T-even phages but cannot support the growth of infective virus. Under some conditions, the infected cells are not killed. Mutant cells infected by phage T6 are able to carry out several metabolic functions associated with normal virus development, including arrest of bacterial nucleic acid and protein synthesis, incorporation of isotopic precursors into viral nucleic acids and proteins, synthesis of early enzymes of deoxyribonucleic acid (DNA) metabolism, formation of rapidly sedimenting DNA intermediates, and formation of normal levels of early and late messenger ribonucleic acid species. Phage are unable to mutate to forms capable of growth on these mutants. The nature of the biochemical alteration leading to tolerance is still unknown.     

Functional interactions of the genomes of Shigella sonnei phages and Escherichia coli phage T4 in mixed infection]

A comparative study of Shigella sonnei phages U and G and Escherichia coli phage T4 has shown that enzymes coded for by the Sh. sonnei phages can functionally substitute for some T4-coded products. This finding in indicative of an evolutionary relationship between T-even phages and disenteric phages U and G. The U phage is uncapable to compensate amber mutants for the genes that control the conversion of cytosine into 5-hydroxymethyl cytosine (5-HMC) and the glucosylation of the latter, which agrees with our earlier finding that the U phage DNA contains no 5-HMC. U and G phages are also found to exclude the T4 phage in the course of mixed infection.     

Isolation of Escherichia coli bacteriophages from the stool of pediatric diarrhea patients in Bangladesh

A 3-week coliphage survey was conducted in stool samples from 140 Bangladeshi children hospitalized with severe diarrhea. On the Escherichia coli indicator strain K803, all but one phage isolate had 170-kb genomes and the morphology of T4 phage. In spot tests, the individual T4-like phages infected up to 27 out of 40 diarrhea-associated E. coli, representing 22 O serotypes and various virulence factors; only five of them were not infected by any of these new phages. A combination of diagnostic PCR based on g32 (DNA binding) and g23 (major capsid protein) and Southern hybridization revealed that half were T-even phages sensu strictu, while the other half were pseudo-T-even or even more distantly related T4-like phages that failed to cross-hybridize with T4 or between each other. Nineteen percent of the acute stool samples yielded T4-like phages, and the prevalence was lower in convalescent stool samples. T4-like phages were also isolated from environmental and sewage water, but with low frequency and low titers. On the enteropathogenic E. coli strain O127:K63, 14% of the patients yielded phage, all of which were members of the phage family Siphoviridae with 50-kb genomes, showing the morphology of Jersey- and beta-4 like phages and narrow lytic patterns on E. coli O serotypes. Three siphovirus types could be differentiated by lack of cross-hybridization. Only a few stool samples were positive on both indicator strains. Phages with closely related restriction patterns and, in the case of T4-like phages, identical g23 gene sequences were isolated from different patients, suggesting epidemiological links between the patients.     

Ambivalent bacteriophages of different species active on Escherichia coli K12 and Salmonella sp. strains

A study was made of several bacteriophages (including phages U2 and LB related to T-even phages of Escherichia coli) that grow both on E. coli K12 and on some Salmonella strains. Such phages were termed ambivalent. T-even ambivalent phages (U2 and LB) are rare and have a limited number of hosts among Salmonella strains. U2 and LB are similar to canonical E. coli-specific T-even phages in morphological type and size of the phage particle and in reaction with specific anti-T4 serum. Phages U2 and LB have identical sets of structural proteins, some of which are similar in size to structural proteins of phages T2 and T4. DNA restriction patterns of phages U2 and LB differ from each other and from those of T2 and T4. Still, DNAs of all four phages have considerable homology. Unexpectedly, phages U2 and LB grown on Salmonella bongori were unstable during centrifugation in a CsCl gradient. Ambivalent bacteriophages were found in species other than T-even phages and were similar in morphotype to lambdoid and other E. coli phages. One of the ambivalent phages was highly similar to well-known Felix01, which is specific for Salmonella. Ambivalent phages can be used to develop a new set for phage typing in Salmonella. An obvious advantage is that ambivalent phages can be reproduced in the E. coli K12 laboratory strain, which does not produce active temperature phages. Consequently, the resulting typing phage preparation is devoid of an admixture of temperate phages, which are common in Salmonella. The presence of temperate phages in phage-typing preparations may cause false-positive results in identifying specific Salmonella strains isolated from the environment or salmonellosis patients. Ambivalent phages are potentially useful for phage therapy and prevention of salmonellosis in humans and animals.     

Der Einfluß der Infektionsmultiplizität auf die Lysogenisierung im System Salmonella typhimurium — Phage P 22

Summary The increase of lysogenization in phage infected cells has been investigated with increasing multiplicities of infection in the system Salmonella thyphimurium-phage P 22. The increase of infection resp. lysis and lysogenization with multiplicity follows first order reaction kinetics as concluded from multiplicities<0.3. Under the experimental conditions employed, the probability per phage is 0.57 for lysogenization and 0.43 for lysis. If multiplicity is>0.3 and cells are infected with more than one phage, the lysogenizations increase according to one hit kinetics, whereas the lysis of cells decreases. It is concluded, that lytic reactions in multicomplexes, which can be initiated independently by every one of the infecting phage particles will be suppressed by lysogenic reactions initiated by other independently infecting phages of the complex. Our experiments suggest, that immunity of the prelysogenic condition is the process responsible for the suppression of the lytic reaction. Therefore, in multicomplexes the immunity induced by one of the infecting phages is superimposed upon the one hit lytic infection causing the percentage of lysogenization increasing with multiplicity.     

DNA sequence heterogeneity in the genes of T-even type Escherichia coli phages encoding the receptor recognizing protein of the long tail fibers

Summary Genes (g) 36 and 37 code for the proteins of the distal half of the long tail fibers of phage T4, gene product (gp) 35 links the distal half to the proximal half of this fiber. The receptor, lipopolysaccharide, most likely is recognized by gp37. Using as probe a restriction fragment consisting of most of g36 and g37 of phage T4 the genes corresponding to g35, g36, and g37 of phages T2 and K3 (using the E. coli outer membrane proteins OmpF and OmpA, respectively, as receptors) have been cloned into plasmid pUC8. Partial DNA sequences of g37 of phage K3 have been determined. One area, corresponding to residues 157 to 210 of the 1026 residue gp37 of phage T4, codes for an identical sequence in phage K3. Another area corresponds to residues 767 to 832 of the phage T4 sequence. Amino acid residues 767 to 832 of the phage T4 sequence are almost identical in both phage proteins while the remainder is rather different. DNAs of T2, T4, T6, another T-even type phage using protein Tsx as a receptor, and 10 different T-even type phages using the OmpA protein as a receptor have been hybridized with restriction fragments covering various parts of the g37 area of phage K3. With probably only one exception all of the 13 phages tested possess unique genes 37 and within the majority of these, sequences highly homologous to parts of g37 of K3 are present in a mosaic type fashion. Other regions of these genes 37 did not show any homology with the K3 probes; in case of the OmpA specific phage M1 absence of homology was evident in most of its g37 even including the area that should serve for recognition of the cellular receptor. In sharp contrast to this situation it was found that a major part of the gene (g23) coding for the major capsid protein is rather highly conserved in all phages studied. The extreme variability in sequences existing in genes 37 might be a consequence of phages during evolution being able to more or less drastically change their receptor specifities.     

Practical Procedures for the Purification of Bacterial Viruses

The efficiencies of the various methods used for phage concentration have been compared. The two-phase concentration method (with polyethylene glycol and dextran sulfate) gave maximal recoveries of infectivity for coliphages of the T-even and T-odd series and for ribonucleic acid phages and single-stranded deoxyribonucleic acid phages. Precipitation of phages by acid gave high yields when applied to T2 and T4 phages but not with T3 and T7 coliphages. Differential centrifugation was efficient when sedimented phages were gently dispersed before repeating the centrifugation cycle. The efficiencies of the various methods have also been confirmed by electron microscope studies, which also show that the two-phase concentration method gave rise to intact phages. Zone centrifugations in sucrose gradients (12.5 to 52.5%) indicated that coliphages of the T-even series sediment faster than T-odd coliphages; they may thus be separated from each other and from empty ghosts by centrifugation at 100,000 x g for 40 min. Equilibrium centrifugation in preformed cesium chloride gradients was also useful for phage concentration and purification. This study also deals with some optical properties of purified phages; optical cross sections and absorbance ratios (at 260 and 280 nm) of the various preparations are given.     

On the lack of host-cell reactivation of UV-irradiated phage T5. I. Interference of T5 infection with the host-cell reactivation of phage T1

UV-irradiated phage T5, in contrast to T1, T3 and T7, fail to display hostcell reactivation (HCR) when infecting excision-repair proficient Escherichia coli cells. Possible causes of this lack of HCR (which T5 shares with the T-even phages) have been investigated by studying HCR of T1 under conditions of superinfection by T5. Repair-proficient B/r cells were infected at low multiplicity with UV-irradiated phage T1 in the presence of 1.8 mg/ml caffeine and were superinfected after 15 min with heavily UV-irradiated T5 amber mutants at high multiplicity. The caffeine, which is later diluted out, prevents any T1 repair prior to T5 superinfection, and UV (254 nm) irradiation of T5 with 144 J/m² reduces the ability of this phage to exclude T1, thus permitting a reasonable fraction of the mixedly infected complexes to produce T1 progeny.Under these conditions, T5 superinfection causes loss of HCR in about 90% of the T1-producing complexes. Superinfection with unirradiated T5 likewise inhibits HCR of T1, but superinfection with irradiated T3 (a host-cell-reactivable phage) does not. This indicates that the observed HCR inhibition of T1 results from T5 infection rather than from competition of irradiated foreign DNA for the excision-repair enzymes of the bacterial host. Employment of apropriate T5 amber mutants has shown that “first-step transfer” (FST) of T5 DNA (involving only 8% of the T5 genome) is sufficient for HCR inhibition, but that transfer of the remainder DNA in addition inhibits a previously described minor T1 recovery process. HCR inhibition of T1, and thus presumably lack of HCR in T5 itself, is ascribed to a substance which is produced either post infection by a gene located in the FST segment of the T5 genome, or which is transferred from extracellular T5 together with the FST DNA.     

The bacteriophage T4 rapid-lysis genes and their mutational proclivities

Like most phages with double-stranded DNA, phage T4 exits the infected host cell by a lytic process requiring, at a minimum, an endolysin and a holin. Unlike most phages, T4 can sense superinfection (which signals the depletion of uninfected host cells) and responds by delaying lysis and achieving an order-of-magnitude increase in burst size using a mechanism called lysis inhibition (LIN). T4 r mutants, which are unable to conduct LIN, produce distinctly large, sharp-edged plaques. The discovery of r mutants was key to the foundations of molecular biology, in particular to discovering and characterizing genetic recombination in T4, to redefining the nature of the gene, and to exploring the mutation process at the nucleotide level of resolution. A number of r genes have been described in the past 7 decades with various degrees of clarity. Here we describe an extensive and perhaps saturating search for T4 r genes and relate the corresponding mutational spectra to the often imperfectly known physiologies of the proteins encoded by these genes. Focusing on r genes whose mutant phenotypes are largely independent of the host cell, the genes are rI (which seems to sense superinfection and signal the holin to delay lysis), rIII (of poorly defined function), rIV (same as sp and also of poorly defined function), and rV (same as t, the holin gene). We did not identify any mutations that might correspond to a putative rVI gene, and we did not focus on the famous rII genes because they appear to affect lysis only indirectly.     

On the lack of host-cell reactivation of UV-irradiated phage T5 II. Further characterization of the repair inhibition exerted by T5 infection

Experiments reported in the preceding paper [4] had shown that host-cell reactivation (HCR) of UV-irradiated phage T1 in excision-repair proficient Escherichia coli cells is inhibited by superinfection with phage T5. Theoretical considerations have led to predictions concerning the dependence of repair inhibition on the multiplicity of superinfecting T5 phage and on the UV fluence to which they were exposed. These predictions have been supported by experimental results described in this paper. The fluence dependence permitted calculation of the relative UV sensitivity of the gene function responsible for repair inhibition; it was found to be about 2.3% that of the plaque-forming ability of phage T5.The T5-inhibitable step in excision repair occurs early in the infective cycle of T1. Furthermore, experiments involving the presence of 400 μg/ml chloramphenicol showed that HCR inhibition of T1 is caused by a protein produced after the FST segment of T5 (i.e. the first 8% of the T5 genome) has entered the host cell. A previously described minor T1 recovery process, occuring in both excision-repair-proficient and -deficient host cells, is inhibited by T5 infection due to a different substance, which is most likely associated with the “second-step-transfer” region of T5 DNA (involving the remainder of the genome). Superinfection with T4ν₁ phage resulted in HCR inhibition of T1, resembling that observed after T5 superinfection. The discussion of these results suggests that inhibition of the bacterial excision repair system by T5 or T4 infection occurs at the level of UV-endonucleolytic incision, and that lack of HCR both in T-even phages and in T5 can be explained in the same manner.     

Construction and Characterization of T7 Bacteriophages Harboring Apidaecin-Derived Sequences

The global spread of multi- and pan-resistant bacteria has triggered research to identify novel strategies to fight these pathogens, such as antimicrobial peptides and, more recently, bacteriophages. In a proof-of-concept study, we have genetically modified lytic T7Select phages targeting Escherichia coli Rosetta by integrating DNA sequences derived from the proline-rich antimicrobial peptide, apidaecin. This allowed testing of our hypothesis that apidaecins and bacteriophages can synergistically act on phage-sensitive and phage-resistant E. coli cells and overcome the excessive cost of peptide drugs by using infected cells to express apidaecins before cell lysis. Indeed, the addition of the highly active synthetic apidaecin analogs, Api802 and Api806, to T7Select phage-infected E. coli Rosetta cultures prevented or delayed the growth of potentially phage-resistant E. coli Rosetta strains. However, high concentrations of Api802 also reduced the T7Select phage fitness. Additionally, plasmids encoding Api802, Api806, and Api810 sequences transformed into E. coli Rosetta allowed the production of satisfactory peptide quantities. When these sequences were integrated into the T7Select phage genome carrying an N-terminal green fluorescent protein (GFP-) tag to monitor the expression in infected E. coli Rosetta cells, the GFP–apidaecin analogs were produced in reasonable quantities. However, when Api802, Api806 and Api810 sequences were integrated into the T7Select phage genome, expression was below detection limits and an effect on the growth of potentially phage-resistant E. coli Rosetta strains was not observed for Api802 and Api806. In conclusion, we were able to show that apidaecins can be integrated into the T7Select phage genome to induce their expression in host cells, but further research is required to optimize the engineered T7Select phages for higher expression levels of apidaecins to achieve the expected synergistic effects that were visible when the T7Select phages and synthetic Api802 and Api806 were added to E. coli Rosetta cultures.