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.     

Two Modes of In Vivo Transcription for Genes 43 and 45 of Phage T4

Sensitivities of the expression of early genes of phage T4 to UV light were determined at various stages of intracellular development of T4 wild type, a DNA-negative mutant (T4 DO), and T4 tsG1, (a mutant that exhibits delayed expression of some T4 early genes). Whereas the sensitivities of some genes in the T4 wild type and T4 DO remain constant, genes 43 and 45 exhibit greatly reduced sensitivities several minutes after the onset of phage development. Since UV sensitivities are a measure of the distance of a gene from its promotor, these observations indicate a switch from distal, "immediate early" promotors to proximal, "delayed early" promotors for genes 43 and 45. In the tsG1 mutant this decrease in UV sensitivities of genes 43 and 45 does not occur at 42 C, suggesting that at high temperature this mutant does not utilize the delayed early promotors.     

Mutations in the gene 5 DNA polymerase of bacteriophage T7 suppress the dominant lethal phenotype of gene 2.5 ssDNA binding protein lacking the C-terminal phenylalanine

Gene 2.5 of bacteriophage T7 encodes a ssDNA binding protein (gp2.5) essential for DNA replication. The C-terminal phenylalanine of gp2.5 is critical for function and mutations in that position are dominant lethal. In order to identify gp2.5 interactions we designed a screen for suppressors of gp2.5 lacking the C-terminal phenylalanine. Screening for suppressors of dominant lethal mutations of essential genes is challenging as the phenotype prevents propagation. We select for phage encoding a dominant lethal version of gene 2.5, whose viability is recovered via second-site suppressor mutation(s). Functional gp2.5 is expressed in trans for propagation of the unviable phage and allows suppression to occur via natural selection. The isolated intragenic suppressors support the critical role of the C-terminal phenylalanine. Extragenic suppressor mutations occur in several genes encoding enzymes of DNA metabolism. We have focused on the suppressor mutations in gene 5 encoding the T7 DNA polymerase (gp5) as the gp5/gp2.5 interaction is well documented. The suppressor mutations in gene 5 are necessary and sufficient to suppress the lethal phenotype of gp2.5 lacking the C-terminal phenylalanine. The affected residues map in proximity to aromatic residues and to residues in contact with DNA in the crystal structure of T7 DNA polymerase-thioredoxin.     

Recombinant expression and purification of T4 phage Hoc, Soc, gp23, gp24 proteins in native conformations with stability studies

Understanding the biological activity of bacteriophage particles is essential for rational design of bacteriophages with defined pharmacokinetic parameters and to identify the mechanisms of immunobiological activities demonstrated for some bacteriophages. This work requires highly purified preparations of the individual phage structural proteins, possessing native conformation that is essential for their reactivity, and free of incompatible biologically active substances such as bacterial lipopolysaccharide (LPS). In this study we describe expression in E. coli and purification of four proteins forming the surface of the bacteriophage T4 head: gp23, gp24, gphoc and gpsoc. We optimized protein expression using a set of chaperones for effective production of soluble proteins in their native conformations. The assistance of chaperones was critical for production of soluble gp23 (chaperone gp31 of T4 phage) and of gpsoc (chaperone TF of E. coli). Phage head proteins were purified in native conditions by affinity chromatography and size-exclusion chromatography. Two-step LPS removal allowed immunological purity grade with the average endotoxin activity less than 1 unit per ml of protein preparation. The secondary structure and stability of the proteins were studied using circular dichroism (CD) spectrometry, which confirmed that highly purified proteins preserve their native conformations. In increasing concentration of a denaturant (guanidine hydrochloride), protein stability was proved to increase as follows: gpsoc, gp23, gphoc. The denaturation profile of gp24 protein showed independent domain unfolding with the most stable larger domain. The native purified recombinant phage proteins obtained in this work were shown to be suitable for immunological experiments in vivo and in vitro.     

Bacteriophage T4 gp2 Interferes with Cell Viability and with Bacteriophage Lambda Red Recombination

The T4 head protein, gp2, promotes head-tail joining during phage morphogenesis and is also incorporated into the phage head. It protects the injected DNA from degradation by exonuclease V during the subsequent infection. In this study, we show that recombinant gp2, a very basic protein, rapidly kills the cells in which it is expressed. To further illustrate the protectiveness of gp2 for DNA termini, we compare the effect of gp2 expression on Red-mediated and Int-mediated recombination. Red-mediated recombination is nonspecific and requires the transient formation of double-stranded DNA termini. Int-mediated recombination, on the other hand, is site specific and does not require chromosomal termini. Red-mediated recombination is inhibited to a much greater extent than is Int-mediated recombination. We conclude from the results of these physiological and genetic experiments that T4 gp2 expression, like Mu Gam expression, kills bacteria by binding to double-stranded DNA termini, the most likely mode for its protection of entering phage DNA from exonuclease V.     

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.     

Membrane-associated assembly of a phage T4 DNA entrance vertex structure studied with expression vectors

The DNA entrance vertex of the phage head is critical for prohead assembly and DNA packaging. A single structural protein comprises this dodecameric ring substructure of the prohead. Assembly of the phage T4 prohead occurs on the cytoplasmic membrane through a specific attachment at or near the gp20 DNA entrance vertex. An auxiliary head assembly gene product, gp40, was hypothesized to be involved in assembling the gp20 substructure. T4 genes 20, 40 and 20 + 40 were cloned into expression vectors under lambda pL promoter control. The corresponding T4 gene products were synthesized in high yield and were active as judged by their ability to complement the corresponding infecting T4 mutants in vivo. The cloned T4 gene 20 and gene 40 products were inserted into the cytoplasmic membrane as integral membrane proteins; however, gp20 was inserted into the membrane only when gp40 was also synthesized, whereas gp40 was inserted in the presence or absence of gp20. The gp20 insertion required a membrane potential, was not dependent upon the Escherichia coli groE gene, and assumed a defined membrane-spanning conformation, as judged by specific protease fragments protected by the membrane. The inserted gp20 structure could be probed by antibody binding and protein A-gold immunoelectron microscopy. The data suggest that a specific gp20-gp40-membrane insertion structure constitutes the T4 prohead assembly initiation complex.     

Repair and recombination of nonreplicating UV-irradiated phage DNA in E. coli III. Enhancement of excision repair in UV-treated bacteria

Summary The question of whether induction of the SOS response in Escherichia coli increases the efficiency of excision repair was addressed by measuring repair of UV-damaged nonreplicating lambda phage DNA in previously irradiated bacteria. Prior UV irradiation of lex ⁺ bacteria enhanced both the rate of regeneration of infective phage DNA (about 10-fold) and the rate of cyclobutane dimer removal early in repressed infections. Indirect induction of SOS-regulated repair activities by the nonreplicating irradiated phage DNA itself seemed negligible. Prior bacterial irradiation reduced the frequency of recombination (loss of a tandem chromosomal duplication) of nonreplicating UV-irradiated DNA. In this respect UV-stimulated recombination of nonreplicating DNA differs from RecF-dependent recombination processes that are stimulated by increased SOS expression.Surprisingly, prior UV irradiation of lexA3 bacteria caused a small but reproducible increase in the regeneration of infective phage DNA.     

Cloning, overexpression and purification of the terminase proteins gp16 and gp17 of bacteriophage T4. Construction of a defined in-vitro DNA packaging system using purified terminase proteins

Terminases of double-stranded DNA bacteriophages are required for packaging and generation of terminii in replicated concatemeric DNA molecules. Genetic evidence suggests that these functions in phage T4 are carried out by the products of genes 16 and 17. We cloned these T4 genes into a heat-inducible cI repressor-lambda PL promoter vector system, and overexpressed them in Escherichia coli. We developed an in-vitro DNA packaging system, which, consistent with the genetic data, shows an absolute requirement for the terminase proteins. The overexpressed terminase proteins gp16 and gp17 appear to form a specific complex and an ATP binding site is present in the gp17 molecule. We purified the terminase proteins either as individual gp16 or gp17 proteins, or as a gp16-gp17 complex. The gp16 function of the terminase complex is dispensable for packaging mature DNA, whereas gp17 is essential for packaging DNA under any condition tested. We constructed a defined in-vitro DNA packaging system with the purified terminase proteins, purified proheads and a DNA-free phage completion gene products extract. All the components of this system can be stored at -90 degrees C without loss of packaging activity. The terminase proteins, therefore, may serve as useful reagents for mechanistic studies on DNA packaging, as well as to develop T4 as a packaging-cloning vector.     

Mycobacteriophage Fruitloop gp52 inactivates Wag31 (DivIVA) to prevent heterotypic superinfection

Bacteriophages engage in complex dynamic interactions with their bacterial hosts and with each other. Bacteria have numerous mechanisms to resist phage infection, and phages must co‐evolve by overcoming bacterial resistance or by choosing an alternative host. Phages also compete with each other, both during lysogeny by prophage‐mediated defense against viral attack and by superinfection exclusion during lytic replication. Phages are enormously diverse genetically and are replete with small genes of unknown function, many of which are not required for lytic growth, but which may modulate these bacteria–phage and phage–phage dynamics. Using cellular toxicity of phage gene overexpression as an assay, we identified the 93‐residue protein gp52 encoded by Cluster F mycobacteriophage Fruitloop. The toxicity of Fruitloop gp52 overexpression results from interaction with and inactivation of Wag31 (DivIVA), an essential Mycobacterium smegmatis protein organizing cell wall biosynthesis at the growing cellular poles. Fruitloop gene 52 is expressed early in lytic growth and is not required for normal Fruitloop lytic replication but interferes with Subcluster B2 phages such as Hedgerow and Rosebush. We conclude that Hedgerow and Rosebush are Wag31‐dependent phages and that Fruitloop gp52 confers heterotypic superinfection exclusion by inactivating Wag31.     

Evidence Against Phenotypic Mixing Between Bacteriophage T4 Wild Type and T4v?

In a recent publication Shames et al. (1973) concluded that the UV-specific T4 endonuclease (a repair enzyme coded for by the gene v of wild-type T4) is a component of extracellular phage, which is injected into the host cell and can perform an early repair step without requiring gene expression. This notion is, however, not supported by results presented in this paper. Lysates obtained from mixed multiple infection of Escherichia coli cells with T4v(1) (-) and T4v(+) (or T4v(2) (-) and T4v(+)) failed to show the expected phenotypic mixing, i.e., incorporation of UV endonuclease into capsids of v(-) phages resulting in recognizable repair. The fraction of v(+) and v(-) particles in such lysates was determined by single-plaque analysis before and after irradiation with a UV dose at which virtually all survivors are particles having undergone repair. Even though our mixed infection conditions were most favorable for the possible occurrence of phenotypic mixing, none out of several hundred individual plaques from survivors were found to be genotypically v(-), whereas 30 were expected in the case that phenotypically mixed v(-) particles were repaired like T4v(+). Our failure to observe phenotypic mixing suggests that the data by Shames et al. reflect intracellular synthesis of endonuclease after phage infection.     

Stimulation of DNA repair and increased light output in response to UV irradiation in Escherichia coli expressing lux genes.

It has previously been suggested that the evolutionary drive of bacterial bioluminescence is a mechanism of DNA repair. By assessing the UV sensitivity of Escherichia coli, it is shown that the survival of UV-irradiated E. coli constitutively expressing luxABCDE in the dark is significantly better than either a strain with no lux gene expression or the same strain expressing only luciferase (luxAB) genes. This shows that UV resistance is dependent on light output, and not merely on luciferase production. Also, bacterial survival was found to be dependent on the conditions following UV irradiation, as bioluminescence-mediated repair was not as efficient as repair in visible light. Moreover, photon emission revealed a dose-dependent increase in light output per cell after UV exposure, suggesting that increased lux gene expression correlates with UV-induced DNA damage. This phenomenon has been previously documented in organisms where the lux genes are under their natural luxR regulation but has not previously been demonstrated under the regulation of a constitutive promoter.     

Bacteriophage T4 Gene 32 Participates in Excision Repair as Well as Recombinational Repair of Uv Damages

Gene 32 of phage T4 has been shown previously to be involved in recombinational repair of UV damages but, based on a mutant study, was thought not to be required for excision repair. However, a comparison of UV-inactivation curves of several gene 32 mutants grown under conditions permissive for progeny production in wild-type or polA- hosts demonstrates that gene 32 participates in both kinds of repair. Different gene 32 mutations differentially inactivate these repair functions. Under conditions permissive for DNA replication and progeny production, all gene 32 mutants investigated here are partially defective in recombinational repair, whereas only two of them, P7 and P401, are also defective in excision repair. P401 is the only mutant whose final slope of the inactivation curve is significantly steeper than that of wild-type T4. These results are discussed in terms of interactions of gp32, a single-stranded DNA-binding protein, with DNA and with other proteins.     

Nongenetic individuality in the host-phage interaction

Isogenic bacteria can exhibit a range of phenotypes, even in homogeneous environmental conditions. Such nongenetic individuality has been observed in a wide range of biological processes, including differentiation and stress response. A striking example is the heterogeneous response of bacteria to antibiotics, whereby a small fraction of drug-sensitive bacteria can persist under extensive antibiotic treatments. We have previously shown that persistent bacteria enter a phenotypic state, identified by slow growth or dormancy, which protects them from the lethal action of antibiotics. Here, we studied the effect of persistence on the interaction between Escherichia coli and phage lambda. We used long-term time-lapse microscopy to follow the expression of green fluorescent protein (GFP) under the phage lytic promoter, as well as cellular fate, in single infected bacteria. Intriguingly, we found that, whereas persistent bacteria are protected from prophage induction, they are not protected from lytic infection. Quantitative analysis of gene expression reveals that the expression of lytic genes is suppressed in persistent bacteria. However, when persistent bacteria switch to normal growth, the infecting phage resumes the process of gene expression, ultimately causing cell lysis. Using mathematical models for these two host–phage interactions, we found that the bacteria's nongenetic individuality can significantly affect the population dynamics, and might be relevant for understanding the coevolution of bacterial hosts and phages.     

Nongenetic Individuality in the Host–Phage Interaction

Isogenic bacteria can exhibit a range of phenotypes, even in homogeneous environmental conditions. Such nongenetic individuality has been observed in a wide range of biological processes, including differentiation and stress response. A striking example is the heterogeneous response of bacteria to antibiotics, whereby a small fraction of drug-sensitive bacteria can persist under extensive antibiotic treatments. We have previously shown that persistent bacteria enter a phenotypic state, identified by slow growth or dormancy, which protects them from the lethal action of antibiotics. Here, we studied the effect of persistence on the interaction between Escherichia coli and phage lambda. We used long-term time-lapse microscopy to follow the expression of green fluorescent protein (GFP) under the phage lytic promoter, as well as cellular fate, in single infected bacteria. Intriguingly, we found that, whereas persistent bacteria are protected from prophage induction, they are not protected from lytic infection. Quantitative analysis of gene expression reveals that the expression of lytic genes is suppressed in persistent bacteria. However, when persistent bacteria switch to normal growth, the infecting phage resumes the process of gene expression, ultimately causing cell lysis. Using mathematical models for these two host–phage interactions, we found that the bacteria's nongenetic individuality can significantly affect the population dynamics, and might be relevant for understanding the coevolution of bacterial hosts and phages.