Allosteric communication in DNA polymerase clamp loaders relies on a critical hydrogen-bonded junction

Clamp loaders are AAA+ ATPases that load sliding clamps onto DNA. We mapped the mutational sensitivity of the T4 bacteriophage sliding clamp and clamp loader by deep mutagenesis, and found that residues not involved in catalysis or binding display remarkable tolerance to mutation. An exception is a glutamine residue in the AAA+ module (Gln 118) that is not located at a catalytic or interfacial site. Gln 118 forms a hydrogen-bonded junction in a helical unit that we term the central coupler, because it connects the catalytic centers to DNA and the sliding clamp. A suppressor mutation indicates that hydrogen bonding in the junction is important, and molecular dynamics simulations reveal that it maintains rigidity in the central coupler. The glutamine-mediated junction is preserved in diverse AAA+ ATPases, suggesting that a connected network of hydrogen bonds that links ATP molecules is an essential aspect of allosteric communication in these proteins.

Genetically Encoded Biosensor-Based Screening for Directed Bacteriophage T4 Lysozyme Evolution

Lysozyme is widely used as a model protein in studies of structure–function relationships. Recently, lysozyme has gained attention for use in accelerating the degradation of secondary sludge, which mainly consists of bacteria. However, a high-throughput screening system for lysozyme engineering has not been reported. Here, we present a lysozyme screening system using a genetically encoded biosensor. We first cloned bacteriophage T4 lysozyme (T4L) into a plasmid under control of the araBAD promoter. The plasmid was expressed in Escherichia coli with no toxic effects on growth. Next, we observed that increased soluble T4L expression decreased the fluorescence produced by the genetic enzyme screening system. To investigate T4L evolution based on this finding, we generated a T4L random mutation library, which was screened using the genetic enzyme screening system. Finally, we identified two T4L variants showing 1.4-fold enhanced lytic activity compared to native T4L. To our knowledge, this is the first report describing the use of a genetically encoded biosensor to investigate bacteriophage T4L evolution. Our approach can be used to investigate the evolution of other lysozymes, which will expand the applications of lysozyme.

A scaled-down model for the translation of bacteriophage culture to manufacturing scale

Therapeutic bacteriophages are emerging as a potential alternative to antibiotics and synergistic treatment of antimicrobial-resistant infections. This is reflected by their use in an increasing number of recent clinical trials. Many more therapeutic bacteriophage is being investigated in preclinical research and due to the bespoke nature of these products with respect to their limited infection spectrum, translation to the clinic requires combined understanding of the biology underpinning the bioprocess and how this can be optimized and streamlined for efficient methods of scalable manufacture. Bacteriophage research is currently limited to laboratory scale studies ranging from 1-20 ml, emerging therapies include bacteriophage cocktails to increase the spectrum of infectivity and require multiple large-scale bioreactors (up to 50 L) containing different bacteriophage-bacterial host reactions. Scaling bioprocesses from the milliliter scale to multi-liter large-scale bioreactors is challenging in itself, but performing this for individual phage-host bioprocesses to facilitate reliable and robust manufacture of phage cocktails increases the complexity. This study used a full factorial design of experiments approach to explore key process input variables (temperature, time of infection, multiplicity of infection, agitation) for their influence on key process outputs (bacteriophage yield, infection kinetics) for two bacteriophage-bacterial host bioprocesses (T4 - Escherichia coli; Phage K - Staphylococcus aureus). The research aimed to determine common input variables that positively influence output yield and found that the temperature at the point of infection had the greatest influence on bacteriophage yield for both bioprocesses. The study also aimed to develop a scaled down shake-flask model to enable rapid optimization of bacteriophage batch bioprocessing and translate the bioprocess into a scale-up model with a 3 L working volume in stirred tank bioreactors. The optimization performed in the shake flask model achieved a 550-fold increase in bacteriophage yield and these improvements successfully translated to the large-scale cultures.

Transposon Insertion Sequencing Elucidates Novel Gene Involvement in Susceptibility and Resistance to Phages T4 and T7 in Escherichia coli O157

Experiments using bacteriophage (phage) to infect bacterial strains have helped define some basic genetic concepts in microbiology, but our understanding of the complexity of bacterium-phage interactions is still limited. As the global threat of antibiotic resistance continues to increase, phage therapy has reemerged as an attractive alternative or supplement to treating antibiotic-resistant bacterial infections. Further, the long-used method of phage typing to classify bacterial strains is being replaced by molecular genetic techniques. Thus, there is a growing need for a complete understanding of the precise molecular mechanisms underpinning phage-bacterium interactions to optimize phage therapy for the clinic as well as for retrospectively interpreting phage typing data on the molecular level. In this study, a genomics-based fitness assay (TraDIS) was used to identify all host genes involved in phage susceptibility and resistance for a T4 phage infecting Shiga-toxigenic Escherichia coli O157. The TraDIS results identified both established and previously unidentified genes involved in phage infection, and a subset were confirmed by site-directed mutagenesis and phenotypic testing of 14 T4 and 2 T7 phages. For the first time, the entire sap operon was implicated in phage susceptibility and, conversely, the stringent starvation protein A gene (sspA) was shown to provide phage resistance. Identifying genes involved in phage infection and replication should facilitate the selection of bespoke phage combinations to target specific bacterial pathogens.IMPORTANCE Antibiotic resistance has diminished treatment options for many common bacterial infections. Phage therapy is an alternative option that was once popularly used across Europe to kill bacteria within humans. Phage therapy acts by using highly specific viruses (called phages) that infect and lyse certain bacterial species to treat the infection. Whole-genome sequencing has allowed modernization of the investigations into phage-bacterium interactions. Here, using E. coli O157 and T4 bacteriophage as a model, we have exploited a genome-wide fitness assay to investigate all genes involved in defining phage resistance or susceptibility. This knowledge of the genetic determinants of phage resistance and susceptibility can be used to design bespoke phage combinations targeted to specific bacterial infections for successful infection eradication.

Transposon Insertion Sequencing Elucidates Novel Gene Involvement in Susceptibility and Resistance to Phages T4 and T7 in Escherichia coli O157

Experiments using bacteriophage (phage) to infect bacterial strains have helped define some basic genetic concepts in microbiology, but our understanding of the complexity of bacterium-phage interactions is still limited. As the global threat of antibiotic resistance continues to increase, phage therapy has reemerged as an attractive alternative or supplement to treating antibiotic-resistant bacterial infections. Further, the long-used method of phage typing to classify bacterial strains is being replaced by molecular genetic techniques. Thus, there is a growing need for a complete understanding of the precise molecular mechanisms underpinning phage-bacterium interactions to optimize phage therapy for the clinic as well as for retrospectively interpreting phage typing data on the molecular level. In this study, a genomics-based fitness assay (TraDIS) was used to identify all host genes involved in phage susceptibility and resistance for a T4 phage infecting Shiga-toxigenic Escherichia coli O157. The TraDIS results identified both established and previously unidentified genes involved in phage infection, and a subset were confirmed by site-directed mutagenesis and phenotypic testing of 14 T4 and 2 T7 phages. For the first time, the entire sap operon was implicated in phage susceptibility and, conversely, the stringent starvation protein A gene (sspA) was shown to provide phage resistance. Identifying genes involved in phage infection and replication should facilitate the selection of bespoke phage combinations to target specific bacterial pathogens.IMPORTANCE Antibiotic resistance has diminished treatment options for many common bacterial infections. Phage therapy is an alternative option that was once popularly used across Europe to kill bacteria within humans. Phage therapy acts by using highly specific viruses (called phages) that infect and lyse certain bacterial species to treat the infection. Whole-genome sequencing has allowed modernization of the investigations into phage-bacterium interactions. Here, using E. coli O157 and T4 bacteriophage as a model, we have exploited a genome-wide fitness assay to investigate all genes involved in defining phage resistance or susceptibility. This knowledge of the genetic determinants of phage resistance and susceptibility can be used to design bespoke phage combinations targeted to specific bacterial infections for successful infection eradication.

Transcriptomic Analysis of the Campylobacter jejuni Response to T4-Like Phage NCTC 12673 Infection

Campylobacter jejuni is a frequent foodborne pathogen of humans. As C. jejuni infections commonly arise from contaminated poultry, phage treatments have been proposed to reduce the C. jejuni load on farms to prevent human infections. While a prior report documented the transcriptome of C. jejuni phages during the carrier state life cycle, transcriptomic analysis of a lytic C. jejuni phage infection has not been reported. We used RNA-sequencing to profile the infection of C. jejuni NCTC 11168 by the lytic T4-like myovirus NCTC 12673. Interestingly, we found that the most highly upregulated host genes upon infection make up an uncharacterized operon (cj0423⁻cj0425), which includes genes with similarity to T4 superinfection exclusion and antitoxin genes. Other significantly upregulated genes include those involved in oxidative stress defense and the Campylobactermultidrug efflux pump (CmeABC). We found that phage infectivity is altered by mutagenesis of the oxidative stress defense genes catalase (katA), alkyl-hydroxyperoxidase (ahpC), and superoxide dismutase (sodB), and by mutagenesis of the efflux pump genes cmeA and cmeB. This suggests a role for these gene products in phage infection. Together, our results shed light on the phage-host dynamics of an important foodborne pathogen during lytic infection by a T4-like phage.

Effect of bacterial growth rate on bacteriophage population growth rate

It is important to understand how physiological state of the host influence propagation of bacteriophages (phages), due to the potential higher phage production needs in the future. In our study, we tried to elucidate the effect of bacterial growth rate on adsorption constant (δ), latent period (L), burst size (b), and bacteriophage population growth rate (λ). As a model system, a well-studied phage T4 and Escherichia coli K-12 as a host was used. Bacteria were grown in a continuous culture operating at dilution rates in the range between 0.06 and 0.98 hr-1 . It was found that the burst size increases linearly from 8 PFU·cell-1 to 89 PFU·cell-1 with increase in bacteria growth rate. On the other hand, adsorption constant and latent period were both decreasing from 2.6∙10-9  ml·min-1 and 80 min to reach limiting values of 0.5 × 10-9  ml·min-1 and 27 min at higher growth rates, respectively. Both trends were mathematically described with Michaelis-Menten based type of equation and reasons for such form are discussed. By applying selected equations, a mathematical equation for prediction of bacteriophage population growth rate as a function of dilution rate was derived, reaching values around 8 hr-1 at highest dilution rate. Interestingly, almost identical description can be obtained using much simpler Monod type equation and possible reasons for this finding are discussed.

Energetic cost of building a virus

Viruses are incapable of autonomous energy production. Although many experimental studies make it clear that viruses are parasitic entities that hijack the molecular resources of the host, a detailed estimate for the energetic cost of viral synthesis is largely lacking. To quantify the energetic cost of viruses to their hosts, we enumerated the costs associated with two very distinct but representative DNA and RNA viruses, namely, T4 and influenza. We found that, for these viruses, translation of viral proteins is the most energetically expensive process. Interestingly, the costs of building a T4 phage and a single influenza virus are nearly the same. Due to influenza's higher burst size, however, the overall cost of a T4 phage infection is only 2-3% of the cost of an influenza infection. The costs of these infections relative to their host's estimated energy budget during the infection reveal that a T4 infection consumes about a third of its host's energy budget, whereas an influenza infection consumes only ≈ 1%. Building on our estimates for T4, we show how the energetic costs of double-stranded DNA phages scale with the capsid size, revealing that the dominant cost of building a virus can switch from translation to genome replication above a critical size. Last, using our predictions for the energetic cost of viruses, we provide estimates for the strengths of selection and genetic drift acting on newly incorporated genetic elements in viral genomes, under conditions of energy limitation.

Phage T4-induced dTTP accretion bolsters a tRNase-based host defense

The anticodon nuclease (ACNase) PrrC is silenced in Escherichia coli by an associated DNA restriction-modification protein, activated by the phage T4-encoded anti-DNA restriction factor Stp and counteracted by T4's tRNA repair enzymes polynucleotide kinase and RNA ligase 1. Hence, only tRNA repair-deficient phages succumb to PrrC's restriction. PrrC's ABC-ATPase motor domains are implicated in driving its activation by hydrolyzing GTP and in stabilizing the activated ACNase by avidly binding dTTP. The latter effect has been associated with dTTP's accumulation early in T4 infection when PrrC is activated. In agreement, delayed dTTP accumulation caused by dCMP deaminase deficiency coincided with impaired manifestation of PrrC's ACNase activity. This impairment did not suffice to suppress the PrrC-mediated restriction of tRNA repair deficient phage but was synthetically suppressive with a leaky stp mutation that only partly impairs PrrC's activation. Presumably, ability to gauge dTTP's changing level helps confine PrrC's toxicity to its viral target.

Oriented immobilization of bacteriophages for biosensor applications

A method was developed for oriented immobilization of bacteriophage T4 through introduction of specific binding ligands into the phage head using a phage display technique. Fusion of the biotin carboxyl carrier protein gene (bccp) or the cellulose binding module gene (cbm) with the small outer capsid protein gene (soc) of T4 resulted in expression of the respective ligand on the phage head. Recombinant bacteriophages were characterized in terms of infectivity. It was shown that both recombinant phages retain their lytic activity and host range. However, phage head modification resulted in a decreased burst size and an increased latent period. The efficiency of bacteriophage immobilization with streptavidin-coated magnetic beads and cellulose-based materials was investigated. It was shown that recombinant bacteriophages form specific and strong bonds with their respective solid support and are able to specifically capture and infect the host bacterium. Thus, the use of immobilized BCCP-T4 bacteriophage for an Escherichia coli B assay using a phage multiplication approach and real-time PCR allowed detection of as few as 800 cells within 2 h.

[Comparative study of the resistance of bacteriophageT4, PhiX174D, MS2 and f2 to gamma radiation]

OBJECTIVE

To screen the suitable bacteriophage as virus indicator in irradiation sterilization.

METHODS

Suspensions of bacteriophage T4, phiX174D, MS2, and f2, Escherichia coli 8099, and Bacillus subtilis var.niger.sp. ATCC9372 were irradiated with (60)Co-gamma ray. The mean log(10) inactivation value (LIV) and killing log value (KL) were calculated.

RESULTS

(1) Under 100 Gy of gamma-radiation, the LIV levels of the bacteriophage T4, PhiX174, f2, and MS2 were 6.31, 6.92, 5.74, and 4.46 log(10) respectively, all reaching the disinfection level (LIV >/= 4.00 log(10)), (2) Under the same absorbed dose, the KL of Escherichia coli 8099 was > 7.97 log(10); (3) Under the same absorbed dose, the KL of the Bacillus subtilis var.niger.sp. ATCC9372 was 1.61 log(10).

CONCLUSION

The order of resistance of the above six microorganisms to gamma-radiation from the biggest to the smallest is as follows: Bacillus subtilis var. niger. sp. > bacteriophage MS2 > bacteriophage f2 > bacteriophage T4 > bacteriophage phiX 174D > E. coli.

Use of Tetrahymena thermophila to study the role of protozoa in inactivation of viruses in water

The ability of a ciliate to inactivate bacteriophage was studied because these viruses are known to influence the size and diversity of bacterial populations, which affect nutrient cycling in natural waters and effluent quality in sewage treatment, and because ciliates are ubiquitous in aquatic environments, including sewage treatment plants. Tetrahymena thermophila was used as a representative ciliate; T4 was used as a model bacteriophage. The T4 titer was monitored on Escherichia coli B in a double-agar overlay assay. T4 and the ciliate were incubated together under different conditions and for various times, after which the mixture was centrifuged through a step gradient, producing a top layer free of ciliates. The T4 titer in this layer decreased as coincubation time increased, but no decrease was seen if phage were incubated with formalin-fixed Tetrahymena. The T4 titer associated with the pellet of living ciliates was very low, suggesting that removal of the phage by Tetrahymena inactivated T4. When Tetrahymena cells were incubated with SYBR gold-labeled phage, fluorescence was localized in structures that had the shape and position of food vacuoles. Incubation of the phage and ciliate with cytochalasin B or at 4 degrees C impaired T4 inactivation. These results suggest the active removal of T4 bacteriophage from fluid by macropinocytosis, followed by digestion in food vacuoles. Such ciliate virophagy may be a mechanism occurring in natural waters and sewage treatment, and the methods described here could be used to study the factors influencing inactivation and possibly water quality.

Architecture of the Bacteriophage T4 Replication Complex Revealed with Nanoscale Biopointers

Our previous electron microscopy of DNA replicated by the bacteriophage T4 proteins showed a single complex at the fork, thought to contain the leading and lagging strand proteins, as well as the protein-covered single-stranded DNA on the lagging strand folded into a compact structure. "Trombone" loops formed from nascent lagging strand fragments were present on a majority of the replicating molecules (Chastain, P., Makhov, A. M., Nossal, N. G., and Griffith, J. D. (2003) J. Biol. Chem. 278, 21276-21285). Here we probe the composition of this replication complex using nanoscale DNA biopointers to show the location of biotin-tagged replication proteins. We find that a large fraction of the molecules with a trombone loop had two pointers to polymerase, providing strong evidence that the leading and lagging strand polymerases are together in the replication complex. 6% of the molecules had two loops, and 31% of these had three pointers to biotin-tagged polymerase, suggesting that the two loops result from two fragments that are being extended simultaneously. Under fixation conditions that extend the lagging strand, occasional molecules show two nascent lagging strand fragments, each being elongated by a biotin-tagged polymerase. T4 41 helicase is present in the complex on a large fraction of actively replicating molecules but on a smaller fraction of molecules with a stalled polymerase. Unexpectedly, we found that 59 helicase-loading protein remains on the fork after loading the helicase and is present on molecules with extensive replication.

Analysis of UV-induced mutation spectra in Escherichia coli by DNA polymerase eta from Arabidopsis thaliana

DNA polymerase eta belongs to the Y-family of DNA polymerases, enzymes that are able to synthesize past template lesions that block replication fork progression. This polymerase accurately bypasses UV-associated cis-syn cyclobutane thymine dimers in vitro and therefore may contributes to resistance against sunlight in vivo, both ameliorating survival and decreasing the level of mutagenesis. We cloned and sequenced a cDNA from Arabidopsis thaliana which encodes a protein containing several sequence motifs characteristics of Pol eta homologues, including a highly conserved sequence reported to be present in the active site of the Y-family DNA polymerases. The gene, named AtPOLH, contains 14 exons and 13 introns and is expressed in different plant tissues. A strain from Saccharomyces cerevisiae, deficient in Pol eta activity, was transformed with a yeast expression plasmid containing the AtPOLH cDNA. The rate of survival to UV irradiation in the transformed mutant increased to similar values of the wild type yeast strain, showing that AtPOLH encodes a functional protein. In addition, when AtPOLH is expressed in Escherichia coli, a change in the mutational spectra is detected when bacteria are irradiated with UV light. This observation might indicate that AtPOLH could compete with DNA polymerase V and then bypass cyclobutane pyrimidine dimers incorporating two adenylates.

Periplasmic domains define holin-antiholin interactions in t4 lysis inhibition

Bacteriophage T4 effects host lysis with a holin, T, and an endolysin, E. T and E accumulate in the membrane and cytoplasm, respectively, throughout the period of late gene expression. At an allele-specific time, T triggers to disrupt the membrane, allowing E to enter the periplasm and attack the peptidoglycan. T triggering can be blocked by secondary infections, leading to the state of lysis inhibition (LIN). LIN requires the T4 antiholin, RI, and is sensitive to the addition of energy poisons. T is unusual among holins in having a large C-terminal periplasmic domain. The rI gene encodes a polypeptide of 97 residues, of which 72 are predicted to be a periplasmic domain. Here, we show that the periplasmic domain of RI is necessary and sufficient to block T-mediated lysis. Moreover, when overexpressed, the periplasmic domain of T (T(CTD)) was found to abolish LIN in T4 infections and to convert wild-type (wt) T4 plaques from small and fuzzy edged to the classic "r" large, sharp-edged plaque morphology. Although RI could be detected in whole cells, attempts to monitor it during subcellular fractionation were unsuccessful, presumably because RI is a highly unstable protein. However, fusing green fluorescence protein (GFP) to the N terminus of RI created a more stable chimera that could be demonstrated to form complexes with wild-type T(CTD) and also with its LIN-defective T75I variant. These results suggest that the function of the unusual periplasmic domain of T is to transduce environmental information for the real-time control of lysis timing.

Transposon-mediated linker insertion scanning mutagenesis of the Escherichia coli McrA endonuclease

McrA is one of three functions that restrict modified foreign DNA in Escherichia coli K-12, affecting both methylated and hydroxymethylated substrates. We present here the first systematic analysis of the functional organization of McrA by using the GPS-LS insertion scanning system. We collected in-frame insertions of five amino acids at 46 independent locations and C-terminal truncations at 20 independent locations in the McrA protein. Each mutant was assayed for in vivo restriction of both methylated and hydroxymethylated bacteriophage (M.HpaII-modified lambda and T4gt, respectively) and for induction of the E. coli SOS response in the presence of M.HpaII methylation, indicative of DNA damage. Our findings suggest the presence of an N-terminal DNA-binding domain and a C-terminal catalytic nuclease domain connected by a linker region largely tolerant of amino acid insertions. DNA damage inflicted by a functional C-terminal domain is required for restriction of phage T4gt. Disruption of the N-terminal domain abolishes restriction of both substrates. Surprisingly, truncation mutations that spare the N-terminal domain do not mediate DNA damage, as measured by SOS induction, but nevertheless partially restrict M.HpaII-modified lambda in vivo. We suggest a common explanation for this "restriction without damage" and a similar observation seen in vivo with McrB, a component of another of the modified-DNA restriction functions. Briefly, we propose that unproductive site-specific binding of the protein to a vulnerable position in the lambda genome disrupts the phage development program at an early stage. We also identified a single mutant, carrying an insertion in the N-terminal domain, which could fully restrict lambda but did not restrict T4gt at all. This mutant may have a selective impairment in substrate recognition, distinguishing methylated from hydroxymethylated substrates. The study shows that the technically easy insertion scanning method can provide a rich source of functional information when coupled with effective phenotype tests.

Blocking the T4 lysis inhibition phenotype

Nonlysogenic Escherichia coli K cells exhibit a delay in lysis when infected by T4rII phage termed lysis inhibition (LIN). E. coli K cells expressing lambda rexB from either a prophage defective for rexA, or a multicopy plasmid supported T4rII infection, but prevented the establishment of LIN. In addition, E. coli null mutations in either the periplasmic "tail-specific protease" tsp, or the 10Sa RNA ssrA, completely blocked the establishment of LIN following T4 infections. The expression of rexB in the absence of rexA resulted in several cellular phenotypes, including aberrant cell surface morphology, the partial to near complete suppression of mutations of lambda S and T4t holin genes, and lysis by cells aging on plates or growing with high rexB expression at elevated temperatures. These activities of RexB were impeded in the presence of RexA.

Over-expression ofrexAnullifies T4rIIexclusion inEscherichia coliK(λ) lysogens

Dosage and relative cellular levels of RexA and RexB proteins encoded by the rexA–rexB genes of a λ prophage are important for the Rex+phenotype, which was nullified when greater RexA or RexB was provided than was necessary for the complementation of a rexA–or a rexB–prophage.Key words: bacteriophage lambda (λ), T4rII exclusion (Rex) phenotype, lambda pM–cI–rexA–rexB–timmoperon.

A role for bacteriophage T4 rI gene function in the control of phage development during pseudolysogeny and in slowly growing host cells

Although most studies on bacteriophages have been performed under laboratory conditions that are optimal for host cell growth, in nature, bacteria and bacteriophages coexist in different habitats. Here, by using different growth rates in carbon-limited chemostats, we investigated the development of phage T4 in its host Escherichia coli. Our results strongly suggest that T4 can form pseudolysogens not only when bacterial growth is completely inhibited, but also in growing host cells. The rI gene, previously known to be indispensable for lysis inhibition, seems to play an important role in optimization of phage development in slowly growing cells as well as during establishment and maintenance of pseudolysogeny.

Structure and morphogenesis of bacteriophage T4

Bacteriophage T4 is one of the most complex viruses. More than 40 different proteins form the mature virion, which consists of a protein shell encapsidating a 172-kbp double-stranded genomic DNA, a 'tail,' and fibers, attached to the distal end of the tail. The fibers and the tail carry the host cell recognition sensors and are required for attachment of the phage to the cell surface. The tail also serves as a channel for delivery of the phage DNA from the head into the host cell cytoplasm. The tail is attached to the unique 'portal' vertex of the head through which the phage DNA is packaged during head assembly. Similar to other phages, and also herpes viruses, the unique vertex is occupied by a dodecameric portal protein, which is involved in DNA packaging.

Regulation of Translation of the Head Protein of T4 Bacteriophage by Specific Binding of EF-Tu to a Leader Sequence

Recent evidence indicates that translation elongation factor Tu (EF-Tu) has a role in the cell in addition to its well established role in translation. The translation factor binds to a specific region called the Gol region close to the N terminus of the T4 bacteriophage major head protein as the head protein emerges from the ribosome. This binding was discovered because EF-Tu bound to Gol peptide is the specific substrate of the Lit protease that cleaves the EF-Tu between amino acid residues Gly59 and lle60, blocking phage development. These experiments raised the question of why the Gol region of the incipient head protein binds to EF-Tu, as binding to incipient proteins is not expected from the canonical role of EF-Tu. Here, we use gol-lacZ translational fusions to show that cleavage of EF-Tu in the complex with Gol peptide can block translation of a lacZ reporter gene fused translationally downstream of the Gol peptide that activated the cleavage. We propose a model to explain how binding of EF-Tu to the emerging Gol peptide could cause translation to pause temporarily and allow time for the leader polypeptide to bind to the GroEL chaperonin before translation continues, allowing cotranslation of the head protein with its insertion into the GroEL chaperonin chamber, and preventing premature synthesis and precipitation of the head protein. Cleavage of EF-Tu in the complex would block translation of the head protein and therefore development of the infecting phage. Experiments are presented that confirm two predictions of this model. Considering the evolutionary conservation of the components of this system, this novel regulatory mechanism could be used in other situations, both in bacteria and eukaryotes, where proteins are cotranslated with their insertion into cellular structures.

Study on interaction between T4 phage and Escherichia coli B by microcalorimetric method

The process that T4 phages multiply in host cells of Escherichia coli B was determined using LKB-2277 Bioactivity Monitor by means of stopped-flow method, and the growth was measured turbidometrically at the same time at 37 degrees C. By analyzing thermo-curves, quantitative parameters could be obtained to characterize the interactions of host cells and phages. The parameters such as k(a), P(max), G etc. change regularly with the decrease of multiplicity of infection (MOI) value. Infection-lysis equations were fitted and the lytic rate constant k(L) was obtained. The results show that the metabolic activity of infected cells is more intensive than that of normal cells. The phenomenon of lysis inhibition (LIN) was first detected with the microcalorimetric method, and the mechanism is discussed.

DNA damage and biological effects induced by photosensitization with new N(1)-unsubstituted furo[2,3-h]quinolin-2(1H)-ones

New furoquinolinones unsubstituted at the N(1) position were prepared and their photobiological activities were studied in comparison with 4,6,8,9-tetramethylfuro[2,3-h]quinolin-2(1H)-one (HFQ) and 8-MOP. The anti-proliferative activity of furoquinolinones 3a-f was tested upon UVA irradiation in mammalian cells, studying DNA synthesis and clonal growth capacity, and in micro-organisms, evaluating T2 infectivity. Almost all compounds appeared to be more active than 8-MOP, and free of any mutagenic activity and skin phototoxicity. Among them, compound 3b was the most effective one. Similarly to HFQ, compound 3b appeared to be very active also in DNA damaging, forming monoadducts and DPC(L=0), but no ISC and DPC(L>0), both responsible for furocoumarin genotoxicity and phototoxicity. Moreover, Ehrlich ascites cells, photoinactivated by the new furoquinolinone 3b and injected into recipient mice, proved to be capable of inducing protection against a successive challenge performed with the same tumor cells. For all these features, 3b seemed to be a new promising potential drug for PUVA therapy and photopheresis.

Genetic effects of space hadrons on bacteriophage under Alpine conditions

A dried film culture of bacteriophage T4Br + was kept in a lead bioblock for 366 days under Alpine conditions at an altitude of 6100 m above sea level to study the genetic effect of space hadrons. In the gelatin-like film under study we discovered some film plots with markedly reduced bacteriophage survival. In such plots, the mutation frequency exceeded the spontaneous background mutation rate 60-100 times. The spectrum of r mutations as classified into standard groups rI, rII and rIII differed from that found for other model radiation systems such as gamma-ray radiation in buffer or nutrient broth, and hadron and HZE particle radiation under space flight conditions. Reversion analysis of 159 rII mutants showed that 54.4% had small and elongated deletions, 23.16% had point mutations, and 22.5% of all the mutants had both small deletion and point mutations.

Bacteriophage T4 development in Escherichia coli is growth rate dependent

Three independent parameters (eclipse and latent periods, and rate of ripening during the rise period) are essential and sufficient to describe bacteriophage development in its bacterial host. A general model to describe the classical "one-step growth" experiment [Rabinovitch et al. (1999a) J. Bacteriol.181, 1687-1683] allowed their calculations from experimental results obtained with T4 in Escherichia coli B/r under different growth conditions [Hadas et al. (1997) Microbiology143, 179-185]. It is found that all three parameters could be described by their dependence solely on the culture doubling time tau before infection. Their functional dependence on tau, derived by a best-fit analysis, was used to calculate burst size values. The latter agree well with the experimental results. The dependence of the derived parameters on growth conditions can be used to predict phage development under other experimental manipulations.

The chaperonins of Synechocystis PCC 6803 differ in heat inducibility and chaperone activity

The chaperonins GroEL and Cpn60 were isolated from the cyanobacterium Synechocystis PCC 6803 and characterized. In cells grown under optimal conditions their ratio was about one to one. However, the amount of GroEL increased considerably more than that of Cpn60 in response to heat stress. The labile chaperonin oligomer required stabilization by MgATP or glycerol during isolation. Use of the E. coli mutant strain, groEL44 revealed that the functional properties of the two cyanobacterial chaperonins are strikingly different. Overexpression of cyanobacterial GroEL in the E. coli mutant strain allowed growth at elevated temperature, the formation of mature bacteriophage T4, and active Rubisco enzyme assembly. In contrast, Cpn60 partially complemented the temperature-sensitive phenotype, the Rubisco assembly defect and did not promote the growth of the bacteriophage T4. The difference in chaperone activity of the two cyanobacterial chaperonins very probably reflects the unique chaperonin properties required during the life of Synechocystis PCC 6803.

The N-terminal ATPase site in the large terminase protein gp17 is critically required for DNA packaging in bacteriophage T4

Double-stranded DNA packaging in bacteriophages is apparently driven by the most powerful molecular motor ever measured. Although it is widely accepted that a translocating ATPase powers the DNA packaging machine, the identity of the ATPase that generates this driving force is unknown. Evidence suggests that the large terminase protein gp17, which possesses two consensus ATP binding motifs and an ATPase activity, is a strong candidate for the translocating ATPase in bacteriophage T4. This hypothesis was tested by a PCR-directed combinatorial mutagenesis approach in which mutant libraries consisting of all possible codon combinations were constructed at the signature residues of the ATP binding motifs. The impact on gp17 function of each randomly selected mutant was evaluated by phenotypic analysis following recombinational transfer into the viral genome. The precise mutation giving rise to a particular phenotype was determined by DNA sequencing. The data showed that the N-terminal ATP binding site I (SRQLGKT(161-167)), but not the ATP binding site II (TAAVEGKS(299-306)), is critical for gp17 function. Even conservative substitutions such as G165A, K166R, and T167A were not tolerated at the GKT signature residues, which are predicted to interact with the ATP substrate. Biochemical analyses of the mutants showed a complete loss of in vitro DNA packaging activity but not the terminase (DNA-cutting) activity. The purified K166G mutant showed a loss of gp17-ATPase activity. The data, for the first time, implicated a specific ATPase center in the viral dsDNA packaging.

Bacteriophage T4 multiplication in a glucose-limited Escherichia coli biofilm

An Escherichia coli K-12 biofilm was grown at a dilution rate of 0.028 h(-1) for 48 h in a glucose-limited chemostat coupled to a modified Robbins' device to determine its susceptibility to infection by bacteriophage T4. Bacteriophage T4 at a multiplicity of infection (MOI) of 10 caused a log reduction in biofilm density (expressed as colony forming units (CFU) per cm2) at 90 min postinfection. After 6 h, a net decrease and equilibrium in viral titer was seen. When biofilms were exposed to T4 phage at a MOI of 100, viral titer doubled after 90 min. After 6 h, viral titers (expressed as plaque forming units (PFU) per cm2) stabilized at levels approximately one order of magnitude higher than seen at a MOI of 10. Scanning confocal laser microscopy images also indicated disruption of biofilm morphology following T4 infection with the effects being more pronounced at a MOI of 100 than at a MOI of 10. These results imply that biofilms under carbon limitation can act as natural reservoirs for bacteriophage and that bacteriophage can have some influence on biofilm morphology.

Genetic analysis of the T4 holin: timing and topology

The t protein of bacteriophage T4 shares with other holins the ability to cause the formation of a lethal membrane lesion which allows the phage endolysin to attack the peptidoglycan. Moreover, T, like other holins, acts in a saltatory manner at a precisely programmed time in the vegetative cycle. Unlike other holins, however, T has the unique ability to postpone its lethal function in response to a secondary infection by a T-even phage during the vegetative cycle. A signal transduction system that responds to the secondary infection is thought to be encoded by some of the numerous r genes, defined by mutations that abolish this lysis-inhibition (LIN) response. The primary structure of T differs from two main structural patterns found in more than 30 orthologous groups of holins. Genetic approaches were taken to probe the t sequence for features involved in membrane localization, functional timing and LIN regulation. Gene fusion analysis indicates that T has a single TMD near the N-terminus, with the bulk of the protein residing in the periplasm. Mapping and phenotypic analysis of deletion and point mutations in t indicates that the periplasmic domain of T is the major determinant of the timing mechanism and is involved in the LIN response.

From minichaperone to GroEL 2: importance of avidity of the multisite ring structure

Structural studies on minichaperones and GroEL imply a continuous ring of binding sites around the neck of GroEL. To investigate the importance of this ring, we constructed an artificial heptameric assembly of minichaperones to mimic their arrangement in GroEL. The heptameric Gp31 co-chaperonin from bacteriophage T4, an analogue of GroES, was used as a scaffold to display the GroEL minichaperones. A fusion protein, MC(7), was generated by replacing a part of the highly mobile loop of Gp31 (residues 23-44) with the sequence of the minichaperone (residues 191-376 of GroEL). The purified recombinant protein assembled into a heptameric ring composed of seven 30.6 kDa subunits. Although single minichaperones (residues 193-335 to 191-376 of GroEL) have certain chaperone activities in vitro and in vivo, they cannot refold heat and dithiothreitol-denatured mitochondrial malate dehydrogenase (mtMDH), a reaction that normally requires GroEL, its co-chaperonin GroES and ATP. But, MC(7) refolded MDH in vitro. The expression of MC(7) complements in vivo two temperature-sensitive Escherichia coli alleles, groEL44 and groEL673, at 43 degrees C. Although MC(7) could not compensate for the complete absence of GroEL in vivo, it enhanced the colony-forming ability of cells containing limiting amounts of wild-type GroEL at 37 degrees C. MC(7 )also reduces aggregate formation and cell death in mammalian cell models of Huntington's disease. The assembly of seven minichaperone subunits on a heptameric ring significantly improves their activity, demonstrating the importance of avidity in GroEL function.

Endoribonuclease RegB from bacteriophage T4 is necessary for the degradation of early but not middle or late mRNAs

The RegB endoribonuclease from bacteriophage T4 cleaves early mRNAs specifically in the middle of the sequence GGAG. We show here that RegB is required for the degradation of bulk T4 early mRNA. In the absence of RegB, the chemical half-life of early transcripts is increased nearly fourfold, whereas their functional half-life is increased twofold. RegB also regulates the translation of several prereplicative genes. The synthesis of several early proteins is down-regulated, probably as a consequence of RegB cleavages in the Shine-Dalgarno sequence of these genes. The synthesis of several other proteins is up-regulated, suggesting that processing by RegB might improve translation by changing the conformation of a transcript. In contrast, RegB does not affect the average half-life of middle and late mRNA. An analysis of the susceptibility to RegB of many GGAG motifs carried by these mRNA species showed that most middle and all late GGAG-carrying mRNAs escape RegB processing in spite of the fact that the enzyme is acting at least until ten minutes post-infection. The sensitivity or resistance to RegB observed during phage infection could be reproduced in uninfected Escherichia coli cells and in vitro. This shows that the GGAG-carrying RNAs that are uncut during T4 infection are not substrates, whatever the period of the T4 cycle when the transcripts are made.

An antitumor drug-induced topoisomerase cleavage complex blocks a bacteriophage T4 replication fork in vivo

Many antitumor and antibacterial drugs inhibit DNA topoisomerases by trapping covalent enzyme-DNA cleavage complexes. Formation of cleavage complexes is important for cytotoxicity, but evidence suggests that cleavage complexes themselves are not sufficient to cause cell death. Rather, active cellular processes such as transcription and/or replication are probably necessary to transform cleavage complexes into cytotoxic lesions. Using defined plasmid substrates and two-dimensional agarose gel analysis, we examined the collision of an active replication fork with an antitumor drug-trapped cleavage complex. Discrete DNA molecules accumulated on the simple Y arc, with branch points very close to the topoisomerase cleavage site. Accumulation of the Y-form DNA required the presence of a topoisomerase cleavage site, the antitumor drug, the type II topoisomerase, and a T4 replication origin on the plasmid. Furthermore, all three arms of the Y-form DNA were replicated, arguing strongly that these are trapped replication intermediates. The Y-form DNA appeared even in the absence of two important phage recombination proteins, implying that Y-form DNA is the result of replication rather than recombination. This is the first direct evidence that a drug-induced topoisomerase cleavage complex blocks the replication fork in vivo. Surprisingly, these blocked replication forks do not contain DNA breaks at the topoisomerase cleavage site, implying that the replication complex was inactivated (at least temporarily) and that topoisomerase resealed the drug-induced DNA breaks. The replication fork may behave similarly at other types of DNA lesions, and thus cleavage complexes could represent a useful (site-specific) model for chemical- and radiation-induced DNA damage.

Gene 61.3 of bacteriophage T4 is the spackle gene

The bacteriophage T4 e gene encodes lysozyme (e-lysozyme), which releases progeny phage after normal infection of Escherichia coli cells. A mutation in the spackle gene suppresses the defect in e-lysozyme (Emrich, 1968). The spackle gene was mapped between genes 41 and 61, but its precise location has not previously been determined. In the current study, we constructed an amber mutant of gene 61.3, amST14, by site-directed mutagenesis. The gene 61.3 mutant shares phenotypes with spackle mutants: The amST14 mutant forms large plaques with sharp edges and exhibits truncated lysis inhibition, and furthermore, the mutation can suppress the defect in e-lysozyme activity. In addition, cloned gene 61.3 can rescue (by homologous recombination) as well as complement the S12 mutation in the spackle gene. These results strongly suggest that gene 61.3 is the spackle gene. Indeed, the S12 mutant has one base deletion of five in a consecutive A tract in the gene 61.3 coding region, substituting an unrelated 6-amino acid sequence for the 9 C-terminal amino acids in the gene 61.3 protein. The gene 61.3 protein is predicted to localize in the periplasmic space after cleavage of a signal sequence.

Bacteriophage T4 rnh (RNase H) null mutations: effects on spontaneous mutation and epistatic interaction with rII mutations

The bacteriophage T4 rnh gene encodes T4 RNase H, a relative of a family of flap endonucleases. T4 rnh null mutations reduce burst sizes, increase sensitivity to DNA damage, and increase the frequency of acriflavin resistance (Acr) mutations. Because mutations in the related Saccharomyces cerevisiae RAD27 gene display a remarkable duplication mutator phenotype, we further explored the impact of rnh mutations upon the mutation process. We observed that most Acr mutants in an rnh+ strain contain ac mutations, whereas only roughly half of the Acr mutants detected in an rnhDelta strain bear ac mutations. In contrast to the mutational specificity displayed by most mutators, the DNA alterations of ac mutations arising in rnhDelta and rnh+ backgrounds are indistinguishable. Thus, the increase in Acr mutants in an rnhDelta background is probably not due to a mutator effect. This conclusion is supported by the lack of increase in the frequency of rI mutations in an rnhDelta background. In a screen that detects mutations at both the rI locus and the much larger rII locus, the r frequency was severalfold lower in an rnhDelta background. This decrease was due to the phenotype of rnh rII double mutants, which display an r+ plaque morphology but retain the characteristic inability of rII mutants to grow on lambda lysogens. Finally, we summarize those aspects of T4 forward-mutation systems which are relevant to optimal choices for investigating quantitative and qualitative aspects of the mutation process.

Model for bacteriophage T4 development in Escherichia coli

Mathematical relations for the number of mature T4 bacteriophages, both inside and after lysis of an Escherichia coli cell, as a function of time after infection by a single phage were obtained, with the following five parameters: delay time until the first T4 is completed inside the bacterium (eclipse period, nu) and its standard deviation (sigma), the rate at which the number of ripe T4 increases inside the bacterium during the rise period (alpha), and the time when the bacterium bursts (mu) and its standard deviation (beta). Burst size [B = alpha(mu - nu)], the number of phages released from an infected bacterium, is thus a dependent parameter. A least-squares program was used to derive the values of the parameters for a variety of experimental results obtained with wild-type T4 in E. coli B/r under different growth conditions and manipulations (H. Hadas, M. Einav, I. Fishov, and A. Zaritsky, Microbiology 143:179-185, 1997). A "destruction parameter" (zeta) was added to take care of the adverse effect of chloroform on phage survival. The overall agreement between the model and the experiment is quite good. The dependence of the derived parameters on growth conditions can be used to predict phage development under other experimental manipulations.

Characterisation of the bacteriophage T4 comC alpha 55.6 and comCJ mutants. A possible role in an antitermination process

We have performed a new screen for T4 mutants (comC) that overcome the phage growth restriction caused by the Escherichia coli rho/tabC mutants. We show that one such mutant (comCJ) identifies a different gene from that identified by canonical comC mutants. We compare the regulation of T4 prereplicative transcription in a rho/tabC mutant infected by T4 wild-type, by a canonical comC mutant (comC alpha 55.6) and by comCJ. The transcription rates of the two prereplicative genes 39 and 43 is depressed in a T4 wild-type infected tabC host mutant. When comC alpha 55.6 and/or comCJ single and double mutants are the infecting phages, transcription of genes 39 and 43 is resumed to different extents; in particular, in the double mutant infections there appears to be a synergistic effect on transcription. Furthermore, we find that the comC alpha 55.6 phage mutant affects the transcription rate of the gene rIIA in a wild-type host.

The spectrum of acridine resistant mutants of bacteriophage T4 reveals cryptic effects of the tsL141 DNA polymerase allele on spontaneous mutagenesis

Mutations in the ac gene of bacteriophage T4 confer resistance to acridine-inhibition of phage development. Previous studies had localized the ac gene region; we show that inactivation of T4 Open Reading Frame 52.2 confers the Acr phenotype. Thus, 52.2 is ac. The resistance mechanism is unknown. The ac gene provides a convenient forward mutagenesis assay. Its compact size (156 bp) simplifies mutant sequencing and diverse mutant types are found: base substitutions leading to missense or nonsense codons, in-frame deletions or duplications within the coding sequence, deletion or duplication frameshifts, insertions, complex mutations, and large deletions extending into neighboring sequences. Comparisons of spontaneous mutagenesis between phages bearing the wild-type or tsL141 alleles of DNA polymerase demonstrate that the impact of the mutant polymerase is cryptic when total spontaneous mutant frequencies are compared, but the DNA sequences of the ac mutants reveal a substantial alteration of fidelity by the mutant polymerase. The patterns of base substitution mutagenesis suggest that some site-specific mutation rate effects may reflect hotspots for mutagenesis arising by different mechanisms. A new class of spontaneous duplication mutations, having sequences inconsistent with misaligned pairing models, but consistent with nick-processing errors, has been identified at a hotspot in ac.

Specific peptide-activated proteolytic cleavage of Escherichia coli elongation factor Tu

Phage exclusion is a form of programmed cell death in prokaryotes in which death is triggered by infection with phage, a seemingly altruistic response that limits multiplication of the phage and its spread through the population. One of the best-characterized examples of phage exclusion is the exclusion of T-even phages such as T4 by the e14-encoded Lit protein in many Escherichia coli K-12 strains. In this exclusion system, transcription and translation of a short region of the major head coat protein gene late in phage infection activates proteolysis of translation elongation factor Tu (EF-Tu), blocking translation and multiplication of the phage. The cleavage occurs between Gly-59 and Ile-60 in the nucleotide-binding domain. In the present work, we show that a 29-residue synthetic peptide spanning the activating region of the major head coat protein can activate the cleavage of GDP-bound EF-Tu in a purified system containing only purified EF-Tu and purified Lit protein. Lit behaves as a bona fide enzyme in this system, cleaving EF-Tu to completion when present at substoichiometric amounts. Two mutant peptides with amino acid changes that reduce the activation of cleavage of EF-Tu in vivo were also greatly reduced in their ability to activate EF-Tu cleavage in vitro but were still able to activate cleavage at a high concentration. Elongation factor G, which has the same sequence at the cleavage site and a nucleotide-binding domain similar to EF-Tu, was not cleaved by this system, and neither was heat-inactivated EF-Tu, suggesting that the structural context of the cleavage site may be important for specificity. This system apparently represents an activation mechanism for proteolysis that targets one of nature's most evolutionarily conserved proteins for site-specific cleavage.

Characteristics of gene 28 product, the constituent of the central part of bacteriophage T4 baseplate

The phage TD gene 28 product has been partially characterized and its biological role has been examined. It was found to be a protein with a molecular size of 24 kDa which cosediments with the membrane fraction of the bacterial extracts and could only be washed out by a 0.2% sarcosyl solution. Other observations indicate that gp 28 has a majority of hydrophobic residues on its surface and forms a homotrimeric complex in the absence of other phage proteins. The product was finally identified as a baseplate structural component. Incubation of purified phage preparation in a buffer which contained active protein 28, did not affect the efficiency of the plating. However, incubation of the phage particles with specific antiserum was found to neutralize phage infectivity.

An E. coli B mutation, rpoB5081, that prevents growth of phage T4 strains defective in host DNA degradation

An E. coli B Tab strain, EM121, was isolated that restricts T4 denA (DNA endonuclease II) mutants at 37 degrees C and above, but is permissive for wild-type T4 at all temperatures examined. At 42 degrees C, other mutants affected in nucleic acid metabolism (T4 dexA, regA and uvsW strains) are also restricted. Genetic analysis revealed that one mutation (rpoB5081) in the RNA polymerase beta subunit gene is sufficient for restricting all denA mutants. rpoB5081, together with a second linked mutation, is also required for restricting the other T4 mutants, rpoB5081 (P806S), previously shown to increase transcription termination in E. coli K-12, causes delayed synthesis of T4 late proteins and reduced DNA synthesis in denA infections. Thus, T4 DNA synthesis and gene expression are impaired by the rpoB5081 beta subunit when degradation of host DNA is reduced. Because the restricted T4 mutants are not readily distinguished from wild-type phage under typical plating conditions, EM121 is an important host for screening and mapping T4 denA mutations.

Effects on mRNA degradation by Escherichia coli transcription termination factor Rho and pBR322 copy number control protein Rop

Mutants in Escherichia coli transcription termination factor Rho, termed rho(nusD), were previously isolated based on their ability to block the growth of bacteriophage T4. Here we show that rho(nusD) strains have decreased average half-lives for bulk cellular mRNA. Decreased E. coli message lifetimes could be because of increased ribonuclease activity in the rho mutant cells: if a Rho-dependent terminator precedes a ribonuclease gene, weaker termination in the rho mutants could lead to nuclease overexpression. However, inactivation of ribonuclease genes in rho026 cells did not relieve the defective phage growth. Unexpectedly, expression of the pBR322 Rop protein, a structure-specific, sequence-independent RNA-binding protein, in rho(nusD) cells restored the ability of T4 to grow and prolonged cellular message half-life in both the wild-type and the rho026 mutant. These results suggest that it is the RNA-binding ability of Rho rather than its transcription termination function that is important for the inhibition of bacteriophage growth and the shorter bulk mRNA lifetime. We propose that altered interaction of the mutant Rho with mRNA could make the RNA more susceptible to degradation. The inability of the RNA-binding proteins SrmB and DeaD to reverse the rho mutant phenotype when each is overexpressed implies that the required RNA interactions are specific. The results show novel roles for Rho and Rop in mRNA stability.

Bacteriophage T4 development depends on the physiology of its host Escherichia coli

Several parameters of phage T4 adsorption to and growth in Escherichia coli B/r were determined. All changed monotonously with the bacterial growth rate (mu), which was modified by nutritional conditions. Adsorption rate was faster at higher mu values, positively correlated to cell size, and increased by pretreatment with low penicillin (Pn) concentrations; it was directly proportional to total cellular surface area, indicating a constant density of T4 receptors on cell envelopes irrespective of growth conditions. Parameters of phage development and cell lysis were mu-dependent. The rate of phage release and burst size increased, while the eclipse and latent periods decreased with increasing mu. Differentiation between the contribution of several physiological parameters to the development of T4 was performed by manipulating the host cells. A competitive inhibitor of glucose uptake, methyl alpha-D-glucoside, was exploited to reduce the growth rate in the same effective carbon source. Synchronous cells were obtained by the "baby-machine' and large cells were obtained by pretreatment with low Pn concentrations. Lysis was delayed by superinfection, and DNA content and concentration were modified by growing a thy mutant in limiting thymine concentrations. The results indicate that burst size is not limited by cell size or DNA composition, nor directly by the rate of metabolism, but rather by the rates of synthesis and assembly of phage components and by lysis time. The rates of synthesis and assembly of phage components seem to depend on the content of the protein-synthesizing system and lysis time seems to depend on cellular dimensions.

Either bacteriophage T4 RNase H or Escherichia coli DNA polymerase I is essential for phage replication

Bacteriophage T4 rnh encodes an RNase H that removes ribopentamer primers from nascent DNA chains during synthesis by the T4 multienzyme replication system in vitro (H. C. Hollingsworth and N. G. Nossal, J. Biol. Chem. 266:1888-1897, 1991). This paper demonstrates that either T4 RNase HI or Escherichia coli DNA polymerase I (Pol I) is essential for phage replication. Wild-type T4 phage production was not diminished by the polA12 mutation, which disrupts coordination between the polymerase and the 5'-to-3' nuclease activities of E. coli DNA Pol I, or by an interruption in the gene for E. coli RNase HI. Deleting the C-terminal amino acids 118 to 305 from T4 RNase H reduced phage production to 47% of that of wild-type T4 on a wild-type E. coli host, 10% on an isogenic host defective in RNase H, and less than 0.1% on a polA12 host. The T4 rnh(delta118-305) mutant synthesized DNA at about half the rate of wild-type T4 in the polA12 host. More than 50% of pulse-labelled mutant DNA was in short chains characteristic of Okazaki fragments. Phage production was restored in the nonpermissive host by providing the T4 rnh gene on a plasmid. Thus, T4 RNase H was sufficient to sustain the high rate of T4 DNA synthesis, but E. coli RNase HI and the 5'-to-3' exonuclease of Pol I could substitute to some extent for the T4 enzyme. However, replication was less accurate in the absence of the T4 RNase H, as judged by the increased frequency of acriflavine-resistant mutations after infection of a wild-type host with the T4 rnh (delta118-305) mutant.

In vitro characterization of transcription termination factor Rho from Escherichia coli rho(nusD) mutants

Escherichia coli nusD strains are bacteria that carry mutations in rho, the gene for transcription termination factor Rho, that block the growth of phages T4 and lambdar32. We have identified the rho mutation in six independent nusD strains, and although five of the strains have different mutations, with one exception the mutations are in the proposed RNA-binding domain of Rho. We overexpressed, purified, and characterized the five different mutant Rho proteins. All show substantial RNA-dependent ATPase activity with several homoribopolymers or the lambda cro message as cofactor. At the lambda tR1 Rho-dependent terminator in vitro, all mutant Rho proteins show decreased termination compared with wild-type, and all also terminate within cro at a new terminator, tRE, with endpoints 5' to tR1 at 170, 200, 245 and 260 nucleotides 3' from the transcription start. The mutant Rho proteins are proposed to interfere with bacteriophage T4 growth through indirect effects on host gene expression.

Effects of T4 phage infection and anaerobiosis upon nucleotide pools and mutagenesis in nucleoside diphosphokinase-defective Escherichia coli strains

Bacteriophage T4 encodes nearly all of its own enzymes for synthesizing DNA and its precursors. An exception is nucleoside diphosphokinase (ndk gene product), which catalyzes the synthesis of ribonucleoside triphosphates and deoxyribonucleoside triphosphates (dNTPs) from the corresponding diphosphates. Surprisingly, an Escherichia coli ndk deletion strain grows normally and supports T4 infection. As shown elsewhere, these ndk mutant cells display both a mutator phenotype and deoxyribonucleotide pool abnormalities. However, after T4 infection, both dNTP pools and spontaneous mutation frequencies are near normal. An E. coli strain carrying deletions in ndk and pyrA and pyrF, the structural genes for both pyruvate kinases, also grows and supports T4 infection. We examined anaerobic E. coli cultures because of reports that in anaerobiosis, pyruvate kinase represents the major route for nucleoside triphosphate synthesis in the absence of nucleoside diphosphokinase. The dNTP pool imbalances and the mutator phenotype are less pronounced in the anaerobic than in the corresponding aerobic ndk mutant strains. Anaerobic dNTP pool data, which have not been reported before, reveal a disproportionate reduction in dGTP, relative to the other pools, when aerobic and anaerobic conditions are compared. The finding that mutagenesis and pool imbalances are mitigated in both anaerobic and T4-infected cultures provides strong, if circumstantial, evidence that the mutator phenotype of ndk mutant cells is a result of the dNTP imbalance. Also, the viability of these cells indicates the existence of a second enzyme system in addition to nucleoside diphosphokinase for nucleoside triphosphate synthesis.

Tracing the interaction of bacteriophage with bacterial biofilms using fluorescent and chromogenic probes

Phages T4 and E79 were fluorescently-labeled with rhodamine isothiocyanate (RITC), fluoroscein isothiocyanate (FITC), and by the addition of 4'6-diamidino-2-phenylindole (DAPI) to phage-infected host cells of Escherichia coli and Pseudomonas aeruginosa. Comparisons of electron micrographs with scanning confocal laser microscope (SCLM) images indicated that single RITC-labeled phage particles could be visualized. Biofilms of each bacterium were infected by labeled phage. SCLM and epifluorescence microscopy were used to observe adsorption of phage to single-layer surface-attached bacteria and thicker biofilms. The spread of the recombinant T4 phage, YZA1 (containing an rII-LacZ fusion), within a lac E. coli biofilm could be detected in the presence of chromogenic and fluorogenic homologs of galactose. Infected cells exhibited blue pigmentation and fluorescence from the cleavage products produced by the phage-encoded beta-galactosidase activity. Fluorescent antibodies were used to detect non-labeled progeny phage. Phage T4 infected both surface-attached and surface-associated E. coli while phage E79 adsorbed to P. aeruginosa cells on the surface of the biofilm, but access to cells deep in biofilms was somewhat restricted. Temperature and nutrient concentration did not affect susceptibility to phage infection, but lower temperature and low nutrients extended the time-to-lysis and slowed the spread of infection within the biofilm.

Protection from proteolysis using a T4::T7-RNAP phage expression-packaging-processing system

DNA coding for bacteriophage T7 RNA polymerase (T7-RNAP) was inserted into a positive selection-vector form of the T4 genome, placing it under the control of bacteriophage T4 ipIII promoters. The recombinant T4::T7-RNAP fusion phage retained infectivity and produced T7-RNAP in infected cells. Fusion genes were constructed by insertion into a plasmid containing an iPIII (encoding internal protein III) target portion and a bacteriophage T7 promoter region. When Escherichia coli cells containing the plasmid were infected with the T4::T7-RNAP re-phage, the bacteria produced fusion protein at high levels. The newly synthesized T4::T7-RNAP re-phage progeny package and process the fusion protein into the phage capsid during head morphogenesis. In this paper, we demonstrate that truncated T4 internal protein IPIII, human IPIII::beta Glo (beta-globin) fusion protein, E. coli IPIII::beta Glo::beta Gal (beta-galactosidase) triple-fusion protein and IPIII::V3 fusion protein (human immunodeficiency virus envelope protein gp120 V3 region) are expressed at high levels by T4::T7-RNAP induction. With IPIII::beta Glo, expression-packaging-processing (EPP) occurs simultaneously with T4::T7-RNAP re-phage infection. We also demonstrate that T4::T7-RNAP re-phage stabilize unstable proteins such as the X90 fragment of beta Gal, thought to be degraded by the lon protease. An unstable 20-kDa fragment of the large subunit of human cytochrome b558, an integral membrane protein in phagocytes, is subject to proteolytic degradation even when produced in the lon-deficient BL21 strain. However, upon induction with T4::T7-RNAP re-phage, the 20-kDa protein is produced intact.(ABSTRACT TRUNCATED AT 250 WORDS)

Mutations in HU and IHF affect bacteriophage T4 growth: HimD subunits of IHF appear to function as homodimers

The Escherichia coli nucleoid-associated DNA-binding proteins HU and IHF are required for numerous biological processes, including phage growth (e.g., lambda, phi 80, Mu and f1) and DNA replication. Here, we show that growth of T4 phage is inhibited both in hupA hupB and himA himD double mutants. The growth profile of triple mutants (hupA hupB himA and hupA hupB himD) suggests that HimD subunits can form homodimers, which are functionally competent for supporting in vivo growth of phage T4.