Sense codon reassignment enables viral resistance and encoded polymer synthesis.

It is widely hypothesized that removing cellular transfer RNAs (tRNAs)-making their cognate codons unreadable-might create a genetic firewall to viral infection and enable sense codon reassignment. However, it has been impossible to test these hypotheses. In this work, following synonymous codon compression and laboratory evolution in Escherichia coli, we deleted the tRNAs and release factor 1, which normally decode two sense codons and a stop codon; the resulting cells could not read the canonical genetic code and were completely resistant to a cocktail of viruses. We reassigned these codons to enable the efficient synthesis of proteins containing three distinct noncanonical amino acids. Notably, we demonstrate the facile reprogramming of our cells for the encoded translation of diverse noncanonical heteropolymers and macrocycles.

Microbial inactivation and cytotoxicity evaluation of UV irradiated coconut water in a novel continuous flow spiral reactor.

A continuous-flow UV reactor operating at 254nm wave-length was used to investigate inactivation of microorganisms including bacteriophage in coconut water, a highly opaque liquid food. UV-C inactivation kinetics of two surrogate viruses (MS2, T1UV) and three bacteria (E. coli ATCC 25922, Salmonella Typhimurium ATCC 13311, Listeria monocytogenes ATCC 19115) in buffer and coconut water were investigated (D10 values ranging from 2.82 to 4.54mJ·cm-2). A series of known UV-C doses were delivered to the samples. Inactivation levels of all organisms were linearly proportional to UV-C dose (r2>0.97). At the highest dose of 30mJ·cm-2, the three pathogenic organisms were inactivated by >5 log10 (p<0.05). Results clearly demonstrated that UV-C irradiation effectively inactivated bacteriophage and pathogenic microbes in coconut water. The inactivation kinetics of microorganisms were best described by log linear model with a low root mean square error (RMSE) and high coefficient of determination (r2>0.97). Models for predicting log reduction as a function of UV-C irradiation dose were found to be significant (p<0.05) with low RMSE and high r2. The irradiated coconut water showed no cytotoxic effects on normal human intestinal cells and normal mouse liver cells. Overall, these results indicated that UV-C treatment did not generate cytotoxic compounds in the coconut water. This study clearly demonstrated that high levels of inactivation of pathogens can be achieved in coconut water, and suggested potential method for UV-C treatment of other liquid foods. INDUSTRIAL RELEVANCE: This research paper provides scientific evidence of the potential benefits of UV-C irradiation in inactivating bacterial and viral surrogates at commercially relevant doses of 0-120mJ·cm-2. The irradiated coconut water showed no cytotoxic effects on normal intestinal and healthy mice liver cells. UV-C irradiation is an attractive food preservation technology and offers opportunities for horticultural and food processing industries to meet the growing demand from consumers for healthier and safe food products. This study would provide technical support for commercialization of UV-C treatment of beverages.

Bacteriophage-host interaction: from splendid isolation into a messy reality.

In the reductionist era T-type coliphage research became one of the foundations for molecular biology. The technological progress in systems biology makes it now possible to study T-type phage-Escherichia coli interaction in the natural ecological niche, the gut of warm blooded animals. This development gives a second chance to phages as anti-microbial agents ('phage therapy'). Bacteria growing in biofilms are difficult to treat with antibiotics while many phages express naturally depolymerases which attack the polysaccharide matrix that enmesh bacteria in biofilms. Phages were already used successfully to reduce contamination levels with medical catheters and might likewise be of use against infections frequently forming bacterial biofilms.

Ingestion and inactivation of bacteriophages by Tetrahymena.

Abiotic factors are thought to be primarily responsible for the loss of bacteriophages from the environment, but ingestion of phages by heterotrophs may also play a role in their elimination. Tetrahymena thermophila has been shown to ingest and inactivate bacteriophage T4 in co-incubation experiments. In this study, other Tetrahymena species were co-incubated with T4 with similar results. In addition, T. thermophila was shown to inactivate phages T5 and lambda in co-incubations. Several approaches, including direct visualization by electron microscopy, demonstrated that ingestion is required for T4 inactivation. Mucocysts were shown to have no role in the ingestion of T4. When (35)S-labeled T4 were fed to T. thermophila in a pulse-chase experiment, the degradation of two putative capsid proteins, gp23(*) and hoc, was observed. In addition, a polypeptide with the apparent molecular mass of 52 kDa was synthesized. This suggests that Tetrahymena can use phages as a minor nutrient source in the absence of bacteria.

A FhuA mutant of Escherichia coli is infected by phage T1-independent of TonB.

Infection of Escherichia coli K-12 by phages T1 and phi 80 requires the FhuA outer membrane protein and the TonB protein. Mutations in the N-terminal globular domain close to the predicted channel in the beta-barrel of FhuA were created. The FhuA Delta 107-111 N104K K110D L111P mutant and the FhuA(L(109)DPNGLK(110)) insertion mutant were sensitive to phage T1, but nearly resistant to phage phi 80. FhuA Delta 107-111 N104K K110D L111P mediated phage T1 infection in a tonB mutant without formation of TonB-independent phage T1 host-range mutants. The FhuA mutants showed no altered sensitivity to phage T5. Although the phages share overlapping binding sites in FhuA, the structural alterations elicited by the mutations resulted in very different phage sensitivities. In the FhuA deletion mutant, the TonB requirement for phage T1 infection was partially bypassed.

Effect of denture cleaner using ozone against methicillin-resistant Staphylococcus aureus and E. coli T1 phage.

We examined the bactericidal and virucidal effectiveness of a denture cleaner that uses ozone (ozone concentration, 10 ppm) against methicillin-resistant Staphylococcus aureus (MRSA) and T1 phage, respectively. In the bactericidal activity test, with the ozone supply turned on, the number of bacteria was 3.1 x 10(3) CFU/mL at the beginning of the experiment, fell to 1.0 x 10(0) CFU/mL 10 min later, and was 1.0 x 10(0) CFU/mL or less afterwards. In contrast, when the ozone supply was cut off (air bubble only), the number of bacteria was 3.4 x 10(3) CFU/mL at the beginning of the experiment, and had fallen to 3.0 x 10(3) CFU/mL 60 min later (no statistically significant difference). In the virucidal activity test, the number of phages was 1.2 x 10(6) PFU/mL before ozone treatment, fell to about 1/10 of that number 10 min later, and was 6.1 x 10(0) PFU/mL 40 min later. These results indicate that the use of ozone in this denture cleaner is effective against MRSA and viruses.

Bacteriophage latent-period evolution as a response to resource availability.

Bacteriophages (phages) modify microbial communities by lysing hosts, transferring genetic material, and effecting lysogenic conversion. To understand how natural communities are affected it is important to develop predictive models. Here we consider how variation between models--in eclipse period, latent period, adsorption constant, burst size, the handling of differences in host quantity and host quality, and in modeling strategy--can affect predictions. First we compare two published models of phage growth, which differ primarily in terms of how they model the kinetics of phage adsorption; one is a computer simulation and the other is an explicit calculation. At higher host quantities (approximately 10(8) cells/ml), both models closely predict experimentally determined phage population growth rates. At lower host quantities (10(7) cells/ml), the computer simulation continues to closely predict phage growth rates, but the explicit model does not. Next we concentrate on predictions of latent-period optima. A latent-period optimum is the latent period that maximizes the population growth of a specific phage growing in the presence of a specific quantity and quality of host cells. Both models predict similar latent-period optima at higher host densities (e.g., 17 min at 10(8) cells/ml). At lower host densities, however, the computer simulation predicts latent-period optima that are much shorter than those suggested by explicit calculations (e.g., 90 versus 1,250 min at 10(5) cells/ml). Finally, we consider the impact of host quality on phage latent-period evolution. By taking care to differentiate latent-period phenotypic plasticity from latent-period evolution, we argue that the impact of host quality on phage latent-period evolution may be relatively small.

Enhancement of solar water pasteurization with reflectors.

A simple and reliable method that could be used in developing countries to pasteurize milk and water with solar energy is described. A cardboard reflector directs sunshine onto a black jar, heating water to pasteurizing temperatures in several hours. A reusable water pasteurization indicator verifies that pasteurization temperatures have been reached.

Phage inhibition, colicin resistance, and tellurite resistance are encoded by a single cluster of genes on the IncHI2 plasmid R478.

A region of the IncHI2 plasmid R478, encoding the phenotypes of tellurite resistance (Ter), phage inhibition (Phi), and colicin resistance (PacB), was cloned and sequenced. Analysis indicated seven open reading frames (ORFs), whose genes were designated terZ, -A, -B, -C, -D, -E, and -F. Five of these predicted ORFs (A to E) had extensive amino acid homology with the previously reported ORFs of the IncHI2 Ter operon from plasmid pMER610. There were domains of highly conserved amino acid residues within the group TerA, -D, -E, and -F and within TerD, -E, and -Z, but no consensus could be found among all five putative polypeptides. There were also regions of good identity and similarity between individual pairs of ORFs which was not reflected in the multiple alignments. The three phenotypes were expressed in Escherichia coli DH5 alpha by an 8.4-kb EcoRI insert subcloned from a cosmid of R478. The latter insert was clonable only as a double insertion with a 4.5-kb fragment, and forced deletion of the smaller fragment was lethal to cells. This lethality was not dependent on the cloned orientation of either fragment, suggesting that there is a trans-acting element in the 4.5-kb fragment. Tn1000 mutagenesis of one of the double-insert clones, pDT2575, showed that the phenotypes, including multiple colicin resistance, were genetically linked. Transpositions into terD, terC, and terZ reduced or abolished all phenotypes, while inserts into terE and terF had no effect on the phenotypes. Insertions in terA reduced phage inhibition levels only. The presence of the terZ and terF ORFs in pMER610 was confirmed, and derivatives of this plasmid mediated Phi, PacB, and Ter.

The tail of a chaperonin: the C-terminal region of Escherichia coli GroEL protein.

The active form of the HSP60 molecular chaperone of Escherichia coli, GroEL, is a pair of seven-membered rings. We have used site-directed mutagenesis to construct forms of the 547-amino-acid monomer truncated at the C-terminus. We show here that forms that are 520 amino acids long or longer are close to being fully functional. Removing one further amino acid, however, results in a protein, GroEL519, which retains little function. This truncated form is metabolically stable but is not recovered from the cell in particle form. When synthesized at high levels, it prevents the normal assembly of GroEL547 present in the same cell. When synthesized at low levels, it can be included, probably at low molar ratios, in particles formed by assembly-competent forms of GroEL. This can be seen as partial complementation of the temperature-sensitive mutant groEL44. We conclude that amino acid 520 is crucial for particle assembly. GroEL516 has in vivo properties similar to those of GroEL516 has in vivo properties similar to those of GroEL519, but the still shorter form, GroEL504, appears to be inactive.

Inactivation of FhuA at the cell surface of Escherichia coli K-12 by a phage T5 lipoprotein at the periplasmic face of the outer membrane.

Inactivation of phage T5 by lysed cells after phage multiplication is prevented by a phage-encoded lipoprotein (Llp) that inactivates the FhuA outer membrane receptor protein (K. Decker, V. Krauel, A. Meesmann, and K. Heller, Mol. Microbiol. 12:321-332, 1994). Using FhuA derivatives carrying insertions of 4 and 16 amino acid residues and point mutations, we determined whether FhuA inactivation is caused by binding of Llp to FhuA and which regions of FhuA are important for inactivation by Llp. Cells expressing Llp were resistant not only to phage T5 but to all FhuA ligands tested, such as phage phi 80, colicin M, and albomycin, and they were strongly reduced in the uptake of ferrichrome. Most of the FhuA derivatives which were not affected by Llp were, according to a previously published FhuA transmembrane topology model, located in periplasmic turns and in the TonB box close to the periplasm. Since the ligands bind to the cell surface, interaction of FhuA with Llp in the periplasm may induce a FhuA conformation which impairs binding of the ligands. This conclusion was supported by the increase rather than decrease of colicin M sensitivity of two mutants in the presence of Llp. The only Llp-resistant FhuA derivatives with mutations at the cell surface contained insertions of 16 residues in the loop that determines the permeability of the FhuA channel and serves as the principal binding site for all FhuA ligands. This region may be inactivated by steric hindrance in that a portion of Llp penetrates into the channel. Outer membranes prepared with 0.25% Triton X-100 from cells expressing Llp contained inactivated FhuA, suggesting Llp to be an outer membrane protein whose interaction with FhuA was not abolished by Triton X-100. Llp solubilized in 1.1% octylglucoside prevented T5 inactivation by FhuA dissolved in octylglucoside.

Bacteriophage T4 encodes a co-chaperonin that can substitute for Escherichia coli GroES in protein folding.

Several bacteriophages use the Escherichia coli GroES and GroEL chaperonins for folding and assembly of their morphogenetic structures. Bacteriophage T4 is unusual in that it encodes a specialized protein (Gp31) that is thought to interact with the host GroEL and to be absolutely required for the correct assembly of the major capsid protein (Gp23) in vivo. Here we show that despite the absence of amino-acid sequence similarity between Gp31 and GroES, Gp31 can functionally substitute for the GroES co-chaperonin in the morphogenesis of bacteriophages lambda and T5, the in vivo and in vitro chaperonin-dependent assembly of ribulose bisphosphate carboxylase (Rubisco), as well as overall bacterial growth at the non-permissive temperature. Like GroES, the bacteriophage Gp31 protein forms a stable complex with the E. coli GroEL protein in the presence of Mg-ATP and inhibits the ATPase activity of GroEL in vitro.

DNA packaging ATPase of bacteriophage T3.

A defined in vitro DNA packaging system of phage T3, which is composed of purified proheads and two packaging proteins, the products of genes 18 and 19 (gp18 and gp19, respectively), displayed a DNA-dependent ATPase activity. ATP was hydrolyzed to ADP and Pi. The ATPase activity was stimulated by nonpackageable DNA, such as single-stranded or circular DNA, or RNA (nonpac-ATPase). Among the inhibitors of DNA packaging, actinomycin D specifically inhibited the ATPase activity that was tightly coupled to DNA packaging (pac-ATPase), but did not inhibit the nonpac-ATPase activity. Both activities depended upon a functional packaging complex, but the nonpac-ATPase, once activated, did not require DNA. Unpackageable pUC18 DNA inhibited the pac-ATPase and the phage yield in parallel. Approximately one molecule of ATP was hydrolyzed during the translocation of 1.8 bp of T3 DNA.

Sequence analysis and phenotypic characterization of groEL mutations that block lambda and T4 bacteriophage growth.

The groES and groEL genes of Escherichia coli have been shown previously to belong to a single operon under heat shock regulation. Both proteins have been universally conserved in nature, as judged by the presence of similar proteins throughout evolution. The GroEL protein has been shown to bind promiscuously to many unfolded proteins, thus preventing their aggregation. ATP hydrolysis by GroEL results in the release of the bound polypeptides, a process that often requires the action of GroES. In an effort to understand GroEL and GroES structure and function, we have determined the nucleotide changes of nine mutant alleles of groEL. All of these mutant alleles were isolated because they block bacteriophage lambda growth. Our sequencing results demonstrate that (i) many of these alleles are identical, in spite of the fact that they were independently isolated, and (ii) most of the different alleles are clustered in the same region of the gene. One of the mutant alleles was shown to possess two nucleotide alterations in the groEL coding phase, one of which is located in a putative ATP-binding domain. The two nucleotide changes were separated by genetic engineering, and each individual change was shown to exert an effect on bacteriophage growth. But, using genetic analyses, we demonstrate that the restriction on bacterial growth at elevated temperatures is conferred only by the mutation within the putative ATP-binding domain. We have cloned the mutant alleles on multicopy plasmids and overexpressed their products. By testing for the ability of bacteriophage either to propagate or to form colonies at 43 degrees C, we have been able to divide the mutant proteins into those with no activity and those with residual activity under the various conditions tested.

DNA sequences necessary for packaging bacteriophage T3 DNA.

A recombinant plasmid, pUCE1-TR, carrying a target for processing of the concatemer joint (TR) and sequences to the left of the target (E1), is efficiently packaged into transducing particles during T3 phage infection. Using this plasmid packaging/transduction system, the minimal sequences necessary for packaging of T3 DNA were determined. The TR sequence contains the targets for initiation cleavage and termination cleavage of concatemer processing (pacCR and pacCL, respectively). A plasmid lacking pacCL was packaged as efficiently as pUCE1-TR but one deleted for pacCR was packaged at a very low efficiency, showing that pacCR is essential for production of transducers but that pacCL is dispensable. DNA from transducing particles carrying a recombinant plasmid lacking pacCL or pacCR had the same right or left end as T3 DNA, respectively, but its other end was not unique. In the absence of pacCL, packaging is initiated from the DNA end created by cleavage at the pacCR and terminated at any sequence after packaging a headful of DNA. In the absence of pacCR, packaging is initiated from the DNA end created by nonspecific, inefficient cleavage and terminated by cleavage at the pacCL after packaging a headful of DNA. A 23-bp segment flanking the site where the mature right end is formed was found to support efficient formation of transducing particles. A 53-bp sequence, including a consensus sequence for the promoter for T3 RNA polymerase, was a responsible element in the E1 sequence for packaging of plasmid DNA. Deletions of the 5'-upstream sequence of the promoter sequence from the left decreased the promoter and packaging activities in parallel, but with those of the 3'-downstream sequence from the right, the packaging activity was impaired before the promoter activity, indicating that transcription from the promoter is necessary but not sufficient for T3 DNA packaging.

Involvement of phage T5 tail proteins and contact sites between the outer and inner membrane of Escherichia coli in phage T5 DNA injection.

The penetration of phage T5 DNA into the Escherichia coli envelope takes place through ion channels (Boulanger, P., and Letellier, L. (1992) J. Biol. Chem. 267, 3168-3172). To identify putative phage protein(s) involved in the formation of these channels, E. coli cells were infected at 37 degrees C with radioactively labeled phage and their envelopes were fractionated. After a flotation gradient, proteins belonging to the phage tail were recovered both in fractions containing the contact sites between the inner and outer membranes and in the outer membrane. The electrophoretic banding pattern of phage proteins indicates that the contact sites were enriched in the protein pb2. Moreover, infected cells were significantly enriched in contact sites as compared to intact cells. There was no enrichment of contact sites and very little radioactivity was found in this fraction and in the outer membrane when the cells were infected at 4 degrees C (i.e. under conditions where the phage does not inject its DNA). These results suggest that both contact sites and pb2 may play a central role in the translocation of phage T5 DNA.

Partial characterization of coliphage WPK and a comparison with coliphage T3.

Coliphage WPK was originally isolated from sewage in Kiel, Germany, because its plaque diameter continued to expand for days. Electron microscopy revealed an isometric capsid with dimensions of 54 nm between opposite apices, and a short, noncontractile tail 16 nm long, placing phage WPK into morphogroup C1. The nucleic acid of phage WPK was linear double stranded DNA. The host ranges of phages WPK and T3 were identical. Of ten E. coli strains tested for host range, two were resistant and of eighteen other Enterobacteriaceae only four were susceptible. Seven gram-negative species which are not members of the Enterobacteriaceae were refractory. However, there were differences in plaque morphology and plaque expansion between the two phages. Phage T3 plaques expanded for at least seven days on E. coli B only, while phage WPK plaques expanded for at least seven days on four strains of E. coli. The buoyant density of WPK, determined by isopycnic density gradient centrifugation in CsCl, was 1,508 g/ml which was significantly different than that of T3 at 1.493 g/ml (P less than 0.05). Phage-encoded proteins were examined for each phage using [35S]methionine incorporation, SDS-PAGE, and autoradiography. Of thirty proteins identified in phage WPK and twenty-eight in phage T3, only fourteen were of the same size in both. We concluded that phage WPK was distinct, but related to T3.

Bacteriophage T7 morphogenesis and gene 10 frameshifting in Escherichia coli showing different degrees of ribosomal fidelity.

Bacteriophage T7 infection has been studied in Escherichia coli strains showing both increased and decreased ribosome fidelity and in the presence of streptomycin, which stimulates translational misreading, in an effort to determine effects on the apparent programmed translational frameshift that occurs during synthesis of the gene 10 capsid protein. Quantitation of the protein bands from SDS-PAGE failed to detect any significant effects on the amounts of the shifted 10B protein relative to the in-frame 10A protein under all fidelity conditions tested. However, any changes in fidelity conditions led to inhibition of phage morphogenesis in single-step growth experiments, which could not be accounted for by reduced amounts of phage protein synthesis, nor, at least in the case of decreased accuracy, by reduced amounts of phage DNA synthesis. Reduction in phage DNA synthesis did appear to account for a substantial proportion of the reduction in phage yield seen under conditions of increased accuracy. Similar effects of varying ribosomal fidelity on growth were also seen with phage T3, and to a lesser extent with phage T4. The absence of change in the high-frequency T7 gene 10 frameshift differs from earlier reports that ribosomal fidelity affects low-frequency frameshift errors.