Phage adsorption to Lactobacillus plantarum: influence of physiological and environmental factors.

Bacteriophage infection of lactic acid bacteria (LAB) constitutes one of the major problems in the dairy industry, causing economic losses and a constant risk of low quality and/or unsafe foods. The first step in the phage biology is the adsorption on the host cell surface. In a previous study, a remarkable thermal, chemical and photocatalytic resistance was demonstrated by four phages of Lactobacillus plantarum (ATCC 8014-B1, ATCC 8014-B2, FAGK1 and FAGK2). In the present work, these phages were used to characterize the adsorption process on L. plantarum ATCC 8014. Clearly, the characterization of this process could increase the possibilities of design useful strategies in order to prevent phage infections. The influence of Ca(2+), temperature, pH and physiological cell state on phage adsorption was investigated. Burst sizes of phages ATCC 8014-B1 and ATCC 8014-B2 were 60 and 83 PFU/infective centre, respectively. The four phages exhibited a high infectivity even at pH 4 and pH 11. Calcium or magnesium ions were not indispensable for cell lysis and plaque formation, and more than 99% of phage particles were adsorbed either in the presence or absence of Ca(2+), after 15 min at 37 degrees C. Phage adsorption was only partially affected at 50 degrees C, while reached its maximum between 30 and 42 degrees C. The highest adsorption values (99.9%) were observed from pH 5 to 7, after 30 min at 37 degrees C. Adsorption rates decreased after the thermal inactivation of cells, though, when 20 microg/ml of chloramphenicol was used, adsorption values were similar on treated and untreated cells. All these results showed that the adsorption process was only partially affected by a few conditions: thermally killed host cells, an incubation temperature of 50 degrees C and pH values of 9 and 10. Nevertheless, and unfortunately, those conditions are not commonly applied during fermented food manufacturing, thus restricting highly the application of strategies currently available to reduce phage infections in industrial environments. This work also contributes to increase the currently knowledge on the biological aspects of L. plantarum bacteriophages.

Indirect detection of Bacillus anthracis using real-time PCR to detect amplified gamma phage DNA.

Typical real-time PCR methods used to identify Bacillus anthracis do not distinguish between viable and non-viable spores, which would be critical in any first response and remediation scenarios. This study combined both real-time PCR, using primers specifically designed for gamma phage, with the highly specific gamma phage amplification into one simple assay to indirectly detect Bacillus anthracis. Since the amplification of gamma phage only occurs in the presence of a suitable host, the detection of increasing concentrations of progeny gamma phage DNA using real-time PCR implies the presence of viable Bacillus anthracis cells. This method detected a starting Bacillus anthracis concentration of 207 cfu/mL, equivalent to less than one cell in 20 microL, in less than 5 h.

Molecular approaches to identify and differentiate Bacillus anthracis from phenotypically similar Bacillus species isolates.

BACKGROUND: Bacillus anthracis and Bacillus cereus can usually be distinguished by standard microbiological methods (e.g., motility, hemolysis, penicillin susceptibility and susceptibility to gamma phage) and PCR. However, we have identified 23 Bacillus spp. isolates that gave discrepant results when assayed by standard microbiological methods and PCR. We used multiple-locus variable-number tandem repeat analysis (MLVA), multiple-locus sequence typing (MLST), and phenotypic analysis to characterize these isolates, determine if they cluster phylogenetically and establish whether standard microbiological identification or PCR were associated with false positive/negative results. RESULTS: Six isolates were LRN real-time PCR-positive but resistant to gamma phage; MLVA data supported the identification of these isolates as gamma phage-resistant B. anthracis. Seventeen isolates were LRN real-time PCR-negative but susceptible to gamma phage lysis; these isolates appear to be a group of unusual gamma phage-susceptible B. cereus isolates that are closely related to each other and to B. anthracis. All six B. anthracis MLVA chromosomal loci were amplified from one unusual gamma phage-susceptible, motile, B. cereus isolate (although the amplicons were atypical sizes), and when analyzed phylogenetically, clustered with B. anthracis by MLST. CONCLUSION: MLVA and MLST aided in the identification of these isolates when standard microbiological methods and PCR could not definitely identify or rule out B. anthracis. This study emphasized the need to perform multiple tests when attempting to identify B. anthracis since relying on a single assay remains problematic due to the diverse nature of bacteria.

DNA base composition, susceptibility to bacteriophages and interspecific transformation as criteria for classification in the genus Bacillus.

With 25 strains belonging to 12 species of the genus Bacillus, the base composition of DNA, the susceptibility to bacteriophages, and the ability to transform Bacillus subtilis strain Marburg were studied. Analyses of phage DNAs were also performed. The results were as follows: (1) The DNA base compositions were not uniform even among strains belonging to one taxonomic species. (2) The DNAs extracted from B. natto, B. megaterium and B. polymyxa could transform genetic traits of B. subtilis Marburg although the frequencies were not equal. (3) The host ranges of some temperate bacteriophages were correlated with the taxonomical data. On these bases, the phylogenetic relatedness of B. subtilis to B. megaterium was discussed.

Comparative analysis of bacterial viruses Bam35, infecting a gram-positive host, and PRD1, infecting gram-negative hosts, demonstrates a viral lineage.

Extra- and intracellular viruses in the biosphere outnumber their cellular hosts by at least one order of magnitude. How is this enormous domain of viruses organized? Sampling of the virosphere has been scarce and focused on viruses infecting humans, cultivated plants, and animals as well as those infecting well-studied bacteria. It has been relatively easy to cluster closely related viruses based on their genome sequences. However, it has been impossible to establish long-range evolutionary relationships as sequence homology diminishes. Recent advances in the evaluation of virus architecture by high-resolution structural analysis and elucidation of viral functions have allowed new opportunities for establishment of possible long-range phylogenic relationships-virus lineages. Here, we use a genomic approach to investigate a proposed virus lineage formed by bacteriophage PRD1, infecting gram-negative bacteria, and human adenovirus. The new member of this proposed lineage, bacteriophage Bam35, is morphologically indistinguishable from PRD1. It infects gram-positive hosts that evolutionarily separated from gram-negative bacteria more than one billion years ago. For example, it can be inferred from structural analysis of the coat protein sequence that the fold is very similar to that of PRD1. This and other observations made here support the idea that a common early ancestor for Bam35, PRD1, and adenoviruses existed.

Characterization of poly-gamma-glutamate hydrolase encoded by a bacteriophage genome: possible role in phage infection of Bacillus subtilis encapsulated with poly-gamma-glutamate.

Some Bacillus subtilis strains, including natto (fermented soybeans) starter strains, produce a capsular polypeptide of glutamate with a gamma-linkage, called poly-gamma-glutamate (gamma-PGA). We identified and purified a monomeric 25-kDa degradation enzyme for gamma-PGA (designated gamma-PGA hydrolase, PghP) from bacteriophage PhiNIT1 in B. subtilis host cells. The monomeric PghP internally hydrolyzed gamma-PGA to oligopeptides, which were then specifically converted to tri-, tetra-, and penta-gamma-glutamates. Monoiodoacetate and EDTA both inhibited the PghP activity, but Zn(2+) or Mn(2+) ions fully restored the enzyme activity inhibited by the chelator, suggesting that a cysteine residue(s) and these metal ions participate in the catalytic mechanism of the enzyme. The corresponding pghP gene was cloned and sequenced from the phage genome. The deduced PghP sequence (208 amino acids) with a calculated M(r) of 22,939 was not significantly similar to any known enzyme. Thus, PghP is a novel gamma-glutamyl hydrolase. Whereas phage PhiNIT1 proliferated in B. subtilis cells encapsulated with gamma-PGA, phage BS5 lacking PghP did not survive well on such cells. Moreover, all nine phages that contaminated natto during fermentation produced PghP, supporting the notion that PghP is important in the infection of natto starters that produce gamma-PGA. Analogous to polysaccharide capsules, gamma-PGA appears to serve as a physical barrier to phage absorption. Phages break down the gamma-PGA barrier via PghP so that phage progenies can easily establish infection in encapsulated cells.

Effect of host bacteria genotype on spontaneous reversions of Bacillus subtilis bacteriophage phi29 sus17 nonsense codon.

Gene 17 of Bacillus subtilis bacteriophage Phi29 is an early gene playing a role in DNA replication. Its mutant sus17(112) carries the TAA nonsense triplet at the fifth codon of the gene. We isolated and sequenced 73 spontaneous revertants producing normal-size plaques on bacteria without an informational suppressor gene. In all revertants, the TAA triplet was changed by a one-base substitution and the sequences CAA, AAA, TTA, TAC and TAT were recovered at its place. The spectrum of these mutations was markedly influenced by the genotype of the bacteria in which the revertants arose. In agreement with the results described in Escherichia coli, the ratio of transversions to transitions (CAA being the only transition acceptable) was higher in strains harboring the functional allele recA(+) than in those with recA4. Our results support the idea that also in the Gram-positive B. subtilis, the spectra of spontaneous mutations are specifically modified by an SOS function. It is assumed that the single-stranded DNA chains generated in the course of phage DNA replication might act as an inducing factor.

Bacteriophage phi29 early protein p17 is conditionally required for the first rounds of viral DNA replication.

The gene 17 of the Bacillus subtilis phage phi29 is known to be involved in the viral DNA replication in vivo. In this paper, we show that the presence of protein p17 is required when phage infection occurs at a low multiplicity of infection (moi), which is probably the natural condition for infection, but is dispensable at a high moi. Gene 17 has been cloned in an Escherichia coli expression vector and protein p17 purified. A stimulatory effect of protein p17 was demonstrated under in vitro conditions required to amplify phi29 DNA, starting with a low amount of input DNA. We propose that p17, which is synthesized early after infection, is required at the very beginning of the phage amplification, conditions in which a low number of viral DNA molecules enter the host cell, possibly to recruit the limiting amount of initiation factors at the replication origins. Once the infection process is established and the other replication proteins reach optimal concentration, p17 becomes dispensable.

Initiation of bacteriophage phi29 DNA replication in vivo: assembly of a membrane-associated multiprotein complex.

Initiation of in vitro phage phi29 DNA replication requires the formation of a heterodimer between a free molecule of terminal protein (TP), which acts as primer, and the viral DNA polymerase. We have analyzed membrane vesicles from phi29-infected Bacillus subtilis cells by quantitative immunoblot techniques. During phage DNA synthesis, large amounts of the viral proteins p1 and free TP were recovered in membrane fractions, as well as a low percentage of the total viral DNA polymerase. Interestingly, the amount of DNA polymerase in membrane fractions increased when viral DNA replication was blocked. Both protein p1 and free TP showed affinity for membranes in the absence of viral DNA. The association of protein p1 with membranes was abolished when the C-terminal 43 amino acid residues were deleted. The above results, together with the critical role of protein p1 for in vivo phi29 DNA replication, led us to conclude that a preliminary stage in the initiation of in vivo phi29 DNA replication could be the assembly of a membrane-associated multiprotein complex containing at least protein p1, free TP and DNA polymerase. Membrane-attachment of this complex could be directly mediated by both protein p1 and free TP. The ability of free TP to bind to membranes and to prime phi29 DNA replication would enable a nascent viral DNA molecule to become membrane-associated when its synthesis begins. We postulate that a general function of the TPs covalently linked to linear DNA genomes in prokaryotes might be, in addition to act as primer, to anchor the linear DNA molecule to the bacterial membrane.

Sequential headful packaging and fate of the cleaved DNA ends in bacteriophage SPP1.

The virulent Bacillus subtilis bacteriophage SPP1 packages its DNA from a precursor concatemer by a headful mechanism. Following disruption of mature virions with chelating agents the chromosome end produced by the headful cut remains stably bound to the phage tail. Cleavage of this tail-chromosome complex with restriction endonucleases that recognize single asymmetric positions within the SPP1 genome yields several distinct classes of DNA molecules whose size reflects the packaging cycle they were generated from. A continuous decrease in the number of molecules within each class derived from successive encapsidation rounds indicates that there are several packaging series which end after each headful packaging cycle. The frequency of molecules in each packaging class follows the distribution expected for a sequential mechanism initiated unidirectionally at a defined position in the genome (pac). The heterogeneity of the DNA fragment sizes within each class reveals an imprecision in headful cleavage of approximately 2.5 kb (5.6% of the genome size). The number of encapsidation events in a packaging series (processivity) was observed to increase with time during the infection process. DNA ejection through the tail can be induced in vitro by a variety of mild denaturing conditions. The first DNA extremity to exit the virion is invariably the same that was observed to be bound to the tail, implying that the viral chromosome is ejected with a specific polarity to penetrate the host. In mature virions a short segment of this chromosome end (55 to 67 bp equivalent to 187 to 288 A) is fixed to the tail area proximal to the head (connector). Upon ejection this extremity is the first to move along the tail tube to exit from the virion through the region where the tail spike was attached.

[Inhibition of phagolysis in a Bacillus thuringiensis culture by chitosan]. / Ingibirovanie khitozanom fagolizisa kul'tury Bacillus thuringiensis.

The ability of chitosan (poly-D-glucosamine) and two chitosan salts to prevent the phagolysis of Bacillus thuringiensis subsp. galleriae strain 1-97 was studied. Chitosan and its salts inhibited the productive infection caused by two nonrelated bacteriophages 1-97A and 1-97B and suppressed the culture lysis upon spontaneous prophage induction. The efficiency of inhibition depended on the chitosan concentration, medium composition, and bacteriophage type.

In vitro assembly of infectious virions of double-stranded DNA phage phi 29 from cloned gene products and synthetic nucleic acids.

Up to 6 x 10(7) PFU of infectious virions of the double-stranded DNA bacteriophage phi 29 per ml were assembled in vitro, with 11 proteins derived from cloned genes and nucleic acids synthesized separately. The genomic DNA-gp3 protein conjugate was efficiently packaged into a purified recombinant procapsid with the aid of a small viral RNA (pRNA) transcript, a DNA-packaging ATPase (gp16), and ATP. The DNA-filled capsids were subsequently converted into infectious virions after the addition of four more recombinant proteins for neck and tail assembly. Electron microscopy and genome restriction mapping confirmed the identity of the infectious phi 29 virions synthesized in this system. A nonstructural protein, gp13, was indispensable for the assembly of infectious virions. The overproduced tail protein gp9 was present in solution in mostly dimeric form and was purified to homogeneity. The purified gp9 was biologically active for in vitro phi 29 assembly. Higher-order concentration dependence of in vitro phi 29 assembly on gp9 suggests that a complete tail did not form before attaching to the DNA-filled capsid, a result contrary to earlier findings for phages T4 and lambda. The work described here constitutes an extremely sensitive assay system for the analysis of components in phi 29 assembly and dissection of functional domains of structural components, enzymes, and pRNA (C.-S. Lee and P. Guo, Virology 202:1039-1042, 1995). Efficient packaging of foreign DNA in vitro and synthesis of viral particles from recombinant proteins facilitate the development of phi 29 as an in vivo gene delivery system. The finding that purified tail protein was able to incorporate into infectious virions might allow the construction of chimeric phi 29 carrying a tail fused to ligands for specific receptor of human cells.

Genes that protect against the host-killing activity of the E3 protein of Bacillus subtilis bacteriophage SPO1.

A cloned rpoB gene, specifying an apparently mutant RNA polymerase beta subunit, protected Escherichia coli against the cytocidal effects of the E3 protein of bacteriophage SPO1, suggesting that RNA polymerase is the primary cellular target of the E3 protein. Two segments of the wild-type E. coli genome, one of which specifies a suppressor of dnaK mutations, and thus, possibly, a molecular chaperone, also provided protection when overexpressed, but wild-type rpoB did not.