Quantitative evaluation of the adhesive activity of Vibrio cholerae with various degrees of virulence

In the studies on the evaluation of V. cholerae adhesion on suckling rabbits by our method, the adhesive activity of the vibrios has been found to be directly related to their virulence. This method may be used as an additional test for the differentiation of virulent and avirulent V. cholerae.     

Discriminative effect of rifampin of RNA replication of various RNA bacteriophages.

Rifampin interferes exclusively with RNA replication in vivo of the group I phages MS2, f2, and R17, whereas QbetaRNA replication is unaffected by the drug. In addition, rifampin has a discriminative effect of group I phage RNA replication. In the experimental system employed by us the antibiotic differentially interferes with the synthesis of minus RNA strands in f2, whereas it has almost no effect on the synthesis of progeny plus strands. In MS2, the drug differentially arrests the synthesis of progeny plus strands and almost fails to affect the synthesis of minus RNA strands. In R17 both steps of its RNA replication are affected by rifampin, although each step is only partially (approximately 50%) inhibited. The relation of the present results to the possible role of bacterial proteins and tertiary structure of phage RNA in the process of template recognition is discussed.     

Flagella-specific bacteriophages of Agrobacterium tumefaciens: demonstration of virulence of nonmotile mutants

Bacteriophages GS2 and GS6 for Agrobacterium tumefaciens were shown by electron microscopy to adsorb to flagella. This specificity was confirmed by the finding that phage-resistant mutants were nonmotile. Such mutants retained tumor-inducing virulence and ability to attach to plant cells, indicating that motility was not required for these properties. Both phages had contractile tails and appeared similar in the electron microscope.     

Common themes among bacteriophage-encoded virulence factors and diversity among the bacteriophages involved

There are common themes among bacteriophage-encoded virulence factors, which include the well-characterized bacterial toxins and proteins that alter antigenicity as well as several new classes of bacteriophage-encoded proteins such as superantigens, effectors translocated by a type III secretion system, and proteins required for intracellular survival and host cell attachment. These virulence factors are encoded by a diversity of bacteriophages, members of the viral families Siphoviridae, Podoviridae, Myoviridae and Inoviridae, with some bacteriophages having characteristics of more than one virus family. The location of virulence genes within the bacteriophage genomes is non-random and consistent with an origin via imprecise prophage excision or as either transferable cassettes or integral components of the bacteriophage genome.     

A role for bacteriophages in the evolution and transfer of bacterial virulence determinants

A virulence-associated region in the genome of Dichelobacter nodosus has been shown to contain an integrase gene which is highly related to the integrases of Shigella flexneri phage Sf6 and coliphages P4 and φR73, together with open reading frames ( vapB, C and D ) related to genes borne on plasmids in Neisseria gonorrhoeae, Escherichia coli, Actinobacillus actinomycetemcomitans and Treponema denticola . Similar to P4 and φR73, the vap region is bracketed by putative bacteriophage att sites and is adjacent to a tRNA gene, which suggests that the vap region has been derived by the integration of a bacteriophage, or a plasmid carrying a bacteriophage-related integrase gene. Many similarities in genes and genes clusters encoding virulence determinants have been found in distantly related bacteria. These genes are often located on plasmids in one organism but on the chromosome in others, implying that transmission of the genes has been followed by integration. Thus, the events which have generated the vap regions of D. nodosus may represent a common mechanism for transfer of virulence determinants. A number of genes involved in the virulence of bacterial pathogens are found on integrated bacteriophages, and we suggest that others will prove to be associated with tRNA genes and/or integrase genes derived from bacteriophages. The use of tRNA genes as integration sites for many bacteriophages and plasmids may favour intergeneric transmission, as tRNA genes are highly conserved.     

Packaging of genomes in bacteriophages: a comparison of ssRNA bacteriophages and dsDNA bacteriophages.

In complex DNA bacteriophages like lambda, T4, T7, P22, P2, the DNA is packaged into a preformed precursor particle which sometimes has a smaller size and often a shape different from that of the phage head. This packaging mechanism is different from the one suggested for the RNA phages, according to which RNA nucleates the shell formation. The different mechanisms could be understood by comparing the genomes to be packaged: single stranded fII RNA has a very compact structure with high helix content. It might easily form quasispherical structures in solution (as seen in the electron microscope by Thach & Thach (1973)) around which the capsid could assemble. Double stranded phage DNA, on the other hand, is a rigid molecule which occupies a large volume in solution and has to be concentrated 15-fold during packaging into the preformed capsid, and the change in the capsid structure observed hereby might provide the necessary DNA condensation energy.     

Effect of 1,3,5-triazines on various bacteriophages and their hosts]

In the agar diffusion test 24 triazines were investigated with regard to their action on the mulplication of DNA phages (lambda and LPP-1) and RNA phages (M12 and Qbeta). In several cases the amount of plaques was diminished or increased depending on the kind of triazine and virus. The investigations demonstrate the triazines to be able to interfere with the formation of plaques by virulent and temperate viruses of procaryotes.