A prophage map for corynebacteriophage beta consisting of seven markers has been constructed and compared with the vegetative map. The mapping system utilizes heteroimmune double lysogens and capitalizes on the fact that these double lysogens are very unstable and throw off monolysogenic segregants. The prophage map, produced by characterizing the recombinant phage in these monolysogenic segregants, appears to be a cyclic permutation of the vegetative map with the gene for toxin at one end of the prophage map and the gene for phage immunity at the other. This permutation is in accord with the Campbell model for insertion of lambda phage if a site between the toxin and immunity genes in the vegetative map is designated as the phage attachment site. The position of the gene for toxin in the prophage map suggests that converting phages may have originated as specialized transducing phages for this gene.
Plasmids were isolated from erythromycin-resistant Corynebacterium diphtheriae and skin coryneforms. Six erythromycin-resistant C. diphtheriae strains, isolated from cutaneous lesions, all contained a 9.5-megadalton (Mdal) plasmid. Loss of resistance was associated with the deletion of a 1-Mdal segment from the plasmid or, less frequently, with loss of the plasmid. Two erythromycin-resistant diphtheroids were isolated from similar skin lesions. One contained a 38-Mdal plasmid that was lost in the conversion to erythromycin susceptibiliy. The other diphtheroid contained a 30- and a 14-Mdal plasmid. Erythromycin-susceptible derivatives of this strain were not recovered. Restriction enzyme analysis indicated that the 9.5-Mdal plasmids in the C. diphtheriae strains are very similar, if not identical, and that each of the deleted plasmids has lost the same 1-Mdal segment. However, the restriction patterns of the plasmids in the two diphtheroids are not closely related to each other nor to the plasmids in the C. diphtheriae strains.
It was reported by Freeman (1951) and Freeman and Morse (1952) that exposure of certain nontoiigenic strains of Corynebacterium diphtheriae to specific bacteriophage resulted in the appearance of toxigenic C. diphtheriae which were
, AND N. B. GROMAN. In vitro inhibition of diphtheria toxin action by ammonium salts and amines. J. Bacteriol. 90:1552-1556. 1965.-An inhibitor for diphtheria toxin action on HeLa cells was demonstrated in the growth supernatant fractions of both toxinogenic and nontoxinogenic strains of Corynebacterium diphtheriae and in the Mueller and Miller medium in which these organisms were grown. The inhibitor in the growth supernatant fractions of the nontoxinogenic strain was dialyzable, stable to autoclaving, and stable on storage in the refrigerator for a period of many months, but was destroyed by ashing. When the components of Mueller and Miller medium were analyzed, only the Casamino Acids proved inhibitory. Further study with artificial mixtures of amino acids revealed that glutamine alone inhibited toxin. It was subsequently shown that ammonium salts and the aliphatic amines, glyeamine and prolamine, could also function as inhibitors. Histamine and 16 amino acids tested individually were ineffective. The effectiveness of the amines and the ineffectiveness of sodium or potassium ions indicates that there is a specific requirement for inhibition.
The transfection and transformation of members of two species of pathogenic corynebacteria, Corynebacterium diphtheriae and Corynebacterium ulcerans, is described. Protoplasts were produced by treatment with lysozyme following growth in glycine, and a medium was defined on which a significant fraction of the osmotically sensitive cells were regenerated. Transfections were carried out with DNA from corynephage 782, a member of the .3 family of converting phages, and transformations were performed with DNA of plasmid pNG2, a 9500-kDa plasmid that was isolated from an erythromycin-resistant strain of C. diphtheriae and carries the resistance gene. Strains of Corynebacterium glutamicum and Escherichia coli were also successfully transformed with pNG2 DNA. Transfection frequencies were in the range of 3-8 x 103 plaque-forming units/pg of phage DNA, and transformation frequencies were in the range of 0.2-150 colony-forming units/
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