Mutations of corynephage beta that affect the yield of diphtheria toxin

Transcription analysis and nucleotide sequence of tox promoter/operator mutants of corynebacteriophage beta

The production of diphtheria toxin (DT) by Corynebacterium diphtheriae C7 (beta) is transcriptionally regulated by the iron-dependent diphtheria toxin repressor, DtxR. Transcription of the tox gene was studied in wild-type C. diphtheriae C7 (beta) and in lysogens carrying mutants of beta that determine insensitivity to inhibition of DT production by iron. Under low iron conditions in all strains, tox-specific mRNA appeared and DT production began during late-log phase, and they increased to maximal levels at stationary phase. Under high iron conditions, tox-specific mRNA and DT production were strongly repressed in C7 (beta) but only partially repressed in C7 (beta tox-202) and C7 (beta tox-201). Under high and low iron conditions, DT production and tox-specific mRNA levels were greater in C7 (beta tox-201) and C7 (beta tox-202) than in wild-type C7 (beta). Addition of iron or rifampicin to low iron cultures of C. diphtheriae C7 (beta) repressed tox-mRNA production promptly and with a similar time course. In contrast, repression of tox-mRNA synthesis in C. diphtheriae C7 (beta tox-201) occurred promptly after addition of rifampicin but more slowly after addition of iron. Nucleotide sequence analysis revealed single G to A mutations at positions -47 and -48, within the preferred '-10' sequence of the tox promoter, in beta tox-201 and beta tox-202, respectively. The single nucleotide substitutions in the tox-201 and tox-202 regulatory alleles, therefore, have pleiotropic effects, causing increased activity of the promoter and partial resistance of the operator to iron-dependent repression.

Regulation of toxinogenesis in Corynebacterium diphtheriae: mutations in the bacterial genome that alter the effects of iron on toxin production

Mutants of Corynebacterium diphtheriae C7(beta) that are resistant to the inhibitory effects of iron on toxinogenesis were identified by their ability to form colonies surrounded by toxin-antitoxin halos on agar medium containing both antitoxin and a high concentration of iron. Chromosomal mutations were essential for the altered phenotypes of four independently isolated mutant strains. During growth in deferrated liquid medium containing various amounts of added iron, these mutants differed from wild-type C. diphtheriae C7(beta) in several ways. Their growth rates were slower under low-iron conditions and were stimulated to various degrees under high-iron conditions. The concentrations of iron at which optimal toxin production occurred were higher for the mutants than for wild-type C. diphtheriae C7(beta). Toxin production by the mutants during growth in low-iron medium occurred throughout the period of exponential growth at nearly constant rates that were proportional to the bacterial growth rates. In contrast, toxin production by wild-type C. diphtheriae C7(beta) in similar low-iron cultures occurred predominantly during the late exponential phase, when iron was a growth-limiting nutrient. Additional studies demonstrated that these mutants had severe defects in their transport systems for ferric iron. We propose that the altered regulation of toxinogenesis by iron in our mutants was caused by the severe defects in their iron transport systems. As a consequence, the mutants exhibited a low-iron phenotype during growth under conditions that permitted wild-type C. diphtheriae C7(beta) to exhibit a high-iron phenotype.

Regulation of toxinogenesis in Corynebacterium diphtheriae. I. Mutations in bacteriophage beta that alter the effects of iron on toxin production

Diphtherial toxin is produced in maximal yields by Corynebacterium diphtheriae (C7(beta tox+) only when iron is present in growth-limiting amounts. Toxin production is markedly decreased under high-iron conditions. We studied the role of the bacteriophage beta genome in this apparent regulation of toxin production by iron. Using a passive immune hemolysis assay to detect toxin antigen production in individual plaques, we identified rare phage mutants that were toxinogenic in high-iron medium. Lysogenic derivatives of C. diphtheriae C7 harboring such phage mutants were constructed. The lysogens were compared with wild-type strain C7(beta) for their ability to produce toxin in deferrated liquid medium containing varying amounts of added iron. Quantitative tests for extracellular toxin were performed by competitive-binding radioimmunoassays. We identified phenotypically distinct mutant strains that produced slightly, moderately, or greatly increased yields of toxin antigen under high-iron conditions. The toxin produced by the mutant lysogens was biologically active and immunochemically indistinguishable from wild-type toxin. Complementation experiments demonstrated that the phage mutation designated tox-201 had a cis-dominant effect on the expression of the toxin structural gene of phage beta. The characteristics of the tox-201 mutation suggest that it defines a regulatory locus of phage beta that is involved in control of toxinogenesis by iron in C. diphtheriae.