Christine Hogrefe scite author profile

Mutants defective in chemolithoautotrophic growth (Aut-) have been isolated from Alcaligenes eutrophus strains H16, N9A, G27, and TF93. Spontaneous Aut- mutants were obtained only with strain TF93. Mutants of the other strains were selected after conventional mutagenesis or treatment with mitomycin. Most of the mutants, including the spontaneous Aut- strains, lacked hydrogenase activity (Hox-) but possessed the ability to fix carbon dioxide (Cfx+). Agar mating of A. eutrophus H16 with Hox- mutants of the various strains resulted in transconjugants which had recovered the ability to grow autotrophically and to express activity of hydrogenase as examined by enzymatic and immunochemical analysis. Transfer of hydrogen-oxidizing ability occurred in the absence of a mobilizing plasmid such as Rp4. The transfer frequency was particularly high (ca. 10(-2) per donor) when the spontaneous Hox- mutants of strain TF93 were used as recipients. These strains proved to be plasmid free, whereas donors, transconjugants, and the mutagen-treated Hox- mutants contained a large plasmid (molecular weight, 270 +/- 10 X 10(6) revealed by agarose gel electrophoresis. The results allow the conclusion that A. eutrophus H16 harbors a self-transmissible plasmid designated pHG1, which carries information for hydrogen-oxidizing ability.

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Genes of lithoautotrophic metabolism are clustered on the megaplasmid pHG1 in Alcaligenes eutrophus

Kortlüke

Hogrefe

Eberz

et al. 1987

Mol Gen Genet

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Alcaligenes eutrophus hydrogenase genes (Hox)

Hogrefe¹,

Römermann²,

Friedrich³

1984

J Bacteriol

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Mutants of Alcaligenes eutrophus H16 lacking catalytically active soluble hydrogenase (Hos-) grew very slowly lithoautotrophically with hydrogen. Mutants devoid of particulate hydrogenase activity (Hop-) were not affected in growth with hydrogen. The use of Hos-and Hopmutants as donors of hydrogen-oxidizing ability in crosses with plasmid-free recipients impaired in both hydrogenases (Hox-) resulted in transconjugants which had inherited the plasmid and the phenotype of the donor. This indicates that the structural genes which code for the hydrogenases reside on plasmid pHG1. The Hox function of one class of Hoxmutants could not be restored by conjugation. These mutants exhibited a pleiotropic phenotype since they were unable to grow with hydrogen and also failed to grow heterotrophically with nitrate (Hox-Nit-). Nitrate was scarcely utilized as electron acceptor or as nitrogen source. Hox-Nitmutants did not act as recipients but could act as donors of the Hox character. Transconjugants derived from those crosses were Hox+ Nit', indicating that the mutation which leads to the Hox-Nitphenotype maps on the chromosome.Apparently, the product of a chromosomal gene is involved in the expression of plasmid-encoded Hox genes. We observed that the elimination of plasmid pHG1 coincided with the occurrence of multiple resistances to various antibiotics. Since Hox+ transconjugate retained the antibiotic-resistant phenotype, we conclude that this property is not directly plasmid associated.

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Molecular cloning of structural and regulatory hydrogenase (hox) genes of Alcaligenes eutrophus H16

Eberz¹,

Hogrefe²,

Kortlüke³

et al. 1986

J Bacteriol

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Isolation and characterization of megaplasmid DNA from lithoautotrophic bacteria

Hogrefe

Friedrich

1984

Plasmid

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