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. 1997 Jan;179(1):1–8. doi: 10.1128/jb.179.1.1-8.1997

Transcriptional regulation and locations of Agrobacterium tumefaciens genes required for complete catabolism of octopine.

K Cho 1, C Fuqua 1, S C Winans 1
PMCID: PMC178654  PMID: 8981973

Abstract

By screening for octopine-inducible gene expression, we previously identified all the genes required for utilization of octopine as a source of carbon, nitrogen, and energy. They are (i) octopine oxidase, which converts octopine to arginine and pyruvate and is encoded by the ooxAB operon, (ii) arginase, which converts arginine to ornithine and urea and is encoded by arcA, (iii) ornithine cyclodeaminase, which converts ornithine to proline and ammonia and is encoded by the homologous arcB and ocd genes, and (iv) proline dehydrogenase, which converts proline to glutamate and is encoded by putA. Here we describe the regulation and localization of each of these genes. The ooxA-ooxB-ocd operon was previously shown to reside on the Ti plasmid and to be directly inducible by octopine. The arcAB operon is directly inducible by arginine, while it is induced by octopine only in strains that can convert octopine to arginine. Ornithine may also be a direct inducer of arcAB. putA is directly inducible by proline, while induction by octopine and by arginine (and probably by ornithine) requires their conversion to proline. Genetic studies indicate that arcAB and putA are localized on a conjugal genetic element. This element can be transferred to other Agrobacterium tumefaciens strains by a mechanism that does not require recA-dependent homologous recombination. Transfer of this genetic element from A. tumefaciens R10 requires at least one tra gene found on its Ti plasmid, indicating that this element is not self-transmissible but is mobilizable by the Ti plasmid. The DNA containing the arcAB and putA genes comigrates with a 243-kb linear molecular weight standard on field inversion electrophoretic gels.

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Selected References

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