Summary
Two classes of mutants ofXanthomonas campestris B1459 were isolated that accumulate more xanthan gum than the parental wild-type in culture broths of shake flask cultures and both batch and fed-batch fermentations. The first mutant class was resistant to the antibiotic rifampicin and accumulated, on average, about 20% more xanthan gum than wild-type. The second mutant class, a derivative of the first, was resistant to both bacitracin and rifampicin, and accumulated about 10% more xanthan than its parent. On a weight basis, the viscosities of the polysaccharides made by each strain were not distinguishable. Only a subset of the drug-resistant mutants were overproducers of xanthan. The biochemical basis for the overproduction of xanthan by the mutant strains has not been determined. Both new strains served as recipients for recombinant plasmids bearing ‘xanthan’ genes and further augmented the effects of multiple copies of those genes on xanthan productivity.
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Marquet, M., Mikolajczak, M., Thorne, L. et al. Improved strains for production of xanthan gum by fermentation ofXanthomonas campestris . Journal of Industrial Microbiology 4, 55–64 (1989). https://doi.org/10.1007/BF01569694
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DOI: https://doi.org/10.1007/BF01569694