In Escherichia coli C, the catabolism of the pentitols ribitol and D-arabitol proceeds through separate, inducible operons, each consisting of a dehydrogenase and a kinase. The ribitol operon is induced in response to ribulose, and the Darabitol operon is induced in response to D-arabitol. Each operon is under negative control. The genes of the ribitol and D-arabitol operons are very closely linked and lie in a mirror image arrangement, rtlB-rtLA-rtlC-atlC-atL4-atlB, between metG and his on the E. coli C chromosome.
All of our Escherichia coli C mutants blocked in the first step of D-arabitol catabolism (D-arabitol dehydrogenase) became unable to grow in the presence of D-arabitol. We have shown that this sensitivity is eliminated by a defect in the second enzyme of the pathway (D-xylulokinase), leading to a pattern of toxicity and its relief which has not been previously reported. We have found a similar pattern of toxicity and its relief in the closely related ribitol pathway. The evolutionary significance of these findings is discussed.
Ribitol+ strains of Escherichia coli acquire the ability to utilize xylitol by mutating to constitutive production of the coordinately controlled ribitol catabolic enzymes ribitol dehydrogenase (RDH) and D-ribulokinase (DRK). Such strains concomitantly acquire toxicity to galacitol and L-arabitol, and to D-arabitol if they are unable to utilize it for growth. Strains selected for resistance to these polyols have DRK structural gene mutations or other mutations that eliminate the constitutive production of DRK, consistent with the view that DRK phosphorylates those polyols to toxic substances. Ribitol+ strains selected for growth on 8 mM xylitol fail to grow on 30 mM xylitol. A product of ribitol and xylitol catabolism represses synthesis of RDH, an enzyme required for growth on xylitol. At 30 mM xylitol, greater than 99% of RDH synthesis is repressed. Strains that grow on 8 mM xylitol can mutate to grow on 30 mM xylitol. Such mutants, relieved of this repression, overproduce RDH, resulting in good growth on the poor substrate, xylitol, but poor growth on the normal substrate, ribitol.
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