Evolution of the D-ribose operon on Escherichia coli B/r.

The D-ribose operon (rbs) of Escherichia coli K-12 maps at 83 min and is inducible. The rbs operon of E. coli B/r maps at 2 min and is constitutive. Evidence is presented showing that a second inducible copy of the rbs operons is present in E. coli B/r mapping at 83 min. The data indicated that the duplication of the rbs operon represented a transposition of the 83-min region to 2 min. The identification of a second copy of the rbs operon in B/r and the determination of its inducibility were based on the reactivation, through mutagenesis, of inducible rbs expression, mapping by P1 transduction of the mutation site to 83 min, and merodiploid complementation analysis of the D-ribokinase expression in E. coli B/r. We also show that the rbs transposition to 2-min continued to generate transposable elements coding for the 1- to 2-min region of the chromosome and transposing onto extrachromosomal DNA target molecules such as pBR322.

Insulin action on Escherichia coli. Regulation of the adenylate cyclase and phosphotransferase enzymes.

Insulin on Escherichia coli was studied using wild type E. coli B/r and K12 strains and a number of phosphoenolpyruvate phosphotransferase mutants. In vivo, the effects of insulin on the differential rate of tryptophanase synthesis, the rate of alpha-methylglucoside uptake and the rate of growth on glucose were determined in E. coli B/r. In vitro, the effect of insulin on the adenylate cyclase and the phosphotransferase activities was determined using toluenized cell preparations of E. coli B/r, E. coli K12 and phosphotransferase mutant strains. The specificity of insulin action on E. coli was determined using glucagon, vasopressin and somatropin as well as insulin antisera. Results show the specific action of insulin on E. coli, inhibiting tryptophanase induction and adenylate cyclase activity, while stimulating growth on glucose and uptake and phosphorylation of alpha-methylglucoside.

Genetic regulation of the constitutive D-ribose operon in Escherichia coli B/r.

Merodiploid complementation analysis of the constitutive synthesis of the D-ribokinase and the D-ribose permease in Escherichia coli B/r has shown that the constitutive D-ribose operon is genetically controlled by a transdominant regulatory gene closely linked to the D-ribokinase and D-ribose permease structural genes. The regulatory mechanism for this operon shows no requirement for operator-repressor interaction, rather a truly positive control mechanism and thus suggests an extension of the operon model in its application to constitutive enzyme regulation in bacteria.

On the regulation of adenosine 3', 5'-monophosphate synthesis in bacteria. I. Effect of carbon source variation on cyclic AMP synthesis in Escherichia coli B/r.

1. The effect of carbon source variation in bacterial growth media on their growth rate, inducible enzyme and cyclic AMP synthesis was examined: an inverse relationship between the culture's growth rate and its differential rate of inducible enzyme (tryptophanase and beta-galactosidase), and cyclic AMP synthesis was found. 2. The effect of the culture's growth phase on its sensitivity or resistance to glucose catabolite repression was determined in the wild type and a catabolite insensitive mutant (ABDROI): the wild type's sensitivity to glucose repression was not affected, whereas the insensitivity of the mutant was found to be limited to its early logarithmic phase of growth. At late log, or stationary phase, the mutant was found to be sensitive to glucose repression. 3. Examination of the kinetics of glucose uptake by the mutant, using alpha-[1 4-C] methyl-glucoside showed evidence for two transport systems each with a different affinity to glucose. A low affinity transport system (apparent Km of 3.4-10-minus 5 M) which appears mostly at the early logarithmic phase of growth. A high affinity transport system (apparent Km of 1.2-10-minus 5 M) which appears mostly at the late log and stationary phases of growth. 4. The effect of the culture density variation on its sensitivity to glucose repression showed that sensitivity to glucose catabolic repression is primarily a reflection of the formation of an allosteric effector molecule between glucose and its specific transport molecule which in turn regulates the activity of the adenylate cyclase.

On the regulation of cyclic AMP level in bacteria. II. In vitro regulation of adenylate cyclase activity. Solubilization and reconstitution of a functional membrane-bound adenylate cyclase system responsive to regulation by glucose.

1. The in vitro regulation of the membrane bound adenylate cyclase of Escherichia coli B/r by a variety of carbohydrates and one mammalian hormone was examined. 2. The membrane bound adenylate cyclase was found responsive to regulation by the various growth substrates and to glucagon. 3. Solubilization of the bacterial membrane preparation by a procedure specific for the solubilization of the phosphotransferase enzyme E1 1 to its E1 1 A and E1 1 B subunits was found to be accompanied by the loss of the adenylate cyclase regulation by glucose. 4. Reconstitution of the membrane was found to result in a recovery of the regulative response of the adenylate cyclase to glucose. 5. A model for the intermediate steps in the interaction between glucose and phosphotransferase E1 1 and the adenylate cyclase is discussed.