Z. Dobrová

Protein phosphorylation in Streptomyces albus.

The phosphorylated proteins of Streptomyces albus, radioactively labeled with [32P]orthophosphate have been analyzed by gel electrophoresis and autoradiography. More than 10 protein species were found to be phosphorylated. With [32P]ATP as substrate cell free extracts phosphorylated endogenous proteins in vitro which were predominantly phosphorylated in vivo. From cell extract which exhibited active phosphorylated in vitro, a protein kinase has been partially purified. The kinase activity was identified in fractions corresponding to a 90 kDa protein.

Characterization of adenylate cyclase fromEscherichia coli

Adenylate cyclase activity was detected and characterized in cell-free preparations of different strains ofEscherichia coli; it was localized not only in the membrane fraction but also in the cytoplasm, the localization differing from strain to strain. The adenylate cyclase activity is highly dependent on the method used for disintegration of cells. The best results were obtained when using vortexing of the cell suspension with ballotini beads. The pH optimum of adenylate cyclase in cell-free preparations was found to be 9.0 –9.5. The enzyme has an absolute requirement for Mg2+ and is inhibited by sodium fluoride and inorganic diphosphate. Release of adenylate cyclase from the membrane leads to an immediate loss of the activity; it was found that adenylate cyclase is quite labile and hence it could not yet been purified. The method used to determine adenylate cyclase activity and cyclic AMP is described.

Cyclic 3′,5′-adenosine monophosphate and catabolite repression in Escherichia coli

Abstract Several strains of E. coli were grown on different sources of carbon and β-galactosidase activity as well as intracellular and extracellular concentrations of c-AMP were determined. There was a good (inverse) correlation between extracellular concentrations of c-AMP and the intensity of catabolite repression, whereas the relationship between intracellular c-AMP levels and catabolite repression was not clear-cut.

Induction of β-D-Glucosidase inStreptomyces granaticolor

Abstractβ-d-Glucosidase inStreptomyces granaticolor is an inducible enzyme. Methyl-β-d-glucoside or cellobiose, added to a glycerol-containing medium, are most suitable inducers. The activity of β-d-glucosidase in a culture fully induced by cellobiose is 50 times higher than the basal level of the enzyme. β-d-Glucosidase is an intracellular enzyme, whose inducibility differ with culture age and reaches its maximum in a 10-h-old mycelium. The enzyme synthesis begins 2 h after the addition of the induced and reaches its maximum after a 10-h-induction.

Effect of protein phosphorylation on the activity of RNA polymerase in streptomycetes

RNA polymerase was isolated fromStreptomyces granaticolor and protein kinase was partially purified fromStreptomyces albus. When RNA polymerase was treated with protein kinasein vitro the activity of RNA polymerase was markedly enhanced. Furthermore, a protein ofM=65 kDa was isolated which, after being phosphorylated, stimulated RNA polymerase activityin vitro. Because neither the β-subunits nor the α-subunits of RNA polymerase were phosphorylated it is assumed that phosphorylation of the 65 kDa protein may regulate the activity of RNA polymerase in streptomycetes.

The control of adenylate cyclase activity in Escherichia coli.

Cell-free extract ofE. coli possessed an inhíbíted adenylate cyclase activíty after a previous anaerobic incubation of cells with glucose which is transported and metabolized. The degree of the inhibition depends on incubation conditions. Glucose analogues that are only transported but not metabolized, are not inhibitory. To restore the adenylate cyclase activity, the cells have to be cultivated aerobically prior to disintegration for a defined period of time without glucose.

The effect of glucose on cellobiose uptake and β-D-glucosidase activity inStreptomyces granaticolor

Glucose inhibits the inducible synthesis of β-D-glucosidase inStreptomyces granaticolor. Neither cAMP nor cGMP influence the inhibitory effect of glucose. Glucose also inhibits the inducible synthesis of the cellobiose uptake system but has no effect on its activity. This may be the mechanism underlying glucose inhibition of induction of β-D-glucosidase inS.granaticolor.

Catabolite repression of different inducible enzymes inEscherichia coli and the effect of cAMP

Simultaneous induction of two enzymes sensitive to catabolite repression does not lead to an additive decrease of the specific activity of the two. Exogenously added cAMP increases the specific activity of catabolically repressed enzymes, irrespective of whether the enzyme is induced separately or simultaneously with another enzyme. In the presence of 12 different substrates metabolized by inducible enzymes glucose does not bring about catabolite repression. Synthesis of cAMP is identical with that occurring under conditions when glucose brings about catabolite repression.

Regulation of cAMP Synthesis in Streptomyces Granaticolor

Adenosine-3′,5′-monophosphate (cAMP) and guanosine-3′,5′-monophosphate (cGMP) are found in a variety of microbial cells (1,2). The important role of cAMP as a regulator of transcription of some catabolite-sensitive operons has been described in several Gram-negative bacteria (3). The mechanism involved and some of the physiological consequences of changes in the levels of cAMP and cGMP are not certain, even in Escherichia coli. In most other microorganisms, all that is known is that the nucleotides can be isolated and identified, and, when added exogenously, that they can influence some physiological activities (2).