Regulation of bacterial glycogen synthesis. Stimulation of glycogen synthesis by endogenous and exogenous cyclic adenosine 3':5'-monophosphate in Escherichia coli and the requirement for a functional CRP gene

In Escherichia coli cya mutants, deficient in adenylate cyclase (EC 4.6.1.1), basal cellular rates of glycogen synthesis were lower and the relative increases produced by exogenous cyclic adenosine 3',5'-monophosphate during growth on glucose were greater than in their respective parent strains. These observations provide strong evidence that endogenous cyclic AMP is one of the key regulators of glycogen synthesis in growing E. coli. In crp mutants, deficient in cyclic AMP receptor protein (CRP), the basal cellular rates of glycogen synthesis were much lower than in their respective parent strains. Stimulation of glycogen synthesis by exogenous cyclic AMP was markedly attenuated in the three crp mutants. Thus, stimulation of glycogen synthesis by either endogenous or exogenous cyclic AMP appears to require CRP. Functional CRP appeared to be required for all three responses observed after cyclic AMP addition: an abrupt step-up in the cellular rate of glycogen synthesis, a continuing exponential increase in rate, and a stimulation of the rate during a subsequent nitrogen starvation. To account for these responses, we derived a mathematical model in which the cyclic AMP-CRP complex regulates the differential rate of synthesis of an enzyme metabolizing an effector of the rate-limiting enzyme of glycogen synthesis.     

Effects of tri-n-butyltin chloride on energy metabolism, macromolecular synthesis, precursor uptake and cyclic AMP production in isolated rat thymocytes

The inhibitor of oxidative phosphorylation tri-n-butyltin chloride (TBTC) causes membrane damage and disintegration of isolated rat thymocytes at concentrations higher than 1 microM. From a concentration of 0.1 microM, TBTC disturbs energy metabolism as indicated by an increase in methylglucose uptake, glucose consumption and lactate production and by a decrease in cellular ATP levels. Over the same TBTC concentration range, the incorporation of DNA, RNA and protein precursors are markedly reduced. Moreover the production of cyclic AMP upon stimulation of the cells with prostaglandin E1 is effectively inhibited. These effects cannot be explained by an inhibition of nucleoside kinase activity, amino acid uptake or adenylate cyclase activity. The effects of TBTC on macromolecular synthesis and cyclic AMP production are possibly due to a disturbance of the cellular energy state.     

On the control mechanism of bacterial growth by cyclic adenosine 3',5'-monophosphate

Inhibition of E. coli growth by cyclic adenosine monophosphate is observed in wild type strains cultured in glucose as carbon source, but not in a cyclic AMP receptor protein deficient mutant. A deletion mutant of the adenylate cyclase gene requires cyclic adenosine monophosphate for optimal growth. Using glucose as carbon source, 2 mM cyclic AMP promotes maximal rates of cell multiplication in this mutant; however higher concentrations of the nucleotide inhibit growth. Cell multiplication of wild type strains grown in glycerol is not affected by cyclic adenosine monophosphate. Nevertheless, in this carbon source the growth rate of the adenylate cyclase mutant is strongly inhibited by concentrations of this nucleotide beyond 0.1 mM. This suggests that growth inhibition by exogenous cyclic adenosine monophosphate is highly dependent on the intracellular levels of the nucleotide.     

Cyclic adenosine 3',5'-monophosphate and coryneform bacteria

Abstract We have detected cyclic AMP in the culture medium of amino acid-producing coryneform bacteria. Extracellular concentrations of cyclic AMP vary depending on the nutritional medium, the growth phase and the carbon source. It is also shown that the activity of Brevibacterium flavum adenylate cyclase in intact cells is stimulated in the presence of glucose. Furthermore, addition of cyclic AMP to B. flavum cultures decreased amino acid production similarly to the effect produced by the addition of inorganic phosphate.     

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.     

Effects of crp mutations on adenosine 3'',5''-monophosphate metabolism in Salmonella typhimurium.

Wild-type Salmonella typhimurium could not grow with exogenous cyclic adenosine 3',5'-monophosphate (AMP) as the sole source of phosphate, but mutants capable of cyclic AMP utilization could be isolated provided the parental strain contained a functional cyclic AMP phosphodiesterase.All cyclic AMP-utilizing mutants had the growth and fermentation properties of cyclic AMP receptor protein (crp) mutants, and some lacked cyclic AMP binding activity in vitro. The genetic defect in each such mutant was due to a single point mutation, which was co-transducible with cysG. crp mutants isolated by alternative procedures also exhibited the capacity to utilize cyclic AMP. crp mutants synthesized cyclic AMP at increased rates and contained enhanced cellular cyclic AMP levels relative to the parental strains, regardless of whether or not cyclic AMP phosphodiesterase was active. Moreover, adenylate cyclase activity in vivo was less sensitive to regulation by glucose, possibly because the enzyme II complexes of the phosphotransferase system, responsible for glucose transport and phosphorylation, could not be induced to maximal levels. This possibility was strengthened by the observation that enzyme II activity (measured both in vitro by sugar phosphorylation and in vivo by sugar transport and chemotaxis) was inducible in the parental strain but not in crp mutants. The results suggest that the cyclic AMP receptor protein regulates cyclic AMP metabolism as well as catabolic enzyme synthesis.     

Effects of tri-n-butyltin chloride on energy metabolism, macromolecular synthesis, precursor uptake and cyclic AMP production in isolated rat thymocytes

The inhibitor of oxidative phosphorylation tri-n-butyltin chloride (TBTC) causes membrane damage and disintegration of isolated rat thymocytes at concentrations higher than 1 μM. From a concentration of 0.1 μM, TBTC disturbs energy metabolism as indicated by an increase in methylglucose uptake, glucose consumption and lactate production and by a decrease in cellular ATP levels. Over the same TBTC concentration range, the incorporation of DNA, RNA and protein precursors are markedly reduced. Moreover the production of cyclic AMP upon stimulation of the cells with prostaglandin E₁ is effectively inhibited. These effects cannot be explained by an inhibition of nucleoside kinase activity, amino acid uptake or adenylate cyclase activity. The effects of TBTC on macromolecular synthesis and cyclic AMP production are possibly due to a disturbance of the cellular energy state.     

Utilization of gluconate by Escherichia coli. A role of adenosine 3'':5''-cyclic monophosphate in the induction of gluconate catabolism.

1. Cultures of Escherichia coli growing on gluconate use both gluconate and glucose when glucose is added. 2. Glycerol-grown cells adapt to gluconate utilization even in media containing glucose as well as gluconate. 3. The rates of gluconate utilization by cells growing on a mixture of glucose and gluconate, and the specific activities of the gluconate uptake system and of gluconate kinase, are greater if adenosine 3':5'-cyclic monophosphate (cyclic AMP) is present in the medium than in its absence. 4. Growth on media containing gluconate and cyclic AMP is accompanied by the formation of methyl glyoxal and pyruvate, and progressive inhibition of growth. 5. A mutant devoid of adenylate cyclase activity (cya) grew well on glucose in the absence of exogenous cyclic AMP but grew only poorly on gluconate; neither the gluconate uptake system nor gluconate kinase was adequately induced. The addition of cyclic AMP promoted growth on gluconate and facilitated the induction of proteins required for gluconate catabolism. 6. Phage Pl-mediated transduction of cya+ into the cya-mutant also restored the wild-type phenotype in its ability to adapt to gluconate utilization.     

Effect of growth conditions on the activity of the enzymes of cyclic 3':5'-AMP synthesis and decay in phototrophic bacteria]

Activity, ratio and summary content of cyclic AMP enzymes, adenylate cyclase and phosphodiesterase varied depending on growth conditions of phototrophic bacteria (Rhodospirillum rubrum and Rhodopseudomonas palustris). It suggests, that membrane-bound and soluble enzymes carry different functions. The increase of adenylate cyclase under chaning growth conditions was usually accompanied by the increase of phosphodiesterase. Sharp increase of both enzymes activity was observed when bacteria were growth in aerobic conditions. The activity of both enzymes in chromatophores was 2.8-fold higher when bacteria were grown in the light in anaerobic conditions, than in chromatophores of bacteria grown under stationary aerobic conditions in the light. It is suggested that 3':5' AMP can participate in autotrophic carbon assimilation or in the synthesis of pigments and other components of bacterial photosynthetizing apparatus. Substitution of NH4+ into NO3- and glutamate under the growing of R. rubrum in anaerobic conditions in the light resulted in the increase of the enzymes activities, which is the evidence of possible role of 3':5' AMP in mineral nitrogen uptake and nitrogen fixation. Glutamate concentration of 4 g/l stimulated the enzymes both in vivo and in vitro. The data obtained suggest that 3':5' AMP can carry multiple functions, participating in regulation of a number of metabolic processes in photorophic bacteria.     

Coordinate regulation of adenylate cyclase, protein kinase, and specific enzyme synthesis by cholera toxin in hormonally unresponsive hepatoma cells

Since none of the hormones which activate adenylate cyclase in other tissues have been found to activate adenylate cyclase or to induce tyrosine aminotransferase in cultured Reuber hepatoma cells (H35), despite the stimulatory effects of cyclic AMP derivatives on the latter enzyme, we tested the ability of cholera toxin to influence these processes. At low concentrations cholera toxin was found to mimic the ability of cyclic AMP derivatives to selectively stimulate the synthesis of the aminotransferase. Adenylate cyclase and protein kinase activity were also enhanced, but only after a lag period as in other systems. Specific phosphorylation of endogenous H₁ histone was also shown to be increased by cholera toxin treatment. The increase in tyrosine aminotransferase activity is due to an increase in de novo synthesis as shown by radiolabeling experiments utilizing specific immunoprecipitation. The activity of another soluble enzyme induced by dibutyryl cyclic AMP, PEP carboxykinase, was also stimulated by exposure of H35 cells to cholera toxin. Combinations of cholera toxin and dexamethasone led to greater than additive increases in the activity of both the aminotransferase and carboxykinase. Close coupling of cyclic AMP production with protein kinase activation and enzyme induction was suggested by the observation that the ED₅₀ values for the stimulation of adenylate cyclase, cyclic AMP production, protein kinase, and tyrosine aminotransferase activities were found to be the same (5–7 ng/ml) within experimental error. The results indicate that the adenylate cyclase system in H35 cells is functionally responsive and they support the suggestion that activation of protein kinase is functionally linked to induction of specific enzymes.     

The regulatory effects of growth rate and cyclic AMP levels on carbon catabolism and respiration in Escherichia coli K-12.

Cyclic AMP levels in glucose and succinate-limited and ammonia-limited glucose-containing continuous cultures of Escherichia coli were measured at different bacterial growth rates. Intracellular cyclic AMP concentrations were fairly constant (about 5 micrometer) at all dilution rates used when glucose was limiting. In ammonia-limited glucose cultures the cyclic AMP content was much lower (about 0.3 micrometer). In succinate-limited cultures cyclic AMP levels fell from 2.7 to 0.8 micrometer as dilution rate increased from 0.05 to 0.4 h-1. The effects of cyclic AMP on respiratory and carbon catabolic enzyme levels were studied. There was no indication of a direct cyclic AMP involvement in the regulation of these cellular functions. It seems more likely that the variations in enzyme levels observed resulted from variation of the specific growth rate of cultures.     

Cyclic AMP may not be involved in catabolite repression in Saccharomyces cerevisiae: evidence from mutants unable to synthesize it

Yeast cells with a nonsense adenylate cyclase mutation, cyr1-3, required cyclic AMP for growth. This phenotype was suppressed by the byc1 mutation; however, cyr1-3 bcy1 cells produced no detectable level of adenylate cyclase or cyclic AMP. On induction, the bcy1 and cyr1-3 bcy1 mutant cells produced the same levels of galactokinase and alpha-D-glucosidase as did the wild-type cells and fourfold-higher levels of invertase. Since galactokinase synthesis was severely repressed by glucose in the constitutive GAL81 mutants, irrespective of the cyr1-3 bcy1 genotype, cyclic AMP may not be involved in catabolite repression.     

Evidence against direct involvement of cyclic GMP or cyclic AMP in bacterial chemotactic signaling.

Defects in phosphotransferase chemotaxis in cya and cpd mutants previously cited as evidence of a cyclic GMP or cyclic AMP intermediate in signal transduction were not reproduced in a study of chemotaxis in Escherichia coli and Salmonella typhimurium. In cya mutants, which lack adenylate cyclase, the addition of cyclic AMP was required for synthesis of proteins that were necessary for phosphotransferase transport and chemotaxis. However, the induced cells retained normal phosphotransferase chemotaxis after cyclic AMP was removed. Phosphotransferase chemotaxis was normal in a cpd mutant of S. typhimurium that has elevated levels of cyclic GMP and cyclic AMP. S. typhimurium crr mutants are deficient in enzyme III glucose, which is a component of the glucose transport system, and a regulator of adenylate cyclase. After preincubation with cyclic AMP, the crr mutants were deficient in enzyme II glucose-mediated transport and chemotaxis, but other chemotactic responses were normal. It is concluded that cyclic GMP does not determine the frequency of tumbling and is probably not a component of the transduction pathway. The only known role of cyclic AMP is in the synthesis of some proteins that are subject to catabolite repression.     

The regulatory effects of growth rate of cyclic AMP levels on carbon catabolism and respiration in Escherichia coli K-12

Cyclic AMP levels in glucose and succinate-fluid and ammonia-limited glucose-containing continuous cultures of Escherichia coli were measured at different bacterial growth rates. Intracellular cyclic AMP concentrations were fairly constant (about 5 μM) at all dilution rates used when glucose was limiting. In ammonia-limited glucose cultures the cyclic AMP content was much lower (about 0.3 μM). In succinate-limited cultures cyclic AMP levels fell from 2.7 to 0.8 μM as dilution rate increased from 0.05 to 0.4 h^?1.The effects of cyclic AMP on respiratory and carbon catabolic enzyme levels were studied. There was no indication of a direct cyclic AMP involvement in the regulation of these cellular functions. It seems more likely that the variations in enzyme levles observed resulted from variation of the specific growth rate of cultures.     

, -Methylene-adenosine-5'-triphosphate--effects of a competitive inhibitor of adenylate cyclase on cyclic AMP accumulation and lipolysis in isolated fat cells

The rapid, transient rise in the intracellular concentration of cyclic AMP which follows addition of L-epinephrine to isolated fat cells is completely prevented by an ATP analog, α,β-methylene-adenosine-5′-triphosphate [Ap(CH₂)pp], a competitive inhibitor of adenylate cyclase activity in liver and fat cell membrane preparations. The concentration of cyclic AMP falls distinctly below that in the basal state after incubating fat cells for seven minutes in the presence of Ap(CH₂)pp. The results are consistent with the view that the ATP analog is also an effective $\text{in vivo}$ inhibitor of adenylate cyclase activity, and that intracellular cyclic AMP levels are normally delicately balanced by very rapid processes of synthesis and degradation. Epinephrine-induced lipolysis in fat cells is not inhibited but is instead enhanced by Ap(CH₂)pp. This is probably explained by the ability of the analog to act (like ATP) as a high-energy phosphate donor, an effect which is independent of its inhibition of adenylate cyclase activity. The predominant effect of this compound on glucose oxidation by fat cells also appears to be the result of this property since its effects are mimicked by ATP.     

Regulation of adenosine 3':5'-monophosphate efflux from animal cells.

Cyclic AMP efflux was measured following hormonal stimulation of adenylate cyclase in a variety of animal cells including C-6 rat glioma cells, WI-38 human fibroblasts, and avian erythrocytes. Using a variety inhibitors of mitochondrial function and glycolysis, a correlation was noted between cellular ATP levels and the rate of cyclic AMP efflux in all cells examined. A relationship between the efflux rate and the magnitude of the membrane potential was not observed. Pharmacological agents which inhibited cyclic AMP egress in these cells without reducing ATP levels included several prostaglandins (A greater than B greater than E greater than F) and probenecid. The characteristics of the cyclic AMP efflux system resemble those of the organic anion transport system.     

Regulation of two phosphatases and a cyclic phosphodiesterase of Salmonella typhimurium.

The regulation of three Salmonella typhimurium phosphatases in reponse to different nutritional limitations has been studied. Two enzymes, an acid hexose phosphatase (EC 3.1.3.2) and a cyclic phosphodiesterase (EC 3.1.4.d), appear to be regulated by the cyclic adenosine 3' ,5'-monophosphate (AMP) catabolite repression system. Levels of these enzymes increased in cells grown on poor carbon sources but not in cells grown on poor nitrogen or phosphorus sources. Mutants lacking adenyl cyclase did not produce elevated levels of these enzymes in response to carbon limitation unless cyclic AMP was supplied. Mutants lacking the cyclic AMP receptor protein did not produce elevated levels of these enzymes in response to carbon limitation regardless of the presence of cyclic AMP. Since no specific induction of either enzyme could be demonstrated, these enzymes appear to be controlled solely by the cyclic AMP system. Nonspecific acid phsphatase activity (EC 3.1.3.2) increased in response to carbon, nitrogen, phosphorus, or sulfur limitation. The extent of the increase depended on growth rate, with slower growth rates favoring greater increases, and on the type of limitation. Limitation for either carbon or phosphorus resulted in maximum increases, whereas severe limitation of Mg2+ caused only a slight increase. The increase in nonspecific acid phosphatase during carbon limitation was apparently not mediated by the catabolite repression system since mutants lacking adenyl cyclase or the cyclic AMP receptor protein still produced elevated levels of this enzyme during carbon starvation. Nor did the increase during phosphorus limitation appear to be mediated by the alkaline phosphatase regulatory system. A strain of Salmonella bearing a chromosomal mutation, which caused constitutive production of alkaline phosphatase (introduced by an episome from Escherichia coli), did not have constitutive levels of nonspecific acid phosphatase.     

The effect of trypsin on sugar uptake in rat thymocytes. Modulation of cellular cyclic AMP concentration and the sugar-transport system.

I have shown that cyclic AMP stimulates sugar uptake in rat thymocytes. However, trypsin treatment, which increases rat thymocyte cyclic AMP concentration, fails to increase sugar uptake. The purpose of the present study is to examine this seeming inconsistency, and to evaluate further the function of trypsin. Mild trypsin treatment of rat thymocytes produced a dose-related increase in cellular cyclic AMP concentration. Trypsin produced the same proportionate increase in cyclic AMP concentration in the presence or absence of optimal concentrations of the phosphodiesterase inhibitor 3-isobutyl-l-methylxanthine, which suggests that trypsin acts to increase thymocyte cyclic AMP concentration by stimulating adenylate cyclase activity. Trypsin at concentrations of 0.3 mg/ml and less had no effect on the uptake of the glucose analogue 2-deoxy-D-glucose (2-DG), whereas at concentrations of 1 mg/ml and higher trypsin produced a small, dose-related, decrease in basal 2-DG uptake, becoming significantly lower than control values only at 5 mg/ml (-22.7%, P less than 0.05). Thymocyte sugar transporters, characterized by means of cytochalasin B binding, consist of a single class of sites with an apparent KD of 0.15 microM and maximum binding capacity of 2.73 pmol/20 x 10(6) cells (8.4 x 10(4) sites/thymocyte). Trypsin produced a dose-related decrease in the sugar-displaceable binding of cytochalasin B, so that at 5 mg of trypsin/ml the number of sugar transporters was decreased by approx. 50%. Thus trypsin treatment of rat thymocytes on the one hand increases cellular cyclic AMP concentration, which itself potentiates 2-DG uptake, and on the other hand decreases the number of sugar transporters, which itself decreases cellular sugar uptake, indicating that the apparent effect of trypsin on thymocyte 2-DG uptake is the result of the balance of its effects on these two systems.     

A possible involvement of cya gene in the synthesis of cyclic guanosine 3':5'-monophosphate in E. coli.

Based on the following genetical experiments, the cya gene in E. coli was shown to be involved in the synthesis of both cyclic AMP and cyclic GMP. First, all five independent cya-deficient mutants accumulated exceedingly low amounts of cyclic GMP. Second, the ability to form both cyclic AMP and cyclic GMP was simultaneously restored by transduction of an intact cya locus to one of the above cya-deficient mutants. Third, a spontaneous revertant from one of the above mutants regained the synthetic activity for cyclic GMP as well as for cyclic AMP. Fourth, the characteristic of a strain overproducing cyclic GMP was co-transduced with the cya locus. These results suggest that the synthesis of both cyclic GMP and cyclic AMP is mediated by the same enzyme, adenylate cyclase, Interestingly, a reciprocal effect of glucose starvation was observed on the accumulation of both cyclic nucleotides. The formation of cyclic AMP was greatly enhanced on glucose starvation, whereas that of cyclic GMP proceeded at a slower rate than in the presence of glucose. This effect was observed only in cells carrying normal cya and crp genes, but not in a cya-altered or a crp-deficient strain.     

Transduction of signals in the activation of T lymphocytes: relation to leukemia

The biochemical events initiated by mitogen in T lymphocytes are the subject of this paper. Following interaction of the mitogen with its receptors, a transmembrane 'trigger-type' signal is propagated which has both positive and negative correlates. The negative signal occurs with high mitogen concentrations and is associated with membrane freezing, microtubular aggregation, receptor capping, adenylate cyclase activation, and cellular cyclic AMP increases. The positive signal occurs with optimal mitogen concentrations and is associated with changes in membrane permeability and transport with influx of calcium and potassium ion and efflux of sodium, in transport processes for glucose, amino acids, and nucleosides, and in a collected series of early membrane lipid changes which can be considered essential for the positive signal. These lipid changes include the uptake of arachidonic acid and other fatty acids, choline, phosphate and other molecules, their incorporation into membrane phospholipids, particularly phosphatidylinositol (PI), and a turnover of PI with the production of inositol triphosphate, which can be related to calcium mobilization and diacylglycerol which activates a cytoplasmic protein kinase C. A key event associated with mitogen action is arachidonic acid release. Arachidonic acid may give rise to prostaglandins and thromboxanes as part of negative components of the signal through effects on the adenylate cyclase/cyclic AMP system. Arachidonic acid gives rise to eicosanoids like 5-, 11-, possibly 12- and 15-hydroxyperoxy and hydroxy eicosatetraenoic acids and leukotrienes B4 and C4. The activation of the 5-lipoxygenase, a critical calcium-dependent step, leads via the production of 5-HPETE and 5-HETE to the activation of membrane and soluble guanylate cyclase and the production of cyclic GMP. Cyclic GMP appears to be essential for mitogen activation and is associated with cyclic GMP-dependent protein kinase activation and the phosphorylation of a number of substrates. Calcium ion influx is clearly central to mitogen action. Calcium through its influx and mobilization from cellular stores is thought to contribute directly and indirectly through the action of calmodulin and protein kinase C to the activation of a number of enzymatic processes involved in the positive signal including phospholipase C, diglyceride kinase and lipase, 5-lipoxygenase, and guanylate cyclase. Cyclic GMP and calcium ion both participate in nuclear processes leading to RNA and protein synthesis. Interleukin 2 is associated with midcycle increases in cyclic GMP and entry into DNA synthesis.(ABSTRACT TRUNCATED AT 400 WORDS)