D-amino acid oxidase fromTrigonopsis variabilis: Comparison of enzyme specificity “in vivo” and “in vitro”

Summary A method is described for permeabilization of intact cells of the yeastTrigonopsis variabilis with respect toin vivo measuring D-amino acid oxidase activity. The kinetic results so obtained differ from those obtained with the purified enzyme, pointing to the advantage of using the purified enzyme or the permeabilized cells in the oxidative deamination of different D-amino acids.     

Regulation of adenylate cyclase in electropermeabilized Dictyostelium discoideum cells.

In Dictyostelium discoideum cells the enzyme adenylate cyclase is functionally coupled to cell surface receptors for cAMP. Coupling is known to involve one or more G-proteins. Receptor-mediated activation of adenylate cyclase is subject to adaptation. In this study we employ an electropermeabilized cell system to investigate regulation of D. discoideum adenylate cyclase. Conditions for selective permeabilization of the plasma membrane have been described by C.D. Schoen, J. C. Arents, T. Bruin, and R. Van Driel (1989, Exp. Cell Res. 181, 51-62). Only small pores are created in the membrane, allowing exchange of exclusively low molecular weight substances like nucleotides, and preventing the loss of macromolecules. Under these conditions functional protein-protein interactions are likely to remain intact. Adenylate cyclase in permeabilized cells was activated by the cAMP receptor agonist 2'-deoxy cAMP and by the nonhydrolyzable GTP-analogue GTP gamma S, which activates G-proteins. The time course of the adenylate cyclase reaction in permeabilized cells was similar to that of intact cells. Maximal adenylate cyclase activity was observed if cAMP receptor agonist or GTP-analogue was added just before cell permeabilization. If these activators were added after permeabilization adenylate cyclase was stimulated in a suboptimal way. The sensitivity of adenylate cyclase activity for receptor occupation was found to decay more rapidly than that for G-protein activation. Importantly, the adenylate cyclase reaction in permeabilized cells was subject to an adaptation-like process that was characterized by a time course similar to adaptation in vivo. In vitro adaptation was not affected by cAMP receptor agonists or by G-protein activation. Evidently electropermeabilized cells constitute an excellent system for investigating the positive and negative regulation of D. discoideum adenylate cyclase.     

Alamethicin or detergent permeabilization of the cell membrane as a tool for adenylate cyclase determination

Treatment of mouse lymphocytes with very low concentrations of alamethicin or Lubrol PX induces spontaneous permeabilization of the plasma membrane to ATP and allows determination of adenylate cyclase activity in whole cells. The permeabilized cells retain responsiveness to hormones (isoproterenol, adenosine analogs) and to fluoride. The main advantage of this new method is that it does not require any homogenization step, and thus adenylate cyclase activities can be accurately and reproducibly measured with very low amounts of cells. It should be especially useful for the study of purified lymphocyte subpopulations.     

Guanine nucleotide regulation of adenylate cyclase in permeabilized cells of Saccharomyces cerevisiae

Adenylate cyclase in permeabilized cells of Saccharomyces cerevisiae was examined. Among various permeabilization procedures, including organic solvents, detergents and other reagents, dimethylsulfoxide (DMSO) and digitonin treatments resulted in the highest recovery of adenylate cyclase activity. Incubation of cells at 30 degrees C with digitonin at 0.01% to 0.1%, or DMSO at 20% to 40% for 15 to 30 min gave optimal adenylate cyclase activity. The enzyme activity in digitonin-permeabilized cells could be supported only by Mn2+, whereas Mg2+ with or without guanine nucleotides did not support cyclase activity. DMSO-permeabilized cells exhibit efficient Mn2+- and Mg2+/Gpp[NH]p-dependent stimulation. Furthermore, digitonin added to yeast membranes at a 1:50 detergent to protein ratio (w/w) abolishes guanyl nucleotide regulation without significantly affecting the Mn2+-supported cyclase activity. The superiority of DMSO is further supported by the fact that recovery of adenylate cyclase activity is better in the DMSO-treated cells than in the digitonin-treated cells. DMSO most probably causes less disturbance of the fabric of the native cell. We conclude that digitonin, but not DMSO, uncouples the catalytic unit of adenylate cyclase from the regulatory GTP binding (ras) proteins.     

Alamethicin or detergent permeabilization of the cell membrane as a tool for adenylate cyclase determination: Application to the study of hormone responsiveness in lymphocytes

Treatment of mouse lymphocytes with very low concentrations of alamethicin or Lubrol PX induces spontaneous permeabilization of the plasma membrane to ATP and allows determination of adenylate cyclase activity in whole cells. The permeabilized cells retain responsiveness to hormones (isoproterenol, adenosine analogs) and to fluoride. The main advantage of this new method is that it does not require any homogenization step, and thus adenylate cyclase activities can be accurately and reproducibly measured with very low amounts of cells. It should be especially useful for the study of purified lymphocyte subpopulations.     

Guanine nucleotide activation of adenylate cyclase in saponin permeabilized glioma cells

We have compared the regulation of adenylate cyclase activity in membrane fractions from C6 glioma cells and in monolayer cultures of C6 cells that had been permeabilized with saponin. Guanine nucleotides (GTP and GTP gamma S) and isoproterenol increase adenylate cyclase activity in C6 membranes and in permeabilized C6 cells. In C6 membranes, guanine nucleotides activate adenylate cyclase in the presence or absence of isoproterenol; in permeabilized cells, however, guanine nucleotides increase adenylate cyclase activity only in the presence of isoproterenol. We suggest that the properties of the permeabilized cells more closely resemble those of intact cells, and that some component which is present in permeabilized cells but is lost following cell disruption may be important for the normal regulation of adenylate cyclase activity.     

In situ analysis of adenylate cyclase activity in permeabilized rat adipocytes: sensitivity to GTP, isoproterenol, and N6-(phenylisopropyl)adenosine

Adenylate cyclase activity in rat adipocyte suspensions was assayed in situ using a digitonin permeabilization technique. Recovery of activity was dependent on digitonin concentration, reaching a maximum at 20 micrograms/ml digitonin and paralleling the effect on cell permeability. Maximum adenylate cyclase activity recovered in permeabilized cells was 75% of that in comparable homogenates. Isoproterenol, a beta-adrenergic agonist, activated adenylate cyclase by 1.4, 2.2 and 4.5 fold at 10(-6), 10(-5) and 10(-3) M, respectively, despite perturbation of the plasma membrane. Exogenous GTP was not required for expression of beta-adrenergic activation, but 10(-5) M GTP maximally increased both basal and isoproterenol-dependent activity. The response to 10(-6) M isoproterenol was increased 2.1 fold by 10(-5) M GTP. N6-(Phenylisopropyl)adenosine at 10(-6) M inhibited both basal and isoproterenol-dependent adenylate cyclase activity by approximately 30%, demonstrating that the adenosine-dependent inhibitory pathway (Ni) remained functional in the digitonin-permeabilized cells. In situ analysis of adenylate cyclase is not only simple and rapid, but provides a unique approach to studying regulation of this key enzyme.     

Regulation of Escherichia coli phosphofructokinase in situ

The activity of E. coli phosphofructokinase in situ has been studied in cells permeabilized to its substrates, products and effectors by a toluene-freezing treatment. The in situ enzyme exhibits moderate cooperativity in respect to F6P (n_H up to 2.0), rather low affinity for ATP (with Km up to 1 mM when saturated with F6P), activation by ADP, and inhibition, within the physiological range of concentrations, by high ATP and phosphoenolpyruvate. This behaviour of the enzyme in situ at concentrations of the effector metabolites as those reported in intact cells in glycolytic and gluconeogenic conditions could account for the changes of phosphofructokinase activity needed for metabolic regulation in vivo.     

The Escherichia coli adenylate cyclase complex. Stimulation by potassium and phosphate

In Escherichia coli, adenylate cyclase activity in toluene-treated cells can be inhibited by glucose while the activity in a broken cell preparation cannot. Adenylate cyclase activity in the permeabilized but not in broken cells is stimulated somewhat specifically and additively by potassium and phosphate. Kinetic studies show sigmoid substrate-velocity curves for the toluene-treated cells but hyperbolic curves for the broken cells. The stimulatory effects of potassium and phosphate on adenylate cyclase activity in tolulene-treated cells are associated with increases in the Vmax and Km for ATP. While the enzyme activity in toluene-treated cells shows a preference for magnesium over manganese, the reverse is observed in broken cells. Stimulation of adenylate cyclase activity in toluene-treated cells requires the presence of the proteins of the phosphoenolpyruvate:sugar phosphotransferase system (PTS). The PTS proteins can be phosphorylated in a P-enolpyruvate-dependent reaction. The stimulatory effects of ions will not occur if the PTS proteins are not phosphorylated. Since potassium phosphate stimulates both adenylate cyclase and PTS activities in toluene-treated cells, it is proposed that the effect of potassium phosphate on adenylate cyclase activity is mediated through an effect on the PTS. A model for dual regulation by glucose of adenylate cyclase activity is proposed. This model involves regulation of both the condition of the PTS proteins as well as the cellular concentration of phosphate.     

Stabilization of cetyltrimethylammonium bromide permeabilized yeast whole cell lactase

Summary Cetyltrimethylammonium bromide-permeabilized cells ofK. fragilis loose -galactosidase activity due to leaking of the enzyme into the medium. This leakage of the enzyme can be prevented by storing the permeabilized cells either in buffer containing 50% glycerol or by treating the permeabilized cells with 0.2% glutaraldehyde at 4°C for 10 min. In repeated batch hydrolysis of lactose in milk, glutaraldehyde treated cells could be repeatedly used very efficiently.     

Neuroblastoma cell adenylate cyclase: direct activation by adenosine and prostaglandins.

—Adenylate cyclase activity of permeabilized neuroblastoma cells was measured by the conversion of [α³²P]ATP into labelled cyclic AMP. Adenosine (10^?6 - 10^?4m ) induced a dose-dependent increase in cyclic AMP formation. This effect could not be accounted for either by an adenosine-induced inhibition of the phosphodiesterase activity present in the enzyme preparation, or by a direct conversion of adenosine into cyclic AMP. This indicates that the observed increase in cyclic AMP accumulation reflected an activation of adenylate cyclase. Adenosine is partially metabolized during the course of incubation with the enzyme preparation. However, none of the identified non-phosphorylated adenosine metabolites were able to induce an adenylate cyclase activation. This suggests that adenosine itself is the stimulatory agent. The apparent K_m of the adenylate cyclase for adenosine was 5 ± 10^?6-10^?5m . Maximal activation represented 3-4 times the basal value (10-100 pmol cyclic AMP formed/10 min/mg protein). The adenosine effect was stereospecific, since structural analogues of adenosine were inactive. Adenosine increased the maximal velocity of the adenylate cyclase reaction. The stimulatory effect of adenosine was inhibited by theophylline. Prostaglandin PGE₁ had a stimulatory effect much more pronounced than that of adenosine (6-10-fold the basal value at 10^?6m ). Dopamine and norepinephrine induced a slight adenylate cyclase activation which was not potentiated by adenosine. It is concluded that adenosine is able to activate directly neuroblastoma cell adenylate cyclase. It seems very likely that such a direct activation is also present in intact nervous tissue and account, at least partly, for the observed cyclic AMP accumulation in response to adenosine.     

Guanylate cyclase activity in permeabilized Dictyostelium discoideum cells

Dictyostelium discoideum cells respond to chemoattractants by transient activation of guanylate cyclase. Cyclic GMP is a second messenger that transduces the chemotactic signal. We used an electropermeabilized cell system to investigate the regulation of guanylate cyclase. Enzyme activity in permeabilized cells was dependent on the presence of a nonhydrolysable GTP analogue (e.g., GTPγS), which could not be replaced by GTP, GDP, or GMP. After the initiation of the guanylate cyclase reaction in permeabilized cells only a short burst of activity is observed, because the enzyme is inactivated with a t_1.2 of about 15 s. We show that inactivation is not due to lack of substrate, resealing of the pores in the cell membrane, product inhibition by cGMP, or intrinsic instability of the enzyme. Physiological concentrations of Ca²⁺ ions inhibited the enzyme (half-maximal effect at 0.3 μM), whereas InsP₃ had no effect. Once inactivated, the enzyme could only be reactivated after homogenization of the permeabilized cells and removal of the soluble cell fraction. This suggests that a soluble factor is involved in an autonomous process that inactivates guanylate cyclase and is triggered only after the enzyme is activated. The initial rate of guanylate cyclase activity in permeabilized cells is similar to that in intact, chemotactically activated cells. Moreover, the rate of inactivation of the enzyme in permeabilized cells and that due to adaptation in vivo are about equal. This suggests that the activation and inactivation of guanylate cyclase observed in this permeabilized cell system is related to that of chemotactic activation and adaptation in intact cells. © 1996 Wiley-Liss, Inc.     

Improvement in cell‐bound phytase activity of Pichia anomala by permeabilization and applicability of permeabilized cells in soymilk dephytinization

Aims: Whole cell permeabilization of Pichia anomala to ameliorate the cell‐bound phytase activity and usability of permeabilized cells in dephytinization of soymilk. Methods and Results: The cells of P. anomala were subjected to permeabilization using the surfactant Triton X‐100 to overcome the permeability barrier and prepare whole cell biocatalysts with high phytase activity. The statistical approach, response surface methodology (RSM) was used to optimize the operating conditions for permeabilization. The treatment of cells with 5% Triton X‐100 for 30 min resulted in c. 15% enhancement in cell‐bound phytase activity. The shrinkage of protoplast was observed, although cell viability and phytase stability were not significantly altered. The free as well as immobilized permeabilized cells hydrolysed soymilk phytate, and the latter could be reused over four consecutive cycles. Conclusions: Whole cell permeabilization of P. anomala using Triton X‐100 led to enhancement in cell‐bound phytase activity. The viability and integrity of yeast cells were not significantly affected because of permeabilization. The permeabilized P. anomala cells effectively dephytinized soymilk, and the permeabilized cells immobilized in alginate could be reused because of sustained phytase activity. Significance and Impact of the Study: This is the first report on the use of permeabilized yeast cells for mitigating phytate content of soymilk. Alginate entrapment of permeabilized P. anomala allows reuse of cells for soymilk dephytinization, thus suggesting a potential application in food industry.     

Fine control of adenylate cyclase by the phosphoenolpyruvate:sugar phosphotransferase systems in Escherichia coli and Salmonella typhimurium.

Inhibition of cellular adenylate cyclase activity by sugar substrates of the phosphoenolpyruvate-dependent phosphotransferase system was reliant on the activities of the protein components of this enzyme system and on a gene designated crrA. In bacterial strains containing very low enzyme I activity, inhibition could be elicited by nanomolar concentrations of sugar. An antagonistic effect between methyl alpha-glucoside and phosphoenolpyruvate was observed in permeabilized Escherichia coli cells containing normal activities of the phosphotransferase system enzymes. In contrast, phosphoenolpyruvate could not overcome the inhibitory effect of this sugar in strains deficient for enzyme I or HPr. Although the in vivo sensitivity of adenylate cyclase to inhibition correlated with sensitivity of carbohydrate permease function to inhibition in most strains studied, a few mutant strains were isolated in which sensitivity of carbohydrate uptake to inhibition was lost and sensitivity of adenylate cyclase to regulation was retained. These results are consistent with the conclusions that adenylate cyclase and the carbohydrate permeases were regulated by a common mechanism involving phosphorylation of a cellular constituent by the phosphotransferase system, but that bacterial cells possess mechanisms for selectively uncoupling carbohydrate transport from regulation.     

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.     

Dopamine effect on ionic conduction and activity of adenylate cyclase in the central nervour system of Lymnaea stagnalis

We investigated the action of 3-hydroxytyramine (dopamine) on ionic conduction in membranes of identified neurons of the large pond snailLymnaea stagnalis and adenylate cyclase activity in membranes of the nervous tissue of this mollusc. Stimulatory and inhibitory influences of dopamine upon adenylate cyclase activity were detected. Application of the mediator to cells which produce growth hormone caused inward and outward currents modulated by a phosphodiesterase inhibitor. An influence of cAMP-dependent phosphorylation on dopamine-dependent and dopamine-independent activity of adenylate cyclase is demonstrated. It is suggested that phosphorylation in nervous tissues is one possible mechanism regulating the action of dopamine as a result of inhibition of the sensitivity of adenylate cyclase to the action of G-proteins.Bogomolets Institute of Physiology, Ukrainian Academy of Sciences, Kiev. Translated from Neirofiziologiya, Vol. 24, No. 4, pp. 437–451, July–August, 1992.     

Adenylate cyclase system of human skeletal muscle: Subcellular distribution and general properties

The subcellular localization of adenylate cyclase was examined in human skeletal muscle. Three major subcellular membrane fractions, plasmalemma, sarcoplasmic reticulum and mitochondria, were characterized by membrane-marker biochemical studies, by dodecyl sulfate polycrylamide gel electrophoresis and by electron microscopy. About 60% of the adenylate cyclase of the homogenate was found in the plasmalemmal fraction and 10–14% in the sarcoplasmic reticulum and mitochondria. When the plasmalemmal preparation was subjected to discontinuous sucrose gradients, the distribution of adenylate cyclase in different subfractions closely paralleled that of (Na⁺ + K⁺)-ATPase. The highest specific activity was found in a fraction which setteled at the 0.6–0.8 M sucrose interface. The electron microscopic study of this fraction revealed the presence of flattened sacs of variable sizes and was devoid of mitochondrial and myofibrillar material. The electron microscopy of each fraction supported the biochemical studies with enzyme markers. The three major membrane fractions also contained a low K_m phosphodiesterase activity, the highest specific activity being associated with sarcoplasmic reticulum.The plasmalemmal adenylate cyclase was more sensitive to catecholamine stimulation than that associated with sarcoplasmic reticulum or mitochondria. The catecholamine-sensitive, but not the basal, enzyme was further stimulated by GTP. The plasmalemmal adenylate cyclase had typical Michaelis-Menten kinetics with respect to ATP and the apparent K_m for ATP was approx. 0.3. mM. The pH optimum for that enzyme was 7.5. The enzyme required Mg²⁺, and the concentration to achieve half-maximal stimulation was approx. 3 mM. Higher concentrations of Mg²⁺ (about 10 mM) were inhibitory. Solubilization of the plasmalemmal membrane fraction with Lubrol-PX resulted in preferential extraction of 106 000- and 40 000-dalton protein components. The solubilized adenylate cyclase lost its sensitivity for catecholamine stimulation, and the extent of fluoride stimulation was reduced to one-sixth of that of the intact membranes. It is concluded that the catalytically active and hormone-sensitive adenylate cyclase is predominantly localized in the surface membranes of the cells within skeletal muscle. (That “plasmalemmal” fraction is considered likely to contain, in addition to plasmalemma of muscle cells, plasmalemma of bloodvessel cells (endothelium, and perhaps smooth muscle) which may be responsible for a certain amount of the adenylate cyclase activity and other propertiesobserved in that fraction.)The method of preparation used in this study provides a convenient material for evaluating the catecholamine-adenylate cyclase interactions in human skeletal muscle.     

Adenylate cyclase system of human skeletal muscle: Characteristics of catecholamine stimulation and nucleotide regulation

The subcellular localization of adenylate cyclase was examined in human skeletal muscle. Three major subcellular membrane fractions, plasmalemma, sarcoplasmic reticulum and mitochondria, were characterized by membrane-marker biochemical studies, by dodecyl sulfate polycrylamide gel electrophoresis and by electron microscopy. About 60% of the adenylate cyclase of the homogenate was found in the plasmalemmal fraction and 10–14% in the sarcoplasmic reticulum and mitochondria. When the plasmalemmal preparation was subjected to discontinuous sucrose gradients, the distribution of adenylate cyclase in different subfractions closely paralleled that of (Na⁺ + K⁺)-ATPase. The highest specific activity was found in a fraction which setteled at the 0.6–0.8 M sucrose interface. The electron microscopic study of this fraction revealed the presence of flattened sacs of variable sizes and was devoid of mitochondrial and myofibrillar material. The electron microscopy of each fraction supported the biochemical studies with enzyme markers. The three major membrane fractions also contained a low K_m phosphodiesterase activity, the highest specific activity being associated with sarcoplasmic reticulum.The plasmalemmal adenylate cyclase was more sensitive to catecholamine stimulation than that associated with sarcoplasmic reticulum or mitochondria. The catecholamine-sensitive, but not the basal, enzyme was further stimulated by GTP. The plasmalemmal adenylate cyclase had typical Michaelis-Menten kinetics with respect to ATP and the apparent K_m for ATP was approx. 0.3. mM. The pH optimum for that enzyme was 7.5. The enzyme required Mg²⁺, and the concentration to achieve half-maximal stimulation was approx. 3 mM. Higher concentrations of Mg²⁺ (about 10 mM) were inhibitory. Solubilization of the plasmalemmal membrane fraction with Lubrol-PX resulted in preferential extraction of 106 000- and 40 000-dalton protein components. The solubilized adenylate cyclase lost its sensitivity for catecholamine stimulation, and the extent of fluoride stimulation was reduced to one-sixth of that of the intact membranes. It is concluded that the catalytically active and hormone-sensitive adenylate cyclase is predominantly localized in the surface membranes of the cells within skeletal muscle. (That “plasmalemmal” fraction is considered likely to contain, in addition to plasmalemma of muscle cells, plasmalemma of bloodvessel cells (endothelium, and perhaps smooth muscle) which may be responsible for a certain amount of the adenylate cyclase activity and other propertiesobserved in that fraction.)The method of preparation used in this study provides a convenient material for evaluating the catecholamine-adenylate cyclase interactions in human skeletal muscle.     

Adentylate cyclase activity in myocardium of spontaneously hypertensive rat: effect of endogenous factors and solubilization

The isoproterenol- and glucagon-stimulated adenylate cyclase activities in the myocardial membranes of hypertensive rat were consistantly lower as compared with normal controls. Addition of cytosolic fraction (100,000 x$\text{g}$ supernatant) to the particulate preparation had an additive effect for glucagon and Gpp(NH)p stimulated enzyme activity and a synergistic effect for isoproterenol stimulation. Cytosolic fraction of normal control animals did not bring the adenylate cyclase activity in SHR equivalent to the control values. The basal and F^?-stimulated enzyme activity of solubilized adenylate cyclase was reduced by about 30% in SHR as compared with WKY, which could be due to a decrease in the actual amount of adenylate cyclase in the myocardium of SHR.