Compartmentalization of adenosine 3':5'-monophosphate and adenosine 3':5'-monophosphate-dependent protein kinase in heart tissue.

In rabbit heart homogenates about 50% of the cAMP-dependent protein kinase activity was associated with the low speed particulate fraction. In homogenates of rat or beef heart this fraction represented approximately 30% of the activity. The percentage of the enzyme in the particulate fraction was not appreciably affected either by preparing more dilute homogenates or by aging homogenates for up to 2 h before centrifugation. The particulate enzyme was not solubilized at physiological ionic strength or by the presence of exogenous proteins during homogenization. However, the holoenzyme or regulatory subunit could be solubilized either by Triton X-100, high pH, or trypsin treatment. In hearts of all species studied, the particulate-bound protein kinase was mainly or entirely the type II isozyme, suggesting isozyme compartmentalization. In rabbit hearts perfused in the absence of hormones and homogenized in the presence of 0.25 M NaCl, at least 50% of the cAMP in homogenates was associated with the particulate fraction. Omitting NaCl reduced the amount of particulate-bound cAMP. Most of the particulate-bound cAMP was probably associated with the regulatory subunit in this fraction since approximately 70% of the bound nucleotide was solubilized by addition of homogeneous catalytic subunit to the particulate fraction. The amount of cAMP in the particulate fraction (0.16 nmol/g of tissue) was approximately one-half the amount of the regulatory subunit monomer (0.31 nmol/g of tissue) in this fraction. The calculated amount of catalytic subunit in the particulate fraction was 0.18 nmol/g of tissue. Either epinephrine alone or epinephrine plus 1-methyl-3-isobutylxanthine increased the cAMP content of the particulate and supernatant fractions. The cAMP level was increased more in the supernatant fraction, possibly because the cAMP level became saturating for the regulatory subunit in the particulate fraction. The increase in cAMP was associated with translocation of a large percentage of the catalytic subunit activity from the particulate to the supernatant fraction. The distribution of the regulatory subunit of the enzyme was not significantly affected by this treatment. The catalytic subunit translocation could be mimicked by addition of cAMP to homogenates before centrifugation. The data suggest that the regulatory subunit of the protein kinase, at least that of isozyme II, is bound to particulate material, and theactive catalytic subunit is released by formation of the regulatory subunit-cAMP complex when the tissue cAMP concentration is elevated. A model for compartmentalized hormonal control is presented.     

Nickel in the catalytically active hydrogenase of Alcaligenes eutrophus.

Nickel is a constituent of soluble and particulate hydrogenase of Alcaligenes eutrophus. Incorporation of 63Ni2+ revealed that almost the total nickel taken up by the cells was bound to the protein. Chromatography of a crude extract on diethylaminoethyl cellulose demonstrated an association of 63Ni2+ with soluble and particulate hydrogenase, supported by further analysis like polyacrylamide gel electrophoresis. Unspecific binding of 63Ni2+ to the protein was excluded by comparison with a mutant extract free of hydrogenase protein. X-ray fluorescence analysis of the homogeneous soluble hydrogenase indicated the presence of 2 mol of nickel per mol of enzyme, whereas the amount of nickel determined by incorporation of 63Ni2+ was calculated to be approximately 1 mol/mol of enzyme. Cells grown under nickel limitation contained catalytically inactive, but serologically active, soluble and particulate hydrogenase. The immunochemical reactions were only partially identical with the enzyme from nickel-cultivated cells indicating a structural modification of the proteins in the absence of nickel. It is concluded that nickel is essential for the catalytic activity of hydrogenase and not involved as a regulatory component in the synthesis of this enzyme.     

A kinetic analysis of activation of smooth muscle adenylate cyclase by forskolin

Forskolin action was studied using uterine smooth muscle adenylate cyclase, an enzyme form that is slowly and irreversibly activated by treatment with nonhydrolyzable GTP analogs. Activation of the particulate smooth muscle enzyme by prolonged treatment with Gpp[NH]p (guanyl-5′-yl imidodiphosphate) at 24 °C followed simple Michaelis-Menten kinetics with respect to the guanine nucleotide. Under these treatment conditions, forskolin increased both the V_max and the K_m for Gpp[NH]p, suggesting diterpene action affected the guanine nucleotide-binding coupling factor. Sensitivity of a detergent-solubilized form of the enzyme to stimulation by both Gpp[NH]p and forskolin was much more labile at 4 °C than was the Mn⁺² sensitivity of the catalytic subunit. In the particulate form, the catalytic subunit was more resistant to the denaturing effects of N-ethylmaleimide than was its sensitivity to stimulation by Gpp[NH]p or forskolin. Forskolin stimulation of the particulate form of the enzyme followed simple Michaelis-Menten kinetics with respect to the concentration of the diterpene. Denaturation of the enzyme by treatment with N-ethylmaleimide lowered the V_max and increased the K_m for forskolin, further suggesting that forskolin had an indirect effect on the activity of the catalytic subunit. These results could be accounted for if the diterpene, like Gpp[NH]p, was bound by the coupling factor.     

EFFECT OF FATTY ACIDS ON RAT BRAIN PARTICULATE HEXOKINASE

Abstract— The effect of free fatty acids on rat brain particulate hexokinase was studied in vitro. Hexokinase bound with brain mitochondrial fraction was found to be sensitive to the action of free fatty acids, resulting in the solubilization of at least part of bound enzyme activity into the supernatant. The decrease of total enzyme activity observed at the highest free fatty acid concentration was probably due to the inhibition of hexokinase. The physiological consequence of hexokinase solubilization by low concentrations of free fatty acids, similar to that observed in vivo , is discussed in relation to activity changes of soluble and particulate enzyme forms demonstrated previously under hypoxic conditions.     

Mitochondrial glycerol kinase activity in rat brain.

Glycerol kinase activity was found in the particulate fraction of rat brain homogenates predominantly associated with mitochondria. The enzyme remained bound to the particulate fraction after treatment with a variety of solubilizing agents.     

Soluble precursor of membrane-associated protein kinase in uterine smooth muscle cells

Incubation of smooth muscle strips from rat uterus with isoproterenol resulted in redistribution of protein kinase activity between the cytosol and a 20,000 to 50,000g membrane fraction. Similarities in the elution properties of the cytosolic and membrane-associated forms of the enzyme on DEAE-cellulose ion exchange chromatography further suggested the two forms were the same. The nature of membrane binding of the soluble enzyme was investigated using smooth muscle microsomal and cytosol fractions. Membranes readily bound the soluble enzyme when the two subcellular compartments were reconstituted and incubated at 30 °C for 10 min. The extent of binding was proportional to the ratio of membranes to cytosol and was characterized by the inhibition of soluble enzyme activity toward exogenous substrates in a Triton X-100 reversible manner. In marked contrast to the binding of soluble protein kinase to heart particulate fractions, binding of the cytosol enzyme to smooth muscle cell membranes was unaffected by ionic strength or cAMP. The latter property indicated holoenzyme was bound in a manner similar to the free catalytic subunit of cAMP-dependent protein kinase and suggested the enzyme was bound by association between the membrane and the catalytic subunit. Binding of cytosol protein kinase to the membranes rendered the enzyme insensitive to trypsin digestion and the capacity of the smooth muscle cell membranes to bind the soluble enzyme exceeded that of other rat tissue fractions. Resistance to salt extraction and proteolysis, as well as its detergent dependence, suggested the soluble enzyme became an integral or intrinsic membrane protein following association with the membrane. The ability of membranes to incorporate [γ-³²P]ATP into phosphoprotein was lost on detergent extraction of protein kinase and restored in an apparently specific manner when extracted and washed membranes were reconstituted with soluble enzyme. The intrinsic nature of membrane protein kinase and the apparent specificity with which the soluble enzyme was hound by membranes further indicated that, in myometrium. hormone-induced translocation of protein kinase is an important mechanism by which enzyme activity is increased in the vicinity of its in situ substrates.     

Substrate inhibition of soluble and bound lactate dehydrogenase (isoenzyme 5)

Substrate inhibition of chicken lactate dehydrogenase (EC 1.1.1.27) isoenzyme 5, was studied with the enzyme in the soluble phase and bound to muscle subcellular particulate structures. Inhibition studies were performed by incubating bound or soluble enzyme with NAD⁺ prior to measuring the reaction with a stopped-flow technique at 40 °C and a concentration of enzyme of 10^?7m. The value of V for soluble lactate dehydrogenase was 610 nmoles per sec, and for the bound enzyme it was 262. k_m (pyruvate) values were similar for both enzymes. Under our experimental conditions, up to 73% inhibition of the soluble enzyme was observed. On the other hand, there was no detectable inhibition of bound lactate dehydrogenase. It is suggested that the resistance to substrate inhibition of bound lactate dehydrogenase may possibly be due to the prevention of dissociation of the enzyme into monomeric or other subunits because of attachment to the particulate structures.     

Purification and characterization of trehalose-hydrolyzing enzymes from thoracic musculature of the american cockroach,Periplaneta americana

Trehalose-hydrolyzing enzymes from particulate and cytosolic components of the thoracic musculature of Periplaneta americana were isolated and purified to homogeneity. The molecular weights of the respective enzymes were determined by SDS-polyacrylamide gel electrophoresis and Sephadex G-150 column chromatography and estimated to be 80,000 Da for the cytosolic enzyme whereas the solubilized enzyme of particulate origin has a molecular weight of approx. 110,000 Da. The cytosolic enzyme hydrolyzes a number of α-glycosides in addition to trehalose and, therefore, may be classified as a general α-glucosidase whereas the particulate enzyme exhibits stringent specificity for trehalose. Chemical modification of the particulate trehalase has revealed involvement of carboxyl and imidazole functions in the catalytic mechanism. Of various compounds tested, castanospermine was the most potent inhibitor of the enzyme.     

Lactate dehydrogenase associated with the mitochondrial fraction and with a mitochondrial inhibitor--I. Enzyme binding to the mitochondrial fraction

Rabbit skeletal muscle mitochondrial fraction shows LDH activity (212 +/- 43 U/g pellet). The majority of the mitochondrial enzyme was solubilized by washing with 0.15 M NaCl, pH 6, or by ultrasonic treatment in the same medium. It was also solubilized on increasing the ionic strength and the pH of the medium. Cytosoluble LDH was observed to bind in vitro to the particulate fraction and the enzyme bound was a sigmoidal function of the amount of soluble enzyme added. The bound enzyme is less active than the soluble one. Kinetically, active mitochondrial fraction or in vitro bound enzyme showed non-hyperbolic behavior which is different from the bi-bi sequential-ordered type mechanism of the soluble enzyme.     

Antiserum against the catalytic subunit of adenosine 3'':5''-cyclic monophosphate-dependent protein kinase. Reactivity towards various protein kinases.

An antiserum against the catalytic subunit C of cyclic AMP-dependent protein kinase, isolated from bovine heart type II protein kinase, was produced in rabbits. Reaction of the catalytic subunit with antiserum and separation of the immunoglobulin G fraction by Protein A-Sepharose quantitatively removed the enzyme from solutions. Comparative immunotitration of protein kinases showed that the amount of antiserum required to eliminate 50% of the enzymic activity was identical for pure catalytic subunit, and for holoenzymes type I and type II. The reactivity of the holoenzymes with the antiserum was identical in the absence or the presence of dissociating concentrations of cyclic AMP. Most of the holoenzyme (type II) remains intact when bound to the antibodies as shown by quantification of the regulatory subunit in the supernatant of the immunoprecipitate. Titration with the antibodies also revealed the presence of a cyclic AMP-independent histone kinase in bovine heart protein kinase I preparations obtained by DEAE-cellulose chromatography. Cyclic AMP-dependent protein kinase purified from the particulate fraction of bovine heart reacted with the antiserum to the same degree as the soluble enzyme, whereas two cyclic AMP-independent kinases separated from the particle fraction neither reacted with the antiserum nor influenced the reaction of the antibodies with the cyclic AMP-dependent protein kinase. Immunotitration of the protein kinase catalytic subunit C from rat liver revealed that the antibodies had rather similar reactivities towards the rat liver and the bovine heart enzyme. This points to a relatively high degree of homology of the catalytic subunit in mammalian tissues and species. Broad applicability of the antiserum to problems related to cyclic AMP-dependent protein kinases is thus indicated.     

Hysteresis behavior of complex I in delta mu H+-dependent reduction of NAD+ succinate

It was shown that the membrane-bound complex I is fully inactive in the absence of NADH during the reverse electron transfer from succinate to NAD+. The enzyme activation is attained by preincubation of submitochondrial particles with low concentrations of NADH; the activating effect persists after a complete oxidation of the latter during long-term (several hours) aerobic incubation. The experimental results suggest that complex I contains a redox component, whose reduction by NADH and aerobic oxidation are not involved in the overall catalytic reaction. An experimental scheme is proposed, according to which the key role of such a component is ascribed to the tightly bound ubiquinone; the activation and inactivation of the enzyme are due to a slow reversible redox conversion (ubiquinone in equilibrium ubisemiquinone), whereas the catalytic act involves a rapid reversible conversion (ubisemiquinone in equilibrium ubiquinol). It was demonstrated that the "redox" mechanism of the inactivation-activation reaction determines the strong dependence of activity of the reverse electron transfer on the mode of preparation of submitochondrial particles. The coupling properties of the submitochondrial particulate membrane and the activities of enzymes involved in the reverse electron transfer are stable at room temperature for over 14 hours.     

Mechanism of aldolase binding to erythrocyte membrane: Part II. Kinetic aspects

The nature of binding of FDP aldolase to bovine erythrocyte membrane was examined. The Km value of bound and soluble enzyme differed by an order. The absence of time-lag in the velocity-time curves at various concentrations of the substrate and the similar extent of inactivation of bound and soluble enzyme on heat treatment suggested that the enzyme was bound at a point other than the catalytic site. The release of the enzyme by various glycolytic intermediates suggested their involvement in binding to the catalytic site through phosphate linkage. The non-phosphorylated compounds like lactate, reduced glutathione, 2-mercaptoethanol and EDTA were ineffective in eluting the enzyme. On the basis of separate binding sites on the enzyme for membrane and ligands, the mechanism of association dissociation of aldolase has been suggested.     

Structure of membrane-associated and solubilized uterine adenylate cyclase. Evidence against activation through dissociable subunit interactions in the lipid bilayer

Adenylate cyclase was extracted from the rat uterus with Lubrol PX in a form which remained soluble following centrifugation for 60 min at 100,000g. The soluble enzyme was stimulated by both Mn+2 and by guanyl-5'-yl-imidodiphosphate (Gpp(NH)p), indicating that both the catalytic subunit (C) and the guanyl nucleotide-binding coupling factor (N) had been extracted. Catalytic activity was bound by a GTP-affinity resin only under conditions which resulted in irreversible activation of the native (particulate) form of the enzyme and could be eluted under acidic conditions shown to reverse the activated state. The S020,w of the soluble enzyme in both its activated and unactivated state was determined by linear sucrose gradient centrifugation. Activation by prolonged treatment with Gpp(NH)p did not alter the S020,w of the enzyme whether treatment was carried out before or after solubilization. The chaotrope LiBr (0.4 M) reduced the S020,w of the soluble enzyme but its smaller size was still not altered by activation with Gpp(NH)p. These results indicate that most adenylate cyclase activity in uterine membranes exists as a preformed complex between the catalytic subunit and the coupling factor: NC. The existence of this complex explains some of the temperature-dependent properties previously described for this form of the enzyme and suggests that dissociable interactions between the subunits do not play a role in the activation of C by guanyl nucleotides.     

Subcellular distribution and activation by non-ionic detergents of guanylate cyclase in cerebral cortex of rat

Non-ionic detergents stimulated particulate guanylate cyclase activity in cerebral cortex of rat 8- to 12-fold while stimulation of soluble enzyme was 1.3- to 2.5-fold. Among various detergents, Lubrol PX was the most effective one. The subcellular distribution of guanylate cyclase activity was examined with or without 0.5% Lubrol PX. Without Lubrol PX two-thirds of the enzyme activity was detected in the soluble fraction. In the presence of Lubrol PX, however, two-thirds of guanylate cyclase activity was recovered in the crude mitochondrial fraction. Further fractionation revealed that most of the particulate guanylate cyclase activity was associated with synaptosomes. The sedimentation characteristic of the particulate guanylate cyclase activity was very close to those of choline acetyltransferase and acetylcholine esterase activities, two synaptosomal enzymes. When the crude mitochondrial fraction was subfractionated after osmotic shock, most of guanylate cyclase activity as assayed in the absence of Lubrol PX was released into the soluble fraction while the rest of the enzyme activity was tightly bound to synaptic membrane fractions. The total guanylate cyclase activity recovered in the synaptosomal soluble fraction was 6 to 7 times higher than that of the starting material. The specific enzyme activity reached more than 1000 pmol per min per mg protein, which was 35-fold higher than that of the starting material. The membrane bound guanylate cyclase activity was markedly stimulated by Lubrol PX. Guanylate cyclase activity in the synaptosomal soluble fraction, in contrast, was suppressed by the addition of Lubrol PX. The observation that most of guanylate cyclase activity was detected in synaptosomes, some of which was tightly bound to the synaptic membrane fraction upon hypoosmotic treatment, is consistent with the concept that cyclic GMP is involved in neural transmission.     

Interaction of ox heart mitochondrial F1-ATPase with immobilized ADP and ATP.

The reaction of mitochondrial F1-ATPase with immobilized substrate was studied by using columns of agarose-hexane-ATP. Mg2+ was required for binding of the enzyme to the column matrix. The column-bound enzyme could be eluted fully by ATP and other nucleoside triphosphates. Nucleoside di- and mono-phosphates were less effective. At a fixed concentration of nucleotide the effectiveness of elution was proportional to the charge on the eluting molecule. The ATP of the column matrix was hydrolysed by the bound F1-ATPase to release phosphate, probably by a uni-site reaction mechanism. Thus the F1-ATPase was bound to the immobilized ATP by a catalytic site. Treatment of the bound F1-ATPase with 4-chloro-7-nitrobenzofurazan prevented complete release of the enzyme by ATP. Only one-third of the bound enzyme was now eluted by the nucleotide. The inhibition of release could be due either to the inhibitor blocking co-operative interactions between sites or to its increasing the tightness of binding of immobilized ADP at the catalytic site.     

Activation of adenylate cyclase by forskolin in rat brain and testis

Detergent-dispersed adenylate cyclase from rat cerebrum was detected in two components, one sensitive to Ca2+ and calmodulin and another sensitive to fluoride or guanyl-5'-yl imidodiphosphate (Gpp(NH)p). The enzyme activity of both components was markedly augmented by forskolin assayed in the presence or absence of other enzyme activators (e.g., NaF, Gpp(NH)p, calmodulin). The catalytic subunit fraction in which G/F protein was totally lacking was also activated by forskolin. During 1-35 days of postnatal development, the basal adenylate cyclase activities in either cerebrum and cerebellum particulate preparations progressively increased. While the fluoride sensitivity of the cerebrum and cerebellum enzyme increased during postnatal development, the responsiveness to forskolin remained unaltered. There was no enhancement of soluble adenylate cyclase (from rat testis) by forskolin under the assay conditions in which there was a marked stimulatory action on the particulate enzyme. The results seen with the solubilized enzyme, with either Lubrol PX or cholate, indicate that the effects of forskolin on the cyclase do not require either G/F protein or calmodulin and the results of our study of brain enzymes support this view. Data on soluble testis cyclase (a poor or absent response to forskolin by this enzyme) imply that it lacks a protein (other than the catalytic unit) which could confer greater stimulation. The present results do not rule out an alternative explanation that forskolin stimulates adenylate cyclase by a direct interaction with the catalytic subunit, if the catalytic proteins do differ widely in various species of cells and their response to this diterpene.     

Purification and characterization of a pyridine nucleotide glycohydrolase from rabbit spleen

A particulate NMN glycohydrolase of rabbit spleen was solubilized with Triton X100 and purified approximately 100-fold. The enzyme was shown to have a pH maximum of 6.5, a Km of 0.25 mM, a Vmax of 5.3 mumol/min/mg protein, an activation energy of 7.9 kcal/mol, and a molecular weight of approximately 400,000. Both of the purified and the particulate enzymes exhibited identical catalytic properties with respect to substrate specificity, activation energy, pH profile and exchange reaction with nicotinic acid, except that the purified enzyme was highly activated with Triton X100 as compared with the particulate enzyme; it appears that the purified enzyme possesses the same catalytic properties as the enzyme present in the tissue and that solubilization does not significantly alter the native protein. In addition to catalytic activity with NMN, the rabbit spleen enzyme catalyzed an irreversible hydrolysis with NAD and NADP, exhibiting catalyzing activity ratios of NMN:NAD:NADP = 1.00:1.45:0.44 and Vmax/Km ratios of 1.00:1.7:2.3, respectively. These ratios of activity remained constant throughout purification of the enzyme and no separation of these activities was detected. Mutually competitive inhibition of the enzyme with Ki values similar to Km, and identical rates of thermal denaturation of the enzyme and activity-pH profiles with NMN or NAD indicated the hydrolysis of the C-N glycosidic linkage of the pyridine nucleotides to be catalyzed by the same enzyme. The enzyme was less specific for the purine structure of the substrate dinucleotides but was stereospecific for the glycosidic linkage cleaved. Nicotinamide riboside, the nicotinic acid analogs and the reduced forms were not hydrolyzed. A linear noncompetitive inhibition of NMN hydrolysis with nicotinamide indicated an ordered Uni-Bi mechanism in which nicotinamide was the first product released from the enzyme. A property that the rabbit spleen enzyme appears to share with other NAD glycohydrolases is the transglycosidation reaction. The ratio of transglycosidation reaction vs. hydrolysis catalyzed by the enzyme in the presence of NMN and nicotinic acid indicated that the enzyme could function as a primary transglycosidase rather than a hydrolytic enzyme in vivo.     

The guanylyl cyclase-receptor family.

Guanylyl cyclase activity exists in the soluble and particulate fractions of most tissue homogenates. Recently, the mRNA encoding members of the enzyme family from both the soluble and particulate fraction have been cloned. The soluble form exists as a heterodimer, both subunits containing cyclase catalytic-like amino acid sequences. Both subunits must be expressed to observe enzyme activity. The particulate (plasma membrane) forms contain a single putative transmembrane domain that separates an extracellular, ligand-binding domain from an intracellular, protein kinase-like and cyclase catalytic region. The protein kinase-like domain appears to serve as an important regulatory element of the receptor.     

Affinity separation of an acid phosphatase from rat tissues and Gaucher spleen with immobilized Cibacron Blue

An acid phosphatase species which was activated by Fe2+ was determined to be partially soluble but mainly particulate in rat spleen. The particulate enzyme could be extracted into 1 M KCl. This enzyme bound to Cibacron Blue-immobilized Sepharose (Blue-Sepharose) and was desorbed by 2 M KCl with a good yield, while the other acid phosphatases in rat spleen did not adsorb on Blue-Sepharose. The enzymes eluted on Blue-Sepharose chromatography of both the soluble and particulate fractions were electrophoretically identical. The enzyme hydrolyzed aryl monophosphates, phosphoproteins, and nucleoside di- and triphosphates. The activity for the three kinds of substrate was similarly activated by Fe2+, ascorbic acid and cysteine, and inhibited by molybdate, Cu2+ and F-. Cibacron Blue inhibited the enzyme competitively with respect to a substrate, p-nitrophenyl phosphate, but kinetic analysis suggested that more than one dye molecule binds to the enzyme. The Blue-Sepharose technique could be applied not only to quantitative separation of acid phosphatases similar to the spleen enzyme from bone and epidermis of rat, but also to that of a tartrate-resistant acid phosphatase from human spleen with Gaucher's disease.     

A unique proteolytic action of HCE, a constituent protease of a fish hatching enzyme: tight binding to its natural substrate, egg envelope

High choriolytic enzyme (HCE), a constituent protease of the hatching enzyme of the teleost, Oryzias latipes, swells its natural substrate, egg envelope (chorion) by hydrolyzing it partially. This enzyme was found to be bound tightly to the chorion when it exerted catalytic action. This was evidenced by the experimental results showing (i) that the turnover of this enzyme seemed to be hindered by the chorion, (ii) that the enzyme bound to the chorion could be recovered by washing with an alkaline medium, and (iii) that the bound enzyme could be quantified by radioimmunological estimation. The bound enzyme sustained its original activity and the binding between the enzyme and the chorion seems to be stoichiometric.