Escherichia coli S-adenosylhomocysteine/5''-methylthioadenosine nucleosidase. Purification, substrate specificity and mechanism of action.

Ca2+-activated protein phosphatase activity was demonstrated in mouse pancreatic acinar cytosol with alpha-casein and skeletal-muscle phosphorylase kinase as substrates. This phosphatase activity preferentially dephosphorylated the alpha subunit of phosphorylase kinase. After DEAE-cellulose chromatography, the Ca2+-activated phosphatase activity became dependent on exogenous calmodulin for maximal activity. Half-maximal activation was achieved at 0.5 +/- 0.1 microM-Ca2+. Trifluoperazine completely inhibited Ca2+-activated phosphatase activity, with half-maximal inhibition occurring at 8.5 +/- 0.6 microM. Mn2+, but not Mg2+, at 1 mM concentration could substitute for Ca2+ in eliciting full enzyme activation. The apparent Mr of the phosphatase as determined by Sephadex G-150 chromatography was 93000 +/- 1000. Submitting active fractions obtained after Sephadex chromatography to calmodulin affinity chromatography resulted in the resolution of a major protein of Mr 55500 +/- 300. In conclusion, Ca2+-activated protein phosphatase activity has been identified in exocrine pancreas and has several features in common with Ca2+-activated calmodulin-dependent protein phosphatases previously isolated from brain and skeletal muscle. It is possible that this Ca2+-activated phosphatase may utilize as substrates certain acinar-cell phosphoproteins previously shown to undergo dephosphorylation in response to Ca2+-mediated secretagogues.     

Interaction of calmodulin with histones. Alteration of histone dephosphorylation

The Ca2+-dependent regulator protein (CDR), also frequently termed "calmodulin" was determined to influence the dephosphorylation of mixed calf thymus histones or purified histones 1, 2A, or 2B by a partially purified bovine brain phosphoprotein phosphatase. CDR increase the rate of dephosphorylation of mixed histones more than 20-fold. With increasing concentrations of mixed histones as substrate, a proportionate increase of CDR concentration was required to maintain maximal expression of histone phosphatase activity. Mixed histones suppressed the activation by CDR of a bovine brain cyclic nucleotide phosphodiesterase activity, with activation being restored by increased quantities of CDR. Dephosphorylation of casein and phosphorylase alpha by the phosphatase preparation was not affected by CDR. These observations support the interpretation that the effects of CDR on histone dephosphorylation are substrate-directed. The rates of dephosphorylation of histones 1, 2A, and 2B by the phosphatase were 4- to 12-fold more rapid at low (sub-micromolar) concentrations of free Ca2+ than at high (200 microM) Ca2+ in incubations containing CDR, but they were unaffected by Ca2+ in incubations without CDR. The addition of stoichiometric quantities of calmodulin increased the apparent Km of the phosphatase for the various histones 2- to 6-fold, while maximal velocities were 4- to 12-fold higher at low than at high added Ca2+. The inhibitory effect of Ca2+ on histone dephosphorylation was immediately reversible by chelation of Ca2+ with EDTA. Ca2+-dependent inhibition of histone 1 or 2B phosphatase activities was also produced by rabbit skeletal muscle troponin C, but not by rabbit skeletal muscle parvalbumin, by poly(L-aspartate) or poly(L-glutamate). The phosphorylated fragment from the NH2-terminal region of either H2A (generated by treatment with N-bromosuccinimide) or H2B (generated by treatment with cyanogen bromide) was dephosphorylated by the phosphatase, with the rates of dephosphorylation being reduced 3- to 6-fold by Ca2+ in incubations containing CDR.     

Doxorubicin inhibits the phosphate-transport protein reconstituted in liposomes. A study on the mechanism of the inhibition

Using Thr(P)-inhibitor-1 and Ser(P)-casein as substrates, studies on the activation of calcineurin purified from bovine brain have been carried out. The phosphatase requires the synergistic action of Ca2+, calmodulin and another divalent cation (Mg2+, Mn2+, Co2+ or Ni2+, but not Zn2+) for full expression of its activity. Ca2+ and Ca2+ X calmodulin act as allosteric activators to transform the phosphatase to a relaxed conformation, while Mg2+ acts solely as a cofactor for the catalytic action of the enzyme. In addition to their function as cofactors for catalysis, transition metal ions can also substitute for Ca2+ as allosteric activators. Ca2+ and calmodulin exert their activating effects mainly by increasing the Vm of the phosphatase reaction with little effect on the Km values for the substrates or on the KA values for the divalent cation cofactors. The predominant factor in dictating the catalytic properties of calcineurin is the divalent cation cofactor. For example, with Mg2+ as a cofactor, the phosphatase exhibits an optimum around pH 8.0-8.5; while with a transition metal ion as a cofactor, the optimum is around pH 7.0-7.5, regardless of whether Thr(P)-inhibitor-1 or Ser(P)-casein serves as a substrate, in the absence or the presence of Ca2+ X calmodulin.     

Characterization of bovine brain calmodulin-dependent protein phosphatase

Calmodulin-dependent protein phosphatase of bovine brain exhibited a pH optimum of 7 and appeared to require sulfhydryl groups for activity. Phosphatase activity was inhibited by both NaF and ZnCl2, but was stimulated approximately 2-fold by MnCl2. The enzyme exhibited broad substrate specificity, dephosphorylating casein, troponin I, protamine, histone, and phosvitin, and was not phosphorylated by cAMP-dependent protein kinase. With 32P-labeled casein as a substrate, phosphatase was activated 15-fold by calmodulin; the dissociation constant of phosphatase for calmodulin was 30 nM. Activation of the enzyme by calmodulin as a function of Ca2+ was highly cooperative; the Hill coefficient was 4.9. At a saturating concentration of calmodulin, half-maximal activation of phosphatase was obtained at 0.3 microM Ca2+. Calmodulin increased the Vmax from 1.7 to 41 nmol mg protein-1 min-1 with no significant change in its Km. Formation of a Ca2+-dependent complex between calmodulin and the phosphatase was demonstrated by a calmodulin-Sepharose affinity column, gel-filtration chromatography, and sedimentation on a sucrose density gradient. The rate of formation and dissociation of the calmodulin X phosphatase complex was rapid and readily reversible in response to changes in Ca2+ concentration. The calmodulin X phosphatase complex consists of 1 mol of calmodulin and 1 mol of phosphatase.     

Insulin-stimulated phosphorylation of calmodulin by rat liver insulin receptor preparations

Insulin stimulates autophosphorylation of the beta subunit of its receptor and activates the associated tyrosine kinase. This kinase, in turn, phosphorylates a number of specific protein substrates; however, the functional and structural identity of these substrates is largely unknown. In this study, we demonstrate that insulin also stimulates the phosphorylation of calmodulin by rat hepatocyte insulin receptors partially purified by wheat germ agglutinin affinity chromatography. Phosphorylation occurred predominantly on tyrosine residues and had an absolute requirement for insulin receptors, divalent cations, and certain basic proteins. Maximal 32P incorporation was observed at an insulin concentration of 5 X 10(-9) M, and the K0.5 for insulin was approximately 4 X 10(-10) M. Phosphorylation of calmodulin was dependent upon ATP, saturating at 100 microM ATP with a K0.5 of 30 microM. Insulin-stimulated phosphorylation of calmodulin was also dependent upon Mg2+ or Mn2+, but was approximately 12-fold greater in the presence of Mg2+. Maximal phosphorylation was observed in the absence of Ca2+ and was inhibited at Ca2+:EGTA ratios greater than 0.8 (0.16 microM free Ca2+). Certain basic proteins, such as polylysine, histone Hf2b, and protamine sulfate, were necessary to observe insulin-stimulated phosphorylation of calmodulin. The relative amount of insulin-stimulated phosphorylation of calmodulin observed in the presence of each of these proteins differed. Maximal insulin-stimulated phosphorylation was observed in the presence of polylysine. These data suggest that both Ca2+ and calmodulin may participate in the early post-receptor events in the cellular mechanism of insulin action in hepatocytes.     

Phosphorylation and characterization of bovine heart calmodulin-dependent phosphodiesterase.

Calmodulin-dependent phosphodiesterase was purified to apparent homogeneity from the total calmodulin-binding fraction of bovine heart in a single step by immunoaffinity chromatography. The isolated enzyme had significantly higher affinity for calmodulin than the bovine brain 60-kDa phosphodiesterase isozyme. The cAMP-dependent protein kinase was found to catalyze the phosphorylation of the purified cardiac calmodulin-dependent phosphodiesterase with the incorporation of 1 mol of phosphate/mol of subunit. The phosphodiesterase phosphorylation rate was increased severalfold by histidine without affecting phosphate incorporation into the enzyme. Phosphorylation of phosphodiesterase lowered its affinity for calmodulin and Ca2+. At constant saturating concentrations of calmodulin (650 nM), the phosphorylated calmodulin-dependent phosphodiesterase required a higher concentration of Ca2+ (20 microM) than the nonphosphorylated phosphodiesterase (0.8 microM) for 50% activity. Phosphorylation could be reversed by the calmodulin-dependent phosphatase (calcineurin), and dephosphorylation was accompanied by an increase in the affinity of phosphodiesterase for calmodulin.     

Characterization of phosphotyrosyl-protein phosphatase activity associated with calcineurin

Calcineurin purified from bovine brain is shown to possess phosphotyrosyl -protein phosphatase activity towards proteins phosphorylated by the epidermal growth factor receptor/kinase. The phosphatase activity is augmented by Ca2+/calmodulin or divalent cation (Ni2+ greater than Mn2+ greater than Mg2+ greater than Co2+). In the simultaneous presence of all three effectors, the enzymatic activity is synergistically increased. Ca2+/calmodulin activates the Mg2+-supported activity by decreasing the Km value for phosphotyrosyl -casein from 2.2 to 0.6 microM, and increasing the Vmax from 0.4 to 4.6 nmol/min/mg. These results represent the first demonstration that calcineurin can dephosphorylate phosphotyrosyl -proteins and suggest a novel mechanism of activation of this enzyme.     

Characterization of a calmodulin-dependent protein phosphatase from human platelets

A calmodulin-dependent protein phosphatase has been identified in human platelets by its cross-reactivity with an antibody developed against a bovine brain calmodulin-dependent protein phosphatase and by its calmodulin-stimulated dephosphorylation of 32P-labeled substrates. The platelet enzyme was partially purified to separate it from calmodulin and calmodulin-independent phosphatases. The partially purified enzyme was stimulated by calmodulin, requiring 15 nM calmodulin for half-maximal activation. Calmodulin increased the Vmax of the phosphatase, with no significant effect on its Km. The enzyme was stimulated irreversibly and made calmodulin-independent by limited proteolysis. The optimal pH for the phosphatase was 7.5. After partial purification, phosphatase activity was significantly increased in the presence of Mn2+ and Ca2+ over that observed in the presence of Ca2+ alone. The enzyme effectively dephosphorylated casein, histone, protamine, and platelet actin. The holophosphatase was estimated to have a molecular weight of 76,900 as determined by sedimentation on sucrose gradients. Immunoblotting techniques using an antibody against the brain phosphatase suggests that the enzyme consists of 2 subunits of 60,000 and 16,500 daltons; the 60,000-dalton subunit co-migrates in sodium dodecyl sulfate-polyacrylamide gel electrophoresis with a 60,000-dalton calmodulin-binding protein in the platelet suggesting that it is the calmodulin-binding subunit of the enzyme. The identification of a calmodulin-dependent protein phosphatase in human platelets suggests a role for Ca2+-dependent dephosphorylation in platelet activation.     

Dephosphorylation of neuromodulin by calcineurin

Neuromodulin (p57, GAP-43, F1, B-50) is a major neural-specific, calmodulin binding protein found in brain, spinal cord, and retina that is associated with membranes. Phosphorylation of neuromodulin by protein kinase C causes a significant reduction in its affinity for calmodulin (Alexander, K. A., Cimler, B. M., Meirer, K. E., and Storm, D. R. (1987) J. Biol. Chem. 262, 6108-6113). It has been proposed that neuromodulin may function to bind and concentrate calmodulin at specific sites within neurons and that activation of protein kinase C causes the release of free calmodulin at high concentrations near its target proteins. It was the goal of this study to determine whether bovine brain contains a phosphoprotein phosphatase that will utilize phosphoneuromodulin as a substrate. Phosphatase activity for phosphoneuromodulin was partially purified from a bovine brain extract using DEAE-Sephacel and Sephacryl S-200 gel filtration chromatography. The neuromodulin phosphatase activity was resolved into two peaks by Affi-Gel Blue chromatography. One of these phosphatases, which represented approximately 60% of the total neuromodulin phosphatase activity, was tentatively identified as calcineurin by its requirement for Ca2+ and calmodulin (CaM) and inhibition of its activity by chlorpromazine. Therefore, bovine brain calcineurin was purified to homogeneity and examined for its phosphatase activity against bovine phosphoneuromodulin. Calcineurin rapidly dephosphorylated phosphoneuromodulin in the presence of micromolar Ca2+ and 3 microM CaM. The apparent Km and Vmax for the dephosphorylation of neuromodulin, measured in the presence of micromolar Ca2+ and 2 microM CaM, were 2.5 microM and 70 nmol Pi/mg/min, respectively, compared to a Km and Vmax of 4 microM and 55 nmol Pi/mg/min, respectively, for myosin light chain under the same conditions. Dephosphorylation of neuromodulin by calcineurin was stimulated 50-fold by calmodulin in the presence of micromolar free Ca2+. Half-maximal stimulation was observed at a calmodulin concentration of 0.5 microM. We propose that phosphoneuromodulin may be a physiologically important substrate for calcineurin and that calcineurin and protein kinase C may regulate the levels of free calmodulin available in neurons.     

Ca2(+)-dependent protein phosphatase which dephosphorylates regulatory light chain-a in scallop smooth muscle myosin

Ca2(+)-dependent protein phosphatase was purified from scallop adductor smooth muscle by a combination of DEAE-Toyoperal 650S ion exchange chromatographies and gel filtration on Sephacryl S-300. The phosphatase consisted of two subunits having molecular weights of 60 and 19 kDa. Phosphorylated regulatory light chain-a (RLC-a) was dephosphorylated by this phosphatase both in free and bound states in myosin prepared from the opaque portion of scallop smooth muscle (opaque myosin). The dephosphorylation was activated by Ca2+. The half maximal activation was a 1 microM free Ca2+ in the presence of calmodulin and 7 microM free Ca2+ in the absence of calmodulin. Opaque myosin phosphorylated at the heavy chain was not dephosphorylated with this phosphatase. p-Nitrophenyl phosphate was dephosphorylated. In addition to Ca2+, the phosphatase activity for RLC-a was activated by Mn2+, while p-nitrophenylphosphatase activity was activated by Mg2+ more strongly than by Mn2+. The pH-activity curves showed a maximum at pH 7 in the presence of Mn2+, but at around pH 8 in the presence of Mg2+. This phosphatase is similar to phosphatase 2B or calcineurin. The possible regulatory function of this phosphatase in scallop catch muscle is discussed.     

Dolichol kinase activity in the developing rat testis

Dolichyl phosphate concentrations, a primary factor in regulating the rate of N-glycosidically linked glycoprotein synthesis, are dependent upon a cytidine triphosphate (CTP)-dependent dolichol kinase. This study examines dolichol kinase in rat testicular microsomes and defines assay conditions. As with dolichol kinases from other tissues, addition of 2-mercaptoethanol increased activity 60%. Inclusion of NaF, an inhibitor of testicular dolichyl phosphate phosphatase activity, also resulted in a 38% increase in activity. Triton X-100 was necessary for phosphorylation of both endogenous and exogenous dolichol; however, concentrations of detergent in excess of 0.25-0.35% were inhibitory. A 2- to 5-fold stimulation of kinase activity was obtained by addition of 50-100 microM exogenous dolichol. The high level of nucleoside triphosphatase activity in testicular microsomes mandated the inclusion of high levels of uridine triphosphate (UTP) to protect the [gamma-32 P] CTP. Increasing UTP concentrations up to 50 mM resulted in increased product formation. A clear requirement for divalent cations was observed; 5 mM ethylenediaminetetraacetate (EDTA) abolished activity. The following order of cation effectiveness was observed: Mn greater than or equal to Ca greater than Cd greater than Zn much greater than Mg. Ten mM optima were established for Ca2+ and Mn2+; the presence of UTP, however, results in significantly reduced concentrations of free Ca2+. Ion combination studies demonstrated interactive inhibitory effects between Ca2+ and other stimulatory divalent cations. Addition of 2 microM brain calmodulin, in the presence of 10 mM Ca2+, resulted in a 75-100% stimulation of activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Selective metal ion binding at the calcium-binding sites of the sea urchin extraembryonic coat protein hyalin

The interaction of metal ions with the sea urchin extraembryonic coat protein hyalin was investigated. Hyalin, immobilized on nitrocellulose membrane, bound Ca2+ and this interaction was disrupted by ruthenium red and selective metal ions. The divalent cations Cd2+ and Mn2+, when present at a concentration of 30 microM, displaced hyalin-bound Ca2+. In competition assays, 1 mM Cd2+ or 3 mM Mn2+ were effective competitors with Ca2+ for binding to hyalin. Cobalt, at a concentration of 30 microM, was unable to displace protein-bound Ca2+, but was effective in competition assays at a concentration of at least 10 mM. Magnesium and the monovalent cation Cs+ were unable to disrupt Ca2(+)-hyalin interaction. Interestingly, Cd2+, Mn2+, and Co2+ mimicked the biological effects of Ca2+ on the hyalin self-association reaction. These results clearly demonstrate that the Ca2(+)-binding sites on hyalin can selectively accommodate other divalent cations in a biologically active configuration.     

Stimulation of calcium transport of sarcoplasmic reticulum vesicles by the calcium complex of ethylene glycol bis(beta-aminoethyl ether)-N,N',-tetraacetic acid

The calcium ion dependence of calcium transport by isolated sarcoplasmic reticulum vesicles from rabbit skeletal muscle has been investigated by means of the Calcium-stat method, in which transport may be measured in the micromolar free calcium ion concentration range, in the absence of calcium buffers. At pH 7.2 and 20 degrees C, ATP, in the range 1 to 10 mM, decreased [Ca2+]0.5 from 2.0 microM to 0.3 microM and decreased Vmax of oxalate-supported transport from 0.5 to 1.3 mumol min-1 mg-1. Simultaneous measurements of transport and of ATPase activity in the range 0.8 to 10 microM free Ca2+ showed a ratio of 2.1 calcium ions translocated/molecule of ATP hydrolyzed. Transport, in the presence of 5 mM ATP, ceased when calcium ion concentration fell to 0.6 to 1.2 microM, whilst ATPase activity of 90 nmol of ATP hydrolyzed min-1 mg-1 persisted. The data obtained by the Calcium-stat method differed from those described previously using calcium buffers, in that they showed lower apparent affinities of the transport site for calcium ions, more marked sigmoidal behavior, an effect of ATP concentration on Ca2+ concentration dependence and lower ATPase activity in the absence of transport. The calcium complex of ethylene glycol bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid (CaEGTA) had no effect when transport was stimulated maximally at saturating free Ca2+ concentrations. However, at calcium ion levels below [Ca2+]0.5, 70 microM CaEGTA stimulated transport to rates of 20 to 45% of Vmax. Half-maximal stimulation of transport occurred at 19 microM CaEGTA. CaEGTA, 50 microM, decreased [Ca2+]0.5, determined at 5 mM ATP, from 1.3 microM to 0.45 microM. It is proposed that a ternary complex, E . Ca2+ . EGTA4-, is formed as an intermediate species during CaEGTA-stimulated calcium transport by sarcoplasmic reticulum membranes and stimulates the calcium pump at limiting free Ca2+ ion concentration.     

Ca(2+)/calmodulin-independent activation of calcineurin from Dictyostelium by unsaturated long chain fatty acids

This study describes a novel mode of activation for the Ca(2+)/calmodulin-dependent protein phosphatase calcineurin. Using purified calcineurin from Dictyostelium discoideum we found a reversible, Ca(2+)/calmodulin-independent activation by the long chain unsaturated fatty acids arachidonic acid, linoleic acid, and oleic acid, which was of the same magnitude as activation by Ca(2+)/calmodulin. Half-maximal stimulation of calcineurin occurred at fatty acid concentrations of approximately 10 microM with either p-nitrophenyl phosphate or RII phosphopeptide as substrates. The methyl ester of arachidonic acid and the saturated fatty acids palmitic acid and arachidic acid did not activate calcineurin. The activation was shown to be independent of the regulatory subunit, calcineurin B. Activation by Ca(2+)/calmodulin and fatty acids was not additive. In binding assays with immobilized calmodulin, arachidonic acid inhibited binding of calcineurin to calmodulin. Therefore fatty acids appear to mimic Ca(2+)/calmodulin action by binding to the calmodulin-binding site.     

Activation of brain calcineurin phosphatase towards nonprotein phosphoesters by Ca2+, calmodulin, and Mg2+

Calcineurin purified from bovine brain was found to be active towards beta-naphthyl phosphate greater than p-nitrophenyl phosphate greater than alpha-naphthyl phosphate much greater than phosphotyrosine. In its native state, calcineurin shows little activity. It requires the synergistic action of Ca2+, calmodulin, and Mg2+ for maximum activation. Ca2+ and Ca2+ X calmodulin exert their activating effects by transforming the enzyme into a potentially active form which requires Mg2+ to express the full activity. Ni2+, Mn2+, and Co2+, but not Ca2+ or Zn2+, can substitute for Mg2+. The pH optimum, and the Vm and Km values of the phosphatase reaction are characteristics of the divalent cation cofactor. Ca2+ plus calmodulin increases the Vm in the presence of a given divalent cation, but has little effect on the Km for p-nitrophenyl phosphate. The activating effects of Mg2+ are different from those of the transition metal ions in terms of effects on Km, Vm, pH optimum of the phosphatase reaction and their affinity for calcineurin. Based on the Vm values determined in their respective optimum conditions, the order of effectiveness is: Mg2+ greater than or equal to Ni2+ greater than Mn2+ much greater than Co2+. The catalytic properties of calcineurin are markedly similar to those of p-nitrophenyl phosphatase activity associated with protein phosphatase 3C and with its catalytic subunit of Mr = 35,000, suggesting that there are common features in the catalytic sites of these two different classes of phosphatase.     

Inactivation of bovine kidney cytosolic protamine kinase by the catalytic subunit of protein phosphatase 2A

Incubation of highly purified preparations of the bovine kidney cytosolic protamine kinase in the presence of near homogeneous preparations of the catalytic subunit of protein phosphatase 2A (PrP2Ac) from bovine kidney resulted in time-dependent inactivation of the protamine kinase. By contrast, incubation of bovine kidney cytosolic casein kinase II with PrP2Ac had no effect on the activity of this casein kinase II. In the presence of 10 mM sodium fluoride, 10 mM inorganic orthophosphate, 1 mM pyrophosphate or 0.1 mM ATP, the inactivation of the protamine kinase by PrP2Ac was completely inhibited. Half-maximal inhibition by ATP occurred at about 20 microM. The rate of inactivation of the protamine kinase by PrP2Ac was unaffected by Mg2+, Mn2+, Ca2+, EDTA or EGTA at 1 mM. The results strongly indicate that the activity of the cytosolic protamine kinase is regulated by phosphorylation/dephosphorylation.     

The bell-shaped Ca2+ dependence of the inositol 1,4, 5-trisphosphate-induced Ca2+ release is modulated by Ca2+/calmodulin.

Calmodulin inhibits inositol 1,4,5-trisphosphate (IP3) binding to the IP3 receptor in both a Ca2+-dependent and a Ca2+-independent way. Because there are no functional data on the modulation of the IP3-induced Ca2+ release by calmodulin at various Ca2+ concentrations, we have studied how cytosolic Ca2+ and Sr2+ interfere with the effects of calmodulin on the IP3-induced Ca2+ release in permeabilized A7r5 cells. We now report that calmodulin inhibited Ca2+ release through the IP3 receptor with an IC50 of 4.6 microM if the cytosolic Ca2+ concentration was 0.3 microM or higher. This inhibition was particularly pronounced at low IP3 concentrations. In contrast, calmodulin did not affect IP3-induced Ca2+ release if the cytosolic Ca2+ concentration was below 0.3 microM. Calmodulin also inhibited Ca2+ release through the IP3 receptor in the presence of at least 10 microM Sr2+. We conclude that cytosolic Ca2+ or Sr2+ are absolutely required for the calmodulin-induced inhibition of the IP3-induced Ca2+ release and that this dependence represents the formation of the Ca2+/calmodulin or Sr2+/calmodulin complex.     

Characterization of Ca2+- or Mg2+-ATPase of the excitable ciliary membrane from Paramecium tetraurelia: comparison with a soluble Ca2+-dependent ATPase

We have characterized divalent-cation-stimulated nucleoside triphosphate hydrolase activity of the excitable ciliary membrane and compared it with a soluble Ca2+-ATPase released upon deciliation of Paramecium. The membrane-bound activity is strongly dependent on a divalent cation; calcium stimulates the basal activity of this enzyme at least 10-fold; magnesium and manganese stimulate less well, and strontium and barium, although less effective, also give measurable stimulation. This membrane-bound activity prefers ATP and GTP as substrates but also hydrolyzes UTP and CTP at measurable rates. The maximum velocity at saturating ATP concentrations and optimal calcium concentrations is 0.3 mumol/min per mg. The pH optimum for the membrane-bound activity is broad and centers around pH 7. From the temperature dependence of ATP hydrolysis, we calculate activation energies of 14 and 11 kcal/mol for the Ca2+- and Mg2+-stimulated activities, respectively. The Arrhenius plot is linear over the temperature range of 4 to 25 degrees C. The membrane ATPase is relatively insensitive to ouabain, oligomycin, N,N'-dicyclohexylcarbodiimide, vanadate, Ruthenium red and two calmodulin antagonists. Polyclonal antisera raised against the purified soluble ATPase from the deciliation supernatant show low reactivity with the membrane-bound ATPase. We conclude from the comparison of properties of the two activities that the ciliary membrane-bound ATPase is distinct from the soluble ATPase released by deciliation.     

Activation of bovine brain calmodulin-dependent protein phosphatase by limited trypsinization

A calmodulin-dependent protein phosphatase isolated from bovine brain [Tallant, E.A., & Cheung, W.Y. (1983) Biochemistry 22, 3630-3635] is stimulated by limited trypsinization to the same activity level as that by calmodulin. Prolonged trypsinization caused gradual loss of phosphatase activity, a process retarded in the presence of Ca2+, and even more in the presence of calmodulin. Trypsinized phosphatase, when fully activated, had a molecular weight of 60 000 and was composed of two protein species of 43 000 and 16 000 daltons. Trypsinization decreased the Km of phosphatase for casein from 10.8 to 1.2 microM and increased the Vmax from 4.9 to 30.9 nmol (mg of protein)-1 min-1. The proteolyzed enzyme was insensitive to calmodulin and did not bind to a calmodulin-Sepharose affinity column. It was, however, stimulated by Ca2+, requiring 0.4 microM Ca2+ for half-maximal activation. Both native and trypsinized phosphatase were stimulated by Mn2+ to a level considerably higher than that by Ca2+.     

Divalent cation sensitivity of BK channel activation supports the existence of three distinct binding sites

Mutational analyses have suggested that BK channels are regulated by three distinct divalent cation-dependent regulatory mechanisms arising from the cytosolic COOH terminus of the pore-forming alpha subunit. Two mechanisms account for physiological regulation of BK channels by microM Ca2+. The third may mediate physiological regulation by mM Mg2+. Mutation of five aspartate residues (5D5N) within the so-called Ca2+ bowl removes a portion of a higher affinity Ca2+ dependence, while mutation of D362A/D367A in the first RCK domain also removes some higher affinity Ca2+ dependence. Together, 5D5N and D362A/D367A remove all effects of Ca2+ up through 1 mM while E399A removes a portion of low affinity regulation by Ca2+/Mg2+. If each proposed regulatory effect involves a distinct divalent cation binding site, the divalent cation selectivity of the actual site that defines each mechanism might differ. By examination of the ability of various divalent cations to activate currents in constructs with mutationally altered regulatory mechanisms, here we show that each putative regulatory mechanism exhibits a unique sensitivity to divalent cations. Regulation mediated by the Ca2+ bowl can be activated by Ca2+ and Sr2+, while regulation defined by D362/D367 can be activated by Ca2+, Sr2+, and Cd2+. Mn2+, Co2+, and Ni2+ produce little observable effect through the high affinity regulatory mechanisms, while all six divalent cations enhance activation through the low affinity mechanism defined by residue E399. Furthermore, each type of mutation affects kinetic properties of BK channels in distinct ways. The Ca2+ bowl mainly accelerates activation of BK channels at low [Ca2+], while the D362/D367-related high affinity site influences both activation and deactivation over the range of 10-300 microM Ca2+. The major kinetic effect of the E399-related low affinity mechanism is to slow deactivation at mM Mg2+ or Ca2+. The results support the view that three distinct divalent-cation binding sites mediate regulation of BK channels.