Lipoxygenase activities of human platelets and their subcellular fractions: Comparison between lipoxygenase-deficient platelets and normal platelets

Lipoxygenase activities were estimated in washed platelets (intact platelets) and their subcellular fractions obtained from 7 patients with deficient platelet lipoxygenase activities and 9 normal subjects. From sonicated platelet preparations, 12,000 g supernatant (F-I), cytosol (F-II) and microsomal fractions (F-III) were prepared by differential centrifugation. When 12-hydroxyeicosatetraenoic acid (12-HETE) produced by the incubation of arachidonic acid with intact platelets or each of their subcellular fractions from normal subjects was measured by reversed-phase high-performance liquid chromatography analysis, the lipoxygenase activities of F-I, F-II and F-III were 87%, 31% and 17%, respectively, of the enzyme activity of intact platelets. One of the patients showed no detectable lipoxygenase activity in any preparation, while the other patients showed reduced enzyme activities in all preparations. The addition of CaCl2 significantly increased 12-HETE synthesis solely by F-I from these patients. In most of these patients, contrary to normal subjects, it appeared that the lipoxygenase activity was not fully expressed in intact platelets, since the F-I produced more 12-HETE than the intact platelets.     

Procalpain I in cytoplasm is translocated onto plasma and granule membranes during platelet stimulation with thrombin and then activated on the membranes.

Thrombin stimulation of platelets resulted in changes in the subcellular localization of calpain I, with a concomitant alteration of its molecular weight as measured by immunoblotting. Calpain I in resting platelets was distributed as procalpain I, an 80 kDa form which does not exhibit the enzyme activity, and 83% of the total antigen was localized in the cytosol fraction. When platelets were stimulated with thrombin, the total content of calpain I antigen was not significantly changed as compared with that of the resting platelets, though a decrease in the cytosolic distribution of 80 kDa form (from 83% to 47% of the total antigen) was observed with concomitant appearance of the active 76 kDa and intermediate 78 kDa forms of calpain I and increase in the 80 kDa form in the granule and membrane fractions. These results indicated that calpain I was translocated from the cytosol to both the plasma and granule membranes as procalpain I and then activated on the membranes during platelet stimulation with thrombin.     

Subcellular fractionation of porcine neutrophils by nitrogen cavitation and sucrose-density-gradient centrifugation

Neutrophils, isolated in large quantities from porcine blood were disrupted by nitrogen cavitation and separated by differential centrifugation into a nuclear fraction and a post-nuclear supernatant. The latter was subfractionated by sucrose density gradient centrifugation into cytosol, a fraction consisting of membrane vesicles and two granule-rich fractions. The membrane fraction accounted for 1.9% of the protein in the post-nuclear supernatant, the light granule fraction for 2.2% and the dense granule fraction for 4.2%. Catalase, lactate dehydrogenase and malate dehydrogenase were largely confined to the cytosol. The dense granule fraction contained the highest quantities of the hydrolytic enzymes, although the membrane fraction was also rich in alkaline and acid phosphatase and gamma-glutamyl transpeptidase activities. Electron microscopy of the membrane fraction showed intact membrane vesicles, whereas the granular fractions consisted of electron-dense, membrane-bound granules. Two granular fractions were isolated which contained granules of differing size and density. 3H-labeled wheat germ agglutinin bound to the surface of intact neutrophils and when these were disrupted and fractionated the membrane fraction showed a specific binding activity 16-times greater than that of the cavitated sample. The membrane fraction interacted with the detergent digitonin and as a result underwent density perturbation increasing from 1.13 g X cm-3 to 1.18 g X cm-3. Dodecylsulphate-polyacrylamide gel electrophoresis showed the membrane fraction to consist of at least 40 protein bands, with relative molecular masses ranging from 200 000-16 000. The granule fractions contained less protein bands, with a protein composition quite distinct from that of the membrane fraction.     

Subcellular distribution of alpha 2-adrenergic receptors, pertussis-toxin substrate and adenylate cyclase in human platelets.

The subcellular distribution of the alpha 2-adrenergic receptor, pertussis-toxin substrates (Gi, the inhibitory G-protein) and adenylate cyclase was determined in human platelets. The alpha 2-adrenergic receptor and pertussis-toxin substrate activity codistribute with surface membranes identified by a novel fluorescent-lectin method. The platelet granule fractions did not contain detectable Gi. Only 2-4% of the total pertussis-toxin substrate activity appears in soluble fractions, and this amount was not increased upon addition of purified beta gamma units or after pretreatment of platelets with adrenaline. There is no evidence for compartmentation of the alpha 2-adrenergic receptor or Gi to account for the low-affinity component of agonist binding to the alpha 2-adrenergic receptor in human platelet membranes. Translocation of Gi from plasma membrane to platelet cytosol or granules does not appear to play any significant role in the mechanism of alpha 2-receptor-mediated platelet activation.     

Identification of a membrane-bound, glycol-stimulated phospholipase A2 located in the secretory granules of the adrenal medulla

Chromaffin granule membranes prepared from bovine adrenal medullae showed Ca2(+)-stimulated phospholipase A2 (PLA2) activity when assayed at pH 9.0 with phosphatidylcholine containing an [14C]-arachidonyl group in the 2-position. However, the activity occurred in both soluble and particulate subcellular fractions, and did not codistribute with markers for the secretory granule. PLA2 activity in the granule membrane preparation was stimulated dramatically by addition of glycerol, ethylene glycol, or poly(ethylene glycol). This glycol-stimulated PLA2 activity codistributed with membrane-bound dopamine beta-hydroxylase, a marker for the granule membranes, through the sequence of differential centrifugation steps employed to prepare the granule membrane fraction, as well as on a sucrose density gradient which resolved the granules from mitochondria, lysosomes, and plasma membrane. The glycol-stimulated PLA2 of the chromaffin granule was membrane-bound, exhibited a pH optimum of 7.8, retained activity in the presence of EDTA, and was inactivated by p-bromophenacyl bromide. When different 14C-labeled phospholipids were incorporated into diarachidonylphosphatidylcholine liposomes, 1-palmitoyl-2-arachidonylphosphatidylcholine was a better substrate for this enzyme than 1-palmitoyl-2-oleylphosphatidylcholine or 1-acyl-2-arachidonyl-phosphatidylethanolamine, and distearoylphosphatidylcholine was not hydrolyzed.     

The neutrophil glycoprotein Mo1 is an integral membrane protein of plasma membranes and specific granules

The glycoprotein Mo1 has previously been demonstrated to be on the cell surface and in the specific granule fraction of neutrophils and to be translocated to the cell surface during degranulation. It is not known, however, whether Mo1 is an integral membrane protein or a soluble, intragranular constituent loosely associated with the specific granule membrane. Purified neutrophils were disrupted by nitrogen cavitation and separated on Percoll density gradients into four fractions enriched for azurophilic granules, specific granules, plasma membrane, and cytosol, respectively. The glycoproteins in these fractions were labeled with 3H-borohydride reduction, extracted with Triton X-114, and immunoprecipitated with 60.3, an anti-Mo1 monoclonal antibody Mo1 was detected only in the specific granule and plasma membrane fractions and partitioned exclusively into the detergent-rich fraction consistent with Mo1 being an integral membrane protein. In addition, treatment of specific granule membranes with a high salt, high urea buffer to remove absorbed or peripheral proteins failed to dissociate Mo1. These data support the hypothesis that Mo1 is an integral membrane protein of plasma and specific granule membranes in human neutrophils.     

5'-Nucleotidase in rat liver lysosomes

5'-Nucleotidase was found in purified rat liver tritosomes. When tritosomes were subfractionated into the membrane and soluble contents fractions, 73% of the total 5'-nucleotidase activity was found in the membrane fraction and 24% in the soluble contents fraction. Immunoblotting using specific polyclonal antibodies against the rat liver plasma membrane 5'-nucleotidase showed that the mobilities on SDS-polyacrylamide gel electrophoresis of both 5'-nucleotidases in the membrane and contents fractions were identical to that of the enzyme in the plasma membranes (Mr = 72,000). 5'-Nucleotidases in the membrane and contents fractions were sensitive to neuraminidase and converted into a form that was 4 kDa smaller after digestion, as observed in the case of plasma membrane enzyme. 5'-Nucleotidases, both from the membrane and contents fractions, were purified using immunoaffinity chromatography, and the isoelectric points, heat stability, and oligomeric structure of the purified enzymes were compared. Isoelectric focusing and the heat stability test indicated the resemblance of the soluble enzyme to the membrane-bound enzyme. However, the membrane-bound enzyme aggregated in the absence of Triton X-100, whereas the soluble enzyme behaved as a dimer. The topography of 5'-nucleotidase in the tritosomal membranes was studied using antibodies against 5'-nucleotidase and neuraminidase treatment. The inhibition of 5'-nucleotidase were not observed in the intact tritosomal fraction until the tritosomes had been disrupted by osmotic shock. These results show that the active sites and the oligosaccharide chains of 5'-nucleotidase are located on the inside surface of the tritosomal membranes.     

Formation of diacyl- and alkylacylphosphatidylcholine by the membranes of human platelets

We have investigated the distribution and fatty acid preference of two acyl-CoA transferase activities in a human platelet mixed membrane fraction and in well-characterised surface and intracellular membrane subfractions prepared from it by high-voltage free-flow electrophoresis. One transferase inserts long-chain unsaturated fatty acids into 1-acyllysophosphatidylcholine (1-acyl-LPC) and the other into lyso-platelet-activating factor (LPAF). Both transferase activities were approx. 4-fold enriched in the intracellular membranes with respect to their specific activities in the mixed membranes. The surface membrane activities were correspondingly depleted. Using 1-acyl-LPC as the acceptor, all the intracellular membrane preparations showed transferase preference for the CoA ester of 8,11,14-eicosatrienoic acid. In contrast when LPAF was the acceptor the CoA esters of linoleic and arachidonic acid were the preferred donors.     

Activity and protein distribution of 12-lipoxygenase in HEL cells: Induction of membrane-association by phorbol ester TPA, modulation of activity by glutathione and 13-HPODE, and Ca-dependent translocation to membranes

The understanding of the intracellular regulation of 12-lipoxygenase requires a knowledge of the distribution of both enzyme protein and its activity. In human erythroleukemia cells, the membrane fraction contains about 90% of the total cellular 12-lipoxygenase activity, whereas only approximately 10% of 12-lipoxygenase activity resides in the cytosol. However, the majority of the cellular 12-lipoxygenase protein is found in the cytosol. Pretreatment of cells for 0–3 days with 160 nM TPA caused a marked, time-dependent increase in membrane-bound 12-lipoxygenase activity and protein, respectively. In contrast, the cytosolic amount of 12-lipoxygenase protein and activity, respectively, were minimally altered by this TPA treatment. Recombining the active membrane fraction with cytosol resulted in no significant inhibition of its 12-lipoxygenase activity, but the addition of GSH to the membrane fraction inhibited 12-lipoxygenase activity in a dose-dependent manner. On the other hand, the cytosolic enzyme can be rendered active in the presence of 1 μM 13-hydroperoxyoctadecadienoic acid. In HEL cell homogenates, a partial translocation of the cytosolic enzyme to the membrane takes place in a Ca²⁺-dependent manner, resulting in an increase in membrane-associated 12-lipoxygenase activity and a concomitant decrease in cytosolic 12-lipoxygenase activity above 0.1 μM Ca²⁺.     

Differences in distribution of ribonuclease isoenzymes in cytosol and granules in normal human granulocytes and in granulocytes of patients with chronic granulocytic leukemia (CGL)

Distribution of ribonuclease (RNAase), acid phosphatase (acid Ph-ase) and beta glucuronidase (BGU) between the granule, cytosol-soluble and post-granule fractions in normal human granulocytes and in granulocytes of chronic granulocytic leukemia (CGL) was studied. CGL granulocytes were found to display relative RNAase activity 1.2 times higher, relative acid Ph-ase activity 2.5 times higher than normal granulocytes. The granule fraction of CGL granulocytes showed 1.4 times higher relative RNAase activity but 0.87 times lower acid Ph-ase activity and the same BGU activity as normal granulocytes. On the other hand, the supernatant soluble fraction of CGL granulocytes showed 4.4 times higher relative RNAase activity, 1.2 times higher relative acid Ph-ase activity and BGU 2.2 times higher than in cytosol soluble fraction of normal granulocytes. Thus, cytosol soluble fraction of CGL granulocytes show a relative activity of the lysosomal enzymes studied which is remarkably higher than in normal granulocytes. The percentage distribution of RNAase, acid Ph-ase and BGU showed that CGL granulocytes contain only 36% of total RNAase activity versus 46% of that in normal ones. On the other hand, CGL granulocytes in cytosol soluble fraction will contain 48% of total RNAase versus 29% of total RNAase in cytosol of normal granulocytes. The isoenzyme profiles of RNAase of granule fractions were similar in normal and CGL granulocytes, while the RNAase isoenzyme profiles of cytosol fractions were different for normal and CGL granulocytes, indicating that some essential part of CGL granulocyte cytosol RNAase differs from RNAase contained in granules and in cytosol of normal granulocytes.     

Hepatic alkaline phosphatase isoenzymes: isolation, characterization and differential alteration.

Although it is generally believed that hepatic alkaline phosphatase is localized to liver plasma membranes, 63% is present in the cytosol fraction after ultracentrifugation of rat liver homogenates. Divalent cation requirements, heat inactivation, pH optima, Km and chemical inhibition characteristics of partially purified alkaline phosphatase enzymes prepared from membrane and cytosol fractions suggested different structural forms. Furthermore, bile duct obstruction and ethinyl estradiol administration preferentially increased membrane-bound alkaline phosphatase activity, while cytosol activity was unaltered. In contrast, phenobarbital treatment decreased membrane-bound alkaline phosphatase and increased cytosol activity. These studies support the presence of two forms of hepatic alkaline phosphatase in rat liver which are regulated by different control mechanisms.     

NADPH oxidase of human neutrophils. Subcellular localization and characterization of an arachidonate-activatable superoxide-generating system

The superoxide-forming NADPH oxidase of human neutrophils was studied in subcellular fractions of unstimulated cells. Purified neutrophils were disrupted by nitrogen cavitation and separated on Percoll density gradients into four fractions: alpha, azurophil granules; beta, mostly specific granules; gamma, plasma membrane, and cytosol. NADPH-dependent O2-. formation by these fractions was quantitated as the rate of superoxide dismutase-inhibitable reduction of ferricytochrome c. In the presence of cytosol, NADPH, and either arachidonic acid (optimum 90 microM) or sodium dodecyl sulfate (optimum 160 microM), 70-75% of the oxidase was in the beta fraction and about 25% was in the gamma fraction. A similar distribution was found for cytochrome b559 and FAD, two putative components of the oxidase. The reaction rates observed with arachidonic acid activation were sufficient to account for 25-75% of the O2-. generated by intact neutrophils. The properties of the beta and gamma enzymes were similar and closely resembled those of the oxidase in intact neutrophils or disrupted prestimulated cells. These included resistance to azide and cyanide, a pH optimum of 7.4, and a preference for NADPH (Km approximately 40-45 microM) rather than NADH (Km approximately 2.5 mM) as the electron donor. The combination of beta and gamma fractions displayed additive activity. The activatable oxidase required Mg2+ but not Ca2+. ATP was required for maximum reaction rates. When beta and gamma membranes were preincubated with cytosol and arachidonic acid in the presence of millimolar Mg2+ and then ultracentrifuged membrane-bound O2-. -forming activity was recovered in the pellet and the enzyme required only NADPH (i.e. no cytosol, arachidonic acid, or Mg2+) for expression of activity. These data suggest that cytosol contains a Mg2+-dependent oxidase-activating factor. Molecular sieve chromatography of cytosol indicated a single peak of activity (i.e. ability to activate O2-. generation by beta and/or gamma fraction) eluting with molecules of about 10,000 daltons.     

Alteration in protein kinase C activity and subcellular distribution in sickle erythrocytes

In agreement with previous data, membrane protein phosphorylation was found to be altered in intact sickle cells (SS) relative to intact normal erythrocytes (AA). Similar changes were observed in their isolated membranes. The involvement of protein kinase C (PKC) in this process was investigated. The membrane PKC content in SS cells, measured by [3H]phorbol ester binding, was about 6-times higher than in AA cells. In addition, the activity of the enzyme, measured by histone phosphorylation was also found to be increased in SS cell membranes but decreased in their cytosol compared to the activity in AA cell membranes and cytosol. The increase in membrane PKC activity was observed mostly in the light fraction of SS cells, fractionated by density gradient, whereas the decrease in cytosolic activity was only observed in the dense fraction. PKC activity, measured in cells from the blood of reticulocyte-rich patients, exhibited an increase in both membranes and cytosol, thus explaining some of the effects observed in the SS cell light fraction, which is enriched in reticulocytes. The increase in PKC activity in the membranes of SS cells is partly explained by their young age but the loss of PKC activity in their cytosol, particularly in that of the dense fraction, seems to be specific to SS erythrocytes. The relative decrease in membrane PKC activity between the dense and the light fractions of SS cells might be related to oxidative inactivation of the enzyme.     

Membrane-bound lipoxygenase of rat cerebral microvessels

The microvessels isolated from rat cerebral cortex has arachidonate lipoxygenase activity, which was not due to possible contamination of the platelets. The major product was identified to be 12-hydroxyeicosatetraenoic acid. After homogenization and sonication of the microvessel preparations, the lipoxygenase activity was recovered both in the membrane- and the cytosol-fractions, whereas that in the platelets was recovered in the cytosol fraction. Membrane-bound lipoxygenase of the microvessels has apparent Km value of 3.8 microM for arachidonic acid, which was corresponded to 1/5 of that in the platelet enzyme. Microvessel lipoxygenase was inhibited by nordihydroguaiaretic acid but not by indomethacin.     

Phospholipid-hydroperoxide glutathione peroxidase (GPx-4) localization in resting platelets, and compartmental change during platelet activation

Seleno-glutathione peroxidases are an important family of antioxidant enzymes, that include the phospholipid hydroperoxide glutathione peroxidase (GPx-4), an enzyme that reduces lipid hydroperoxides in membranes. The essential characteristics of platelet GPx-4 were found to be the same as the GPx-4 from other tissues. To explore the subcellular expression of GPx-4 in human platelets, we first investigated both its activity and localization in subcellular fractions. About 47% of the total cell enzyme activity was found in the membrane fractions, 29% in the mitochondria and 23% in the cytosol fractions. The same subcellular distribution of GPx-4 protein was demonstrated in resting platelets. This distribution data was further established by confocal microscopy. Of major potential biological significance, this distribution changed when platelets were activated. Confocal immunofluorescence microscopy localized mainly GPx-4 to membranes in contrast to cytoplasm in the resting cells. Based on these results we propose that cytoplasmic GPx-4 could be moved to the membrane for protection during platelet activation. This enzyme would then be important to maintain the integrity of platelet function in vascular system stressed by oxidative reactions.     

Localization of neutrophil adherence-inhibiting factor in guinea pig platelets

The effect of constituents of guinea pig platelets on neutrophil adherence was examined. The platelet sonicate supernatant contained adherence-inhibiting activity which strongly inhibited neutrophil adherence to glass. When the platelet sonicate supernatant was treated with neuraminidase or trypsin, the adherence-inhibiting activity was significantly inhibited, suggesting that the adherence-inhibiting factor (AIF) is a glycoprotein. The subcellular fractionation experiments indicated that the AIF activity was present at about 40% in both the cytosol and granule fractions. From the Sephadex G-200 gel filtration analysis, AIF of cytosol fraction and granule fraction proved to be different molecules, with molecular masses of about 230 and 12 kDa, respectively. When platelets were stimulated with thrombin, about 20% of total AIF was released extracellularly without the release of the cytoplasmic enzyme lactate dehydrogenase. These results suggest the possibility that a biologically active substance, AIF, is released from platelets in response to stimuli and regulates neutrophil functions through interference with neutrophil adherence.     

Localization of neutrophil adherence-inhibiting factor in guinea pig platelets

The effect of constituents of guinea pig platelets on neutrophil adherence was examined. The platelet sonicate supernatant contained adherence-inhibiting activity which strongly inhibited neutrophil adherence to glass. When the platelet sonicate supernatant was treated with neuraminidase or trypsin, the adherence-inhibiting activity was significantly inhibited, suggesting that the adherence-inhibiting factor (AIF) is a glycoprotein. The subcellular fractionation experiments indicated that the AIF activity was present at about 40% in both the cytosol and granule fractions. From the Sephadex G-200 gel filtration analysis, AIF of cytosol fraction and granule fraction proved to be different molecules, with molecular masses of about 230 and 12 kDa, respectively. When platelets were stimulated with thrombin, about 20% of total AIF was released extracellularly without the release of the cytoplasmic enzyme lactate dehydrogenase. These results suggest the possibility that a biologically active substance, AIF, is released from platelets in response to stimuli and regulates neutrophil functions through interference with neutrophil adherence.     

Occurrence of Sialyltransferase Activity in the Synaptosomal Membranes Prepared from Calf Brain Cortex

The possible occurrence of sialyltransferase activity in the plasma membranes surrounding nerve endings (synaptosomal membranes) was studied, using calf brain cortex. The synaptosomal membranes were prepared by an improved procedure which provided: (a) a ?nerve ending fraction” consisting of at least 85% well-preserved nerve endings and containing only small quantities of membranes of intracellular origin; (b) a ?synaptosomal membrane fraction” carrying high amounts of authentic plasma membrane markers (Na⁺-K⁺ ATPase, 5′-nucleotidase, sialidase, gangliosides) with values of specific activity four to fivefold higher than those in the ?nerve ending fraction” and very small amounts of cerebroside sulphotransferase, marker of the Golgi apparatus, and of other markers of intracellular membranes (rotenone-insensitive NADH and NADPH: cytochrome c reductases), the specific activities of which were, respectively, 0.5- and 0.7-fold that in the ?nerve ending fraction”. Thus the preparation of synaptosomal membranes used had the characteristics of plasma membranes and carried a negligible contamination of membranes of intracellular origin. The distribution of sialyltransferase activity in the main brain subcellular fractions (microsomes; P₂ fraction; nerve ending fraction; mitochondria) resembled most closely that of thiamine pyrophosphatase, the enzyme known to be linked to the Golgi apparatus and the plasma membranes and of acetylcholine esterase, the enzyme known to be linked to either intracellular or plasma membranes. The enrichment of sialyltransferase activity in the ?synaptosomal membrane fraction”, referred to the ?nerve ending fraction”, was practically the same as that exhibited by authentic plasma membrane markers. All this is consistent with the hypothesis that in calf brain cortex sialyltransferase has two different subcellular locations: one at the level of intracellular structures, most likely the Golgi apparatus (as described by other authors), the other in the synaptosomal plasma membranes. The basic properties (pH optimum, V/S, V/t and V/protein relationships) and detergent requirements of the synaptosomal membrane-bound sialyltransferase were established. The highest enzyme activities were recorded on exogenous acceptors, lactosylceramide and ds -fetuin. The K_m values for CMP-NeuNAc were different using lactosylceramide and ds -fetuin as acceptor substrates (0.57 and 0.135 mm , respectively); the thermal stability of the enzyme acting on glycolipid acceptor was higher than that on the glycoprotein acceptor; the effect of detergents was different when using glycoprotein from glycolipid acceptors; no competition was observed between lactosylceramide and ds -fetuin. Thus the synaptosomal membranes carry at least two different sialyltransferase activities: one acting on lactosylceramide (and glycolipid acceptors), the other working on ds -fetuin (and glycoprotein acceptors). Ganglioside GM₃ was recognized as the product of synaptosomal membrane-bound sialyltransferase activity working on lactosylceramide as acceptor substrate.     

Adrenal Chromaffin Cell Calmodulin: Its Subcellular Distribution and Binding to Chromaffin Granule Membrane Proteins

Bovine adrenal medullae were homogenized in the presence or in the absence of EGTA and different subcellular fractions were prepared by differential and density gradient centrifugations. In the presence of the chelating agent, 69% of the total calmodulin, measured by radioimmunoassay, was present in the cytosol; the rest was bound to different membrane-containing fractions (nuclei, microsomal, and crude granule fraction). When the chelating agent was omitted, 43% of the calmodulin was present in the cytosol, the remaining calmodulin being membrane-bound. Further resolution of the crude granule fraction by sucrose density centrifugation demonstrated that the distribution of calmodulin in the density gradient was similar to the distribution of chromaffin granules rather than to that of mitochondria, Golgi elements, and lysosomes. In this case, there was also more calmodulin bound to chromaffin granules when EGTA was omitted from the density gradient. Experiments with 125I-calmodulin indicated the presence of high-affinity binding sites (KD = 1.3 X 10(-8) M; Bmax = 30 pmol/mg protein) for calmodulin in chromaffin granule membranes. Further, photoaffinity crosslinking experiments with 125I-calmodulin followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography indicated the presence of three calmodulin-binding polypeptide complexes (84,000; 41,000; and 38,000 daltons) in chromaffin granule membranes. These polypeptides were not labelled when either Ca2+ was omitted or an excess of nonradioactive calmodulin was present in the photolysis buffer, indicating the Ca2+ dependency and the specificity of the interaction. On the basis of the results described, it is suggested that the cellular levels of Ca2+ control the cellular distribution of calmodulin and its binding to specific chromaffin granule membrane proteins. Further, it is also suggested that the interactions between calmodulin and granule proteins might play a role in stimulus-secretion coupling.     

Possible involvement of angiotensin I-converting enzyme in the inactivation of bradykinin by intact macrophages

As intact macrophages inactivated bradykinin, the subcellular localization of the bradykinin-inactivating activity was studied using guinea-pig macrophages. The bradykinin-inactivating activity was found to be present in membrane and cytosol fractions but not in granular and nuclear fractions. The bradykinin-inactivating activity of the membrane fraction was inhibited by captopril, a specific inhibitor of angiotensin I-converting enzyme, whereas that of the cytosol fraction was hardly inhibited by various proteinase inhibitors used. Angiotensin I-converting enzyme activity was located predominantly in the membrane fraction and its activity was inhibited by captopril. Angiotensin I-converting enzyme activity measured with a synthetic substrate was competitively inhibited by bradykinin, suggesting that bradykinin is a possible substrate for macrophage angiotensin I-converting enzyme. When macrophages were modified chemically by diazotized sulfanilic acid, a poorly permeant reagent, both the bradykinin-inactivating activity and the angiotensin I-converting enzyme activity of macrophages decreased significantly without any inhibition of the cytosol bradykinin-inactivating activity. These findings seem to suggest that the angiotensin I-converting enzyme would be responsible for the inactivation of bradykinin in intact macrophages.