The inositol 1,4,5-trisphosphate-binding site in adrenal cortical cells is distinct from the endoplasmic reticulum

The distribution of binding sites for the calcium-mobilizing second messenger inositol 1,4,5-trisphosphate (Ins(1,4,5)P3) was investigated in subcellular fractions of bovine adrenal cortex. The [3H]Ins(1,4,5)P3-binding capacity was enriched in the microsomal fraction, which contained a single class of high affinity binding sites with a Kd of 21.6 +/- 3.0 nM. The specific [3H]Ins(1,4,5)P3 binding appeared to be sharply pH dependent and was inhibited by millimolar concentrations of ATP. Upon fractionation of microsomes on sucrose density gradient there was a clearcut separation of the Ins(1,4,5)P3 receptor-containing fractions from those enriched in specific endoplasmic reticulum markers such as sulfatase C activity or RNA content. The microsomes enriched in Ins(1,4,5)P3-binding sites were of lower density than the endoplasmic reticulum and co-purified partly with the plasma membrane. In addition, Ins(1,4,5)P3-sensitive 45Ca2+ uptake into the microsomes was maximal in the lighter fractions. This distinction between Ins(1,4,5)P3-binding sites and endoplasmic reticulum-derived microsomes was confirmed upon fractionation according to their electrophoretic mobilities by free flow electrophoresis. These results indicate that in adrenal cortical cells, the source of Ca2+ mobilized by Ins(1,4,5)P3 upon stimulation with an agonist is not located in the endoplasmic reticulum. Our data support the hypothesis that a specialized vesicular organelle, distinct from endoplasmic reticulum and in close apposition with the plasma membrane, is involved in intracellular Ca2+ homeostasis.     

Subcellular distribution of the inositol 1,4,5-trisphosphate receptors: functional relevance and molecular determinants

The inositol 1,4,5-trisphosphate receptor (IP3R) is an intracellular Ca2+ channel that is for the largest part expressed in the endoplasmic reticulum. Its precise subcellular localization is an important factor for the correct initiation and propagation of Ca2+ signals. The relative position of the IP3Rs, and thus of the IP3-sensitive Ca2+ stores, to mitochondria, nucleus or plasma membrane determines in many cases the physiological consequences of IP3-induced Ca2+ release. Most cell types express more than one IP3R isoform and their subcellular distribution is cell-type dependent. Moreover, it was recently demonstrated that depending on the physiological status of the cell redistribution of IP3Rs and/or of IP3-sensitive Ca2+ stores could occur. This indicates that the cell must be able to regulate not only IP3R expression but also its distribution. The various proteins potentially determining IP3R localization and redistribution will therefore be discussed.     

Studies on isolated subcellular components of cat pancreas. I. Isolation and enzymatic characterization.

Pancreas of the cat was fractionated into its subcellular components by centrifugation through an exponential ficoll-sucrose density gradient in a zonal rotor. This enables a preparation of four fractions enriched in plasma membranes, endoplasmic reticulum, mitochondria and zymogen granules, respectively. The first fraction, enriched by 9- to 15-fold in the plasma membrane marker enzymes, hormone-stimulated adenylate cyclase, (Na+K+)-ATPase, and 5'-nucleotidase, is contaminated by membranes derived from endoplasmic reticulum but is virtually free from mitochondrial and zymogen-granule contamination. The second fraction from the zonal gradient shows only moderate enrichment of the above marker enzymes but contains a considerable quantity of plasma membrane marker enzymes and represents mostly rough endoplasmic reticulum. The third fraction contains the bulk of mitochondria and the fourth mainly zymogen granules as assessed by electron microscopy and marker enzymes for both mitochondria and zymogen granules, namely succinic dehydrogenase, trypsin and amylase. Further purification of the plasma membrane fractions by differential and sucrose step-gradient centrifugation yields plasma membranes enriched 40-fold in basal and hormone-stimulated adenylate cyclase and (Na+K+)-ATPase.     

Metabolism and functions of inositol phosphates

Activation of Ca2+-mobilizing receptors rapidly increases the cytoplasmic Ca2+ concentration both by releasing Ca2+ stored in endoplasmic reticulum and by stimulating Ca2+ entry into the cells. The mechanism by which Ca2+ release occurs has recently been elucidated. Receptor activation of phospholipase C results in the hydrolysis of the plasma membrane lipid, phosphatidylinositol 4,5-bisphosphate (PIP2), to yield two intracellular messengers, diacylglycerol (DAG) and (1,4,5)inositol trisphosphate [(1,4,5)IP3]. DAG remains in the plasma membrane where it stimulates protein phosphorylation via the phospholipid-dependent protein kinase C. (1,4,5)IP3 diffuses to and interacts with specific sites on the endoplasmic reticulum to release stored Ca2+. Receptor stimulation of phospholipase C appears to be mediated by one or more guanine nucleotide-dependent regulatory proteins by a mechanism analogous to hormonal activation of adenylyl cyclase. The actions of (1,4,5)IP3 on Ca2+ mobilization are terminated by two metabolic pathways, sequential dephosphorylation to inositol bisphosphate (IP2), inositol monophosphate (IP) and inositol or by phosphorylation to inositol tetrakisphosphate (IP4) and sequential dephosphorylation to different inositol phosphates. A sustained cellular response also requires Ca2+ entry into the cell from the extracellular space. The mechanism by which hormones increase Ca2+ entry is not known; a recent proposal involving movement of Ca2+ through the endoplasmic reticulum, possibly regulated by IP4, will be considered here.     

Subcellular fractionation of pig coronary artery smooth muscle

A detailed procedure for subcellular fractionation of the smooth muscle from pig coronary arteries based on dissection of the proper tissue, homogenization, differential centrifugation and sucrose density gradient centrifugation is described. A number of marker enzymes and Ca2+ uptake in presence or absence of oxalate, ruthenium red and azide were studied. The ATP-dependent oxalate-independent azide- or ruthenium red-insensitive Ca2+ uptake, and the plasma membrane markers K+-activated ouabain-sensitive p-nitrophenylphosphatase, 5'-nucleotidase and Mg2+-ATPase showed maximum enrichment in the F2 fraction (15-28% sucrose) which was also contaminated with the endoplasmic reticulum marker NADPH: cytochrome c reductase, and to a small extent with the inner mitochondrial marker cytochrome c reductase, and also showed a small degree of oxalate stimulation of the Ca2+ uptake. F3 fraction (28-40% sucrose) was maximally enriched in the ATP- and oxalate-dependent azide-insensitive Ca2+ uptake and the endoplasmic reticulum marker NADPH: cytochrome c reductase but was heavily contaminated with the plasma membrane and the inner mitochondrial markers. The mitochondrial fraction was enriched in cytochrome c oxidase and azide- or ruthenium red-sensitive ATP-dependent Ca2+ uptake but was heavily contaminated with other membranes. Electron microscopy showed that F2 contained predominantly smooth surface vesicles and F3 contained smooth surface vesicles, rough endoplasmic reticulum and mitochondria. The ATP-dependent azide-insensitive oxalate-independent and oxalate-stimulated Ca2+ uptake comigrated with the plasma membrane and the endoplasmic reticulum markers, respectively, and were preferentially inhibited by digitonin and phosphatidylserine, respectively. This study establishes a basis for studies on receptor distribution and further Ca2+ uptake studies to understand the physiology of coronary artery vasodilation.     

Subcellular localization of prostaglandin E2 binding sites in bovine adrenal medulla

Prostaglandins E₁ and E₂ are specifically bound by particulate fractions from bovine adrenal medulla. The subcellular localization of these binding sites has been investigated by comparing their distribution in subcellular fractions obtained by differential and gradient centrifugation to those of marker enzymes for various organelles. Prostaglandin E₂ binding sites were purified about 16-fold with respect to the homogenate in a fraction which was highly enriched in plasma membranes on the basis of the activities of the marker enzymes acetylcholinesterase and calcium-dependent ATPase, which were both purified by about 12-fold in this fraction. The plasma membrane fraction contained relatively low activities of marker enzymes for mitochondria (monoamine oxidase), lysosomes (acid phosphatase), endoplasmic reticulum (glucose-6-phosphatase), Golgi (galactosyl transferase) and chromaffin granule membranes (dopamine β-hydroxylase). The only other fractions enriched in prostaglandin E₂ binding sites were those for the endoplasmic reticulum and the Golgi, in which the binding sites were purified about 4-fold and 7-fold, respectively. This is probably due mainly to contamination with plasma membranes, since calcium-dependent ATPase and acetylcholinesterase were each purified to a similar extent in these two fractions. These data suggest that the high-affinity prostaglandin E₂ binding sites of the adrenal medulla are localized primarily on the plasma membranes of the medullary cells.     

Ca2+ transporting activity of membrane fractions isolated from the post-mitochondrial supernatant of rat liver

The post-mitochondrial supernatant of rat liver contains two vesicular fractions which transport Ca2+ actively. The heavier fraction, sedimenting at 17.500 xg, 20 min, is enriched in plasma membrane markers and apparently contains both a Ca2+ pumping ATPase and a Na+/Ca2+ exchanger. These activities have been attributed to the plasma membrane vesicles. The lighter fraction, sedimenting at 100.000 xg, 60 min, is enriched in endoplasmic reticulum markers, and contains only a Ca2+ pumping ATPase, which can be differentiated from that of the heavier fraction on the basis of the sensitivity to vanadate. The Ca2+ pumping activity of endoplasmic reticulum appears to be regulated by both a cAMP-dependent, and a calmodulin-dependent system. The former system involves a heat-stable protein fraction from the cytosol. The regulation by the cAMP and the calmodulin-dependent systems involves the phosphorylation of several proteins in the endoplasmic reticulum membrane.     

Subcellular distribution of leukotriene C4 binding units in cultured bovine aortic endothelial cells

The subcellular distribution of specific binding sites for [3H]leukotriene C4 ([3H]LTC4) was analyzed after sedimentation of organelles from disrupted bovine aortic endothelial cells on sucrose density gradients and was shown to be in membrane fractions I (20% sucrose) and IV (35% sucrose). Saturation binding studies of [3H]LTC4 on endothelial cell monolayers at 4 degrees C demonstrated high-affinity binding sites with a dissociation constant (Kd) of 6.8 +/- 2.2 nM (mean +/- SD) and a density of 0.12 +/- 0.02 pmol/10(6) cells. At 4 degrees C, the specific binding of [3H]LTC4 by each of the subcellular fractions reached equilibrium at 30 min and remained stable for an additional 60 min. After 30 min of incubation with [3H]LTC4, the addition of excess unlabeled LTC4 to each subcellular fraction reversed more than 70% of [3H]LTC4 binding in 10 min. The [3H]LTC4 binding activities of subcellular fractions were enhanced approximately twofold to fourfold in the presence of Ca2+, Mg2+, and Mn2+, whereas Na+, K+, and Li+ were without effect. As measured by saturation experiments, the Kd and density of LTC4 binding sites in fraction I were 4.8 +/- 1.6 nM and 16.5 +/- 1.9 pmol/mg of protein, respectively, and in fraction IV were 4.7 +/- 1.5 nM and 81.4 +/- 19 pmol/mg of protein, respectively. Inhibition of [3H]LTC4 binding in membrane-enriched subcellular fractions I and IV by LTC4 occurred with molar inhibition constant (Ki) values of 4.5 +/- 0.1 nM and 4.7 +/- 1.2 nM, respectively, whereas Ki values for LTD4 were 570 +/- 330 nM and 62.5 +/- 32.8 nM, respectively, and for LTE4 were greater than 1000 nM for each fraction; LTB4 and reduced glutathione were even less active. FPL55712, a putative antagonist of the sulfidopeptide LT components of slow reacting substance of anaphylaxis, had Ki values of 1520 +/- 800 nM and 1180 +/- 720 nM for [3H]LTC4 binding sites on membrane-enriched subcellular fractions I and IV, respectively. Thus as defined by Kd, Ki, and specificity, the LTC4 binding units that are distributed to the plasma membrane and the binding units in the subcellular fraction of greater density were similar to each other. Pretreatment of the isolated subcellular membrane fractions with trypsin abolished [3H]LTC4 binding by fraction I, enriched for the plasma membrane marker 5' nucleotidase, and that by fraction IV, enriched for the mitochondrial membrane marker succinate-cytochrome C reductase.(ABSTRACT TRUNCATED AT 400 WORDS)     

Inositol 1,4,5-trisphosphate receptors. Localization in epithelial tissue.

Using a polyclonal antiserum raised against the inositol 1,4,5-trisphosphate receptor (IP3R) purified from rat cerebellum, we examined the subcellular distribution of IP3R in canine pancreatic homogenates. IP3R was present primarily in a smooth microsomal fraction (low density), a (high density) rough microsomal (RM) fraction previously shown to consist of highly purified rough endoplasmic reticulum (RER) vesicles, and, to a much lesser extent, in an intermediate density microsomal fraction which did not contain markers for RER or plasma membrane. When the RM fraction was subjected to isopycnic centrifugation on sucrose gradients, IP3R equilibrated at high sucrose densities. When ribosomes were extracted from the RM fraction by treatment with puromycin/high salt, IP3R equilibrated at considerably lighter sucrose densities. This shift in density indicated that IP3R which was present in the RM fraction is associated with the RER. Because of a significant amount of IP3R fractionating into the smooth microsomal fraction (which contains plasma membrane, among other "smooth" membranes) and a considerable amount of IP3R present in the nuclear pellet which is also enriched in plasma membrane, we examined the possibility that IP3R may be present in plasma membrane. Further subfractionation of a crude plasma membrane pellet from rat liver revealed that IP3R coenriched with a plasma membrane marker and strongly suggested an association of IP3R with plasma membrane. The issue of why the same receptor is found in multiple biochemically and morphologically distinct membrane fractions is discussed in terms of the possibility of RER subcompartmentalization and IP3R subtypes. The fractionation pattern of IP3R in pancreas is significantly different from that previously reported for calcium (Ca2+)-binding proteins and an intracellular Ca-ATPase (Nigam, S. K. and Towers, T. (1990) J. Cell Biol. 111, 197-200), raising questions as to links between these latter proteins and IP3 sensitive Ca2+ pools. Nevertheless, although the fractionation patterns are different, all of these proteins are clearly associated with the RER.     

Subcellular fractionation of pig stomach smooth muscle. A study of the distribution of the (Ca2+ + Mg2+)-ATPase activity in plasmalemma and endoplasmic reticulum

Isolated membrane vesicles from pig stomach smooth muscle (antral part) were subfractionated by a density gradient procedure modified in order to obtain an efficient extraction of extrinsic proteins. By using this method in combination with digitonin-treatment, an endoplasmic reticulum fraction contaminated with maximally 10 to 20% of plasma membranes was isolated, together with a plasma membrane fraction containing at most 30% endoplasmic reticulum. The endoplasmic reticulum and plasma membrane fractions differed in protein composition, reaction to digitonin, binding of wheat germ agglutinin, activities of marker enzymes and in the characteristics of the Ca2+ uptake. The Ca2+ uptake by the endoplasmic reticulum was much more stimulated by oxalate than the uptake by plasma membranes. Both fractions showed a (Ca2+ + Mg2+)-ATPase activity, but the largest amount of this enzyme was present in the plasma membranes. The study of the phosphorylated intermediates of the (Ca2+ + Mg2+)-ATPase by polyacrylamide gel electrophoresis revealed two phosphoproteins one of 130 kDa and one of 100 kDa (Wuytack, F., Raeymaekers, L., De Schutter, G. and Casteels, R. (1982) Biochim. Biophys. Acta 693, 45-52). The 130 kDa enzyme was predominant in the fraction enriched in plasma membrane whereas the distribution of the 100 kDa polypeptide correlated with the endoplasmic reticulum markers. The 130 kDa ATPase was the main 125I-calmodulin binding protein detected on nitrocellulose blots of proteins separated by gel electrophoresis. The (Ca2+ + Mg2+)-ATPase activity of the plasma membranes was higher than the (Na+ + K+)-ATPase activity, suggesting that the Ca2+ extrusion from these cells depends much more on the activity of the (Ca2+ + Mg2+)-ATPase than on Na+-Ca2+ exchange.     

Mitochondria suppress local feedback activation of inositol 1,4, 5-trisphosphate receptors by Ca2+.

The concerted action of inositol 1,4,5-trisphosphate (IP3) and Ca2+ on the IP3 receptor Ca2+ release channel (IP3R) is a fundamental step in the generation of cytosolic Ca2+ oscillations and waves, which underlie Ca2+ signaling in many cells. Mitochondria appear in close association with regions of endoplasmic reticulum (ER) enriched in IP3R and are particularly responsive to IP3-induced increases of cytosolic Ca2+ ([Ca2+]c). To determine whether feedback regulation of the IP3R by released Ca2+ is modulated by mitochondrial Ca2+ uptake, the interactions between ER and mitochondrial Ca2+ pools were examined by fluorescence imaging of compartmentalized Ca2+ indicators in permeabilized hepatocytes. IP3 decreased luminal ER Ca2+ ([Ca2+]ER), and this was paralleled by an increase in mitochondrial matrix Ca2+ ([Ca2+]m) and activation of Ca2+-sensitive mitochondrial metabolism. Remarkably, the decrease in [Ca2+]ER evoked by submaximal IP3 was enhanced when mitochondrial Ca2+ uptake was blocked with ruthenium red or uncoupler. Moreover, subcellular regions that were relatively deficient in mitochondria demonstrated greater sensitivity to IP3 than regions of the cell with a high density of mitochondria. These data demonstrate that Ca2+ uptake by the mitochondria suppresses the local positive feedback effects of Ca2+ on the IP3R, giving rise to subcellular heterogeneity in IP3 sensitivity and IP3R excitability. Thus, mitochondria can play an important role in setting the threshold for activation and establishing the subcellular pattern of IP3-dependent [Ca2+]c signaling.     

Localization of the essential histidine and carboxylate group in D-xylose isomerases.

A light hepatic microsomal preparation was fractionated by sucrose-density centrifugation into one rough, one intermediate and two smooth fractions. The four fractions were characterized with respect to parameters relevant to Ca2+ sequestration. Ca2(+)-ATPase activity was similar in the rough, intermediate and smooth I fractions, but lower in the smooth II fraction. Ca2+ accumulation was the highest in the smooth I and intermediate fractions. On the other hand, Ca2+ efflux from the rough fraction was several-fold faster than from the smooth I fraction. All four subfractions exhibited specific binding sites for inositol 1,4,5-trisphosphate (IP3) and ryanodine; however, the receptors were especially enriched in the smooth I fraction. The total binding sites for ryanodine in that fraction exceeded the number of binding sites for IP3 by about 10-fold. The two receptors responded differently to pharmacological agents; caffeine and dantrolene strongly inhibited ryanodine binding but not IP3 binding, whereas heparin inhibited IP3 binding only. Thus the two receptors are distinct entities. The four fractions also showed distinct gel electrophoretic patterns. The use of two different SDS/polyacrylamide-gel gradients and two protein-staining methods revealed major differences in the distribution of the bands corresponding to Mr values of (x 10(-3) 380, 320, 260, 170, 90, 29 and 21. These proteins were enriched in the smooth fraction. The results indicate that the smooth I fraction might have special importance in stimulus-evoked Ca2(+)-release processes.     

Alterations in binding of inositol 1,4,5-trisphosphate to subcellular structures of rat liver during chronic endotoxemia

Inositol 1,4,5-trisphosphate (IP3) binding to, and Ca2+ uptake and release by plasma membrane- and endoplasmic reticulum-enriched fractions of rat liver were measured after continuous Escherichia coli endotoxin (ET) administration in vivo. IP3 binding to both fractions was significantly reduced by ET treatment. This was associated with decreased Ca2+ uptake and impaired IP3-dependent Ca2+ release. A decrease of 5'-nucleotidase specific activity of plasma membrane-enriched fraction was also observed in ET treated rats. The results suggest that previously observed impairments in the ability of hepatocytes to mobilize Ca2+, to activate glycogen phosphorylase and to respond--when saponin permeabilized--by Ca2+ release upon IP3 addition during chronic endotoxemia are due to alterations in both IP3 binding to the subcellular fractions that are imputed to be targets of IP3, and a decrease in the size of IP3-sensitive pool of releasable Ca2+.     

Distribution of endoplasmic reticulum and calciosome markers in membrane fractions isolated from different regions of the canine brain

Four regions of the canine brain (frontal lobe, parieto-occipital lobe, brainstem, and cerebellum) were each fractionated by differential centrifugation into a crude mitochondrial pellet (P2) and a crude microsomal pellet (P3). Markers of endoplasmic reticulum (glucose-6-phosphate phosphatase and rotenone-insensitive NADPH cytochrome c reductase) and markers of the 1,4,5-trisphosphate (IP3)-sensitive Ca2+ store ([3H]IP3 binding and IP3-induced Ca2+ release) were measured. No correlation was found between the two classes of markers, which suggests that the IP3 receptor does not belong to the endoplasmic reticulum in canine brain. Cerebellum P2 and P3 fractions displayed levels of [3H]IP3 binding 10- to 30-fold higher, and rates of IP3-induced Ca2+ release greater than 15-fold faster than the homologous cerebrum and brainstem fractions. Actively accumulated Ca2+ was only partially released by IP3, both before and after saponin disruption of the plasma membrane compartment. The proportion of the IP3-sensitive Ca2+ store relative to that of the total (IP3-sensitive and IP3-insensitive) Ca2+ store was variable; i.e., it was larger in cerebellum P2 (approximately 90%) than in cerebrum fractions (less than 30%). Cerebellum fractions constitute the best source from which an IP3-sensitive Ca2+ storing organelle can be purified.     

Studies on canine gastric antrum smooth muscle: preparation and characterization of a plasma membrane enriched fraction

A method is described for preparation of large amounts of a plasma membrane (PM) enriched fraction from the smooth muscle of dog antrum. It consists of preparing microsomes, treating them with ATP + EGTA + Mg, centrifuging in 30% sucrose and then centrifuging the resulting supernatant in 15% sucrose to yield the plasma membrane enriched fraction P6. The subcellular fractions obtained at various steps during purification were characterized by: 5'-nucleotidase and phosphodiesterase I as plasma membrane markers; cytochrome c oxidase as an inner mitochondrial marker; NADPH-cytochrome c reductase as a putative endoplasmic reticulum marker; electron microscopy; polyacrylamide sodium dodecyl sulfate slab gel electrophoresis. The distribution of ATP-dependent and independent Ca uptake in presence and absence of azide and the effect of 5 mM oxalate or 25 mM phosphate on this uptake was also examined. The fraction P6 consists of mostly smooth surface vesicles 164.3 +/- 7.2 nm in diameter, has an exclusion volume of 9.7 microL/mg for [3H]inulin and 11.1 microL/mg for [3H]sucrose. P6 is maximally enriched in the ATP-dependent azide-insensitive Ca-uptake capacity and as compared with the postnuclear supernatant (S1) it shows a very small percent stimulation by oxalate and phosphate. The ATP-dependent Ca uptake by the P6 fraction occurs optimally at pH 7.0-7.4 and is much larger than the ATP-independent Ca uptake. At pH 7.1, the ATP-dependent Ca uptake occurs with a Km of 0.27 microM and a Hill coefficient greater than 2 for Ca2+. Half maximum binding of Ca2+ occurred at 300 microM Ca2+. Ca ionophores A23187 and ionomycin inhibited the ATP-dependent Ca uptake, and if added after the uptake, these caused a release of the accumulated Ca2+. From these and other data it is concluded that this PM preparation contains a Ca transport system which can lead to formation of greater than 1000-fold Ca2+ concentration gradient across the vesicle membrane in 1 min when extravesicular Ca2+ concentration is 0.3 microM. Thus this preparation is an extremely useful material for studying the mechanism of action of the Ca pump in smooth muscle plasma membrane.     

myo-Inositol 1,4,5-trisphosphate mobilizes Ca2+ from isolated adipocyte endoplasmic reticulum but not from plasma membranes.

The effects of myo-inositol 1,4,5-trisphosphate (IP3) on Ca2+ uptake and release from isolated adipocyte endoplasmic reticulum and plasma membrane vesicles were investigated. Effects of IP3 were initially characterized using an endoplasmic reticulum preparation with cytosol present (S1-ER). Maximal and half-maximal effects of IP3 on Ca2+ release from S1-ER vesicles occurred at 20 microM- and 7 microM-IP3, respectively, in the presence of vanadate which prevents the re-uptake of released Ca2+ via the endoplasmic reticulum Ca2+ pump. At saturating IP3 concentrations, Ca2+ release in the presence of vanadate was 20% of the exchangeable Ca2+ pool. IP3-induced release of Ca2+ from S1-ER was dependent on extravesicular free Ca2+ concentration with maximal release occurring at 0.13 microM free Ca2+. At 20 microM-IP3 there was no effect on the initial rate of Ca2+ uptake by S1-ER. IP3 promoted Ca2+ release from isolated endoplasmic reticulum vesicles (cytosol not present) to a similar level as compared with S1-ER. Addition of cytosol to isolated endoplasmic reticulum vesicles did not affect IP3-induced Ca2+ release. The endoplasmic reticulum preparation was further fractionated into heavy and light vesicles by differential centrifugation. Interestingly, the heavy fraction, but not the light fraction, released Ca2+ when challenged with IP3. IP3 (20 microM) did not promote Ca2+ release from plasma membrane vesicles and had no effect on the (Ca2+ + Mg2+)-ATPase activity or on the initial rate of ATP-dependent Ca2+ uptake by these vesicles. These results support the concept that IP3 acts exclusively at the endoplasmic reticulum to promote Ca2+ release.     

Kinetic characteristics of Ca2+, Mg2+-ATPases in cells of the submandibular salivary gland of rats

Kinetic properties of Ca2+, Mg2+-ATPases membranes from acinar cells of rat submandibular salivary glands have been investigated. It was found that kinetics of ATP hydrolysis dependent on Ca2+, Mg2+-ATPases corresponds to the first-order reaction during first 2 min. It was found that the initial velocity of the reaction (V0), maximal amount of the reaction product (Pmax) and characteristic time of the reaction (T) comprised 1.8 +/- 0.4 and 1.6 +/- 0.2 mmole Pi/min per 1 mg protein, 7.5 +/- 1.3 and 1.4 +/- 0.2 mmole Pi/mg protein and 4.1 +/- 0.7 min and 1.1 +/- 0.1 for Ca2+-ATPases from plasma and endoplasmic reticulum membranes, correspondingly. High- and low-affinity sites of ATP and Ca2+-binding in Ca2+-ATPases from plasma and endoplasmic reticulum membranes were identified. Negative cooperation in ATP binding to Ca2+-ATPase from plasma membrane and a positive cooperation for Ca2+-ATPase from endoplasmic reticulum has been found. Ca2+ binding to low-affinity sites of both Ca2+-ATPases showed no cooperation, while Ca2+ binding to high-affinity sites showed the positive cooperation. Using the Hill's coordinates we have found the values of the Mg2+ Michaelis constant (K(Mg)) which yielded 3.89 x 10(-5) and 3.80 x 10(-5) mole/l for Ca2+-ATPases from plasma and endoplasmic reticulum membranes, correspondingly. It is supposed that obtained data are important for further studies of molecular and membrane mechanisms involved in the regulation of intracellular calcium signalling and secretion by salivary acinar cells.     

Studies on isolated subcellular components of cat pancreas

Summary Pancreas of the cat was fractionated into its subcellular components by centrifugation through an exponential ficoll-sucrose density gradient in a zonal rotor. This enables a preparation of four fractions enriched in plasma membranes, endoplasmic reticulum, mitochondria and zymogen granules, respectively. The first fraction, enriched by 9- to 15-fold in the plasma membrane marker enzymes, hormone-stimulated adenylate cyclase, (Na⁺K⁺)-ATPase, and 5-nucleotidase, is contaminated by membranes derived from endoplasmic reticulum but is virtually free from mitochondrial and zymogen-granule contamination. The second fraction from the zonal gradient shows only moderate enrichment of the above marker enzymes but contains a considerable quantity of plasma membrane marker enzymes and represents mostly rough endoplasmic reticulum. The third fraction contains the bulk of mitochondria and the fourth mainly zymogen granules as assessed by electron microscopy and marker enzymes for both mitochondria and zymogen granules, namely succinic dehydrogenase, trypsin and amylase. Further purification of the plasma membrane fractions by differential and sucrose step-gradient centrifugation yields plasma membrane enriched 40-fold in basal and hormone-stimulated adenylate cyclase and (Na⁺K⁺)-ATPase.     

Localization of the oxytocin receptor in the plasma membrane of rat myometrium.

The distribution of [3H]oxytocin binding sites among various subcellular fractions of rat myometrium paralleled the distribution of 5'-nucleotidase, a plasma membrane marker enzyme, but not of NADPH-cytochrome c reductase or succinate-cytochrome c reductase, which are endoplasmic reticulum and mitochondrial marker enzymes respectively. [3H]Oxytocin binding to the most enriched plasma membrane fraction showed the degree of selectivity with respect to hormone analogues that is expected for the oxytocin receptor. The binding of oxytocin to this fraction showed an apparent Kd of 1.98 X 10(-9) M and a capacity of 1.28 pmol mg-1. It is concluded that the oxytocin receptor is located on the plasma membrane of the smooth muscle cells of the rat uterus.     

Calcium sequestration in the liver: Review article

Hepatic parenchymal cells maintain intracellular total and cytosolic free Ca2+ levels by: entry of Ca2+ through channels, extrusion of Ca2+ by an outwardly directed Ca2+ pump, and controlled sequestration into intracellular pools. The mechanism of Ca2+ inflow is poorly characterized. The plasma membrane Ca2+ channels seem to share some of the characteristics of Ca2+ channels in excitable cells, but also differ from them. The outwardly directed plasma membrane Ca2(+)-ATPase is a calmodulin independent, P-type enzyme. Ca2+ uptake into the endoplasmic reticulum is due to the activity of a different Ca2(+)-ATPase, which is similar in molecular weight and shares antigenic determinants with the sarcoplasmic reticulum enzyme. In addition, mitochondria and nuclei also take up calcium. The exact mechanism by which Ca2+ is released from intracellular organelles is not well known. Several mechanisms for Ca2+ release from the endoplasmic reticulum were reported, including IP3 and GTP-induced. The most effective identified way of eliciting Ca2+ release from microsomal fraction is by the oxidation of critical -SH groups. This mechanism is likely to be involved in the rise of cytosolic Ca2+ observed in many situations of hepatocellular injury. In addition to being sequestered into subcellular organelles, some of the intracellular Ca2+ is bound to specific Ca2+ binding proteins. Both calmodulin and members of the annexin family were identified in the liver. Stimulation of the liver with gluconeogenic hormones results in increased Ca2+ entry into the cell, the release of Ca2+ from intracellular pools, and an oscillatory increase in free cytosolic Ca2+ levels. Extensive research is still needed for the elucidation of the exact mechanisms by which these events occur.