Subcellular localization of the delayed rectifier K(+) channels KCNQ1 and ERG1 in the rat heart

In the heart, several K(+) channels are responsible for the repolarization of the cardiac action potential, including transient outward and delayed rectifier K(+) currents. In the present study, the cellular and subcellular localization of the two delayed rectifier K(+) channels, KCNQ1 and ether-a-go-go-related gene-1 (ERG1), was investigated in the adult rat heart. Confocal immunofluorescence microscopy of atrial and ventricular cells revealed that whereas KCNQ1 labeling was detected in both the peripheral sarcolemma and a structure transversing the myocytes, ERG1 immunoreactivity was confined to the latter. Immunoelectron microscopy of atrial and ventricular myocytes showed that the ERG1 channel was primarily expressed in the transverse tubular system and its entrance, whereas KCNQ1 was detected in both the peripheral sarcolemma and in the T tubules. Thus, whereas ERG1 displays a very restricted subcellular localization pattern, KCNQ1 is more widely distributed within the cardiac cells. The localization of these K(+) channels to the transverse tubular system close to the Ca(2+) channels renders them with maximal repolarizing effect.     

Immunolocalization of caveolin-1 and caveolin-3 in monkey skeletal,cardiac and uterine smooth muscles

Caveolin, a 20-24 kDa integral membrane protein, is a principal component of caveolar domains. Caveolin-1 is expressed predominantly in endothelial cells, fibroblasts, and adipocytes, while the expression of caveolin-3 is confined to muscle cells. However, their localization in various muscles has not been well documented. Using double-immunofluorescence labeling and confocal laser microscopy, we examined the localization of caveolins-1 and 3 in adult monkey skeletal, cardiac and uterine smooth muscles and the co-immunolocalization of these caveolins with dystrophin, which is a product of the Duchenne muscular dystrophy gene. In the skeletal muscle tissue, caveolin-3 was localized along the sarcolemma except for the transverse tubules, and co-immunolocalized with dystrophin, whereas caveolin-1 was absent except in the blood vessels of the muscle tissue. In cardiac muscle cells, caveolins-1 and -3 and dystrophin were co-immunolocalized on the sarcolemma and transverse tubules. In uterine smooth muscle cells, caveolin-1, but not caveolin-3, was co-immunolocalized with dystrophin on the sarcolemma.     

Immunohistochemical localization of annexin V (CaBP33) in rat organs.

We investigated the cellular distribution of annexin V (CaBP33) in rat tissues by immunohistochemistry. Several cell types were shown to express the protein. Glial cells in the cerebellum and in the optic nerve, the corneal epithelium, the posterior epithelium in the iris, chondrocytes, skeletal muscle cells and cardiomyocytes, the capillary endothelial cells in many organs, the muscularis mucosae and the muscular layer in the intestinal tract, hepatocytes, Müller cells in the retina, the lens fibers, Sertoli and Leydig cells in the testis, and smooth muscle cells in the epididymis and bronchi displayed intense immunostaining. In the adrenal gland, only the cortex showed immunoreaction product. In the kidney, no apparent staining of renal cells was observed, whereas endothelial cells of peritubular capillaries were stained. In the heart, annexin V was found associated exclusively with the sarcolemma and intercalated discs, as opposed to the diffuse distribution of the protein in skeletal muscle cells. In the spleen, only reticular elements in the white pulp and endothelial cells in the red pulp appeared to be immunostained. The present data complement the biochemical work thus far done on annexin V and suggest that the protein is neither restricted to secretory cells nor exclusively related to exocytotic events in secretory cells.     

Subcellular localization of S100A11 (S100C,calgizzarin) in developing and adult avian skeletal muscles

S100A11 is a member of a multigenic family of Ca(2+)-modulated proteins of the EF-hand type. We studied the subcellular localization of S100A11 in developing and adult avian skeletal muscle cells by confocal laser scanning microscopy and immunogold cytochemistry to get information about possible functional roles of this protein. Analyses of alpha-actinin, S100A1 and S100B were done in parallel for comparison. Low levels of S100A11 were found in skeletal muscle cells at embryonic day (E) 8. At E12, S100A11 was found in myotubes in the form of fine dots located between Z-discs, and on the sarcolemma and its invaginations. At E15, S100A11 was found on the sarcolemma and internal membranes, likely longitudinal tubules, where the protein was co-localized in part with S100A1 and S100B. At E18 and afterwards, co-localization of the three S100 proteins on internal membranes was almost complete. No evidence for association of S100A11 with the contractile elements of the sarcomeres was obtained. Our data suggests that, like S100A1 and S100B, S100A11 might have a role in the regulation of membrane activities, probably in relation to Ca(2+) fluxes in skeletal muscle cells.     

Calcium ions inhibit the allosteric interaction between the dihydropyridine and phenylalkylamine binding site on the voltage-gated calcium channel in heart sarcolemma but not in skeletal muscle transverse tubules

Calcium channel blockers bind with high affinity to sites on the voltage-sensitive Ca2+ channel. Radioligand binding studies with various Ca2+ channel blockers have facilitated identification and characterization of binding sites on the channel structure. In the present study we evaluated the relationship between the binding sites for the Ca2+ channel blockers on the voltage-sensitive Ca2+ channel from rabbit heart sarcolemma and rabbit skeletal muscle transverse tubules. [3H]PN200-110 binds with high affinity to a single population of sites on the voltage-sensitive Ca2+ channel in both rabbit heart sarcolemma and skeletal muscle transverse tubules. [3H]PN200-110 binding was not affected by added Ca2+ whereas EGTA and EDTA noncompetitively inhibited binding in both types of membrane preparations. EDTA was a more potent inhibitor of [3H]PN200-110 binding than EGTA. Diltiazem stimulates the binding of [3H]PN200-110 in a temperature-sensitive manner. Verapamil inhibited binding of [3H]PN200-110 to both types of membrane preparations in a negative manner, although this effect was of a complex nature in skeletal muscle transverse tubules. The negative effect of verapamil on [3H]PN200-110 binding in cardiac muscle was completely reversed by Ca2+. On the other hand, Ca2+ was without effect on the negative cooperativity seen between verapamil and [3H]PN200-110 binding in skeletal muscle transverse tubules. Since Ca2+ did not affect [3H]PN200-110 binding to membranes, we would like to suggest that Ca2+ is modulating the negative effect of verapamil on [3H]PN200-110 binding through a distinct Ca2+ binding site.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cholesterol regulates membrane binding and aggregation by annexin 2 at submicromolar Ca(2+) concentration

Annexin 2 is a member of the annexin family which has been implicated in calcium-regulated exocytosis. This contention is largely based on Ca(2+)-dependent binding of the protein to anionic phospholipids. However, annexin 2 was shown to be associated with chromaffin granules in the presence of EGTA. A fraction of this bound annexin 2 was released by methyl-beta-cyclodextrin, a reagent which depletes cholesterol from membranes. Restoration of the cholesterol content of chromaffin granule membranes with cholesterol/methyl-beta-cyclodextrin complexes restored the Ca(2+)-independent binding of annexin 2. The binding of both, monomeric and tetrameric forms of annexin 2 was also tested on liposomes of different composition. In the absence of Ca(2+), annexin 2, especially in its tetrameric form, bound to liposomes containing phosphatidylserine, and the addition of cholesterol to these liposomes increased the binding. Consistent with this observation, liposomes containing phosphatidylserine and cholesterol were aggregated by the tetrameric form of annexin 2 at submicromolar Ca(2+) concentrations. These results indicate that the lipid composition of membranes, and especially their cholesterol content, is important in the control of the subcellular localization of annexin 2 in resting cells, at low Ca(2+) concentration. Annexin 2 might be associated with membrane domains enriched in phosphatidylserine and cholesterol.     

Rabbit annexins: comparison of a series of proteins in cell-free homogenates and membranes from various tissues and a method of rapid preliminary identification of individual components after two-dimensional electrophoresis]

The annexin sets in cell-free homogenates and membranes of rabbit skeletal and heart muscles, liver, kidney, lung, and brain, have been compared by one- and two-dimensional electrophoresis. The pIs and M(r)s of the proteins identified have been determined. The data on two-dimensional electrophoresis of annexins from different animals have been systematized. Simple graphs are proposed which allow to identify annexins on electrophoregrams. The technique has definite potentialities in recognition of some unidentified Ca(2+)-dependent membrane-binding proteins and may be used to predict the trend of search for novel members of the annexin family.     

Mechanism of Ca2+ inhibition of inositol 1,4,5-trisphosphate (InsP3) binding to the cerebellar InsP3 receptor.

Ca2+ efficiently inhibits binding of inositol 1,4,5-trisphosphate (InsP3) to the InsP3 receptor in cerebellar membranes but not to the purified receptor. We have now investigated the mechanism of action by which Ca2+ inhibits InsP3 binding. Our results suggest that Ca2+ does not cause the stable association of a Ca(2+)-binding protein with the receptor. Instead, Ca2+ leads to the production of a soluble, heat-stable, low molecular weight substance from cerebellar membranes that competes with InsP3 for binding. This inhibitory substance probably represents endogenously generated InsP3 as judged by the fact that it co-purifies with InsP3 on anion-exchange chromatography, competes with [3H]InsP3 binding in a pattern similar to unlabeled InsP3, and is in itself capable of releasing 45Ca2+ from permeabilized cells. A potent Ca(2+)-activated phospholipase C activity producing InsP3 was found in cerebellar microsomes that exhibited a Ca2+ dependence identical to the Ca(2+)-dependent inhibition of InsP3 binding. Together these results suggest that the Ca(2+)-dependent inhibition of InsP3 binding to the cerebellar receptor is due to activation of a Ca(2+)-sensitive phospholipase C enriched in cerebellum. Nevertheless, Ca2+ probably also modulates the InsP3 receptor function by a direct interaction with the receptor that does not affect InsP3 binding but regulates InsP3-dependent channel gating.     

Membrane-bound annexin V isoforms (CaBP33 and CaBP37) and annexin VI in bovine tissues behave like integral membrane proteins.

The distribution of annexin V isoforms (CaBP33 and CaBP37) and of annexin VI in bovine lung, heart, and brain subfractions was investigated with special reference to the fractions of these proteins which are membrane-bound. In addition to EGTA-extractable pools of the above proteins, membranes from lung, heart, and brain contain EGTA-resistant annexins V and VI which can be solubilized with detergents (Triton X-100 or Triton X-114). A strong base like Na2CO3, which is usually effective in extracting membrane proteins, only partially solubilizes the membrane-bound, EGTA-resistant annexins analyzed here. Also, only 50-60% of the Triton X-114-soluble annexins partition in the aqueous phase, the remaining fractions being recovered in the detergent-rich phase. Altogether, these findings suggest that, by an as yet unknown mechanism, following Ca(2+)-dependent association of annexin V isoforms and annexin VI with membranes, substantial fractions of these proteins remain bound to membranes in a Ca(2+)-independent way and behave like integral membrane proteins. These results further support the possibility that the above annexins might play a role in membrane trafficking and/or in the regulation of the structural organization of membranes.     

The lack of annexin A7 affects functions of primary astrocytes

Annexin A7 is a Ca(2+)- and phospholipid-binding protein, which is thought to function in membrane organization and Ca(2+)-dependent signaling processes. It localizes to different cellular compartments and exists in a 47- and 51-kDa isoform with the large isoform being expressed in brain, skeletal, and heart muscle. In human temporal brain annexin A7 was found exclusively in astroglial cells. As astrocytes are thought to play key roles in several processes of the brain we focused on Ca(2+)-dependent signaling processes and astrocyte proliferation. Primary astrocytes from an anxA7(-/-) mouse exhibited an increased velocity of mechanically induced astrocytic Ca(2+) waves as compared to wild type. We also observed a remarkably increased proliferation rate in cultured mutant astrocytes. A search for annexin A7 binding partners with advanced biochemical methods confirmed sorcin as the major binding protein. However, in vivo GFP-tagged annexin A7 and sorcin appeared to redistribute mainly independently from each other in wild type and in mutant astrocytes. Our results favor an involvement of annexin A7 in Ca(2+)-dependent signaling or Ca(2+) homeostasis in astrocytes.     

Characterization of mammalian heart annexins with special reference to CaBP33 (annexin V)

Porcine heart was observed to express annexins V (CaBP33) and VI in large amounts, and annexins III and IV in much smaller amounts. Annexin V (CaBP33) in porcine heart was examined in detail by immunochemistry. Homogenization and further processing of heart in the presence of EGTA resulted in the recovery of annexin V (CaBP33) in the cytosolic fraction and in an EGTA-resistant, Triton X-100-soluble fraction from cardiac membranes. Including Ca2+ in the homogenization medium resulted in a significant decrease in the annexin V (CaBP33) content of the cytosolic fraction with concomitant increase in the content of this protein in myofibrils, mitochrondria, the sarcoplasmic reticulum and the sarcolemma. The amount of annexin V (CaBP33) in each of these subfractions depended on the free Ca2+ concentration in the homogenizing medium. At the lowest free Ca2+ concentration tested, 0.8 microM, only the sarcolemma appeared to contain bound annexin V (CaBP33). Membrane-bound annexins V (CaBP33) and VI partitioned in two fractions, one EGTA-resistant and Triton X-100-extractable, and one Triton X-100-resistant and EGTA-extractable. Altogether, these data suggest that annexins V and VI are involved in the regulation of membrane-related processes.     

Shape, size, and distribution of Ca(2+) release units and couplons in skeletal and cardiac muscles.

Excitation contraction (e-c) coupling in skeletal and cardiac muscles involves an interaction between specialized junctional domains of the sarcoplasmic reticulum (SR) and of exterior membranes (either surface membrane or transverse (T) tubules). This interaction occurs at special structures named calcium release units (CRUs). CRUs contain two proteins essential to e-c coupling: dihydropyridine receptors (DHPRs), L-type Ca(2+) channels of exterior membranes; and ryanodine receptors (RyRs), the Ca(2+) release channels of the SR. Special CRUs in cardiac muscle are constituted by SR domains bearing RyRs that are not associated with exterior membranes (the corbular and extended junctional SR or EjSR). Functional groupings of RyRs and DHPRs within calcium release units have been named couplons, and the term is also loosely applied to the EjSR of cardiac muscle. Knowledge of the structure, geometry, and disposition of couplons is essential to understand the mechanism of Ca(2+) release during muscle activation. This paper presents a compilation of quantitative data on couplons in a variety of skeletal and cardiac muscles, which is useful in modeling calcium release events, both macroscopic and microscopic ("sparks").     

Modification of annexin II expression in PC12 cell lines does not affect Ca(2+)-dependent exocytosis.

The Ca2+/phospholipid/cytoskeletal-binding protein annexin II has been proposed to play an important role in Ca(2+)-dependent exocytosis; however, the evidence for this role is inconclusive. More direct evidence obtained by manipulating annexin II levels in cells is still required. We have attempted to do this by generating stably transfected PC12 cell lines expressing proteins which elevate or lower functional annexin II levels and using these cell lines to investigate Ca(2+)-dependent exocytosis. Three cell lines were generated: one expressing an annexin II mutant which aggregates annexin II in at least a proportion of the cells, thereby removing functional protein from the cell; a mixed clonal cell line constitutively overexpressing human annexin II; and a clonal cell line capable of over-expressing annexin II in the presence of sodium butyrate. After digitonin permeabilization, Ca(2+)-dependent dopamine release from these cell lines was compared with that from control nontransfected cells, and, in addition, release was compared in induced to uninduced cells. There were no significant differences in Ca(2+)-dependent exocytosis between any of the transfected cell lines before or after induction and the control cells. In addition, nontransfected PC12 cells treated with nerve growth factor, which elevates annexin II levels severalfold, failed to increase Ca(2+)-dependent exocytosis after digitonin permeabilization, compared with control cells. We conclude that annexin II is not an important regulator of Ca(2+)-dependent exocytosis in PC12 cells.     

Immunocytochemical localization of 67 KD Ca2+ binding protein (p67) in ventricular, skeletal, and smooth muscle cells.

By using immunocytochemical techniques, we examined the localization of a 67 kDa Ca2+ binding protein (p67) and calpactin I heavy chain (p36) in ventricular myocytes, skeletal myocytes, and intestinal smooth muscle cells. Immunofluorescence microscopy revealed that the p67 was expressed in all these muscle cells, whereas anti-p36 antibody stained cells in connective tissues but failed to stain these muscle cells. Immunogold electron microscopy was carried out to examine the subcellular localization of the p67 in muscle cells. The results showed that the p67 was exclusively confined to the plasma membrane of muscle cells and the presumptive transverse tubules of the striated myocytes. Immunoblot analysis with anti-p67 antibody showed that the p67 was indeed a constitutive protein of the sarcolemma isolated from rat hearts. These results indicate that the p67 is a sarcolemma-associated Ca2+ binding protein expressed in both striated myocytes and intestinal smooth muscle cells.     

Stimulation of calcium accumulation in cardiac sarcolemma by protein kinase.

Sarcolemmal membranes isolated from guinea pig heart ventricles contained an ATP-dependent calcium-sequestering activity. Sarcolemmal calcium accumulation but not binding was enhanced by preincubation of membranes with exogenous protein kinase, with cyclic AMP, or with isoproterenol. Protein kinase (EC 2.7.1.37) increased the V of Ca2+ accumulation by sarcolemma without any significant effect on the affinity for Ca2+. The endogenous protein kinase activity present in isolated sarcolemma affected membrane phosphorylation. Cyclic AMP increased the endogenous kinase activity modestly, whereas histone increased it significantly. Exogenous protein kinase also catalyzed phosphorylation of these membranes. Endogenous and exogenous kinase-catalyzed phosphorylation of sarcolemma was hydroxylamine-insensitive. Ca2+-dependent ATPase (EC 3.6.1.3) (extra ATPase) activity of sarcolemma was also increased by protein kinase.     

Annexin V counteracts apoptosis while inducing Ca(2+) influx in human lymphocytic T cells

We have previously shown that when annexin V is present during the execution of a cell death program, apoptosis is delayed. This is reflected by the inhibition of DNA cleavage and of the release of apoptotic membrane particles, and by reduction of the proteolytic processing of caspase-3. Here, we have studied the mechanism(s) through which annexin V counteracts apoptosis in the human CEM T cell line. The degree of apoptosis inhibition was associated with an increase of intracellular Ca(2+) concentration ([Ca(2+)](i)). Reduction of the extracellular Ca(2+) concentration by EGTA abolished the anti-apoptotic effect, suggesting that annexin V favors Ca(2+) influx and that Ca(2+) acts as an inhibitor rather than an activator of apoptosis in CEM T cells. The effects on apoptosis and [Ca(2+)](i) of several modified annexins with different electrophysiological properties indicate that the N-terminal domain of annexin V is necessary for the Ca(2+)-dependent anti-apoptotic action of annexin V. These results suggest that annexin V regulates membrane Ca(2+) permeability and is protective against apoptosis by increasing [Ca(2+)](i) in CEM T cells.     

Binding of annexins to lung lamellar bodies and the PMA-stimulated secretion of annexin V from alveolar type II cells

To identify lung lamellar body (LB)-binding proteins, the fractions binding to LB-Sepharose 4B in a Ca(2+)-dependent manner from the lung soluble fractions were analyzed with Mono Q column. Four annexins (annexins III, IV, V, and VIII) were identified by partial amino acid sequence analyses as the LB-binding proteins in the lung soluble fractions. A control experiment using phospholipid (phosphatidylserine/phosphatidylglycerol/phosphtidylcholine) liposome-Sepharose 4B revealed that annexins III, IV and V were the Ca(2+)-dependent proteins binding to the column in the lung soluble fractions, while annexin VIII was not detected. Thus, annexin VIII might preferentially bind to LB. On the other hand, the only Ca(2+)-dependent LB-binding protein identified in the bronchoalveolar lavage fluids was annexin V. It was further demonstrated that annexin V was secreted by isolated alveolar type II cells from rats and that the secretion was stimulated by the addition of phorbol ester (PMA), a potent stimulator of surfactant secretion. The PMA-dependent stimulation of annexin V was attenuated by preincubation with surfactant protein-A (SP-A), a potent inhibitor of surfactant secretion. As LB is thought to be an intracellular store of pulmonary surfactant, which is secreted by alveolar type II cells, annexin V is likely to be secreted together with the lamellar body.     

Identification of novel proteins unique to either transverse tubules (TS28) or the sarcolemma (SL50) in rabbit skeletal muscle

Novel proteins unique to either transverse tubules (TS28) or the sarcolemma (SL50) have been identified and characterized, and their in situ distribution in rabbit skeletal muscle has been determined using monoclonal antibodies. TS28, defined by mAb IXE112, was shown to have an apparent relative molecular mass of 28,000 D. Biochemical studies showed that TS28 is a minor membrane protein in isolated transverse tubular vesicles. Immunofluorescence and immunoelectron microscopical studies showed that TS28 is localized to the transverse tubules and in some subsarcolemmal vesicles possibly corresponding to the subgroup of caveolae connecting the transverse tubules with the sarcolemma. In contrast, TS28 is absent from the lateral portion of the sarcolemma. Immunofluorescence studies also showed that TS28 is more densely distributed in type II (fast) than in type I (slow) myofibers. Although TS28 and the 1,4-dihydropyridine receptor are both localized to transverse tubules and subsarcolemmal vesicles, TS28 is not a wheat germ agglutinin (WGA)-binding glycoprotein and does not appear to copurify with the 1,4-dihydropyridine receptor after detergent solubilization of transverse tubular membranes. SL50, defined by mAb IVD31, was shown to have an apparent relative molecular mass of 50,000 D. Biochemical studies showed that SL50 is not related to the 52,000-D (beta subunit) of the dihydropyridine receptor but does bind to WGA-Sepharose. Immunofluorescence labeling imaged by standard and confocal microscopy showed that SL50 is associated with the sarcolemma but apparently absent from the transverse tubules. Immunofluorescence labeling also showed that the density of SL50 in type II (fast) myofibers is indistinguishable from that of type I (slow) myofibers. The functions of TS28 and SL50 are presently unknown. However, the distinct distribution of TS28 to the transverse tubules and subsarcolemmal vesicles as determined by immunocytochemical labeling suggests that TS28 may be directly involved in excitation-contraction coupling. Our results demonstrate that, although transverse tubules are continuous with the sarcolemma, each of these membranes contain one or more unique proteins, thus supporting the idea that they each have a distinct protein composition.     

Insulin unmasks a COOH-terminal Glut4 epitope and increases glucose transport across T-tubules in skeletal muscle

An improved immunogold labeling procedure was used to examine the subcellular distribution of glucose transporters in Lowricryl HM20- embedded skeletal muscle from transgenic mice overexpressing either Glut1 or Glut4. In basal muscle, Glut4 was highly enriched in membranes of the transverse tubules and the terminal cisternae of the triadic junctions. Less than 10% of total muscle Glut4 was present in the vicinity of the sarcolemmal membrane. Insulin treatment increased the number of gold particles associated with the transverse tubules and the sarcolemma by three-fold. However, insulin also increased the total Glut4 immunogold reactivity in muscle ultrathin sections by up to 1.8- fold and dramatically increased the amount of Glut4 in muscle sections as observed by laser confocal immunofluorescence microscopy. The average diameter of transverse tubules observed in longitudinal sections increased by 50% after insulin treatment. Glut1 was highly enriched in the sarcolemma, both in the basal state and after insulin treatment. Disruption of transverse tubule morphology by in vitro glycerol shock completely abolished insulin-stimulated glucose transport in isolated rat epitrochlearis muscles. These data indicate that: (a) Glut1 and Glut4 are targeted to distinct plasma membrane domains in skeletal muscle; (b) Glut1 contributes to basal transport at the sarcolemma and the bulk of insulin-stimulated transport is mediated by Glut4 localized in the transverse tubules; (c) insulin increases the apparent surface area of transverse tubules in skeletal muscle; and (d) insulin causes the unmasking of a COOH-terminal antigenic epitope in skeletal muscle in much the same fashion as it does in rat adipocytes.     

The presence of a secretory phospholipase A2 in the nuclei of neuronal and glial cells of rat brain cortex

Confocal immunofluorescence analysis indicated a relatively high localization of group V secretory phospholipase A(2) (GV) in the nuclei of cultured PC12 and U251 astrocytoma cells. Here, we report the biochemical evidence for the presence of a secretory PLA(2) in the nuclei of neuronal and glial cells from rat brain cortex. Enzymic activity was determined using [(3)H]oleate labelled Escherichia coli membranes in intact nuclei and in their soluble fractions in which the specific activity was significantly more elevated. The treatment of soluble nuclear fractions with inhibitors of cytosolic Ca(2+)-dependent or Ca(2+)-independent phospholipases A(2) was ineffective whereas DTT or Indoxam, a specific inhibitor of all isoforms of sPLA(2), abolished enzyme activity. The enzyme was identified as group V secretory phospholipase A(2) (GV) by Western blot analysis and its nucleoplasmic localization was demonstrated by CLSM.