Calcium and pancreatic secretion. I. Subcellular distribution of calcium and magnesium in the exocrine pancreas of the guinea pig

Preferential Coupling of the NAADP Pathway to Exocytosis in T-Cells

A cytotoxic T-lymphocyte (CTL) kills an infected or tumorigenic cell by Ca2+-dependent exocytosis of cytolytic granules at the immunological synapse formed between the two cells. However, these granules are more than reservoirs of secretory cytolytic proteins but may also serve as unique Ca2+ signaling hubs that autonomously generate their own signals for exocytosis. This review discusses a selective role for the Ca2+-mobilizing messenger, nicotinic acid adenine dinucleotide phosphate (NAADP) and its molecular targets, two-pore channels (TPCs), in stimulating exocytosis. Given that TPCs reside on the exocytotic granules themselves, these vesicles generate as well as respond to NAADP-dependent Ca2+ signals, which may have wider implications for stimulus-secretion coupling, vesicular fusion, and patho-physiology.

How to measure Ca2+ in cellular organelles?

The review will aim to briefly summarise information on calcium measurements in cellular organelles with emphases on studies conducted in live cells using optical probes. When appropriate we will try to compare the effectiveness of different indicators for intraorganellar calcium measurements. We will consider calcium measurements in endoplasmic reticulum, Golgi apparatus, endosomes/lysosomes, nucleoplasm, nuclear envelope, mitochondria and secretory granules.

Organelles Containing Inositol Trisphosphate Receptor Type 2 in Adrenal Medullary Cells

To identify which organelles contained inositol trisphosphate (InsP(3)) receptor type 2 (InsP(3)R2) in adrenal medullary (AM) cells, immunocytochemical and biochemical studies were performed on AM cells of several species. InsP(3)R2-like immunoreactive materials produced by two different anti-InsP(3)R2 antibodies (Abs) (Chemicon and Sigma) were distributed in rat AM cells in agreement with BODIPY-FL-InsP(3) binding sites. For two other Abs (KM1083 and Santa Cruz), some of the anti-InsP(3)R2 immunoreactive materials were stained with an anti-dopamine-beta-hydroxylase Ab, but not by BODIPY-FL-InsP(3). BODIPY-FL-thapsigargin binding sites were consistent with a distribution of the endoplasmic reticulum (ER) identified by an anti-calnexin Ab, and a prior application of thapsigargin significantly eliminated BODIPY-FL-thapsigargin bindings, suggesting that BODIPY-FL-thapsigargin bindings were mediated by thapsigargin, but not the fluorescence molecule. The anti-InsP(3)R2 Ab that produced stainings consistent with BODIPY-FL-InsP(3) bindings recognized a protein with about 250 kDa. A fractional analysis of bovine adrenal medullae revealed that the 250 kDa InsP(3)R2 was detected in a crude membrane fraction, but not in a secretory granule fraction. The results suggest that the InsP(3)R2 was present in the ER, but not in secretory granules in AM cells.

Evidence that zymogen granules do not function as an intracellular Ca2+ store for the generation of the Ca2+ signal in rat parotid acinar cells

Rat parotid acinar cells lacking zymogen granules were obtained by inducing granule discharge with the beta-adrenoceptor agonist isoproterenol. To assess whether zymogen granules are involved in the regulation of Ca(2+) signalling as intracellular Ca(2+) stores, changes in cytosolic free Ca(2+) ion concentration ([Ca(2+)](i)) were studied with imaging microscopy in fura-2-loaded parotid acinar cells lacking zymogen granules. The increase in [Ca(2+)](i) induced by muscarinic receptor stimulation was initiated at the apical pole of the acinar cells, and rapidly spread as a Ca(2+) wave towards the basolateral region. The magnitude of the [Ca(2+)](i) response and the speed of the Ca(2+) wave were essentially similar to those in control acinar cells containing zymogen granules. Western blot analysis of the inositol 1,4,5-trisphosphate receptor (IP(3)R) was performed on zymogen granule membranes and microsomes using anti-IP(3)R antibodies. The immunoreactivity of all three IP(3)Rs was clearly observed in the microsomal preparations. Although a weak band of IP(3)R type-2 was detected in the zymogen granule membranes, this band probably resulted from contamination by the endoplasmic reticulum (ER), because calnexin, a marker protein of the ER, was also detected in the same preparation. Furthermore, Western blotting and reverse transcriptase-PCR analysis failed to provide evidence for the expression of ryanodine receptors in rat parotid acinar cells, whereas expression was clearly detectable in rat skeletal muscle, heart and brain. These results suggest that zymogen granules do not have a critical role in Ca(2+) signalling in rat parotid acinar cells.

Inositol trisphosphate and cyclic ADP-ribose-mediated release of Ca2+ from single isolated pancreatic zymogen granules

In pancreatic acinar cells low (physiological) agonist concentrations evoke cytosolic Ca2+ spikes specifically in the apical secretory pole that contains a high density of secretory (zymogen) granules (ZGs). Inositol 1,4,5-trisphosphate (IP3) is believed to release Ca2+ from the endoplasmic reticulum, but we have now tested whether the Ca(2+)-releasing messengers IP3 and cyclic ADP-ribose (cADPr) can liberate Ca2+ from AGs. In experiments on single isolated ZGs, we show using confocal microscopy that IP3 and cADPr evoke a marked decrease in the free intragranular Ca2+ concentration. Using a novel high resolution method, we have measured changes in the Ca2+ concentration in the vicinity of an isolated AG and show that IP3 and cADPr cause rapid Ca2+ release from the granule, explaining the agonist-evoked cytosolic Ca2+ rise in the secretory pole.

Calcium loading of secretory granules in stimulated neurohypophysial nerve endings

The total calcium content of secretory granules, Cag, was evaluated in isolated neurohypophysial nerve endings. The Cag in the resting state, as measured by X-ray microanalysis, is relatively high with an average of 7.4 +/- 0.6 mmol/kg wet weight. Following a depolarizing potassium challenge, a subpopulation of granules with even higher Cag could be detected, dispersed over a wider range of concentrations (up to 70 mmol/kg wet weight). After subsequent rinsing in physiological saline, Cag decreased to control values. This could have resulted from Ca2+ extrusion, or from preferential secretion of calcium-enriched granules. Our data can be interpreted in favor of the second explanation since no decrease in Cag was observed when secretion was blocked by a hyperosmotic saline. The effect of hyperosmotic conditions on isolated nerve endings was further studied by monitoring free cytoplasmic Ca2+ with the calcium-sensitive dye Fura-2 and by conventional electron microscopy. It was demonstrated that hyperosmotic treatment alone did not increase basal cytosolic Ca2+ concentrations but did significantly reduce the potassium-induced cytosolic rise in Ca2+. Electron microscopy of nerve endings in hyperosmotic conditions showed numerous exocytotic figures at various stages. The observed changes in Cag are in accord with a published hypothesis which proposes that intragranular calcium is a significant variable in regulated secretion.

Localization of salivary proteins in granules of human parotid and submandibular acinar cells

Electron microscopic immunocytochemistry was used to investigate the distribution of four secretory proteins within the granules of human parotid and submandibular gland acinar cells. The results demonstrate that the distribution of the individual proteins differs significantly. Amylase is concentrated within the electron-dense regions of the granules, whereas agglutinin is present mainly in the regions of lower density. In contrast, the proline-rich proteins and histatins are distributed throughout the content of the granules and do not appear to be concentrated in either the high- or low-density regions. The results also suggest that different mechanisms, such as self-aggregation or ionic complexes with metal ions and charged macromolecules, may be involved in the packaging of individual proteins within the same granule. Further, they also show that among the salivary glands of various species, the intragranular distribution of similar proteins (e.g., amylase and proline-rich proteins) may differ.

GP-2/THP gene family encodes self-binding glycosylphosphatidylinositol-anchored proteins in apical secretory compartments of pancreas and kidney

A family of homologous genes is shown to encode GP-2, the major glycosylphosphatidylinositol (GPI)-linked glycoprotein of pancreatic zymogen granule membranes, and Tamm-Horsfall protein (THP), a GPI-linked glycoprotein associated with apical vesicles in kidney thick ascending limb of Henle (TALH) cells. The C-terminal regions of GP-2 (Asp54-Phe530) and THP (Asp175-His644) from rat show 53% identity, 86% similarity, and 26 conserved cysteine residues including one epidermal growth factor motif. The unique N-terminal domain of rat THP (unique-THP, Pro29-Gln174) shows four conserved epidermal growth factor motifs, three in tandem and one in reverse orientation. GP-2 homologues are observed in a wide variety of epithelial cells, several of which contain highly regulated secretory processes. GP-2 released from zymogen granule membranes with phosphatidylinositol phospholipase C reacts with anti-cross-reactive determinant antibody (anti-CRD), confirming the GPI nature of the pancreatic homologue. In contrast, GP-2 and THP, released endogenously from pancreas and kidney, respectively, do not react with anti-cross-reactive determinant antibody, suggesting alternative enzymatic mechanisms for their physiological release. Globular domains of GP-2 and THP, but not albumin, show pH- and ion-dependent self-association in vitro. The GP-2/THP family appears to represent a newly discovered class of GPI-anchored proteins, which may utilize pH- and ion-dependent self-association mechanisms for establishing membrane (micro)domains targeted to intracellular secretory compartments.

The calcium content of cortical granules and the loss of calcium from sea urchin eggs at fertilization

In many species, fertilization triggers a wave of cortical granule exocytosis in the egg that is the consequence of an increase in intracellular free calcium concentration. We have measured the total calcium content of cortical granules from two species of sea urchins by quantitative X-ray microanalysis and spectrometric measurements. Our results show that cortical granules: (1) contain a high concentration of total calcium (around 30 and 95 mM for Paracentrotus lividus and Arbacia lixula, respectively), (2) represent a major cortical storage site of calcium in the egg (5 and 11% of total egg calcium for P. lividus and A. lixula, respectively), and (3) exchange part of their accumulated calcium by an ATP dependent mechanism. In addition we have confirmed that at fertilization, sea urchin eggs lose a sizeable amount of their calcium (7% for P. lividus and 15% for A. lixula). The kinetics and magnitude of the loss suggest that some of this calcium could be provided by cortical granules during exocytosis.

Differential distribution of salivary agglutinin and amylase in the Golgi apparatus and secretory granules of human salivary gland acinar cells

The secretory granules of salivary glands often display complex internal substructures, yet little is known of the molecular organization of their contents or the mechanisms involved in packaging of the secretory proteins. We used post-embedding immunogold labeling with antibodies to two secretory proteins, agglutinin and alpha-amylase, to determine their distribution in the Golgi apparatus and secretory granules of the human submandibular gland acinar cells. With monoclonal antibodies specific for carbohydrate epitopes of the agglutinin, reactivity was found in the trans Golgi saccules, trans Golgi network, and immature and mature secretory granules. In the granules, labeling was seen in regions of low and medium electron density, but not in the dense cores. Reactivity seen on the apical and basolateral membranes of acinar and duct cells was attributed to a shared epitope on a membrane glycoprotein. Labeling with a polyclonal antibody to amylase was found in the Golgi saccules, immature and mature secretory granules, but not in the trans Golgi network. In the granules, amylase was present in the dense cores and in areas of medium density, but not in the regions of low density. These results indicate that these two proteins are distributed differently within the secretory granules, and suggest that they follow separate pathways between the Golgi apparatus and forming secretory granules. Small vesicles and tubular structures that labeled only with the antibodies to the agglutinin were observed on both faces of the Golgi apparatus and in the vicinity of the cell membrane. These structures may represent constitutive secretion vesicles involved in transport of the putative membrane glycoprotein to the cell membrane.

Elemental composition of pyroantimonate precipitates analysed by electron spectroscopic imaging (ESI) and electron energy-loss spectroscopy (EELS) in vitellogenic ovarian follicles of Drosophila

Ca2+ was precipitated with potassium antimonate in vitellogenic follicles of the fruit fly Drosophila melanogaster and the distribution of the precipitates formed was studied by electron microscopy. The microvilli of the oolemma in mid- and late vitellogenic follicles were lined with precipitates. The chemical composition of the precipitates was analysed by electron spectroscopic imaging (ESI). The images produced by inelastically scattered electrons at specific ionization edges were compared, and the non-specific background signals were subtracted by an image processing system. The presence of Ca2+, antimony and oxygen in the precipitates formed could be demonstrated. The elemental composition of the precipitates and of yolk spheres was also analysed by electron energy-loss spectroscopy (EELS). With respect to the precipitates, signals at the calcium L2,3-edge, the oxygen K-edge and the antimony M4,5-edge were recorded without deconvolution and background subtraction. The yolk spheres, which were free of precipitates, gave the characteristic signal of the nitrogen K-edge. The applied techniques combine good ultrastructural resolution with the possibility of analysing the elemental composition of histochemical reaction products and cellular structures.

Cerulein-induced acute pancreatitis in rats: evidence for reduced calcium affinity of secretory granule membranes

Membranes of secretory granules in pancreatic acinar cells seem to be interrelated in the regulation of intragranule Ca2+ concentrations. Since low intragranule Ca2+ levels are involved in zymogen stabilization versus autoactivation of proteases, a disturbance of the Ca2(+)-regulating system in secretory granules could be invoked to account for uncontrolled proenzyme activation. This is proposed as the initial mechanism in the pathogenesis of acute pancreatitis. Using pancreatic subcellular fractions obtained from control rats and after induction of acute cerulein pancreatitis we found a markedly reduced Ca2+ affinity of membranes from the secretory granule fraction in pancreatitis. The strong Ca2+ binding of control zymogen granule membranes primarily seemed to be a function of non-proteinacous membrane components, e.g. phosphatidylinositols. It is suggested, that part of the inner surface of membranes from secretory granules acts as a calcium-buffering system that works in synergy with other protective mechanisms to stabilize the zymogen granule population. In cerulein pancreatitis there seemed to be an imbalance of this system.

Ultrastructural localization of Ca2(+)-binding sites in the middle ear mucosa of the rat

Cations were precipitated with potassium-pyroantimonate in the middle ear mucosa of the rat and the distribution of the formed precipitates was studied by electron microscopy. The precipitate density in various cells of the different epithelia of the middle ear mucosa was determined on electron micrographs by counting the number of precipitates per unit area. Electron spectroscopic imaging was also performed to obtain information about the spatial distribution of the precipitates and their elemental composition.

Caerulein-induced acute pancreatitis in rats: changes in glycoprotein-composition of subcellular membrane systems in acinar cells

Caerulein-induced acute pancreatitis is characterized by the occurrence of two membrane-bound vacuolar systems in acinar cells. Beside digestive enzymes containing secretory vacuoles, lysosomal autophagic structures can be identified at the ultrastructural level. In the present study glycoconjugate patterns of the surrounding membranes were characterized by ultrastructural lectin-binding experiments using five colloidal-gold labeled lectins with distinct sugar specificities. Furthermore, the profile of membrane glycoproteins of isolated vacuolar fractions was studied by SDS-PAGE and lectin-blotting. In pancreatitis, membranes of secretory vacuoles showed a significant lower degree of lectin-binding compared to normal zymogen granules. In contrast, newly appearing autophagic vacuoles in pancreatitis revealed a strong membrane labelling for most lectins used. The pattern of membrane glycoproteins of secretory and autophagic vacuoles as determined by SDS-PAGE and lectin-blotting differed from those of normal zymogen granules resembling the protein profile of smooth microsomes. Since this pattern requires a previous passage through Golgi stacks, it is assumed that the two types of vacuoles derive from Golgi elements. For the pathogenesis of caerulein pancreatitis these vacuolar post-Golgi structures seem to play an important role.

Ion permeation and rectification in ATP-sensitive channels from insulin-secreting cells (RINm5F): effects of K+, Na+ and Mg2+

Patch-clamp techniques were used to study the permeability to ions of an ATP-sensitive channel in membranes from the pancreatic B-cell line (RINm5F). With patches in the outside-out configuration, the I-V curves for different Na+-K+ mixtures in the bath and 140 mM K+ in the pipette were almost linear, and crossed the zero-current axis at voltages that indicated a variable permeability ratio. When K+ was added symmetrically, the plot of the conductance vs. K+ activity exhibited saturation, with a Gmax of about 160 pS and a half-maximal activity of 216 mM. The I-V behavior for different K+-Na+ mixtures in the bath could be accurately described with a model based on Eyring theory, assuming two sites and one-ion occupancy. For K+, the dissociation constants (KK) of the two sites were 290 and 850 mM, the lower value pertaining to the site close to the intracellular medium. In experiments with inside-out patches, both Na+ and Mg2+, when present in the bath, induced a voltage-dependent block of the outward current. Fitting the data with the model suggested that for these ions only one of the two sites binds significantly, the corresponding dissociation constants being (mM): 46 for Na+ and 34 for Mg2+. Blocking by Na+ and Mg2+ may account for the low outward current seen in intact cells. This hypothesis is consistent with the observation that such current is further reduced by addition of 2,4-DNP, since metabolism inhibitors are expected to lower the ATP level, thereby liberating Mg2+ from the Mg2+-ATP complex, as well as inducing accumulation of Na+ by decreasing the rate of the Na+-K+ pump.

Histochemical and elemental localization of calcium in the granular cell subapical granules of the amphibian urinary bladder epithelium

The ultrahistochemical analysis of apical granules in the epithelial cells, i.e., granular cells, of the amphibian urinary bladder using the N,N-naphthaloylhydroxylamine procedure identified the presence of calcium in these structures. Subsequent analytical microscopy employing fresh-frozen ultrathin cryosections for X-ray microanalysis of the granules further confirmed the above histochemical findings. In addition to calcium, elemental analysis indicated the presence of magnesium, phosphorus, sulfur, silicon, potassium, and chlorine either within or in close proximity to the granules. The possibility that these granules function as subcellular compartments for the uptake and storage of calcium ions, in a way similar to mitochondria, and thus function in intracellular calcium homeostasis, is discussed. Additionally, a role for this cation in the secretion of granular glycoproteins, i.e., stimulus-secretion coupling, is hypothesized.

Distribution of calcium and potassium in presynaptic nerve terminals from cerebellar cortex

The elemental composition of the presynaptic nerve terminals in rapidly frozen synapses of the cerebellar molecular layer was determined by electron probe x-ray microanalysis and elemental imaging of characteristic x-rays. Elemental imaging of thin freeze-dried cryosections from fresh cerebellar slices frozen within 20 sec of removal from the brain showed normal concentrations of potassium (95 +/- 6 mmol/liter wet tissue +/- SEM) and calcium (0.8 +/- 0.4 mmol/liter) in whole presynaptic terminals, even though mitochondrial and nonmitochondrial sites containing up to 30 mmol of calcium per liter were present elsewhere in the neuropil. Quantitative electron probe analysis of synaptic vesicle clusters and intraterminal mitochondria indicated that their calcium concentrations were 0.4 +/- 0.1 and 1.2 +/- 0.2 mmol/liter, respectively. The low calcium content of presynaptic organelles was confirmed by the absence of detectable deposits in preparations freeze-substituted so as to stabilize calcium content. Similar experiments were carried out on cerebellar slices rapidly frozen after incubation in vitro. The distribution of potassium and calcium in presynaptic terminals of resting and depolarized (55 mM potassium) slices was qualitatively and quantitatively similar to that in freshly excised cortex, although resting slices lacked the few calcium-rich sites that appeared in other areas of the neuropil after stimulation. The calcium concentrations in whole terminals, synaptic vesicles, and mitochondria of resting slices were 1.4 +/- 0.7, 0.7 +/- 0.2, and 0.9 +/- 0.2 mmol/liter, respectively. Thus, amounts of calcium typical of storage organelles in other tissues are not present within cerebellar synaptic vesicles, suggesting that they have a limited role in calcium storage and release.

Stimulus-secretion coupling in the developing exocrine pancreas: secretory responsiveness to cholecystokinin

We have studied the onset of secretory responsiveness to cholecystokinin (CCK) during development of the rat exocrine pancreas. Although acinar cells of the fetal pancreas (1 d before birth) are filled with zymogen granules containing the secretory protein, alpha-amylase, the rate of amylase secretion from pancreatic lobules incubated in vitro was not increased in response to CCK. In contrast, the rate of CCK-stimulated amylase discharge from the neonatal pancreas (1 d after birth) was increased four- to eightfold above that of the fetal gland. The postnatal amplification of secretory responsiveness was not associated with an increase in the number or cell surface expression of 125I-CCK binding sites. When 125I-CCK-33 binding proteins were analyzed by affinity crosslinking, two proteins of Mr 210,000 and 100,000-160,000 were labeled specifically in both fetal and neonatal pancreas. To determine if cell surface receptors for CCK in the fetal pancreas are functional and able to generate a rise in the cytosolic [Ca++], we measured 45Ca++ efflux from tracer-loaded lobules. 45Ca++ efflux from both fetal and neonatal pancreas was comparably increased by CCK, indicating CCK-induced Ca++ mobilization and elevated cytosolic [Ca++]. The Ca++ ionophore A23187 also stimulated the rate of 45Ca++ extrusion from pancreas of both ages. Increased amylase secretion occurred concurrently with A23187-stimulated 45Ca++ efflux in neonatal pancreas, but not in the fetal gland. A23187 in combination with dibutyryl cAMP potentiated amylase release from the neonatal gland, but not from fetal pancreas. Similarly, the protein kinase C activator, phorbol dibutyrate, did not increase the rate of secretion from the fetal gland when added alone or in combination with A23187 or CCK. We suggest that CCK-receptor interaction in the fetal pancreas triggers intracellular Ca++ mobilization. However, one or more signal transduction events distal to Ca++ mobilization have not yet matured. The onset of secretory response to CCK that occurs postnatally may depend on amplification of these transduction events.

VIP regulation of a human pancreatic cancer cell line: Capan-1

VIP and secretin control the secretory function of the normal pancreas. We analysed their regulatory functions in a human pancreatic cancer cell line: Capan-1. Saturation binding experiments with 125I-VIP showed the existence of one class of binding sites of very high affinity: KD 6.4 +/- 3.0 X 10(-11) M and a low Bmax: 12 fmoles/10(6) cells, in both intact cells and membrane preparations. This site has not yet been described in normal or tumorous digestive cells. Competition binding experiments let us characterize two more binding sites, KD: 2.1 +/- 0.7 X 10(-9) M and 5.0 +/- 0.6 X 10(-8) M and the corresponding Bmax: 120 and 500 fmoles/10(6) cells. These sites are similar to those found on cells of the digestive tract. Competition binding experiments gave the following IC50: 3.0 +/- 0.9 X 10(-9) M for VIP; 2 +/- 0.6 X 10(-6) M for PHI; and 1 +/- 0.7 X 10(-5) M for secretin. VIP elicited a cAMP rise, the half maximal response being obtained at 1.2 X 10(-10) M. Secretin induced a cAMP response but only for concentrations higher than 10(-8) M. VIP receptors were found to be modulated by two factors: cell ageing and cell density. Cells chronically treated with VIP showed a slight decrease of their proliferation; insulin exerted an opposite effect. It is concluded that at the difference of normal pancreatic cells, the present cell line lacks secretin-preferring receptors and acquires some of the properties of intestinal cells.

X-ray microanalysis of resting and stimulated rat pancreas

The elemental distribution in acinar cells of rat pancreas was investigated by X-ray microanalysis of thin, freeze-dried cryosections. In the resting cell, the highest calcium concentrations were found in the basal part of the cell (including the endoplasmic reticulum) and in the zymogen granules. Mitochondrial calcium concentrations were low. Zymogen granules were rich in sulphur, but low in phosphorus, sodium and potassium. Stimulation of the pancreas by perfusion in vivo with the cholinergic agonist carbachol caused a significant decrease of the calcium concentration in the basal part of the cell and an increase in the calcium concentration in the apical part of the cell. The mitochondrial calcium concentration was not significantly altered. In addition, increased sodium and decreased potassium concentrations, giving rise to a significant increase in Na/K ratio were observed in all cell compartments measured, except in the zymogen granules.

Hydration kinetics of exocytosed mucins in cultured secretory cells of the rabbit trachea: a new model

Experiments have been done to test the idea that mucins undergo postexocytotic swelling. Previous work led to the hypothesis that the glycoprotein network of the mucus gel is probably held together by entanglements and low energy bonds, rather than by interchain covalent bonding. Since glycoproteins and other proteins in the mucus are polyions, it was further proposed that mucus must be capable of swelling, with its swelling properties depending on the pH and ionic strength of the medium hydrating the mucus. Experiments using oestrous cervical mucus from cows as a model confirmed this prediction. Observations on tissue cultures of respiratory secretory cells reported here show that freshly secreted mucins also undergo swelling during and after exocytosis. This evidence supports the hypothesis that the rheological properties of mucus may be physiologically regulated by hydration via control of the transepithelial movement of water, ions and soluble proteins, rather than by variations in the degree of covalent cross-linking between glycoprotein chains as proposed earlier.

Concentration of amylase along its secretory pathway in the pancreatic acinar cell as revealed by high resolution immunocytochemistry

The modified protein A-gold immunocytochemical technique was applied to the localization of amylase in rat pancreatic acinar cells. Due to the good ultrastructural preservation of the cellular organelles obtained on glutaraldehyde-fixed, osmium tetroxide-postfixed tissue, the labelling was detected with high resolution over the cisternae of the rough endoplasmic reticulum (RER), the Golgi apparatus, the condensing vacuoles, the immature 'pre-zymogen' granules, and the mature zymogen granules. Over the Golgi area, the labelling was present over the transitional elements of the endoplasmic reticulum, some of the smooth vesicular structures at the cis- and trans-faces and all the different Golgi cisternae. The acid phosphatase-positive rigid trans-cisternae as well as the coated vesicles were either negative or weakly labelled. Quantitative evaluations of the degree of labelling demonstrated an increasing intensity which progresses from the RER, through the Golgi, to the zymogen granules and have identified the sites where protein concentration occurs. The results obtained have thus demonstrated that amylase is processed through the conventional RER-Golgi-granule secretory pathway in the pancreatic acinar cells. In addition a concomitance has been found between some sites where protein concentration occurs: the trans-most Golgi cisternae, the condensing vacuoles, the pre- and the mature zymogen granules, and the presence of actin at the level of the limiting membranes of these same organelles as reported previously (Bendayan, 1983). This suggests that beside their possible role in transport and release of secretory products, contractile proteins may also be involved in the process of protein concentration.

Calcium pathway through a mineralizing epithelium in the crustacean Orchestia in pre-molt: ultrastructural cytochemistry and X-ray microanalysis

During the pre-exuvial period of the terrestrial crustacean Orchestia, the calcium of the old cuticle is almost entirely reabsorbed and stored as calcareous concretions in the lumen of the midgut posterior caeca. The elaboration of these concretions is due to transport by the caecal epithelium. With ultrastructural cytochemistry controlled by X-ray microanalysis, it can be demonstrated that the main sites of ionized or ionizable calcium are the apical microvilli and an extracellular (lateral and basal) network of channels. Direct precipitating cytochemical methods, using potassium pyroantimonate or pyrophosphate, potassium oxalate or oxalic acid, sodium fluoride, sodium tungstate, and indirect substitution methods, using lead acetate or nitrate and cobalt nitrate were comparatively used. The results are interpreted in favour of the hypothesis of an extracellular transport pathway for calcium through the lateral smooth septate junctions, in conjunction with a more classical apical transport through the microvilli.

Calcium movements and intracellular calcium distribution in neoplastic GH3 cells

Experiments were carried out to investigate the nature of the calcium homeostatic mechanisms in neoplastic GH3 rat pituitary cells. GH3 cells grown and maintained in Ham's F10 culture medium contained 35 nmoles calcium/mg cell protein. When stimulated by thyrotropin releasing hormone (TRH) or elevated K+ concentrations, only the latter caused cell calcium levels to rise although both resulted in hormone release. When exposed to EGTA, the GH3 cells lost calcium. When the temperature was lowered to 4 degrees C, the cells gained calcium and when rewarmed were able to extrude the previously accumulated calcium. The increased cell calcium following cold exposure could be blocked by prior treatment with rotenone. If rotenone was added subsequent to the cold exposure, it did not block the extrusion seen upon rewarming. In the absence of glucose in the medium, the GH3 cells took up more calcium upon exposure to 4 degrees C, and upon rewarming the cells could not return to their previous low levels. There are thus significant differences in calcium homeostasis between the neoplastic GH3 cells and their normal pituitary counterparts. When intracellular calcium was localized with the potassium pyroantimonate technique, there was calcium found in/on mitochondria, membrane bound vesicles and plasma membrane. Nuclear staining was sparse, and nucleolar staining was virtually absent. Upon stimulation with TRH, there was a decrease in mitochondrial calcium along with increases in both plasma membrane and nucleolar calcium levels. Since total calcium is unchanged, this indicates a significant calcium redistribution in response to TRH. The increased nucleolar calcium may reflect a calcium dependent increase in mRNA synthesis as has been reported. Since TRH presumably acts at a surface receptor, the increased plasma membrane calcium might be functionally related to receptor activation.

A cytochemical study of the effect of cholinergic and beta-adrenergic stimulation on calcium fluxes of rat parotid gland

Parotid gland tissue from carbachol-treated and isoproterenol-treated rats was studied cytochemically by pyroantimonate precipitation and x-ray microanalysis in an effort to identify any intracellular calcium reservoirs that might be available for use in a stimulus-secretion coupling mechanism, and to determine any differences that might exist in terms of calcium utilization due to the cholinergic or beta-adrenergic receptor mechanisms. Stimulation by either secretagogue results in a reduction of mitochondrial and plasma membrane calcium, but the reduction in mitochondrial calcium deposits of carbachol-treated animals is only one-half that of the beta-adrenergic-treated animals. This could possibly suggest a greater dependency on mitochondrial calcium for beta-adrenergic stimulated animals.

Cytochemical localisation of calcium binding sites in adrenal chromaffin cells and their relation to secretion

The ultrastructural localisation of calcium in the chromaffin cells of the adrenal medulla was investigated using the pyroantimonate technique. The electron-dense precipitate resulting from processing in the presence of pyroantimonate was removed by treatment of sections with 2 mM EGTA suggesting that the pyroantimonate technique was localising calcium since this chelator shows a 1000:1 preference for Ca2+ over Mg2+. Using dissociated cells from the bovine adrenal medulla, calcium was localised in control cells and in cells stimulated with 1 mM carbamylcholine for 1, 10 and 30 min. Stimulation resulted in an increase in plasma membrane-associated calcium within 1 min. Much of this calcium was localised at sites of granule-plasma membrane interaction and was also seen at sites of coated-vesicle formation at longer periods of stimulation. Membrane-bounded vacuoles, appearing in cells stimulated for 10 or 30 min, also showed associated electron-dense precipitate. The results obtained are consistent with a role for the calcium ion as a mediator in exocytosis at the stage of granule-plasma membrane fusion.

Calmodulin stimulation of 45Ca2+ transport and protein phosphorylation in cholinergic synaptic vesicles

Cholinergic synaptic vesicles isolated from the electric organ of Torpedo californica exhibit ATP-dependent uptake of 45Ca2+ that is stimulated by exogenous calmodulin. ATP-independent uptake also occurs, but it is only weakly stimulated by calmodulin. Saturating calmodulin decreased the Michaelis constant for ATP-dependent 45Ca2+ uptake from 52 +/- 0.4 to 12 +/- 0.2 microM and increased the maximal velocity from 3.4 +/- 0.3 to 5.2 +/- 0.5 nmol/mg of protein per min. The dose-response curve for calmodulin-dependent stimulation showed a maximal increase of 3.5-fold in the uptake rate; 0.2 microM calmodulin gave half-maximal stimulation. The activity of the vesicle-associated ATPase was unaffected. Incubation of vesicles with [gamma-32P]ATP and Ca2+ resulted in phosphorylation of four polypeptides of molecular weights about 64,000, 58,000, 54,000, and 41,000 when calmodulin was added. Vesicles that were previously phosphorylated and purified exhibited 2-fold enhanced ATP-independent uptake of 45Ca2+. Cyclic AMP could not substitute for calmodulin. The calcium transport system of the cholinergic synaptic vesicle is regulated by a calcicalmodulin-dependent protein kinase that is vesicle-associated.

Amounts and distribution of intracellular magnesium and calcium in pancreatic beta-cells

beta-Cell-rich pancreatic islets were incubated for 60-120 min in the presence of 1 mM or 20 mM glucose and analysed with regard to their contents of magnesium and calcium and how these elements were distributed among subcellular fractions. The islets contained 42 mmol magnesium per kg protein with as much as 70 mmol per kg protein in the microsomal fraction. Both the total amount and intracellular distribution of magnesium remained unaffected after raising the glucose concentration of the incubation medium. The islet content of calcium was twice as high as that of magnesium, the mitochondria and secretory granules accounting for most of the calcium in the sedimentable fractions. In both organelles a substantial fraction of calcium was exchangeable as indicated from the incorporation of 45Ca during 90 min of incubation of the islets. When raising the glucose concentration to 20 mM the percentage exchange of calcium increased from 10 to 27 in the mitochondria and from 13 to 28 in the secretory granules. The glucose stimulation of 45Ca uptake was not associated with a statistically significant increase in the total amounts of calcium. However, in addition to stimulating calcium/calcium exchange, it cannot be excluded that glucose also induces a net accumulation of intracellular calcium in the beta-cells.

The effects of manganese, cobalt and calcium on amylase secretion and calcium homeostasis in rat pancreas

1. Mn(2+) evoked an atropine-resistant secretion of amylase from the isolated pancreas of the young rat. The lowest effective concentration of Mn(2+) was 10(-3)m. The response to 10(-2)m-Mn(2+) was biphasic, an initial peak being followed by a slow sustained rise in amylase output. The maximal effect of 10(-2)m-Mn(2+) was to double the basal rate of amylase secretion after 70 min incubation.2. Co(2+) (10(-2)m) also stimulated amylase secretion. The maximal rate, about three times the basal value, was attained after 20 min incubation. Atropine partially inhibited this effect.3. Ca(2+) (10(-2)m) evoked an atropine-resistant amylase secretion similar in both magnitude and time course to the sustained phase observed with 10(-2)m-Mn(2+).4. Mn(2+) (10(-4)-10(-2)m) also increased the rate of (45)Ca efflux from the gland. Maximal efflux rates were attained after 30 min incubation and thereafter declined to basal values. A small increase was also observed with 10(-2)m-Co(2+), but not with 10(-2)m-Ca(2+). The effect of Co(2+) was almost completely abolished by atropine.5. Reducing the extracellular Ca(2+) concentration from 2.5 x 10(-3) to 10(-5)m did not reduce amylase secretion in response to 10(-2)m-Mn(2+), but secretion was abolished in a Ca(2+)-free medium containing EGTA. The increase in (45)Ca efflux rate evoked by Mn(2+) was inversely related to the extracellular Ca(2+) concentration.6. Mn(2+) (10(-2)m) increased the concentration of cyclic 3',5'-guanosine monophosphate (cyclic GMP) within the pancreas. Also, Mn(2+) accumulated within the cellular pool of the gland. The time course of both these effects was similar to the time course of (45)Ca efflux.7. Mn(2+) displaced Ca(2+) bound to isolated pancreatic microsomal membranes. The cation-binding sites on these membranes probably have a higher affinity for Mn(2+) than Ca(2+).8. We conclude that Mn(2+) stimulates enzyme secretion by displacing membrane-bound Ca(2+), the resulting increase in cytosolic Ca(2+) concentration activating the secretory mechanism.9. Mn(2+) partially inhibited amylase secretion stimulated by optimal doses of either acetylcholine (ACh) or caerulein. Maximal inhibition (about 60%) occurred with 10(-3)m-Mn(2+) (i.e. the lowest concentration required to stimulate secretion in the absence of secretagogues). Decreasing the extracellular Ca(2+) concentration reduced the inhibitory effect of Mn(2+).10. When glands were exposed to ACh and Mn(2+) simultaneously, the time required for inhibitory effects to develop was inversely related to the dose of ACh and the concentration of Mn(2+).11. Mn(2+) did not alter the acceleration of (45)Ca efflux evoked by ACh or by caerulein in a medium containing 2.5 x 10(-3)m-Ca(2+). However, under conditions of Ca(2+) deprivation ACh-stimulated (45)Ca efflux was greatly enhanced.12. Mn(2+) reduced the total amount of Ca(2+) accumulated into the cellular pool of the pancreas after 60 min incubation, but had no effect on the initial, rapid phase of Ca(2+) uptake.13. The effects of Mn(2+) on the relationship between ACh dose, amylase release and the extracellular Ca(2+) concentration suggest that the inhibitory actions of Mn(2+) cannot be explained by a simple, competitive interaction with the stimulant or with extracellular Ca(2+). However, the time course of inhibition is consistent with a requirement for Mn(2+) to accumulate within the acinar cells.14. Mn(2+) partially inhibited amylase secretion stimulated by hyperosmolarity and also increased the (45)Ca efflux rate under these conditions.15. Our results are not consistent with Mn(2+) exerting its inhibitory effect on secretagogue-stimulated enzyme secretion solely by blocking Ca(2+) influx from the extracellular space. We conclude that inhibition probably depends on the ability of Mn(2+) to displace Ca(2+) from binding sites involved in secretion, presumably coupled with a reduced ability of Mn(2+) to replace Ca(2+) in the secretory process.

Transport of Ca2+ and Na+ across the chromaffin-granule membrane

Bovine chromaffin-granule ghosts accumulate 45Ca2+ in a temperature- and osmotic-shock-sensitive process; the uptake is saturable, with Km 38 microM and Vmax. 28 nmol/min per mg at 37 degrees C. Entry occurs by exchange with Ca2+ bound to the inner surface of the membrane. It is inhibited non-competitively by Na+, La3+ and Ruthenium Red (Ki 10.7 mM, 7 microM and 2 microM respectively), and competitively by Mg2+ (ki 0.9 mM). Uptake was not stimulated by ATP. Na+ induces Ca2+ efflux; Ca2+ can re-enter the ghosts by a process of Ca2+/Na+ exchange. La3+ inhibits Ca2+ efflux during Ca2+-exchange, and Ca2+ efflux induced by Na+, suggesting that Ca2+ uptake and efflux, and Ca2+/Na+ exchange, are catalysed by the same protein. Na+ enters ghosts during CA2+ efflux, but the kinetics of its entry are not exactly similar to the kinetics of Ca2+ efflux. Initially 1-2 Na+ enter per Ca2+ lost, but at equilibrium 3-4 Na+ have replaced each Ca2+. There is no evidence that either Ca2+ uptake or efflux by Ca2+/Na+ exchange is electrogenic, suggesting that the stoichiometry of exchange is Ca2+/2Na+. This exchange reaction may have a role in depleting cytoplasmic Ca2+ after depolarization-induced Ca2+ entry through the adrenal medulla plasma membrane; there is some evidence that there may be an additional entry mechanism for Na+ across the granule membrane.

Secretory protein decondensation as a distinct, Ca2+-mediated event during the final steps of exocytosis in Paramecium cells

The contents of secretory vesicles ("trichocysts") were isolated in the condensed state from Paramecium cells. It is well known that the majority portion of trichocysts perform a rapid decondensation process during exocytosis, which is visible in the light microscope. We have analyzed this condensed leads to decondensed transition in vitro and determined some relevant parameters. In the condensed state, free phosphate (and possibly magnesium) ions screen local surplus charges. This is supported by x-ray spectra recorded from individual trichocysts (prepared by physical methods) in a scanning transmission electron microscope. Calcium, as well as other ions that eliminate phosphate by precipitation, produces decondensation in vitro. Under in vivo conditions, Ca2+ enters the vesicle lumen from the outside medium, once an exocytic opening has been formed. Consequently, within the intact cell, membrane fusion and protein decondensation take place with optimal timing. Ca2+ might then trigger decondensation in the same way by precipitating phosphate ions (as it does in vitro) and, indeed, such precipitates (again yielding Ca and P signals in x-ray spectra) can be recognized in situ under trigger conditions. As decondensation is a unidirectional, rapid process in Paramecium cells, it would contribute to drive the discharge of the secretory contents to the outside. Further implications on the energetics of exocytosis are discussed.

Subcellular distribution of calcium in zona fasciculata cells of the rat adrenal cortex

Zona fasciculata cells from the adrenal cortex of female Sprague-Dawley rats were fixed by immersion in potassium pyroantimonate-osmium tetroxide and potassium pyroantimonate-glutaraldehyde to study the distribution of calcium. Potassium pyroantimonate-osmium tetroxide treatment gave reproducible patterns of electron-opaque precipitate, whereas inconsistent deposits of reaction product were seen after potassium pyroantimonate-glutaraldehyde fixation. Nuclei showed sparse precipitate over heterochromatin and dense aggregates over areas of nucleoli surrounded by portions of the nucleolar-dense component. Two major cytoplasmic sites of precipitate were identified: mitochondria and vesicles of smooth endoplasmic reticulum. Most of the intramitochondrial precipitate was localized to the intracristal space. Precipitate was also seen in vesicles of Golgi apparatus. The extracellular space was filled with closely packed electron-opaque particles. Observation of tissues treated with control fixative saturated with EGTA showed little if any reaction, confirming that calcium was the primary cation precipitated by potassium pyroantimonate. Our results provide a method suitable for accurate localization of calcium in adrenocortical cells.

Calcium and the secretory cycle of prolactin cells: a cytochemical and ultrastructural study of dopamine inhibition and monobutyryl cyclic AMP-stimulation of prolactin secretion

To identify intracellular calcium pools that may be involved in the secretory process in prolactin (PRL) cells, hemi pituitaries were incubated in medium containing 10(-6) M dopamine, 5 mM cyclic cAMP (experimentals), or in medium alone (controls) and then processed for electron microscopy using potassium pyroantimonate to localize intracellular calcium. PRL in the medium was measured by radioimmunoassay. The concentration of antimonate associated with mitochondria, Golgi saccules, and secretory granules was estimated. Dopamine inhibition of PRL secretion (> 80% at 1, 2, 3 h) resulted in accumulation of secretory granules in all stages of maturation and dilation of Golgi saccules at 2 and 3 h, accompanied by increased mitochondria antimonate and increased Golgi-associated antimonate. Cyclic AMP stimulation of secretion (635% at 5 min., declining to 34% at 1 h) resulted in marked exocytosis at 5 and 15 min., declining after 30 min. Mitochondrial antimonate decreased after 30 min. Stimulated cells exhibited numerous coated membrane structures at or near exocytotic pits and an amassing of microvesicles at the margin of the Golgi apparatus. Although some secretory granules consistently exhibited reactivity to antimonate (unchanged by inhibition or stimulation), plasma membrane, and granule membrane translocated to the plasma membrane during exocytosis, were not reactive.

Sodium and calcium localization in cells and tissues by precipitation with antimonate: a quantitative study

Komnick's antimonate technique, which was devised to localize Na+ in cells and tissues, was studied quantitatively. Some modifications, as well as its application to Ca2+ localization, were also investigated. We combined measurements of Na+ and Ca2+ retention in plant roots during the various procedures, electron microscopy, autoradiography, and semiquantitative X-ray microanalysis. We were able to show that (at least in barley roots) antimonate does not precipitate at all with Na+, irrespective of the Na+ content of the tissue or the method of antimonate application. (Even during precipitative freeze dissolution or after freeze drying, no Na+ is precipitated.) By means of Komnick's antimonate technique Ca2+ is trapped within the tissue, but only after serious dislocation. Perspectives for reliable localization of diffusible ions in cells and tissues, by precipitation simultaneously with conventional fixations, are bad.