Recycling of transferrin receptors and heparan sulfate proteoglycans in a rat parathyroid cell line.

We examined recycling of heparan sulfate (HS) proteoglycans and transferrin receptor (Tf-R) in a rat parathyroid cell line. While extracellular Ca2+ concentration ([Ca2+]e) regulates the recycling of HS proteoglycans in parathyroid cells, such that HS proteoglycans only recycle when [Ca2+]e is lowered below physiological levels, recycling of Tf-R occurs equally well both in 0.05 mM (low) and 2 mM (high) [Ca2+]e. Inhibiting endocytosis chemically with phenylarsine oxide or at low temperature (4 degrees C) did not abolish the effects of changing [Ca2+]e on HS proteoglycans in the recycling compartment even though transport of HS proteoglycans from the Golgi complex to the cell surface was inhibited in low [Ca2+]e. Microtubules are not involved in the recycling of HS proteoglycans or of Tf-R since nocodazole did not affect these processes. Inhibiting the increase of intracellular Ca2+ by an intracellular Ca2+ chelator sustained recycling of HS proteoglycans even in the presence of high [Ca2+]e. These observations show that the exocytosis pathway of HS proteoglycans in the recycling compartment is specifically regulated by [Ca2+]e, whereas that for constitutive secretion is not. Therefore, the recycling of HS proteoglycans may be directly related to some functions of parathyroid cells regulated by [Ca2+]e. Although the mechanism by which [Ca2+]e regulates the exocytosis and recycling of HS proteoglycans is uncertain, it is suggested that an increase of intracellular Ca2+ is necessary, but not necessarily sufficient, for inhibiting their exocytosis.     

Effects of MgCl2 on the release and recycling of heparan sulfate proteoglycans in a rat parathyroid cell line.

Divalent cations, such as Mg2+, Ba2+, and Co2+, are known to mimic the effects of Ca2+ in parathyroid cells, but it is not clear whether the mechanism of their action is the same as that of Ca2+. We have shown that extracellular Ca2+ concentration ([Ca2+]e) regulates the distribution and recycling of cell-surface heparan sulfate (HS) proteoglycans in a rat parathyroid cell line; at normal to high [Ca2+]e (e.g., 2 mM) HS proteoglycans are primarily localized intracellularly, while at low [Ca2+]e (0.05 mM) they are translocated to the cell surface and rapidly recycle (Takeuchi, Y., Sakaguchi, K., Yanagishita, M., Aurbach, G. D., and Hascall, V. C., 1990, J. Biol. Chem. 265, 13661-13668). We now show that a high concentration of Mg2+ (8 mM) reduces the amount of recycling HS proteoglycans in low [Ca2+]e. However, the primary effects of high Ca2+ and high Mg2+ on the recycling HS proteoglycans are different. High [Ca2+]e causes translocation of HS proteoglycans to intracellular compartments, while high Mg2+ stimulates cleavage of their core proteins and subsequent shedding of HS proteoglycans into the medium, thereby depleting the recycling molecules. However, high Mg2+ does not induce shedding of HS proteoglycans in high [Ca2+]e. The effects of Ba2+ and Co2+ were similar to those of Mg2+, but Sr2+ showed no significant effects on HS proteoglycan translocation. Otherwise, 8 mM Mg2+ did not alter biosynthesis or intracellular catabolism of HS proteoglycans. These observations suggest that the recycling of HS proteoglycans in parathyroid cells is sensitive only to [Ca2+]e, whereas several other divalent cations can deplete the recycling HS proteoglycans by a distinctly different mechanism. Thus, the mechanism by which Ca2+ regulates the amounts of the recycling HS proteoglycans may be more physiological and play a functional role in parathyroid cells.     

Metabolic pathways of heparan sulfate proteoglycans in a rat parathyroid cell line.

The distribution of heparan sulfate (HS) proteoglycans in clonal rat parathyroid cells is regulated by the extracellular Ca2+ concentration, which is a principal factor for parathyroid cell function (Takeuchi, Y., Sakaguchi, K., Yanagishita, M., Aurbach, G. D., and Hascall, V. C. (1990) J. Biol. Chem. 265, 13661-13668). Increasing the concentration of extracellular Ca2+ in the physiological range redistributes HS proteoglycans from the cell surface to an intracellular compartment. We have now examined effects of the extracellular Ca2+ concentration on the metabolism of the HS proteoglycans in detail using [35S]sulfate metabolic labeling-chase experiments. Two distinct metabolic pathways were demonstrated: (i) the intracellular generation of HS chains from HS proteoglycans in prelysosomal compartments followed by their release into the medium (pathway 1), and (ii) intracellular generation of HS oligosaccharides from HS chains in prelysosomal compartments, which are eventually degraded into free sulfate in lysosomes (pathway 2). The HS oligosaccharides were exclusively present within the cells, whereas HS chains were found primarily in the medium. The cells do not internalize either HS proteoglycans or HS chains from the medium. These observations indicate that these two degradation pathways are independent. In addition to these pathways, approximately 15% of the HS proteoglycans were released into the medium as a proteoglycan form. Treatment of cells with chloroquine, a lysosomotropic agent, did not affect generation of HS chains but inhibited conversion of HS chains to HS oligosaccharides or to free sulfate and resulted in the release of HS chains from the cells. The drug did not affect metabolic pathway 1. The extracellular Ca2+ concentration did not alter these intracellular degradation pathways for HS proteoglycans in the parathyroid cells. Thus, extracellular Ca2+ appears to regulate only the distribution of HS proteoglycans between the cell surface and intracellular compartments, and the process of cycling between these compartments when extracellular Ca2+ is low.     

Heparan sulphate proteoglycans on rat parathyroid cells recycle in low Ca2+ medium

A rat parathyroid cell line, with some differentiated properties of the parathyroid gland, synthesizes predominantly a heparan sulphate proteoglycan (HS-PG) typical of cell surface HS-PGs (core protein = approximately 70 kDa, three to four HS chains of approximately 30 kDa). A 10 min pulse-chase protocol was used to determine the metabolic fate of the HS-PGs for cells maintained in 2.1 mM-Ca2+ (high Ca) or in 0.05 mM-Ca2+ (low Ca). In low Ca, approximately 60% of the labelled HS-PGs reach the cell surface (t1/2 = approximately 15 min) as determined by trypsin accessibility. This population of HS-PGs recycles (t1/2 = approximately 9 min) between the cell surface and an intracellular (presumably endosome) compartment. After approximately 2 h, this population of HS-PGs is internalized and rapidly degraded in lysosomes. In high Ca, only approximately 10% of the HS-PGs reach the cell surface, where they do not recycle. Changing from high to low Ca any time between 30-120 min of chase, rapidly (t1/2 less than 4 min) redistributes the HS-PGs to the cell surface where they begin recycling; conversely, changing from low to high Ca leads to a rapid sequestration of the cell surface HS-PGs within the cells. Other divalent cations fail to mimic the response to Ca2+. The results suggest that most of the HS-PGs in this cell line are anchored in a membrane compartment involved in a transport process between endosomes and the cell surface which is regulated by the concentration of extracellular Ca2+.     

Glycosylphosphatidylinositol-anchored and core protein-intercalated heparan sulfate proteoglycans in rat ovarian granulosa cells have distinct secretory, endocytotic, and intracellular degradative pathways.

Rat ovarian granulosa cells synthesize two distinct species of plasma membrane-intercalated heparan sulfate (HS) proteoglycans; glycosylphosphatidylinositol (GPI)-anchored and core protein-intercalated HS proteoglycans. Both species of HS proteoglycans are primarily localized on the plasma membrane. Cell surface localization of GPI-anchored and protein-intercalated HS proteoglycans can be determined by their accessibility to exogenously added phosphatidylinositol-specific phospholipase C (PI-PLC) and trypsin, respectively. Kinetic parameters for the processes involving their transfer from the Golgi to the cell surface, endocytosis and secretion, and the modes of intracellular degradation were determined by metabolic labeling experiments using [35S]sulfate and various chase protocols in combination with the use of PI-PLC and trypsin in rat ovarian granulosa cells. The experiments demonstrated that (i) both HS proteoglycan species are transferred from the Golgi to the cell surface with an average transit time of approximately 12 min. (ii) GPI-anchored HS proteoglycans are endocytosed with a t1/2 approximately 3 h, without being shed into the medium, and they are rapidly degraded, t1/2 approximately 25 min, without generating recognizable degradation intermediates. (iii) Protein-intercalated HS proteoglycans are partly (approximately 30%) shed from the cell surface into the medium and the remaining approximately 70% are endocytosed with a t1/2 approximately 4 h. After endocytosis, they undergo a slow (t1/2 approximately 4 h) stepwise degradation generating distinct HS oligosaccharides as degradation intermediates. These results indicate that the GPI-anchored and the protein-intercalated HS proteoglycans have distinct secretory, endocytotic, and intracellular degradation pathways probably due to the differences in their anchor structures.     

Metabolism of proteoglycans in rat ovarian granulosa cell culture. Multiple intracellular degradative pathways and the effect of chloroquine

The metabolism of endogenously labeled proteoglycans was studied in rat ovarian granulosa cell cultures by a series of pulse-chase experiments using [35S]sulfate as a precursor. More than 90% of the newly synthesized proteoglycans are transported to the cell surface (trypsin-accessible compartment) with a median transit time of 13 min. The membrane-bound heparan sulfate-proteoglycan (HS-PG) is lost from the cell surface either by release into the medium (30%, with t1/2 of 4 h) or by internalization (70%, with t1/2 of 4 h). Internalized HS-PG, which does not recycle to the cell surface, is degraded by two major pathways. In pathway 1, 60% of the internalized HS-PG migrates to lysosomes with a relatively short t1/2 of 30 min, where it is rapidly degraded, releasing free [35S]sulfate without detectable intermediate products. Chloroquine treatment inhibited degradation, resulting in the accumulation of intact proteoglycans inside the cell. In pathway 2, 40% of the internalized HS-PG is first subjected to extensive proteolysis and limited endoglycosidic degradation yielding single HS chains about 1/3 of their original size (t1/2 of 30 min). Chloroquine did not inhibit this step. The partially degraded HS is then degraded further by limited endoglycosidic activity to about 1/4-1/5 the original size (t1/2 of 30-60 min). This step is inhibited by chloroquine. These smaller fragments have a relatively long t1/2 of 3-4 h before rapid degradation in the lysosomes, releasing free [35S]sulfate. Approximately 7% of the newly synthesized HS-PG that is not transported to the cell surface is degraded directly by pathway 2. The larger dermatan sulfate proteoglycan (DS-I) is transported to the cell surface from which it is quantitatively released into the medium with a t1/2 of 4-6 h. The smaller DS-PG (DS-II) is metabolized similarly to the HS-PG. Most (greater than 90%) is transported to the cell surface from which it is lost either by release into the medium (40%) or by internalization (60%). About 60% of the internalized DS-II is degraded by pathway 1 (t1/2 of 30 min), while the remainder appears to be degraded by pathway 2 with an overall t1/2 of 4 h. However, in contrast to the degradation of HS-PG by pathway 2, no endoglycosidic degradation of the DS chains occurred.     

Characterization of proteoglycans synthesized by a rat parathyroid cell line

The structure, biosynthesis, and distribution of cell-associated proteoglycans in a clonal line of parathyroid cells, which exhibit differentiated characteristics such as calcium-regulated hormone secretion and cell growth, were studied by metabolic labeling with [3H] glucosamine and [35S]sulfate as precursors. Proteoglycans were isolated by two consecutive ion exchange chromatography steps and then analyzed by gel filtration, polyacrylamide gel electrophoresis, and specific enzyme and chemical reactions. The cells synthesize almost exclusively (greater than 95%) heparan sulfate (HS) proteoglycans with a glycosaminoglycan synthesis rate of approximately 0.5 micrograms/10(6) cells/24 h. Two major HS proteoglycan species were identified. HS proteoglycan-I has a mass of approximately kDa with a single HS chain (approximately 12 kDa) and a core protein of approximately 150 kDa including oligosaccharides. HS proteoglycan-II has a mass of approximately 170 kDa with 3-4 HS chains (approximately 30 kDa) and a core protein of 70-80 kDa including oligosaccharides. In the medium with low ionized calcium (0.05 mM), HS proteoglycan-I is synthesized at approximately 1.6 times the rate and HS proteoglycan-II at a similar rate as for cells cultured in the medium with high ionized calcium (2.1 mM). The distribution of proteoglycans, examined by the accessibility of the molecules to trypsin, was dramatically influenced by environmental calcium concentration; at low calcium levels 70-80% of the HS proteoglycans are trypsin-accessible while only 20-30% are accessible at high calcium levels. This suggests that the proteoglycans are primarily on the cell surface in low calcium and in trypsin-inaccessible compartments in high calcium conditions.     

Characterization of proteoglycans synthesized by rat thyroid cells in culture and their response to thyroid-stimulating hormone

A Fisher rat thyroid cell line was maintained in culture and the cells were labeled with [3H]glucosamine, [35S]sulfate, and [35S]cysteine to examine the synthesis of proteoglycans. 3H and 35S radioactivity from these precursors were incorporated into both chondroitin sulfate (CS) and heparan sulfate (HS) proteoglycans. CS proteoglycans were almost exclusively secreted into the medium while HS proteoglycans remained mainly associated with the cell layer. Single chain glycosaminoglycans released by papain digestion or alkaline borohydride treatment of either the CS or HS proteoglycans had average molecular weights of approximately 30,000 on Sepharose CL-6B chromatography. Both CS and HS proteoglycans were relatively small and contained only one or two glycosaminoglycans chains. 3H and 35S incorporation into both CS and HS proteoglycans were increased by thyroid-stimulating hormone (TSH) in a dose-dependent manner, which is in part explained by an adenylate cyclase-dependent mechanism as indicated by a similar effect in response to dibutyryl cAMP. TSH enhanced the incorporation of 35S into CS from [35S]cysteine about 1.5-fold and that from [35S]sulfate about 2-fold. This result demonstrated that the increased 35S incorporation from the [35S]sulfate precursor reflects an actual increase in sulfate incorporation and is not simply a result from an apparent increase in specific activity of the phosphoadenosine phosphosulfate donor. Analysis of disaccharides from chondroitinase digests revealed that the proportion of non-sulfated, 4-sulfated, and 6-sulfated disaccharides was not altered appreciably by TSH. These results, together with the disproportionate increase in 3H incorporation into CS from [3H]glucosamine, indicated that TSH increased the specific activity of the 3H label as well. Chase experiments revealed that CS proteoglycans were rapidly (t1/2 = 15 min) secreted into the medium and that the degradation of cell-associated proteoglycans was enhanced by TSH.     

Acidic fibroblast growth factor autocrine system as a mediator of calcium-regulated parathyroid cell growth.

Both parathyroid hormone secretion and cell growth are negatively regulated by extracellular calcium in parathyroid cells. The mechanism of growth regulation by calcium has been unknown. Previously, we reported that clonal parathyroid cells (PT-r cells) bear two high affinity receptors for acidic fibroblast growth factor (aFGF) and that at least a subpopulation of the receptors with a higher molecular mass carries heparan sulfate (HS) glycosaminoglycan chains which give the receptor higher affinity (Sakaguchi, K., Yanagishita, M., Takeuchi, Y., and Aurbach, G. D. (1991) J. Biol. Chem. 266, 7270-7278). Here, I have found that the parathyroid cells expressed aFGF and that aFGF receptors with lower affinity apparently translocated in response to changing extracellular calcium concentrations. Expression of both aFGF mRNA and peptide was suppressed by calcium. Cells had more ligand-accessible receptors on the cell surface at lower calcium concentrations. This apparent translocation was temperature-dependent but independent of de novo protein synthesis. Heparin or HS glycosaminoglycans are a prerequisite for the FGF receptor encoded by flg gene to bind basic FGF (Yayon, A., Klagsbrun, M., Esko, J. D., Leder, P., and Ornitz, D. M. (1991) Cell 64, 841-848). In PT-r cells, major cellular HS proteoglycans redistribute between intracellular and extracellular compartments with more HS proteoglycans expressed on the cell surface at lower calcium concentrations (Takeuchi, Y., Sakaguchi, K., Yanagishita, M., Aurbach, G. D., and Hascall, V. C. (1990) J. Biol. Chem. 265, 13661-13668). However, this redistribution of HS proteoglycans cannot explain the difference in bindability of radiolabeled aFGF to its receptors in different calcium concentrations, since addition of heparin did not change the binding of radiolabeled aFGF to the receptors either at high or low calcium conditions. In concordance with the apparent translocation of aFGF receptors, thymidine incorporation was stimulated by decreasing extracellular calcium concentrations with further stimulation by added aFGF. Anti-aFGF antibody inhibited thymidine incorporation by more than 32% in the cells exposed to 0.05 mM Ca2+ shortly before adding [3H]thymidine, whereas the incorporation was not significantly affected by the antibody at 0.7 mM Ca2+. Cell growth was also stimulated by low calcium. Anti-aFGF antibody inhibited cell growth significantly only at low calcium concentrations. From these observations, an aFGF autocrine system including the apparent translocation of aFGF receptors may explain, if not entirely, the mechanism by which calcium regulates parathyroid cell growth.     

Calcium signaling in a low calcium environment: how the intracellular malaria parasite solves the problem

Malaria parasites, Plasmodia, spend most of their asexual life cycle within red blood cells, where they proliferate and mature. The erythrocyte cytoplasm has very low [Ca2+] (<100 nM), which is very different from the extracellular environment encountered by most eukaryotic cells. The absence of extracellular Ca2+ is usually incompatible with normal cell functions and survival. In the present work, we have tested the possibility that Plasmodia overcome the limitation posed by the erythrocyte intracellular environment through the maintenance of a high [Ca2+] within the parasitophorous vacuole (PV), the compartment formed during invasion and within which the parasites grow and divide. Thus, Plasmodia were allowed to invade erythrocytes in the presence of Ca2+ indicator dyes. This allowed selective loading of the Ca2+ probes within the PV. The [Ca2+] within this compartment was found to be approximately 40 microM, i.e., high enough to be compatible with a normal loading of the Plasmodia intracellular Ca2+ stores, a prerequisite for the use of a Ca2+-based signaling mechanism. We also show that reduction of extracellular [Ca2+] results in a slow depletion of the [Ca2+] within the PV. A transient drop of [Ca2+] in the PV for a period as short as 2 h affects the maturation process of the parasites within the erythrocytes, with a major reduction 48 h later in the percentage of schizonts, the form that re-invades the red blood cells.     

Effects of monensin on the synthesis, transport, and intracellular degradation of proteoglycans in rat ovarian granulosa cells in culture

Rat ovarian granulosa cells, isolated from immature female rats 48 h after stimulation with 5 IU of pregnant mare's serum gonadotropin, were maintained in culture. The effects of monensin, a monovalent cationic ionophore, on various aspects of proteoglycan metabolism were studied by metabolically labeling cultures with [35S]sulfate, [3H]glucosamine, or [3H]glucose. Monensin inhibited post-translational modification of both heparan sulfate (HS) proteoglycans and dermatan sulfate (DS) proteoglycans, resulting in decreased synthesis of completed proteoglycans [( 35S]sulfate incorporation decreased to 10% of control by 30 microM monensin, with an ED50 approximately 1 microM). Proteoglycans synthesized in the presence of monensin showed undersulfation of both DS and HS glycosaminoglycans and altered N-linked and O-linked oligosaccharides, suggesting that the processing of all sugar moieties is closely associated. Monensin caused a decrease in the endogenous sugar supply to the UDP-N-acetylhexosamine pool as indicated by an increased 3H incorporation into DS chains [( 3H]glucosamine as precursor) in spite of the decrease in glycosaminoglycan synthesis. Monensin reduced and delayed transport of both secretory and membrane-associated proteoglycans from the Golgi complex to the cell surface. It took 2-4 min for newly labeled proteoglycans to reach the main transport process inhibited by monensin. Monensin at 30 microM did not prevent internalization of cell surface 35S-labeled proteoglycans but almost completely inhibited their intracellular degradation to free [35S]sulfate (ED50 approximately 1 microM), resulting in intracellular accumulation of both DS and HS proteoglycans. Pulse-chase experiments demonstrated that one of the intracellular degradation pathways involving proteolysis of both DS and HS proteoglycans and limited endoglycosidic cleavage of HS continued to operate in the presence of monensin. These results suggest that the intracellular degradation of proteoglycans involve both acidic and nonacidic compartments with monensin inhibiting those processes that normally occur in such acidic compartments as endosomes or lysosomes by raising their pH.     

Two forms of plasma membrane-intercalated heparan sulfate proteoglycan in rat ovarian granulosa cells. Labeling of proteoglycans with a photoactivatable hydrophobic probe and effect of the membrane anchor-specific phospholipase C

The structures of cell-associated heparan sulfate (HS) proteoglycans and their interaction with the plasma membrane was studied using rat ovarian granulosa cell culture. HS proteoglycans were either metabolically labeled by incubating cell cultures with [3H] leucine and [35S]sulfate or labeled in plasma membrane preparations with a photoactivatable reagent, 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine (TID), a compound which has been shown to selectively label the hydrophobic membrane-binding domains of several proteins. After purification of HS proteoglycans from the labeled cell cultures or from the labeled membrane preparations by repeated Q-Sepharose ion exchange chromatography in 8 M urea, they were analyzed by Superose 6 gel filtration and octyl-Sepharose chromatography both in 4 M guanidine HCl. The results indicated that the HS proteoglycans were labeled with 125I and therefore have an intramembranous domain. Phospholipase C (Bacillus thuringiensis), which specifically cleaves phosphatidylinositol membrane anchors, released approximately 25% of the 35S-labeled HS proteoglycans from the cell surface as well as 20-30% of the 125I-label from the 125I-TID-labeled HS proteoglycans. These data indicate that a subpopulation of HS proteoglycans are intercalated into the plasma membrane through a linkage structure involving phosphatidylinositol. Phospholipase C-resistant, 125I-labeled HS proteoglycans represent those species inserted into membrane through an intercalated peptide sequence. Core protein size of phosphatidylinositol-anchored species estimated by polyacrylamide gel electrophoresis after heparitinase digestion was approximately 80 kDa, and it was significantly larger than that of the directly intercalated species (approximately 70 kDa).     

A dynamic pool of calcium in catecholamine storage vesicles. Exploration in living cells by a novel vesicle-targeted chromogranin A-aequorin chimeric photoprotein

Chromaffin vesicles contain very high concentration of Ca2+ (approximately 20-40 mM total), compared with approximately 100 nM in the cytosol. Aequorin, a jellyfish photoprotein with Ca(2+)-dependent luminescence, measures [Ca2+] in specific subcellular compartments wherein proteins with organelle-specific trafficking domains are fused in-frame to aequorin. Because of the presence of vesicular trafficking domain within CgA we engineered sorting of an expressed human CgA-Aequorin fusion protein (hCgA-Aeq) into the vesicle compartment as confirmed by sucrose density gradients and confocal immunofluorescent co-localization studies. hCgA-Aeq and cytoplasmic aequorin (Cyto-Aeq) luminescence displayed linear functions of [Ca2+] in vitro, over >5 log10 orders of magnitude (r > 0.99), and down to at least 10(-7) M sensitivity. Calibrating the pH dependence of hCgA-Aeq luminescence allowed estimation of [Ca2+]ves at granule interior pH (approximately 5.5). In the cytoplasm, Cyto-Aeq accurately determined [Ca2+]cyto under both basal ([Ca2+]cyto = 130 +/- 35 nM) and exocytosis-stimulated conditions, confirmed by an independent reference technique (Indo-1 fluorescence). The hCgA-Aeq chimera determined vesicular free [Ca2+]ves = 1.4 +/- 0.3 microM under basal conditions indicating that >99% of granule total Ca2+ is in a "bound" state. The basal free [Ca2+]ves/[Ca2+]cyto ratio was thus approximately 10.8-fold, indicating active, dynamic Ca2+ uptake from cytosol into the granules. Stimulation of exocytotic secretion revealed prompt, dynamic increases in both [Ca2+](ves) and [Ca2+]cyto, and an exponential relation between the two (y = 0.99 x e(1.53x), r = 0.99), reflecting a persistent [Ca2+]ves/[Ca2+]cyto gradient, even during sharp increments of both values. Studies with inhibitors of Ca2+ translocation (Ca(2+)-ATPase), Na+/Ca(+)-exchange, Na+/H(+)-exchange, and vesicle acidification (H(+)-translocating ATPase), documented a role for these four ion transporter classes in accumulation of Ca2+ inside the vesicles.     

Alpha 1-adrenoceptor activation elevates cytosolic calcium in rat pinealocytes by increasing net influx

The regulation of [Ca2+]i in rat pinealocytes was studied using the fluorescent indicator quin2. Pinealocyte resting [Ca2+]i was approximately 100 nM; this rapidly decreased in low Ca2+ medium (approximately 10 microM), indicating there was a high turnover of [Ca2+]i in these cells. Norepinephrine (NE, 10(-6) M) increased [Ca2+]i to approximately 350 nM within 1 min; [Ca2+]i then remained elevated for 30 min. The relative potency of adrenergic agonists was NE greater than phenylephrine much greater than isoproterenol. Phentolamine (10(-6) M) and prazosin (10(-8) M) blocked the effects of adrenergic agonists; in contrast, propranolol (10(-6) M) or yohimbine (10(-6) M) had little or no effect. These observations indicate NE acts via alpha 1-adrenoceptors to elevate [Ca2+]i. The [Ca2+]i response to NE did not occur when [Ca2+]e was reduced to approximately 10 microM by adding EGTA 5s before NE, indicating an increase in net Ca2+ influx is involved rather than mobilization of Ca2+ from intracellular stores. The effect of NE was not blocked by nifedipine (10(-6) M), which did block a K+-induced increase in [Ca2+]i, presumably involving voltage-sensitive channels. Ouabain (10(-5) M) caused a gradual increase in [Ca2+]i; this increase was not blocked by nifedipine. Together these data indicate that pinealocyte [Ca2+]i may be influenced by mechanisms regulated by alpha 1-adrenoceptors, voltage-dependent Ca2+ channels, and perhaps a Na+/Ca2+ exchange mechanism stimulated by ouabain. These studies indicate that the pinealocyte is an interesting model to use to study the adrenergic regulation of [Ca2+]i because of the rapid and prolonged changes in [Ca2+]i produced by alpha 1-adrenoceptor activation.     

Rapid mobilization of cellular Ca2+ in bovine parathyroid cells evoked by extracellular divalent cations. Evidence for a cell surface calcium receptor

The concentration of intracellular free Ca2+ ([Ca2+]i) was measured in dissociated bovine parathyroid cells using the fluorescent indicator quin-2 or fura-2. Small increases in the concentration of extracellular Ca2+ produced relatively slow, monophasic increases in [Ca2+]i in quin-2-loaded cells, but rapid and transient increases followed by lower, yet sustained (steady-state), [Ca2+]i increases in fura-2-loaded cells. The different patterns of change in [Ca2+]i reported by quin-2 and fura-2 appear to result from the greater intracellular Ca2+-buffering capacity present within quin-2-loaded cells, which tends to damp rapid and transient changes in [Ca2+]i. In fura-2-loaded parathyroid cells, other divalent cations (Mg2+, Sr2+, Ba2+) also evoked transient increases in [Ca2+]i, and their competitive interactions suggest that they all affect Ca2+ transients by acting on a common site. In contrast, divalent cations failed to cause increases in steady-state levels of cytosolic Ca2+. Low concentrations of La3+ (0.5-10 microM) depressed steady-state levels of cytosolic Ca2+ elicited by extracellular Ca2+ but were without effect on transient increases in [Ca2+]i elicited by extracellular Ca2+, Mg2+ or Sr2+, suggesting that increases in the steady-state [Ca2+]i arise from the influx of extracellular Ca2+. Mg2+- and Sr2+-induced cytosolic Ca2+ transients persisted in the absence of extracellular Ca2+ but were abolished by pretreatment with ionomycin. These results show that cytosolic Ca2+ transients arise from the mobilization of cellular Ca2+ from a nonmitochondrial pool. Extracellular divalent cations thus appear to act at some site on the surface of the cell, and this site can be considered a "Ca2+ receptor" which enables the parathyroid cell to detect small changes in the concentration of extracellular Ca2+.     

Stimulus-secretion coupling in bovine parathyroid cells. Dissociation between secretion and net changes in cytosolic Ca2+

The relationship between the concentration of cytosolic free Ca2+ ([Ca2+]i) and secretion of parathyroid hormone (PTH) was investigated in isolated bovine parathyroid cells using the fluorescent Ca2+ indicator, quin 2. Increasing the concentration of extracellular Ca2+ from 0.5 to 2.0 mM caused a 3-fold increase in [Ca2+]i (from 183 +/- 4 to 568 +/- 21 nM) which was associated with a 2-4-fold decrease in secretion of PTH. Decreasing extracellular Ca2+ to about 1 microM caused a corresponding fall in [Ca2+]i to 60-90 nM. Extracellular Ca2+-induced changes in [Ca2+]i were not affected by omission of extracellular Na+. Depolarizing concentrations of K+ (30 mM) depressed [Ca2+]i at all concentrations of extracellular Ca examined, and this was associated with increased secretion of PTH. Ionomycin (0.1 or 1 microM) increased [Ca2+]i at extracellular Ca2+ concentrations of 0.5, 1.0, and 2.0 mM, but inhibited secretion of PTH only at Ca concentrations near the "Ca2+ set point" (1.25 microM). In contrast, dopamine, norepinephrine (10 microM each), and Li+ (20 mM) potentiated secretion of PTH without causing any detectable change in [Ca2+]i. The results obtained with these latter secretagogues provide evidence for a mechanism of secretion which is independent of net changes in [Ca2+]i. The phorbol ester 12-O-tetradecanoyl phorbol 13-acetate (TPA) did not alter [Ca2+]i or secretion of PTH at low (0.5 mM) extracellular Ca2+ concentrations. At 2.0 mM extracellular Ca2+, however, TPA (20 nM or 1 microM) depressed [Ca2+]i and potentiated secretion of PTH. The addition of TPA prior to raising the extracellular Ca2+ concentration reduced the subsequent increase in [Ca2+]i. The results show that the effects of TPA on secretion in the parathyroid cell are not readily dissociated from changes in [Ca2+]i and suggest that some TPA-sensitive process, perhaps involving protein kinase C, may be involved in those mechanisms that regulate [Ca2+]i in response to changes in extracellular Ca2+.     

Measurement of intracellular Ca2+ in BC3H-1 muscle cells with Fura-2: relationship to acetylcholine receptor synthesis

Synthesis of acetylcholine receptors (AChR) can be affected by calcium, but the role played by this cation is controversial. The effect of changes in extracellular calcium, [Ca2+]o, on AChR synthesis was examined in a cultured mouse muscle cell line, BC3H-1. Reduction of [Ca2+]o for long periods (approximately 22 h) leads to a decrease in total surface AChR levels, a finding that is consistent with inhibition of AChR synthesis. A half-maximal reduction in surface AChR levels is observed when [Ca2+]o is decreased from 1.8 to approximately 5o microM. Under these conditions, however, total protein synthesis is also largely inhibited, suggesting that the effect of [Ca2+]o on AChR synthesis may be relatively non-specific. Increasing [Ca2+]i by adding the Ca2+ ionophore, A23187 (in the presence of 1.8 mM [Ca2+]o) also gives similar and significant reductions of both AChR and protein synthesis. Since the time course of changes in intracellular calcium [( Ca2+]i) produced by these manoeuvres is unknown, we examined the effects of briefer (1-6 h) reductions in [Ca2+]o and achieved a more specific reduction in AChR synthesis. A direct measurement of the changes in [Ca2+]i resulting from changes in [Ca2+]o was made using the fluorescent indicator Fura-2 and video fluorescence microscopy. Our results show that in BC3H-1 muscle cells the resting intracellular calcium decreases reversibly over 20 min when [Ca2+]o is decreased. We suggest that a reduction of [Ca2+]i produced by the lower [Ca2+]o underlies the reduction in AChR synthesis observed in these experiments.     

HgCl2-induced changes in cytosolic Ca2+ of cultured rabbit renal tubular cells

Fura 2 was used to measure changes in cytosolic [Ca2+] ([Ca2+]i) in cultured rabbit kidney proximal tubule cells exposed to HgCl2. Treatment with 2.5-10 microM HgCl2 resulted in an extracellular [Ca2+] ([Ca2+]e)-independent 2- to 12-fold increase in [Ca2+]i above resting levels of about 100 nM. Treatment with 25-100 microM HgCl2 caused a rapid [Ca2+]e-independent 10- to 12-fold increase in [Ca2+]i within 1 min followed by a recovery to about 2-fold steady state by 3 min. With 25-100 microM HgCl2, both magnitude and rate of Ca2+ increase were similar, but recovery was greater with increasing doses. A slower, secondary increase in [Ca2+]i followed which varied with HgCl2 concentration and required [Ca2+]e. The first increase in [Ca2+]i represents release from intracellular pools. Calcium channel blockers, calmodulin inhibitors, and mitochondrial inhibitors do not alter the patterns of [Ca2+]i changes due to HgCl2. The recovery response with higher HgCl2 concentrations appears to be triggered by Hg2+ and not by the increased [Ca2+]i. Sulfhydryl modifiers N-ethylmaleimide, PCMB and PCMBS produced [Ca2+]e-independent [Ca2+]i increases similar to those induced by low HgCl2 concentrations. Cell killing with HgCl2 was about 50% greater with normal [Ca2+]e than with low [Ca2+]e, suggesting that [Ca2+]e influx is important in accelerating injury leading to cell death.     

Cell Swelling, Blebbing, and Death Are Dependent on ATP Depletion and Independent of Calcium During Chemical Hypoxia in a Glial Cell Line (ROC-1)

The morphological and biochemical changes that occur during chemical hypoxic injury in a neural cell line were studied in the presence and absence of calcium. Oligodendroglial-glioma hybrid cells (ROC-1) were subjected to inhibitors of glycolytic and oxidative ATP synthesis (chemical hypoxia). Complete respiratory inhibition depleted [ATP] to less than 5% of control by 4 min. Blebs appeared on the cell surfaces and cells began to swell within a few minutes of ATP depletion. A 200% increase in cell volume and bleb coalescence preceded irreversible cell injury (lactate dehydrogenase release) which began at approximately 20 min with 50% cell death by 40 min. In energized cells an equivalent degree of osmotic swelling induced by ouabain inhibition of the Na+, K(+)-ATPase pump did not produce blebbing or cell death. Partial inhibition of respiration decreased [ATP] to approximately 10% of control by 40 min. Blebbing and swelling began at 40 min and bleb coalescence preceded plasma membrane disruption which began at approximately 55 min. ATP depletion, blebbing, swelling, and death followed similar time courses in the presence or absence of extracellular calcium ([Ca2+]e). Intracellular calcium ([Ca2+]i) was measured using fura-2. In calcium-containing medium metabolic inhibition caused a transient increase in resting [Ca2+]i (100 +/- 17 nM) followed by a low steady-state level preceding plasma membrane disruption. Following deenergization in calcium-free medium, [Ca2+]i remained below 60 nM throughout injury and death. These data suggest that decreased ATP initiates a sequence of events including bleb formation and cell swelling that lead to irreversible cell injury in the absence of large increases in [Ca2+]i.     

Mobilization of intracellular calcium by alpha 1-adrenergic receptor activation in muscle cell monolayers

The fluorescent chelating agent quin 2 has been employed to monitor alterations of intracellular free Ca2+ concentrations ([Ca2+]i) in response to alpha 1-adrenergic receptor activation in adherent BC3H-1 cells. To correlate the kinetics of [Ca2+]i changes with transmembrane fluxes of this ion, continuous monitoring of [Ca2+]i has been undertaken on a monolayer of cells. Previous measurements of the transmembrane efflux of Ca2+ show a distinct lag in the response over a range of phenylephrine concentrations. By contrast, the elevation of [Ca2+]i is rapid (t1/2 approximately 2 s) and maintained for 30 s before it begins to decline to basal concentrations. The differences in kinetics indicate that the temporal delay in cellular Ca2+ efflux results from either activation of the transport system for Ca2+ extrusion or translocation of free Ca2+ to the transport site. The decline of [Ca2+]i with continued agonist exposure parallels both the efflux kinetics from the cell and the decline of total cellular Ca2+. At a time when free [Ca2+]i approaches the resting concentration, total cellular Ca2+ is reduced to a steady state value of 60% of that seen prior to stimulation. The Kact for phenylephrine-stimulated elevation in [Ca2+]i on the monolayer is 0.51 microM, which is similar to the Kact of 0.90 microM observed for phenylephrine-activated 45Ca2+ efflux. Addition of phentolamine subsequent to phenylephrine addition immediately reverses the agonist-stimulated Ca2+ mobilization, initiating a rapid return of [Ca2+]i to resting levels. A comparison of the kinetics of Ca2+ mobilization with its transmembrane flux suggests that the agonist augments the rate of recycling of intracellular Ca2+ between the free and bound states rather than causing release as a single bolus from the bound stores.