Development of a human stanniocalcin radioimmunoassay: serum and tissue hormone levels and pharmacokinetics in the rat.

Stanniocalcin (STC) is a polypeptide hormone that was first discovered in fish and recently identified in humans and other mammals. In fish STC is produced by one gland, circulates freely in the blood and plays an integral role in mineral homeostasis. In mammals, STC is produced in a number of different tissues and serves a variety of different functions. In kidney, STC regulates phosphate reabsorption by proximal tubule cells, whereas in ovary it appears to be involved in steroid hormone synthesis. However there is no information on circulating levels of STC in mammals or the regulation of its secretion. In this report we have developed a radioimmunoassay (RIA) for human STC. The RIA was validated for measuring tissue hormone levels. However human and other mammalian sera were completely devoid of immunoreactive STC (irSTC). To explore the possibility that mammalian STC might have a short half-life pharmacokinetic analysis was carried out in rats. STC pharmacokinetics were best described by a two compartment model where the distribution phase (t1/2(alpha)) equaled 1 min and the elimination phase (t1/2(beta)) was 60 min. However the STC in the elimination phase no longer crossreacted in the RIA indicating it had undergone substantial chemical modification, which could explain our inability to detect irSTC in mammalian sera. When we compared the pharmacokinetics of human and fish STC in mammalian and fish models the human hormone was always eliminated faster, indicating that human STC has unique structural properties. There also appears to be a unique clearance mechanism for STC in mammals. Hence there are major differences in the delivery and biology of mammalian STC. Unlike fishes, mammalian STC does not normally circulate in the blood and functions instead as a local mediator of cell function. Future studies will no doubt show that this has had important ramifications on function as well.

Stanniocalcin in the seawater salmon: structure, function, and regulation.

Stanniocalcin (STC) is a homodimeric glycoprotein hormone that was first discovered in fish, where it is produced by unique endocrine glands known as the corpuscles of Stannius (CS). In freshwater salmon, STC plays an integral role in Ca2+ and phosphate homeostasis. High levels of extracellular Ca2+ promote the synthesis and release of STC, which on entering the bloodstream reduces the levels of gill and gut Ca2+ transport and renal phosphate excretion to restore normocalcemia. In this report, we have examined STC in seawater salmon. We have studied the distribution of STC protein and mRNA in marine Atlantic salmon CS cells, the responsiveness of these cells to Ca2+, and some physical properties of the hormone. Our results demonstrated that all Atlantic salmon CS cells expressed the STC gene. Furthermore, these cells exhibited a Ca2+ sensitivity that was remarkably similar to those in freshwater salmon in terms of its ability to stimulate STC secretion and gene expression. When Atlantic salmon glands were fractionated by concanavalin A (ConA)-Sepharose chromatography, two distinct forms of the hormone were identified, both of which were recognized by sockeye salmon STC antiserum, and designated as STC1 and STC2. STC1 was a glycosylated, 42-kDa disulfide-linked dimer, with a high affinity for ConA. STC2 did not bind to ConA, was 44 kDa in size, and had a different subunit structure. STC2 was also a less effective inhibitor of gill Ca2+ transport in fish. Collectively, the results suggest that there is a second form of STC in salmon.

Salmon calcitonin inhibits whole body Ca2+ uptake in young rainbow trout.

Gill Ca2+ transport (GCAT) in fish is regulated by a number of different hormones. Stanniocalcin (STC) from the corpuscles of Stannius (CS) is an inhibitor of GCAT, whereas pituitary-derived prolactin and cortisol stimulate GCAT. Other than this, however, little is known about the effects of other hormones on this important transport process. The role of calcitonin (CT) in calcium homeostasis in fish is still controversial. Whereas many studies have shown significant effects of CT on plasma calcium levels, an equal number of studies have failed to find any correlations between plasma calcium and CT levels in fish. Previous in vitro studies have shown that salmon CT has potent inhibitory effects on GCAT in isolated, perfused fish gill preparations, a finding that has never been corroborated in vivo. Therefore, in this report we examined the effects of salmon CT on whole body 45Ca uptake (as a measure of GCAT) in young rainbow trout. In support of the in vitro findings, we found that CT had significant inhibitory effects on GCAT. In parallel studies, we found that CT had no effects on STC secretion and only modest, stimulatory effects on STC mRNA levels in cultured trout CS cells. These finding suggest that both CT and STC function as negative regulators of GCAT in fish.

Effect of oxygen on ascorbic acid uptake and concentration in embryonic chick brain.

The effects of oxygen on ascorbic acid concentration and transport were studied in chick embryo (Gallus gallus domesticus). During normoxic incubations, plasma ascorbic acid concentration peaked on fetal day 12 and then fell, before increasing again on day 20 when pulmonary respiration began. In contrast, cerebral ascorbic acid concentration rose after day 6, was maintained at a relatively high level during days 8-18, and then fell significantly by day 20. Exposure of day 16 embryos for 48 h to 42% ambient O2 concentration decreased ascorbic acid concentration by four-fifths in plasma and by one-half in brain, compared to values in normoxic (21% O2) or hypoxic (15% O2) controls. Hyperoxic preincubation of embryos also inhibited ascorbic acid transport, as evidenced by decreased initial rates of saturable and Na(+)-dependent [14C]ascorbic acid uptake into isolated brain cells. It may be concluded that changes in ascorbic acid concentration occur in response to oxidative stress, consistent with a role for the vitamin in the detoxification of oxygen radicals in fetal tissues. However, changing O2 levels have less effect on ascorbic acid concentration in brain than in plasma, indicating regulation of the vitamin by brain cells. Furthermore, the effect of hyperoxia on cerebral vitamin C may result, in part, from inhibition of cellular ascorbic acid transport.

Ascorbate uptake by ROS 17/2.8 osteoblast-like cells: substrate specificity and sensitivity to transport inhibitors.

Ascorbate (reduced vitamin C) is required for bone formation. We have shown previously that both the osteoblast-like cell line ROS 17/2.8 and primary cultures of rat calvarial cells possess a saturable, Na(+)-dependent uptake system for L-ascorbate (J Membr Biol 111:83-91, 1989). The purpose of the present study was to investigate the specificity of this transport system for organic anions and its sensitivity to transport inhibitors. Initial rates of ascorbate uptake were measured by incubating ROS 17/2.8 cells with [L-14C]ascorbate at 37 degrees C. Uptake of [L-14C]ascorbate (5 microM) was inhibited 98 +/- 1% by coincubation with unlabeled L-ascorbate (3 mM) and 48 +/- 4% by salicylate (3 mM), but it was not affected by 3 mM formate, lactate, pyruvate, gluconate, oxalate, malonate, or succinate. Uptake of the radiolabeled vitamin also was not affected by acute (1 minute) exposure of the cells to the Na+ transport inhibitors amiloride and ouabain or the glucose transport inhibitor cytochalasin B. In contrast, anion transport inhibitors rapidly (less than 1 minute) and reversibly blocked [L-14C]ascorbate uptake. In order of potency, these drugs were 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS) approximately equal to sulfinpyrazone greater than furosemide approximately equal to 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid (SITS). These findings indicate that the ascorbate transporter is relatively specific for the ascorbate anion, since other organic anions (with the exception of salicylate) did not compete with ascorbate for uptake. Rapid and reversible inhibition by the impermeant antagonists DIDS and SITS suggests that they interact directly with the ascorbate transporter, consistent with location of the transport system in the plasma membrane.

Evidence for electrogenic sodium-dependent ascorbate transport in rat astroglia.

The dependence of ascorbate uptake on external cations was studied in primary cultures of rat cerebral astrocytes. Initial rates of ascorbate uptake were diminished by lowering the external concentrations of either Ca2+ or Na+. The Na(+)-dependence of astroglial ascorbate uptake gave Hill coefficients of approximately 2, consistent with a Na(+)-ascorbate cotransport system having stoichiometry of 2 Na+:1 ascorbate anion. Raising external K+ concentration incrementally from 5.4 to 100 mM, so as to depolarize the plasma membrane, decreased the initial rate of ascorbate uptake, with the degree of inhibition depending on the level of K+. The depolarizing ionophores gramicidin and nystatin slowed ascorbate uptake by astrocytes incubated in 5.4 mM K+; whereas, the nondepolarizing ionophore valinomycin did not. Qualitatively similar results were obtained whether or not astrocytes were pretreated with dibutyryl cyclic AMP (0.25 mM for 2 weeks) to induce stellation. These data are consistent with the existence of an electrogenic Na(+)-ascorbate cotransport system through which the rate of ascorbate uptake is modulated by endogenous agents, such as K+, that alter astroglial membrane potential.

Substrate regulation of ascorbate transport activity in astrocytes.

Astrocytes possess a concentrative L-ascorbate (vitamin C) uptake mechanism involving a Na(+)-dependent L-ascorbate transporter located in the plasma membrane. The present experiments examined the effects of deprivation and supplementation of extracellular L-ascorbate on the activity of this transport system. Initial rates of L-ascorbate uptake were measured by incubating primary cultures of rat astrocytes with L-[14C]ascorbate for 1 min at 37 degrees C. We observed that the apparent maximal rate of uptake (Vmax) increased rapidly (less than 1 h) when cultured cells were deprived of L-ascorbate. In contrast, there was no change in the apparent affinity of the transport system for L-[14C]ascorbate. The increase in Vmax was reversed by addition of L-ascorbate, but not D-isoascorbate, to the medium. The effects of external ascorbate on ascorbate transport activity were specific in that preincubation of cultures with L-ascorbate did not affect uptake of 2-deoxy-D-[3H(G)]glucose. We conclude that the astroglial ascorbate transport system is modulated by changes in substrate availability. Regulation of transport activity may play a role in intracellular ascorbate homeostasis by compensating for regional differences and temporal fluctuations in external ascorbate levels.