Hormones and Calcium Regulation in Fundulus heteroclitus

For the past 20 years, our laboratory has been involved in studyingthe endocrine control of calcium balance in the killifish, Fundulusheteroclitus. We have surveyed almost all endocrine systemsand discovered two main ones directly involved in plasma calciumregulation. They are the pituitary gland and the corpusclesof Stannius. When fish adapted to low-calcium seawater werehypophysectomized, hypocalcemia and tetany were observed. Whenfish adapted to high-calcium seawater were Stanniectomized,hypercalcemia was seen. In both cases, other electrolytes wereunaffected and replacement therapy corrected the plasma calciumchanges. We have tried to characterize the active principlesin both glands. We discovered that prolactin is hyperacalcemic.The pituitary gland also seems to contain a second hypercalcemicfactor which may be located in the PAS-positive pars intermediacells. For the Stannius corpuscle factors, we developed a bioassayand named the active substance(s) hypocalcin. In collaborationwith Dr. Hirofumi Sokabe at Jichi Medical School, Japan, weshowed that the Stannius corpuscles also contain a renin-likesubstance capable of generating a hypocalcemic angiotensin-likesubstance. The exact chemical nature of the hypocalcemic substanceis being investigated. Calcium balance in the whole fish wasalso studied with 47-calcium. These studies were carried outin collaboration with Dr. Nicole Mayer-Gostan at Villefranche-sur-Mer,France. We discovered that killifish depend on the environmentrather than bone as a calcium reservoir. Hormones may be involvedin the exchanges with the environment.     

Hypocalcemic effects of bovine parathyroid hormone (1-34) and Stannius corpuscle homogenates in teleost fish adapted to low-calcium water

Injections of bovine parathyroid hormone (PTH 1-34) and homogenates of corpuscles of Stannius produce hypocalcemia in male killifish and tilapia adapted to calcium-deficient seawater or fresh water, respectively. In fish from water with normal calcium concentrations no effects are noticeable. These results suggest similarity in bioactivity between PTH, the hypercalcemic hormone of terrestrial vertebrates, and the hypocalcemic factor of the corpuscules of Stannius in teleost fish.     

The relationship between the ionic composition of the environment and the secretory activity of the endocrine cell types of stannius corpuscles in the teleost Gasterosteus aculeatus

Summary The corpuscles of Stannius of threespined sticklebacks contain two glandular cell types of presumed endocrine nature. To elucidate the function of both cell types the secretory activity of the cells was studied in fully adapted seawater and freshwater fishes and in specimens transferred from sea water to fresh water or adapted to media of various ionic composition. The secretory activity was established, in tissue sections and freeze-etch replicas, by estimating the volume of the nuclei, the density of the nuclear pores, and the frequency of exocytotic phenomena.The type-1 cells, ultrastructurally comparable to the predominant or only cell type described in many other teleosts, are more active in sea water than in fresh water. The activity of the type-2 cells, whose ultrastructural appearance is known only for salmonids and eels, is higher in fresh water. Transfer of seawater fishes to fresh water results in reduction of type-1 cells and activation of type-2 cells. The factors responsible for these changes were analyzed by exposure of fishes to solutions of various salts in fresh water and to artificial sea water with a reduced content of one of its components. The high activity of type-1 cells in sea water proved to be related to the high calcium content of this medium. These cells probably produce a substance comparable to hypocalcin, the endocrine factor isolated from the Stannius corpuscles of some other teleost species. The high activity of type-2 cells in fresh water appeared to be connected with the low sodium and potassium levels of this medium. Type-2 cells possibly produce a hitherto unknown hormone involved in the control of sodium and/or potassium metabolism.The technical assistance of Miss C. Mein and Mr. J. Zagers is gratefully acknowledged     

Evolution of Calcium Regulation in Lower Vertebrates

Calcium regulation in lower vertebrates appears to be a continuum.The predominant hypercalcemic hormone in reptiles, birds andmammals is parathyroid hormone, while the major hypercalcemiccontrol in fishes is a pituitary factor, probably prolactin.In the amphibians dual controlling mechanisms are at work, sothat both the pituitary and parathyroids exert their influence.Prolactin may still retain some hypercalcemic potency in thehigher vertebrate groups, either directly or indirectly by influencingthe secretion of other hypercalcemic hormones. On the otherhand, parathyroid hormone does not occur in, nor does it elevateblood calcium in fishes. It thus seems to be a new inventionof tetrapods, or possibly to have evolved from a pituitary factorof fishes. The ability to lower blood calcium seems to be veryimportant in seawater fishes, in which the corpuscles of Stanniusexert major control. In terrestrial forms, the corpuscles ofStannius are not present, and hypocalcemic factors assume aminor role in overall calcium regulation     

Evidence of hypocalcemic factor from corpuscles of Stannius of the teleost Heteropneustes fossilis (Bloch)

The administration of acid extract of corpuscles of Stannius has no effect on the plasma calcium level, in the normal fish, whereas the same dose shows typical hypocalcemic response in hypercalcemic fish, H. fossilis. It is concluded that acid extract of corpuscles of Stannius is effective only in hypercalcemic condition.     

The Calcium-sensitive Cells of the Pars Intermedia in the Eel

In the pituitary, the PAS-positive calcium-sensitive (Ca-s) cells of the pars intermedia appear less active in seawater (SW)- than in freshwater (FW)-adapted eels. The kinetics of their response during adaptation to SW or readaptation to FW was investigated. Morphometric studies show that transfer to SW induces a rapid nuclear atrophy which accentuates in eels kept for several weeks in SW. Readaptation to FW stimulated the Ca-s cells after 2–10 days; after 1 or 2 months, the cells tend to be similar to those of eels kept in FW. Plasma calcium decreases slightly but significantly in SW eels. The response of the Ca-s cells is not modified by an ovine prolactin treatment inducing hypercalcemia, hypernatremia and stimulation of the corpuscles of Stannius. Minor changes occurring in the MSH cells remain difficult to interpret; the short stimulation during readaptation to FW may be related to a stress effect and/or to release of other peptides present in the MSH cells of fish.     

A second cell type in stannius bodies of two euryhaline teleost species

In the corpuscles of Stannius of sticklebacks and eels two cell types are described of presumably endocrine nature. The predominating type, comparable to the cells observed in other species, responds to variation in calcium content of the medium and possibly produces a hypocalcemic hormone. The second cell type is unreactive to calcium. Since it is more active in freshwater than in seawater specimens, this cell type is possibly involved in ionic regulation. It was not found in two seawater teleost species.     

Effects of changes in environmental calcium on prolactin secretion in Japanese eel,Anguilla japonica

Effects of changes in environmental Ca²⁺ on the secretion of prolactin, a possible hypercalcemic hormone, were examined both in vivo and in vitro in the Japanese ecl, Anguilla japonica. Transfer of seawater- or freshwater-adapted fish to fresh water, fresh water containing 10 mmol Ca²⁺ · 1^-1 sea water, Ca²⁺-free sea water, or deionized water was accompanied by significant changes in plasma Ca²⁺ levels after 7 days, except for the fish transferred from fresh water to fresh water and from sea water to sea water. Changes in external Ca²⁺ concentrations did not affect plasma prolactin levels, although plasma prolactin levels as well as pituitary prolactin contents were significantly greater in fish in a hypotonic environment than those in a hypertonic environment, regardless of the external Ca²⁺ concentration. Hypercalcemia, induced by removal of the corpuscles of Stannius, did not alter plasma prolactin levles. Incubation of the pituitary in the medium with different Ca²⁺ concentrations (up to 2.9 mmol·l^-1) did not affect the basal release of prolactin, except at an extremely low Ca²⁺ concentration (less than 0.1 mmol·l^-1) where prolactin release was inhibited. Addition of Ca²⁺ ionophore (A23187) to the medium led to a marked and significant increase in prolactin release, indicating that an increase in intracellular Ca²⁺ stimulates prolactin release. However, the effect was not specific to prolactin cells; a similar increase was seen in growth hormone release. These results indicate that changes in environmental Ca²⁺ concentration may not be the primary factor influencing prolactin secretion in the eel; changes in environmental osmolality or Na⁺ levels seem to be more critical for the regulation of prolactin secretion.Abbreviations CSX stanniectomy - DMSO dimethylsulphoxide - DW deionized water - FW fresh water - GH growth hormone - PRL prolactin - SW sea water     

Fine Structure of the Adrenocortical Homolog and the Corpuscles of Stannius of Amia calva L.

A comparison is made between the fine structure of yellow corpuscles and white corpuscles located within the kidneys of the holostean fish, Amia calva L. The yellow corpuscles are composed of epithelial cells possessing all the features of steroid-producing tissues, namely an abundance of vacuoles, tubular smooth endoplasmic reticulum, and mitochondria with tubular cristae. The Golgi apparatus is also a conspicuous component of their cytoplasm. These cells are homologous to adrenocortical cells of higher vertebrates and they have cytoplasmic projections which extend into the lumina of surrounding sinusoids. The white corpuscles possess epithelial cells of variable appearance but all cells contain secretory granules and an extensive rough endoplasmic reticulum. The secretory granules appear to originate at the Golgi apparatus and occasionally are observed intact in the intercellular space. However the method of release of these granules was not clearly defined. These corpuscles are similar to the corpuscles of Stannius which have been described in modern bony fish. The presence of multivesicular bodies and smooth endoplasmic reticulum in some cells may reflect the origin of the corpuscles of Stannius from the tubular nephron. A. calva appears to be a suitable organism for comparative studies into the function of the adrenocortical homolog and corpuscles of Stannius in “primitive” fish.     

Intraspecific variation in gene expression after seawater transfer in gills of the euryhaline killifish Fundulus heteroclitus

Previous research has suggested that northern populations of the euryhaline killifish (Fundulus heteroclitus) are better adapted to freshwater environments than their southern counterparts. In this study, we examined whether this adaptation has come at an ionoregulatory cost in seawater, by comparing published data for northern killifish to newly acquired data on the molecular responses of southern killifish to seawater transfer. After abrupt transfer from brackish water (10 per thousand) to seawater, Na,K-ATPase activity, Na,K-ATPase alpha(1a) mRNA expression, and NKCC1 mRNA expression increased 1 and 4 days after transfer in the gills of southern fish (by 2-3-fold), but increased at 1 day and not 4 days after transfer in northern fish. Small increases in mRNA expression were observed in both populations at 14 days. CFTR expression also increased in southern and northern fish at 1 and 4 days into seawater, and was also elevated at 14 days in northern fish. Because fish from both southern and northern populations maintained plasma Na(+) and Cl(-) balance after seawater transfer, the differences in activity and expression could not have been caused by differences in plasma ion levels. Instead, some other regulatory factor may account for the differences in expression between populations. This study shows that freshwater adaptation in northern populations of killifish has not necessarily come at a significant ionoregulatory cost in seawater, but has altered the molecular responses of their gills to seawater transfer compared to southern killifish.     

Comparative physiology of the renin-angiotensin system.

Renin or a renin-like substance is found in the kidneys of many vertebrate species. It is absent from the kidneys of cyclostomes and elasmobranchs and first appears in holosteans and the bony fishes as well as in all higher vertebrate species. Juxtaglomerular cell granules also appear first in holosteans and the bony fishes while the macula densa first appears in amphibians. In telecost fishes, the corpuscles of Stannius contain Bowie-stainable granules and a renin-like pressor substance. Among classes and, in some cases, species of vertebrates, specificity in the reaction of renin with a substrate has been demonstrated. There is also some species and class variation in the angiotensin molecule since angiotensins of fishes, amphibians, reptiles and birds have chemical characteristics different from each other and from those of ammmals. A role for renin in stimulating interrenal gland steroid biosynthesis and in influencing water and ion regulation in nonmammalian vertebrates is discussed.     

Differential Activity of Stanniocalcin in Male and Female Fresh Water Teleost Mastacembelus armatus (Lacepede) during Gonadal Maturation

The present study was carried out to analyze the differences in the activity of hormone stanniocalcin (STC) between male and female fishes of Mastacembelus armatus during their gonadal cycle. A large variation in nuclear diameter of cells of corpuscles of Stannius (CS) were recorded in relation to testicular cycle as well as ovarian cycle which indicates that the cellular activity varied with different phases of reproductive cycle in both male and female fish. Similar changes in nuclear diameter of CS cells were also observed after 17alpha-methyltestosterone administration in males and 17 β-estradiol administrations in females. A positive correlation was observed between plasma STC levels, gonadosomatic index (GSI) and the sex steroids in both sexes, suggesting that STC has a role in the processes involved in gonadal development. In addition females showed remarkable changes in plasma calcium level during gonadal cycle while no such change for males were observed. In females the plasma calcium level estimated during different phases of reproductive cycle indicates positive correlation between plasma level of calcium and gonad growth. Thus hyperactivity of CS cells was noted in both male and female fishes during gonadal cycle along with the differences in the activity of STC as well. In female it may act as hypocalcemic factor and bring the level of calcium to normal which increases during preparatory and pre spawning phases to fulfill the increased demand of calcium for vitellogenesis. However data of male fishes indicated that plasma STC concentration varied widely during gonadal cycle but showed no consistent relationship to plasma calcium level.     

Expression of aquaporin 3 in gills of the Atlantic killifish (Fundulus heteroclitus): Effects of seawater acclimation

Estuarine fish, such as the Atlantic killifish (Fundulus heteroclitus), are constantly and rapidly exposed to changes in salinity. Although ion transport in killifish gills during acclimation to increased salinity has been studied extensively, no studies have examined the role of aquaglyceroporin 3 (AQP3), a water, glycerol, urea, and ammonia transporter, during acclimation to increased salinity in this sentinel environmental model organism. The goal of this study was to test the hypothesis that transfer from freshwater to seawater decreases AQP3 gene and protein expression in the gill of killifish. Transfer from freshwater to seawater decreased AQP3 mRNA in the gill after 1 day, but had no effect on total gill AQP3 protein abundance as determined by western blot. Quantitative confocal immunocytochemistry confirmed western blot studies that transfer from freshwater to seawater did not change total AQP3 abundance in the gill; however, immunocytochemistry revealed that the amount of AQP3 in pillar cells of secondary lamellae decreased in seawater fish, whereas the amount of AQP3 in mitochondrion rich cells (MRC) in primary filaments of the gill increased in seawater fish. This response of AQP3 expression is unique to killifish compared to other teleosts. Although the role of AQP3 in the gill of killifish has not been completely elucidated, these results suggest that AQP3 may play an important role in the ability of killifish to acclimate to increased salinity.     

A divergent CFTR homologue: highly regulated salt transport in the euryhaline teleost F.heteroclitus

The killifish,Fundulus heteroclitus, is a euryhalineteleost fish capable of adapting rapidly to transfer from freshwater (FW) to four times seawater (SW). To investigate osmoregulation at amolecular level, a 5.7-kilobase cDNA homologous to human cysticfibrosis transmembrane conductance regulator (hCFTR) was isolated froma gill cDNA library from SW-adapted killifish. This cDNA encodes aprotein product (kfCFTR) that is 59% identical to hCFTR,the most divergent form of CFTR characterized to date. Expression ofkfCFTR in Xenopus oocytes generatedadenosine 3',5'-cyclic monophosphate-activated,Cl-selective currentssimilar to those generated by hCFTR. In SW-adapted killifish,kfCFTR was expressed at high levels in the gill, opercular epithelium, and intestine. After abrupt exposure of FW-adapted killifish to SW, kfCFTR expression in the gill increasedseveralfold, suggesting a role for kfCFTR in salinity adaptation. Undersimilar conditions, plasma Na⁺levels rose significantly after 8 h and then fell, although it is notknown whether these changes are directly responsible for the changes inkfCFTR expression. The killifish provides a unique opportunity to understand teleost osmoregulation and the role of CFTR.

     

Stanniocalcin 1 as a pleiotropic factor in mammals

Stanniocalcin (STC)1 is the mammalian homologue of STC which was originally identified as a calcium/phosphate-regulating hormone in bony fishes. STC1 is a homodimeric phosphoglycoprotein with few if any identified unique motifs in its structure with the exception of CAG repeats in the 5'-untranslated region. In contrast to fish STC which is expressed mainly in the corpuscles of Stannius, STC1 is expressed in a wide variety of tissues, but unexpectedly is not detected in the circulation under normal circumstances. Thus, STC1 may play an autocrine/paracrine rather than a classic endocrine role in mammals. Consistent with this, pleiotropic effects of STC1 have been postulated in physiological and measured in pathological situations. There is much current interest in identifying a specific STC1 receptor and putative signaling pathways to which it may be coupled. In this regard, STC1 may regulate intracellular calcium and/or phosphate (Pi) levels. In the skeletal system, for example, Pi uptake in bone-forming osteoblasts via a direct effect of STC1 on expression of the NaPi transporter Pit1 may contribute to bone formation. Here we review current understanding of the role of STC1 and its possible molecular mechanisms in the skeleton and elsewhere.     

In vivo regulation by calcium of thyroid metabolism of iodine in rats]

In vivo experiments using a calcium deficient or a normal diet, proved that calcium enhance iodine entry and concentration into the thyroid gland of the rat and the intra-thyroidal T4 pool, T4 level in serum was also increased. Peripheral metabolism of T4, serum TSH levels and pituitary TSH contents were unaffected. Calcium has a local regulatory function on the thyroid gland.     

Cellular localization of somatolactin in the pars intermedia of some teleost fishes

Summary We report here on the cellular localization in the fish pituitary of somatolactin (SL), a putative new pituitary hormone related to growth hormone and prolactin, which has been recently identified in the piscine pituitary gland. Immunocytochemical staining, using anti-cod SL serum, revealed that in the cod pituitary gland, SL is produced by cells in the intermediate lobe, bordering the neural tissue. These cells, staining weakly with periodic-acid-Schiff (PAS), are distinct from the melanocyte stimulating hormone (MSH) cells which, as in all teleosts, are PAS-negative. SL-immunoreactivity was observed in the same location in all other teleost species examined: flounder, rainbow trout, killifish, molly, catfish and eel. In most fish the SL-immunoreactive cells are either strongly or weakly PAS-positive but in rainbow trout are chromophobic, indicating that the SL protein can probably exist in glycosylated and non-glycosylated forms. Thus, in demonstrating the cellular localization of SL, this study provides the first identification of the enigmatic, second cell-type of the fish pars intermedia.     

Stannius corpuscles and plasma calcium levels during the reproductive cycle in the cichlid teleost fish,Oreochromis mossambicus

Summary The corpuscles of Stannius (CS) of the cichlid Oreochromis mossambicus (formerly Sarotherodon mossambicus) were studied in relation to sexual maturation and plasma calcium levels. After sexual maturation, the CS are enlarged in female fish, because of an increase in size and number of the type-1 cells. During the ovarian cycle, the size of the CS increases in parallel with the growth of the ovaries. Concurrently, plasma total calcium increases markedly until spawning. This increase is mainly accounted for by calcium bound to proteins (vitellogenins), but the ultrafiltrable calcium fraction is also slightly higher than in males. Ovariectomy is followed by a reduction in the size of the CS, mainly a result of involution of the type-1 cells, and by a reduction in plasma calcium to levels typical for males. Gonadectomy in males does not affect size or ultrastructure of the CS, or plasma calcium levels. Since the type-1 cells of the CS are the presumptive source of a hypocalcemic hormone, we conclude that activation of the CS during the female reproductive cycle is a response to elevated calcium levels that accompany ovarian maturation. We suggest that the CS respond in particular to the elevated ultrafiltrable or ionic calcium levels.     

Stanniocalcin-like immunoreactivity in the corpuscles of Stannius of the bowfin Amia calva L.

Summary We used an antiserum against salmon stanniocalcin in an immunohistochemical, immunocytochemical, and Western blot analysis of bowfin (Amia calva) corpuscles of stannius. The bowfin is one of two extant holostean species with ancient ancestral links to modern-day bony fishes. The corpuscles of Stannius (white corpuscles) of the bowfin were scattered throughout much of the kidney among the adrenocortical homolog (yellow corpuscles) but could be distinguished from the adrenocortical homolog by their positive staining with both the periodic acid-Schiff reaction and a salmon stanniocalcin antiserum. Immunoreactivity was confined to cytoplamic granules and was absent when the antiserum was blocked with salmon stanniocalcin or with a crude extract of bowfin corpuscles of Stannius. When bowfin corpuscle-of-Stannius extracts were subjected to sodium dodecyl sulphate electrophoresis and Western blot analysis, two closely spaced bands were evident (43–45 kDa). Staining of both bands was abolished by pre-absorption of the antiserum with salmon stanniocalcin. In comparison to salmon stanniocalcin, the reputed bowfin hormone migrated faster in gels, suggesting a smaller apparent size. The purification of bowfin stanniocalcin should yield important new information regarding the evolution of this unique calcium-regulating hormone.     

Pressure Effects on Cholesterol and Lipid Synthesis by the Swimbladder of an Abyssal Coryphaenoides Species

SYNOPSIS. The swimbladder gas gland is recognized as a cholesterolsynthesis site in abyssal rattail fishes, Coryphaenoides sp.(from 2000 m depth), and Galápagos Islands surface fish,Orthopristis forbesi, Seriola mazatlana, and Sphoeroides annulatus.This relates to high levels of cholesterol in the gas gland(up to 21% of lipid) and high cholesterol levels in the fattyswimbladder interior (up to 49% of lipid). The gas gland hasmore protein (45.4%) than the internal fatty mass (18%). Lipidssynthesized include phospholipids and triglycerides in 2:1 ratioin the gas gland and 1:2 ratio in the liver. Deep fish havefatty livers (66%) compared to shallow fish (28%). Shallow fishincorporated five times as much acetate-l-¹⁴C into lipids asdid deep fish, and seven to eight times as much acetate-l-¹⁴Cinto cholesterol. Pressure facilitation of cholesterol synthesiswas observed in gas gland and liver of O. forbesi and Coryphaenoides,whereas total lipid synthesis was inhibited by higher pressures.Optimal acetate-l-¹⁴C incorporation into lipids occurred at5000 psi and 2°C in Coryphaenoides; it occurred at 14.7psi and 15° in O. forbesi. These conditions closely approximatethe environment of the fish.