Isolation and characterization of two distinct gonadotropins from chum salmon pituitary glands

Ultrastructural characteristics of two distinct gonadotropes (GTH I- and GTH II-cells) in the pituitary of rainbow trout Oncorhynchus mykiss

The salmonid pituitary produces two chemically distinct gonadotropins (GTHI and GTHII). Ultrastructural characteristics of GTHI- and GTHII-producing cells were studied in the trout pituitary with electronmicroscopic immunocytochemistry using antisera against salmon GTHIβ- and IIβ-subunits. In pituitaries from vitellogenic fish, GTHI-cells were characterized by numerous dilated cisternae of the granular endoplasmic reticulum (GER) and a small number of Iβ-positive granules (diameter, 100-300 nm), whereas GTHIIβ-immunoreactivity was found on granules (diameter, 200-400 nm) and large globules (diameter, 500-4000 nm) in apparently different cells (GTHII-cells). Distinct cellular distributions of GTHI and GTHII were maintained during gametogenesis, although morphological characteristics of GTHI- and GTHII-cells overlapped each other due to changes in number and size of the granules, globules and cisternae of the GER. Interestingly, the globules in the GTHI-cells were immunonegative for GTHIβ, although in the GTHII-cells they were always stained with GTHIIβ-antiserum. These results confirm that GTHIβ and GTHIIβ are synthesized in distinctly different cell-types in the salmonid pituitary and indicate that morphological characteristics cannot be used to distinguish these two cell-types.

Purification of gonadotropins (PmGTH I and II) from red seabream (Pagrus major) and development of a homologous radioimmunoassay for PmGTH II

Two gonadotropic glycoproteins (PmGTH I and II) were purified by ion-exchange chromatography, gel filtration and preparative SDS-PAGE, from pituitaries of red seabream, a marine teleost which has an asynchronous-type ovary and spawns almost daily during the spawning season. The glycoproteins were composed of distinct subunits and the molecular weights were estimated to be 32 and 38 kDa for PmGTH I and PmGTH II, respectively. Both PmGTH I and II were active in two homologous bioassays: in vitro oocyte maturation and/or in vitro estradiol-17β production assays. These two GTHs were distinct in electrostatic properties, molecular weight, stability and yields from pituitaries during the spawning season. These properties suggest that PmGTH I and II correspond to salmon GTH I and II, respectively.A homologous radioimmunoassay with which to measure PmGTH II was developed using a rabbit antiserum against the β subunit of PmGTH II and intact PmGTH II as standards and radioactive competitors. Competition curves for red seabream plasma and pituitary extract were parallel to the standard curve, while PmGTH I had low cross-reactivity (3.1 %) with the antibody. This specific RIA system showed an in vivo LHRHa induced GTH surge in the plasma of female red seabream.

Isolation and characterization of two distinct gonadotropins, GTHI and GTHII, from bonito (Katsuwonus plelamis) pituitary glands

Two distinct glycoproteins homologous to chum salmon GTHI and GTHII were isolated from the pituitary glands of a marine fish, the bonito (Katsuwonus plelamis), and characterized by amino acid sequence analysis in order to obtain additional evidence for duality of teleost GTHs. Glycoproteins were extracted from the pituitary glands, and intact GTHI and GTHII, consisting of two distinct subunits, were purified by ion-exchange chromatography on DEAE-cellulose, rpHPLC on Asahipak C4P-50 in alkaline buffer, and gel filtration on Superdex 75. The association of the subunits was stable in GTHI (39 kD) and unstable in GTHII (30 kD) in acidic conditions. Immunoblotting revealed that antisera against beta subunits of chum salmon GTHs reacted with GTHII, but not with GTHI. In addition, none of the GTHs was stained with antiserum against human TSH beta. Sequence analysis demonstrated that bonito GTHI beta is homologous to salmon GTHI beta with 43% sequence identity, and bonito GTHII beta is homologous to salmon GTHII beta with 67% identity. Sequence identity between bonito GTHI beta and GTHII beta was only 28%. Thus, it is evident that the bonito pituitary gland produces two chemically distinct gonadotropins homologous to chum salmon GTHs.

Isolation of maturational gonadotropin subunits from spotted seatrout (Cynoscion nebulosus) and development of a beta-subunit-directed radioimmunoassay for gonadotropin measurement in sciaenid fishes

Maturational gonadotropin (GTH) subunits were isolated from pituitaries of the spotted seatrout (Cynoscion nebulosus), a marine perciform teleost, by ethanolic extraction and ion-exchange, gel-filtration, and reverse-phase chromatography. Partial amino acid sequencing of the N-terminal regions of the alpha and beta subunits indicated 60-80% identities with various carp and salmon GTH subunits. The spotted seatrout GTH beta-subunit was used as radioligand in a radioimmunoassay (RIA) with Atlantic croaker (Micropogonias undulatus) GTH antiserum. Pituitary extracts and plasmas from a variety of sciaenid fishes diluted parallel to the croaker GTH standard in the RIA. These data suggest that there is a high degree of immunological similarity among the GTH beta subunits of sciaenid fishes. The RIA measured increased levels of GTH in the plasmas of three species of sciaenid fishes, spotted seatrout, orangemouth corvina (Cynoscion xanthulus), and red drum (Sciaenops ocellatus), following injections of a luteinizing hormone-releasing hormone analog. The beta-subunit-directed GTH RIA increases considerably the number of species in which studies of GTH physiology can now be conducted.

Changes in brain gonadotropin-releasing hormone, pituitary and plasma gonadotropins, and plasma thyroxine during smoltification in chinook salmon (Oncorhynchus tschawytscha)

Concentrations of brain salmon gonadotropin-releasing hormone (sGnRH), plasma gonadotropin I (GTH I), and pituitary GTH I and GTH II were determined in yearling chinook salmon (Oncorhynchus tschawytscha) during the parr-smolt transformation in two successive seasons. There were significant elevations in brain sGnRH content from February to March in 1988, and from February to April in 1989. Increases in brain sGnRH content coincided with elevations in plasma thyroxine levels that occurred from February to March, 1988 and 1989. Plasma GTH levels were relatively constant (1-2 ng/ml) throughout the period of sampling. However, during 1988, plasma concentrations of GTH I decreased significantly between late March and early April. During 1989, plasma GTH I levels appeared to reach a peak (2 ng/ml) in mid-February, but otherwise remained near 1 ng/ml. Previous studies have shown that GTH II was not detectable in plasma at this stage. During 1989, pituitary GTH I concentrations were 50- to 70-fold higher than that of GTH II, and increased, though not significantly, from February through April. Although GTH II was detected in the pituitary by RIA, it is likely that the measurable levels are due to GTH I cross-reaction in the GTH II RIA. Histological examination of the gonads indicated that throughout smoltification the oocytes remained in the perinucleolar stage of oogenesis and the testes were in the spermatogonial stage of spermatogenesis. Although no observable changes in gametogenesis occurred, the changes in brain sGnRH content, plasma GTH I levels, and pituitary GTH content suggest that some changes in the hypothalamic-pituitary axis may occur during smoltification.

Maturational gonadotropin from the African catfish, Clarias gariepinus: purification, characterization, localization, and biological activity

A gonadotropic hormone of the African catfish, Clarias gariepinus, was was purified and chemically characterized. Its biological activity was tested and its localization in the gonadotropic cells of the pituitary demonstrated. An ethanolic extract of 500 pituitaries of adult male and female African catfish was subjected to ion-exchange chromatography on DE-52. The 31- to 38-kDa fraction was further purified on Sephadex G-75. On rpHPLC over an ODS 120T column two major components appeared as single bands after SDS-PAGE. From the amino acid composition and sequence analysis of these fractions, compared with those of salmon and carp GTH II-alpha and salmon GTH II-beta it was concluded that they represent catfish GTH alpha- and II-beta-subunits. The biological activity of the complete hormone (the 31- to 38-kDa fraction from the G-75 column) was tested on the production of 11 beta-hydroxyandrostenedione and 17 alpha-hydroxy-20 beta-dihydroprogesterone by catfish testis in vitro. Polyclonal antibodies were raised against the purified beta-subunit. Immunocytochemical study using these showed them to bind specifically to hypophysial gonadotropic cells. To date only one form of GTH has been demonstrated in the African catfish.

Involvement of cyclic adenosine monophosphate in the stimulation of gonadotropin secretion from the pituitary of the teleost fish, tilapia

The present study examines the involvement of cAMP in the transduction of the short-term effect of gonadotropin-releasing hormone (GnRH) on gonadotropin release in the teleost fish, tilapia. A 5 min pulse of dibutyryl cyclic AMP (dbcAMP; 0.03-3 mM) or forskolin (0.1-10 microM) resulted in dose-dependent surges in tilapia gonadotropin (taGTH) secretion from the perifused pituitary. The initial increase in taGTH in response to dbcAMP (3 mM) occurred within 6 min. The concentration of cAMP in the effluent medium increased about 20-fold after a pulse of [D-Ala6,Pro9-NEt]-luteinizing hormone-releasing hormone (LHRH) (GnRHa; 100 nM). To rule out the possibility that the observed effects were due to stimulation by endogenous GnRH release from intact nerve terminals present in the fragments, further experiments were performed in primary cultures of dispersed pituitary cells. Exposure (30 min) of the cells to forskolin (0.01-1.0 microM) resulted in a dose-dependent increase in taGTH release similar to that achieved by GnRHa (1 pM to 10 nM). Also 8-bromo cAMP (0.01-1.0 mM) evoked a dose-related increase in taGTH release. A 3-fold increase in the release occurred in the presence of isobutylmethylxanthine (IBMX) (0.2 mM), similar to that obtained by GnRHa (1.0 nM) in the absence of IBMX. However, when combined, the increase in taGTH release was 16-fold. Moreover, exposure of the cultured cells to GnRHa (0.1 or 10 nM, 60 min) resulted in a dose-related elevation of intracellular cAMP levels and taGTH release.(ABSTRACT TRUNCATED AT 250 WORDS)

Fundulus heteroclitus gonadotropins. 3. Cloning and sequencing of gonadotropic hormone (GTH) I and II beta-subunits using the polymerase chain reaction

mRNA was isolated from Fundulus heteroclitus pituitaries and used to construct a cDNA library in lambda gt22A. A series of synthetic oligonucleotides, based on conserved regions of teleost gonadotropic hormone (GTH) beta-subunits, were constructed and used as primers in the polymerase chain reaction (PCR) to amplify GTH cDNAs. Appropriate length PCR products were subcloned and sequenced. Eight clones were eventually identified as cDNAs encoding two distinct beta-subunits of F. heteroclitus, GTH I and GTH II. By comparison with known GTH sequences, putative signal sequences of 19 end 21 amino acids and mature beta-subunits of 95 and 115 amino acids were found for GTH I and GTH II, respectively. Both beta-subunits had well conserved cysteine positions when aligned with other members of the glycoprotein family. The elucidation of the complete nucleotide sequences of two types of F. heteroclitus GTH provides definitive proof that in this species there are at least two distinct forms of pituitary GTH analogous to the classical luteinizing hormone-follicle stimulating hormone family.

Effect of salmon gonadotropic hormone on sex steroids in male rainbow trout: plasma levels and testicular secretion in vitro

Male rainbow trout were treated with salmon gonadotropic hormone (GTH) at different stages of the circannual reproductive cycle; spawning fish were also treated with an antiserum against salmon GTH. Injection of GTH led to a several-fold increase of plasma sex steroid levels during spermatogenesis and in the spawning season but was without effect at early stages of testicular development. GTH neutralization during the spawning season was followed by a several-fold decrease of plasma sex steroid levels. During spermatogenesis and in the spawning season, both treatment regimes resulted in an increased sensitivity of testicular explants in response to a subsequent stimulation of steroid secretion in vitro. This up-regulatory response may facilitate and maintain the high sex steroid plasma levels observed during the spawning season. It may also be necessary to allow for concomitant peak values of plasma GTH and sex steroids in the spawning season, a situation difficult to understand within the negative feedback concept. The adaptive capacities of the testicular steroidogenic system indicate that it is not only an effector site for GTH but also an active part of the endocrine system controling reproduction.

Immunocytochemical identification of growth hormone, prolactin, and gonadotropin cells in the pituitary of male plaice (Pleuronectes platessa) during gonadal maturation

Somatotrophs, gonadotrophs, and prolactin (PRL) cells have been demonstrated in male plaice (Pleuronectes platessa) pituitary by immunocytochemistry. All cell types exhibited patterns of activity correlated with gonadal maturity. Immature and maturing male plaice (gonads very small or filling with sperm, stages I and III) had numerous densely staining somatotrophs and PRL cells but only a few weakly stained gonadotrophs. Mature plaice (fish in which sperm could be extruded under light pressure, stage VI) contained two populations of gonadotrophs. The PRL cells of these fish were densely stained and the somatotrophs more lightly stained. Spent plaice (thin, flabby gonads, stage VII) had little or no staining in PRL cells. Somatotrophs and gonadotrophs from these fish stained weakly with the antisera used in the study and, in some fish, vacuoles were observed in areas of the pituitary normally occupied by gonadotrophs.

Properties of common carp gonadotropin I and gonadotropin II

Two gonadotropins, GtH I and GtH II, were extracted with 35% ethanol-10% ammonium acetate, pH 6.1, from female common carp pituitary glands and purified by ion-exchange chromatography on a DE-52 column followed by gel filtration on a Sephadex G-75 column. Molecular weights of GtH I and GtH II as determined by SDS-PAGE were 45,000 and 35,000, respectively. Both GtHs dissociate into two subunits following reduction with beta-mercaptoethanol. These subunits contain different N-terminal amino acids (Tyr and Gly for GtH I; Tyr and Ser for GtH II). GtH I was acid stable and did not dissociate into subunits following treatment with 0.1% trifluoroacetic acid; GtH II readily dissociated into subunits by this treatment. GtH I and GtH II have distinct elution profiles on reverse-phase HPLC. The N-terminal amino acid sequence of the beta-subunit of GtH II was identical to that of common carp maturational GtH described by other workers suggesting that GtH I is a newly identified molecule. This was supported by radioimmunoassay analysis. GtH II and a common carp maturational GtH preparation (F11 cGtH; Peter et al., 1982, J. Interdiscipl. Cycle Res. 13, 229-239) had similar immunological activity in tests with antisera to the beta-subunit of maturational GtH whereas GtH I had low (less than 6%) cross-reactivity. GtH I, GtH II, and F11 cGtH were equipotent in tests with antisera to the alpha-subunit of maturational GtH suggesting these molecules contain a similar alpha-subunit. In vitro bioassays using goldfish revealed that GtH I and GtH II share the same spectrum of biological activities causing stimulation of ovarian and testicular steroidogenesis and induction of oocyte final maturation. The demonstration of two chemically distinct GtHs in common carp is similar to what has been described for chum and coho salmon.

Purification and characterization of maturation-promoting factor in fish

Maturation-promoting factor (MPF) activity has been demonstrated for the first time in fish oocytes. We purified MPF from a 100,000g supernatant of crushed, naturally spawned carp oocytes using four chromatography columns: Q-Sepharose Fast-Flow, p13suc1-affinity Sepharose, Mono S, and Superose 12. The final preparation was purified over 1000-fold with a recovery of about 1%. On Superose 12, MPF eluted as a single peak with an apparent molecular weight of 100 kDa. SDS-PAGE analysis of the active fractions after Superose 12 revealed the presence of four proteins of 33, 34, 46, and 48 kDa. A monoclonal antibody against the PSTAIR sequence of cdc2 kinase recognized the 33- and 34-kDa proteins for which the 46- and 48-kDa proteins are endogenous substrates. The 46- and 48-kDa proteins were recognized by a monoclonal antibody against Escherichia coli-produced goldfish cyclin B, but not by an anti-cyclin A antibody. When oocytes were matured in the presence of 32P, the labeling was seen with the 34-kDa protein, but not with the 33-kDa protein. The 34-kDa protein corresponded to the MPF activity, but the 33-kDa protein did not. These findings indicate that carp MPF is a complex of cdc2 kinase and cyclin B, and further that active MPF contains the phosphorylated form of cdc2 kinase.

Organization and nucleotide sequence of carp gonadotropin α subunit genes

We have used PCR to amplify and align the sequence of two genes encoding cGTH alpha. Both genes comprise four exons and three introns. The organization of cGTH alpha genes is very similar to that of mammalian GTH alpha genes. However, the cGTH alpha genes only span a region of 1.2 kb which is much smaller than those mammalian GTH alpha genes.

Histochemical and immunocytochemical identification of the pituitary cell types in three sciaenid fishes: Atlantic croaker (Micropogonias undulatus), spotted seatrout (Cynoscion nebulosus), and red drum (Sciaenops ocellatus)

The adenohypophysial cell types in three species of sciaenid teleosts were identified using a combination of classical histochemical techniques and immunocytochemistry with antisera raised against piscine and human pituitary hormones. In general greater specificity for the different cell types was observed with antisera to the piscine pituitary hormones than with antisera raised against the human hormones. The distribution of the cell types did not differ significantly among the three species, Atlantic croaker (Micropogonias undulatus), spotted seatrout (Cynoscion nebulosus), and red drum (Sciaenops ocellatus), and was similar to that reported in several other teleosts. A major portion of the rostral pars distalis was composed of acidophilic prolactin cells which showed specific binding to antisera to carp, coho salmon, and chinook salmon prolactins. The acidophilic corticotrops formed cords of cells which bordered the prolactin cells and showed strong immunoreactivity with anti-human ACTH. This antiserum also cross-reacted with the lead hematoxylin-positive cells in the pars intermedia. The acidophilic growth hormone cells were restricted to the dorsal part of the proximal pars distalis in close contact with the neurohypophysis and were specifically bound by anti-carp and anti-chum salmon growth hormone. The basophilic thyrotrops were located in the dorsal-anterior part of the proximal pars distalis and showed strong immunoreactivity to antiserum to the human thyrotropin beta subunit. This antiserum also bound weakly to the basophilic gonadotrops which were concentrated in the ventral part of the proximal pars distalis and also extended posteriorly to form a border around the pars intermedia. Antiserum to croaker maturational gonadotropin, which recognizes two distinct gonadotropins in sciaendis, bound strongly and specifically to the gonadotrops. The gonadotrops were also bound specifically by antisera to the alpha and beta subunits of human luteinizing hormone. Antisera to the beta subunits of two recently isolated coho salmon gonadotropins, GTH-I and GTH-II, failed to bind the gonadotrops strongly or differentially in the three sciaenid species. Consequently, the number of gonadotropin cell types in sciaenid fishes remains unresolved.

Effects of 17 beta-estradiol and carp gonadotropin on vitellogenesis in normal and hypophysectomized European silver female eel (Anguilla anguilla L.) employing a homologous radioimmunoassay for vitellogenin

The European silver eels are at the early stages of vitellogenesis before the marine reproductive migration. Vitellogenesis was induced by 17 beta-estradiol (E2) alone and by a purified carp gonadotropin (cGTH). We studied and compared their effects on plasma vitellogenin (Vg) levels and ovarian yolk contents in female normal (N) and hypophysectomized (H) eels for both treatments. To this purpose an homologous radioimmunoassay (RIA) was established. Eel Vg was purified to homogeneity on 0.1% SDS-Electrophoresis. Native Vg has a molecular weight of 340 +/- 15 kilodalton (kDa) and was partially separated into subunits. The RIA was established with a sensitivity of 1.1 ng and was specific for eel Vg. In control (N and H) silver eels, plasma Vg levels were 0.04 +/- 0.02 microgram/ml and unchanged throughout the experiment. Similarly, yolk was indetectable in control ovarian extracts. E2 treatment increased plasma Vg levels proportionally with time to 783.4 +/- 130.7 micrograms/ml in N eels. The same profile was seen in H eels but terminally the mean value was 36.7 times lower than in N eels (P less than 0.01). Yolk at 0.005 microgram/g in N eels was indetectable in H eels. cGTH treatment gave a biphasic kinetic change: plasma Vg increased within 12 days, peaked at 93.6 +/- 13.0 micrograms/ml at 20 to 24 days, and stabilized to decrease at 40.2 +/- 7.5 micrograms/ml. The gonadosomatic index (GSI) increased alongside the yolk content (980.4 +/- 153.1 micrograms Vg/g). The kinetic profile for H eels was different: a peak was not apparent, rather there was a delayed increase, and at 67 days levels were still 8.23 times lower than in N eels (P less than 0.01). The GSI increased as the yolk content to 202.7 +/- 64.8 micrograms Vg/g ovary showing an ovarian incorporation of Vg in H eels.

Involvement of gonadotropin in the uptake of vitellogenin into vitellogenic oocytes of the rainbow trout, Oncorhynchus mykiss

The effects of two fully characterized, structurally distinct gonadotropins, GtH I and GtH II, on the uptake of vitellogenin (VTG) into oocytes of the rainbow trout, Oncorhynchus mykiss, were investigated both in vivo and in vitro. GtH I, injected into maturing vitellogenic females at a dose of 10 micrograms.kg body wt-1, increased the rate of [3H]VTG uptake into oocytes by more than two-fold, effectively doubling their rate of growth. Ovaries from females similarly treated with GtH II sequestered VTG at rates similar to controls. In vitro, GtH I stimulated VTG uptake in a dose-dependent manner. At a GtH I concentration of 100 ng.ml-1 and above, the rate of VTG uptake was significantly greater than that of the controls and at 1000 ng.ml-1 the rate of uptake was more than doubled. GtH II did not significantly increase VTG sequestration into isolated oocytes at concentrations up to, and including, 1000 ng.ml-1. These data provide the first evidence that GtH I has a primary function in stimulating VTG uptake and strongly support the contention that at least two functionally distinct GtHs occur in fish.

Stimulation of in vitro ovarian estradiol-17 beta synthesis in the rainbow trout by the carbohydrate-poor protein fraction from sockeye salmon pituitary glands

The role of carbohydrate-poor (Con A I) and carbohydrate-rich (Con A II) pituitary protein fractions, isolated from sockeye salmon (Oncorhynchus nerka), were investigated pertaining to in vitro estradiol-17 beta (E2) production by rainbow trout (Oncorhynchus mykiss) ovarian follicles. During the early vitellogenic phase of the reproductive cycle, using defolliculated ovarian follicle preparations (outer epithelium-thecal layer absent), it was demonstrated that the Con A I fraction was capable of increasing E2 production, in the presence of exogenous testosterone (T) as the substrate. Under similar conditions the Con A II fraction (containing the maturational gonadotropin) was inactive. However the Con A II fraction or T, separately, increased E2 production by intact ovarian follicles, whereas the Con A I fraction did not. A mechanism proposed to explain the regulation of ovarian E2 synthesis involves the Con A I fraction enhancing aromatase activity in granulosa cells permitting an increased conversion of T to E2.

Expression of two forms of carp gonadotropin alpha subunit in insect cells by recombinant baculovirus

There are two types of cDNA clones (designated alpha 1 and alpha 2) encoding the alpha subunit of carp gonadotropin. These two cDNAs are derived from different genes and encode proteins that differ by seven amino acid residues (three in the signal peptide and four in the mature polypeptide). Expression of these two cDNAs in insect cells by recombinant baculovirus revealed that the alpha 1 subunit, after noncovalent association with the beta subunit, has the same potency as the native alpha subunit purified from the pituitary. In contrast, the alpha 2 subunit can associate with the beta subunit, but only to form an inactive gonadotropin. Competition of the alpha 2 subunit with the alpha 1 subunit for association with the beta subunit decreases the gonadotropin activity of the alpha/beta complex. In addition, both alpha 1 and alpha 2 subunits are secreted into the culture medium by insect cells and have an apparent molecular mass approximately 5 kDa higher than that of the native alpha subunit. These results indicate that the insect cell-derived alpha 1 subunit is biologically active and that those four amino acid changes in the mature of alpha 2 protein affect the biological activity and thus provide valuable clues for the study of the structure-function relationship of the alpha subunit of glycoprotein hormones.

In vitro effects of arginine vasotocin on testosterone production by testes of rainbow trout (Oncorhynchus mykiss)

The objective of this study was to investigate the effect of arginine vasotocin (AVT) on testosterone (T2) production by the rainbow trout testis in culture. AVT increased T2 production in a dose-dependent manner in immature testes. The maximum response (10 nM AVT) increased T2 production 6-fold over basal (3-6 pg/mg tissue protein). Mature testes did not respond to AVT. Salmon gonadotropin (2.5 nM sGtH, SGA-GtH) stimulated T2 production by both juvenile (5-fold) and mature (11-fold) testes. When AVT (100 nM) was added in addition to salmon gonadotropin (sGtH; from 0.1 to 100 nM), AVT had a stimulatory effect at the submaximal doses of sGtH, but T2 production did not exceed the maximum level obtained with sGtH (100 nM) alone. Isotocin also increased T2 production although to a lesser degree than AVT. The maximum response at 10 nM increased T2 production 4-fold over basal. beta-Endorphin had no effect on T2 production.

Development and validation of a competitive enzyme immunoassay for chum salmon prolactin: a comparison to radioimmunoassay

An enzyme immunoassay (EIA), based on a competitive assay system, for the measurement of prolactin (PRL) in the pituitary of salmonid fishes and of hormone released in medium from incubated pituitary was developed using a rabbit antiserum to chum salmon PRL (PRL, a combination of PRL I and PRL II). Chum salmon PRL was coupled to horseradish peroxidase (HRP). The incubation procedure for the antigen-antibody reaction was analogous to that in the radioimmunoassay (RIA) for PRL. The antibody-bound HRP-PRL was separated by a double antibody method. The enzyme activity in the precipitate was followed by a colorimetric method, in which 2,2'-azinobis(3-ethylbenzothiazoline-6-sulfonic acid) and o-phenylenediamine were used as substrates. PRL, PRL I, and PRL II showed exactly the same competitive curves in the EIA system. PRL (127-158) showed the highest cross-reactivity among the fragments of PRL examined. Low cross-reactivity was seen with other hormones isolated from chum salmon pituitary. The displacement curves for pituitary extracts from several salmonids, including chum salmon, coho salmon, and rainbow trout, were parallel to that of the PRL standard, whereas those from the carp and tilapia showed negligible cross-reactivity. A parallel displacement curve to the PRL standard was also seen with incubation medium of the pars distalis of the chum salmon pituitary. Plasma from chum salmon, coho salmon, and rainbow trout gave nonspecific HRP activity in the EIA. The values of PRL-EIA were significantly correlated (y = 0.99x + 1.06, r = 0.942, P less than 0.05, n = 24) with those obtained in PRL-RIA.(ABSTRACT TRUNCATED AT 250 WORDS)

The development of monoclonal antibodies against salmon (Oncorhynchus kisutch and O. keta) pituitary hormones and their immunohistochemical identification

Monoclonal antibodies (MCAs) directed against several salmon pituitary hormones were generated by the fusion of myeloma cells with spleen cells from mice that had been immunized with either chum salmon (Oncorhynchus keta) growth hormone (GH) or prolactin (PRL), or one of two purified protein preparations from coho salmon (O. kisutch) pituitaries. Hybridoma were cloned by limiting dilution and screened for MCA production using immunohistochemical procedures. MCAs were generated that bound specifically to GH, PRL, or gonadotropic cells. MCAs were generated that bound to either fine granular material or large globular inclusions in the cytoplasm of the "classical" strongly PAS-positive globular gonadotropic cell type found in mature fish. This suggests that these MCAs are directed against gonadotropin II (GTH II). A MCA was also generated that bound both granular and globular material in the globular gonadotrops and granular material in the weakly PAS-positive vesicular gonadotrops in pituitaries from mature fish and to a cell type in immature rainbow trout pituitaries which is tentatively identified as the gonadotropin I (GTH I) cell type. This MCA did not bind to thyrotrops in immature rainbow trout pituitaries.

Cloning and sequence analysis of the cDNA for the pituitary glycoprotein hormone alpha-subunit of the European eel

A cDNA library constructed using mRNAs isolated from pituitary glands of estradiol-treated eels was screened with a cDNA fragment for the rat glycoprotein hormone alpha-subunit. Three out of 10,000 cDNA clones were revealed and subcloned in pUC13 for characterization and sequencing. All three had the same nucleotide sequence except for a single, silent change in the coding sequence for one of them, and for the location of the poly(A) tail. Analysis of the deduced amino acid sequence strongly suggests that these cDNA clones encode the precursor for the eel common glycoprotein hormone alpha-subunit. This precursor would therefore consist of a 93 amino acid apoprotein preceded by a 24 amino acid long signal peptide. Alignment with glycoprotein hormone alpha-subunits from fish and mammals reveals high homology, ranging from 60 to 90%. Particularly, the ten cysteines and the two putative N-linked glycosylation sites were at the same position. Comparison between fish and mammals shows also that two regions are highly conserved, comprising about half of the protein length. This high conservation rate through evolution argues for the importance of these regions in the conservation of biological properties of the alpha-subunits. In contrast, other regions are highly variable and could be responsible for the immunological specificity. Northern blot analysis of pituitary RNA from control and estradiol-treated eels showed that estradiol treatment strongly increases the pituitary content of mRNA encoding the glycoprotein hormone alpha-subunit.

Trout steroidogenic testicular cells in primary culture. I. Changes in free and conjugated androgen and progestagen secretions: effects of gonadotropin, serum, and lipoproteins

Isolated trout steroidogenic testicular cells were cultured for 10-15 days, either mixed with other round cells or after enrichment in interstitial cells. Free and conjugated progestagen and androgen secretions were assayed using specific radioimmunoassays (RIA). Free progesterone, 17 alpha-hydroxyprogesterone (17 alpha-OH-P), 17 alpha-hydroxy,20 beta-dihydroprogesterone (17 alpha,20 beta-OH-P), androstenedione, testosterone (T), and 11-ketotestosterone (11KT) were produced by testicular cells prepared from testes in spermatogenesis and mature testes. Discrete amounts of dehydroepiandrosterone (DHA) and of estradiol were secreted by mixed testicular cells prepared from mature testes, but no estradiol was detected in interstitial cell media. Conjugated androgens were produced by interstitial cells. While the production of progestagens by cells from spermatogenetic and mature testes either remained constant or increased throughout culture duration, those of free and conjugated androgens progressively decreased to low values whatever the components added to the medium. When salmon gonadotropin (s-GtH) was present permanently, androgen (free and conjugated) and progestagen secretions were stimulated for 3 to 4 days. When GtH was present discontinuously (1 day in every 3 days), the sensitivity of the cells was maintained for at least 7 days. While the GtH-stimulated/basal ratio was high for androgens, it was rather low for 17 alpha 20 beta-OH-P as compared to the values obtained with testis fragments. Trout serum (5%) stimulated the secretion of free and conjugated T and 11KT when testes were mature, but not when they were in spermatogenesis, while it stimulated 17 alpha 20 beta-OH-P secretion at the two stages. Total trout lipoproteins (125-500 micrograms/ml) stimulated 17 alpha 20 beta-OH-P secretion by cells from spermatogenetic testes, but not 11KT secretion.

The complete amino acid sequences of alpha subunits of chum salmon gonadotropins

The complete amino acid sequences of alpha subunits of chum salmon (Oncorhynchus keta) gonadotropins (GTHs), GTH I and GTH II, were determined. Subunits were separated by reversed-phase high-performance liquid chromatography. Two alpha subunits, I alpha 1 and I alpha 2, were obtained from GTH I, whereas only one alpha subunit was obtained from GTH II. Sequence analysis revealed that GTH I alpha 2 is identical to GTH II alpha, but distinct from GTH I alpha 1. The I alpha 1 and II alpha consist of 95 and 92 amino acid residues, respectively. GTH I alpha 1 has 72% sequence identity with GTH I alpha 2. The two alpha subunits show approximately 65% sequence identity with bovine alpha subunit. This is the first finding of two chemically distinct alpha subunits from one species.

Salmonid pituitary gonadotrophs. I. Distinct cellular distributions of two gonadotropins, GTH I and GTH II

Using antisera specific for the beta subunits of two distinct coho salmon gonadotropins, GTH I and GTH II, an immunocytochemical study of rainbow trout and Atlantic salmon pituitaries was done. Cells which immunostained with anti-GTH I beta were distributed in the periphery of the glandular cords of the proximal pars distalis (PPD), in close association with somatotrophs. On the other hand, cells immunostained with anti-GTH II beta were located in the central parts of the glandular cords of the PPD. Neither the GTH I-producing nor the GTH II-producing cells stained with antisera against chum salmon growth hormone or the beta subunit of human thyroid-stimulating hormone. Moreover, GTH I and GTH II were localized in distinctly different cells. In no case was colocalization of these GTHs in the same cell observed. Finally, it was concluded that classification of GTH cells as globular and vesicular forms does not reflect the type of hormone produced by the cell, but may reflect differences in the physiological conditions of the cells.

The effect of cortisol on the secretion of sex steroids from cultured ovarian follicles of rainbow trout

In a series of experiments, the effect of cortisol on the ability of rainbow trout (Salmo gairdneri) ovarian follicles to secrete sex steroids in vitro was investigated. The basal rate of secretion of sex steroids (oestradiol and testosterone) was suppressed in a dose-dependent manner by the addition of cortisol to the incubation medium. This suppression was evident using physiological levels of cortisol (less than 100 ng ml-1). The possibility of elevated plasma cortisol levels (due to stress) reducing the reproductive ability of sexually maturing female trout through a direct effect of cortisol on the ovary is discussed.

Molecular cloning and sequence analysis of chum salmon gonadotropin cDNAs

cDNAs encoding alpha and beta subunits of salmon gonadotropins, sGTHI and sGTHII, have been isolated from the cDNA library prepared from salmon pituitary mRNA. sGTHI alpha, sGTHI beta, and sGTHII beta cDNAs encode polypeptides of 114, 137, and 142 amino acids, including signal peptides of 22, 24, and 23 amino acids, respectively. The deduced amino acid sequence for sGTHI alpha revealed rather high homology (66-69%) to mammalian alpha chains, whereas sGTHI beta and sGTHII beta show lower homology (30%) to each other and to mammalian beta subunits. The existence of two distinct beta-subunit cDNAs in the teleost suggests that divergence of the GTH gene took place earlier than divergence of teleosts from the main line of evolution leading to tetrapods.

Pituitary steroids in two teleost species: immunohistological and biochemical studies

Antisera raised against steroid hormones [estradiol-17 beta (E2), testosterone (T), 11 beta-hydroxyandrostenedione (OHA)] were used to localize immunoreactive material in fixed and paraffin-embedded pituitaries of the African catfish and the rainbow trout. Organic extracts of pituitary homogenates were analyzed for steroid hormones by radioimmunoassay and gas chromatography-mass spectrometry (E2 in female catfish only). With the exception of an E2-positive cell type in the catfish neurointermediate lobe, steroid immunoreactivity was found to be restricted to the cytoplasm of adenohypophyseal cells, which were also labeled after incubation with catfish alpha,beta-gonadotropin and salmon gonadotropin antisera, respectively. Steroid levels determined by radioimmunoassay in the catfish ranged between 85 and 628 pg/pituitary, while lower levels (2-8 pg/pituitary) were found in the rainbow trout. E2 was identified by gas chromatography-mass spectrometry at a level of 84 pg/pituitary. The observation that immunolabeling after steroid antiserum incubation is confined mainly to gonadotrops provides morphological evidence for direct steroid effects on this particular cell type.

Role of calcium ions in action of gonadotropin-releasing hormone on gonadotropin secretion in the African catfish, Clarias gariepinus

The aim of the present study was to establish the role of calcium ions in the mechanism of action of gonadotropin-releasing hormone (GnRH) in stimulating gonadotropin (GTH) release in the African catfish, Clarias gariepinus. For that purpose, GTH release from pituitary fragments was monitored in a perifusion system. GTH release, induced by the GnRH analog Buserelin, was strongly diminished in the absence of Ca2+, as well as in the presence of the Ca2+ channel antagonist nifedipine. In addition, the Ca2+ ionophore A23187 stimulated GTH secretion in the absence of GnRH. These results indicate that calcium ions play an intermediate role in the mechanism of action of GnRH in the African catfish.

Seasonal variations in plasma and pituitary levels of gonadotrophin in males and females of two strains of rainbow trout (Salmo gairdneri)

Male and female rainbow trout of an autumn- and a winter-spawning strain were sampled every 28 days over a period of 2 years, starting when they were approximately 6 months old. Plasma and pituitary levels of gonadotrophin (GTH) were measured by a radioimmunoassay that preferentially detected the gonadotrophin referred to as either GTH II or "maturational and ovulatory" GTH. The general pattern of gonadal development and the profile of GTH in plasma and pituitary were similar in the two strains, except that the timing was different. Gonadal development in both sexes began about 9 months before spawning, concomitant with an increase in pituitary GTH content. In both sexes, pituitary GTH levels rose dramatically by about 50,000-fold, peaking at the beginning of spawning. They remained high many months thereafter, before falling slowly. Plasma GTH levels during the reproductive cycle were different in the two sexes. In both sexes plasma GTH levels remained very low and unchanged until shortly before full sexual maturity was reached. GTH levels then rose only slightly in males, but markedly in females. The slightly elevated GTH levels persisted many months in males, throughout the period when they could be stripped of milt, but in females they were elevated only a short time around ovulation. These results suggest that although a GTH II-like gonadotrophin is present in the pituitary gland throughout the period of gonadal growth, it does not appear to be released in any substantial amounts into the blood until near spawning.

The duality of teleost gonadotropins

The duality of salmon gonadotropins has been proved by biochemical, biological, and immunological characterization of two chemically distinc gonadotropins. GTH I and GTH II were equipotent in stimulating estradiol production, whereas GTH II appears to be more potent in stimulating maturational steroid synthesis. The ratio of plasma levels and pituitary contents of GTHs and the secretory control by a GnRH suggest that GTH I is the predominant GTH during vitellogenesis and early stages of spermatogenesis in salmonids, whereas GTH II is predominant at the time of spermiation and ovulation. GTH I and GTH II are found in distinctly separate cells. In trout, GTH I is expressed first in ontogeny, whereas GTH II cells appear coincident with the onset of spermatogenesis and vitellogenesis, and increase dramatically at the time of final reproductive maturation. Comparison of the amino acid sequences of polypeptides and the base sequences of cDNA revealed that salmon GTH I β is more similar to bovine FSHβ than bovine LHβ and salmon GTH II β shows higher homology to bovine LHβ than to bovine FSHβ. The existence of two pituitary gonadotropins in teleosts as well as tetrapods suggests that the divergence of the GTH gene took place earlier than the time of divergence of teleosts from the main line of evolution leading to tetrapods.

Control of gonadotropin release in the Atlantic croaker (Micropogonias undulatus): evidence for lack of dopaminergic inhibition

Gonadotropin (GTH) secretion is known to be under inhibitory dopaminergic control in several species of fish. To investigate whether this is also the case in the Atlantic croaker (Micropogonias undulatus), juvenile and adult croaker were treated with a gonadotropin-releasing hormone analog (des-Gly10D-Ala6Pro9 n ethylamide luteinizing hormone-releasing hormone (LHRHa), 1-100 ng/g body wt) in combination with various dopaminergic drugs (1-20 mg/kg body wt). None of the dopamine antagonists tested, metoclopramide, pimozide, haloperidol, and domperidone, were able to increase plasma GTH levels above those induced by treatment with LHRHa alone and in some cases the gonadotropin response to LHRHa was reduced. The dopamine agonists bromocriptine and apomorphine either had no effect on the normal response to LHRHa or increased it. None of the drugs tested had any detectable effect on GTH levels in the absence of LHRHa. These results provide evidence for a lack of dopaminergic inhibition in the control of GTH secretion in the Atlantic croaker.

Gonadotropins I and II in juvenile coho salmon

The present study was designed to obtain basic endocrine information on GTH I and GTH II in previtellogenic and prespermatogenic coho salmon (immature). Levels of GTH II in pituitary extracts were 6.5 ± 2.0 and 6.7 ± 2.0 pg/μg pituitary protein in male and female fish, respectively. In contrast, the pituitary content of GTH I was approximately 100-fold higher than GTH II (1.302 ± .22 and 1.173 ± .21 ng/μg pituitary protein in male and female fish, respectively). Plasma levels of GTH II in immature salmon were not detectable by RIA whereas plasma GTH I levels were approximately 0.62 ± 0.12 and 0.78 ± 0.13 ng/ml in male and female fish, respectively. Highly purified coho salmon GTH I and GTH II stimulated testicular testosterone production and ovarian estradiol productionin vitro in a similar manner, though GTH II appeared more potent than GTH I. Therefore, it appears that although the salmon pituitary contains predominantly GTH I prior to puberty, the gonad can respond to both GTH I and GTH II.

Purification of maturational gonadotropin from Atlantic croaker (Micropogonias undulatus) and development of a homologous radioimmunoassay

The isolation of a maturational gonadotropin from pituitaries of Atlantic croaker (Micropogonias undulatus), a marine teleost belonging to the order perciformes, is described. A radioimmunoassay has been developed for the measurement of this hormone in blood samples and validation of the assay is presented. The hormone measured is an acidic isoform of GTH and can be detected in the plasma at concentrations from 25 to 0.05 ng/ml. At least one other gonadotropic fraction was detected during the purification. The acidic form of GTH is released from croaker pituitaries after stimulation with luteinizing hormone-releasing hormone analog (LHRHa), both in vivo and in vitro. The GTH is steroidogenic, is active in an in vitro oocyte germinal-vesicle breakdown assay, and is elevated in the blood of fish undergoing LHRHa-induced ovulation.

Steroidogenic activities of two distinct salmon gonadotropins

The effects of salmon gonadotropins, GTH I and GTH II, on production of two major steroid hormones in female salmonid reproduction, estradiol-17 beta and 17 alpha,20 beta-dihydroxy-4-pregnen-3-one (17 alpha,20 beta-diOHprog) were compared using amago salmon (Oncorhynchus rhodurus) intact ovarian follicles in vitro. In addition, the production of 17 alpha-hydroxyprogesterone (17 alpha-OHprog) by thecal layers and 17 alpha,20 beta-diOHprog by granulosa layers in response to GTH I and II was examined during oocyte maturation. Both GTHs enhanced estradiol-17 beta production by midvitellogenic ovarian follicles in a dose-dependent manner; there was no significant difference in potency between GTH I and II. In postvitellogenic follicles, GTH II appeared to be more effective in stimulating 17 alpha,20 beta-diOHprog production than GTH I. GTH II was also found to be more potent than GTH I in stimulating 17 alpha-OHprog production by thecal layers and 17 alpha,20 beta-diOHprog production by granulosa layers in the presence of 17 alpha-OHprog. Thus, GTH II appears to differ from GTH I showing a reproductively high specificity for 17 alpha,20 beta-diOHprog production during oocyte maturation.

The complete amino acid sequences of beta-subunits of two distinct chum salmon GTHs

The complete amino acid sequences of beta-subunits of chum salmon (Oncorhynchus keta) gonadotropin (GTH) I and GTH II were determined. Both GTH I beta and GTH II beta were treated with neuraminidase, and then reduced and carboxymethylated. Both of the modified subunits were digested separately with several endopeptidases. The resulting fragments were purified by reversed-phase high-performance liquid chromatography and subjected to sequence analysis by manual Edman degradation. GTH I beta was a single component consisting of 113 amino acid residues including 12 half-cystine residues. GTH II beta was composed of two variants, both of which consisted of 119 amino acid residues including 12 half-cystine residues and differed from each other by substitutions at only two amino acid residues. The presence of an N-linked glycosylation consensus sequence (Asn-X-Thr) in both GTH I beta and GTH II beta is also proved. GTH I beta has only a 31% sequence identity with GTH II beta and less than 40% with human LH beta and FSH beta, and differed from these beta-subunits in the disulfide alignments. It appeared that GTH II beta is almost identical to the molecule previously characterized as the beta-subunits of maturational GTH from chinook and carp, and more similar to human LH beta (48% identity) than to human FSH beta (38% identity). Thus, the elucidation of the complete amino acid sequences for GTH I beta and GTH II beta firmly establishes that the chum salmon pituitary gland secretes two chemically distinct molecules homologous to LH and FSH of the tetrapods.

Development of salmon GTH I and GTH II radioimmunoassays

Radioimmunoassays (RIAs) for the measurement of two gonadotropins, GTH I and GTH II, in the plasma and pituitary of salmonid fish were developed using a rabbit antiserum to beta-subunits of chum salmon GTH I and GTH II. Intact GTH I and GTH II were used as standards and radioactive competitors. The displacement curves for plasma of salmonids including chum salmon, amago salmon, and rainbow trout were parallel to chum salmon GTH I and GTH II standards. Parallel displacement curves were obtained for pituitary extracts of chum salmon and amago salmon. The cross-reactivities of growth hormone, prolactin, and proopiomelanocortin (POMC)-related hormones were less than 1% in both RIAs. However, cross-reactivities of GTH I in the GTH II RIA and GTH II in the GTH I RIA were 10 and 12%, respectively. Plasma concentrations of both GTHs from salmonids at various stages of reproductive development were compared. In immature rainbow trout of both sexes (males: average (AV) gonadosomatic index (GSI) = 0.05; females: AV GSI = 0.24), plasma levels of GTH I and GTH II were low (less than 2 ng/ml). During prematurational stages of spermatogenesis and vitellogenesis in rainbow trout (males: AV GSI = 0.43; females: AV GSI = 2.8), the predominant GTH in the pituitary and plasma was GTH I. In contrast, plasma concentrations of GTH II were significantly higher than those of GTH I in postovulatory amago and chum salmon. Similarly, pituitary concentrations of GTH II were significantly higher than those of GTH I in postovulatory and spermiating amago salmon and postovulatory chum salmon.(ABSTRACT TRUNCATED AT 250 WORDS)

Isolation and characterization of subunits from two distinct salmon gonadotropins

Two distinct gonadotropins, GTH I and GTH II, isolated from female chum salmon pituitary glands, were separated into subunits by acid treatment and subsequent fractionation on reversed-phase high-performance liquid chromatography. GTH II was completely dissociated in 0.1% trifluoroacetic acid, while GTH I was partially dissociated. The acid-stable form of GTH I exhibited a potency identical to that of GTH I in stimulating estradiol-17 beta production in vitro. Both GTH I and GTH II consist of two dissimilar subunits. One subunit (alpha) is common to both GTHs, has Tyr as its N-terminal residue, and a molecular weight (Mr) of 22K by sodium dodecyl sulfate-polyacrylamide gel electrophoresis after reduction. The other subunit (beta) has a Mr of 17K and an N-terminal residue of Gly for GTH I, whereas GTH II beta is 18K and has an N-terminal residue of Ser, after reduction.