Beneficial Immune Effects of Myeloid-Related Proteins in Kidney Transplant Rejection.

Acute rejection is a risk factor for inferior long-term kidney transplant survival. Although T cell immunity is considered the main effector in clinical acute rejection, the role of myeloid cells is less clear. Expression of S100 calcium-binding protein A8 (S100A8) and S100A9 was evaluated in 303 biopsies before and after transplantation from 190 patients. In two independent cohorts of patients with acute rejection (n = 98 and n = 11; mostly cellular rejections), high expression of S100 calcium-binding protein A8 (S100A8) and A9 (S100A9) was related to improved graft outcome. Mechanisms of action of the S100 molecules were investigated. In the graft and peripheral blood cells, S100A8 and S100A9 expression correlated with myeloid-derived suppressor markers. In line with this finding, recombinant S100A8 and S100A9 proteins inhibited maturation and the allogeneic T cell stimulatory capacity of dendritic cells. S100A9 enhanced the production of reactive oxygen species by macrophages, which suppressed T cell activity at low concentrations in the form of hydrogen peroxide. Intragraft S100A8 and S100A9 expression linked to reduced expression of T cell immunity and tissue injury markers and higher expression of immune regulatory molecules. This study sheds new light on the importance of myeloid cell subsets in directing the outcome of T cell-mediated acute rejection.

Data analysis and other considerations concerning the study of precipitation in Al-Mg-Si alloys by Atom Probe Tomography.

Atom Probe Tomography (APT) analysis and hardness measurements were used to characterize the early stages of precipitation in an Al-0.51 at%Mg-0.94 at%Si alloy as reported in the accompanying Acta Materialia paper [1]. The changes in microstructure were investigated after single-stage or multi-stage heat treatments including natural ageing at 298 K (NA), pre-ageing at 353 K (PA), and automotive paint-bake ageing conditions at 453 K (PB). This article provides and a detailed report on the experimental conditions and the data analysis methods used for this investigation. Careful design of experimental conditions and analysis methods was carried out to obtain consistent and reliable results. Detailed data on clustering for prolonged NA and PA treatments have been reported.

Increased metallothionein expression reflects steroid resistance in renal allograft recipients.

Steroid-refractory acute rejection is a risk factor for inferior renal allograft outcome. We aimed to gain insight into the mechanisms underlying steroid resistance by identifying novel molecular markers of steroid-refractory acute rejection. Eighty-three kidney transplant recipients (1995-2005), who were treated with methylprednisolone during a first acute rejection episode, were included in this study. Gene expression patterns were investigated in a discovery cohort of 36 acute rejection biopsies, and verified in a validation cohort of 47 acute rejection biopsies. In the discovery set, expression of metallothioneins (MT) was significantly (p < 0.000001) associated with decreased response to steroid treatment. Multivariate analysis resulted in a predictive model containing MT-1 as an independent covariate (AUC = 0.88, p < 0.0000001). In the validation set, MT-1 expression was also significantly associated with steroid resistance (p = 0.029). Metallothionein expression was detected in macrophages and tubular epithelial cells. Parallel to the findings in patients, in vitro experiments of peripheral blood mononuclear cells from 11 donors showed that nonresponse to methylprednisolone treatment is related to highly elevated MT levels. High expression of metallothioneins in renal allografts is associated with resistance to steroid treatment. Metallothioneins regulate intracellular concentrations of zinc, through which they may diminish the zinc-requiring anti-inflammatory effect of the glucocorticoid receptor.

Sex steroids and their involvement in the cortisol-induced inhibition of pubertal development in male common carp, Cyprinus carpio L.

The onset and regulation of puberty is determined by functional development of the brain-pituitary-gonad (BPG) axis. Sex steroids produced in the gonads play an important role in the onset of puberty. Stress interferes with reproduction and the functioning of the BPG axis, and cortisol has frequently been indicated as a major factor mediating the suppressive effect of stress on reproduction. Prolonged elevated cortisol levels, implicated in stress adaptation, inhibited pubertal development in male common carp (Cyprinus carpio). Cortisol treatment caused a retardation of pubertal testis development and reduced the LH pituitary content and the salmon GnRHa-stimulated LH secretion in vitro. A reduced synthesis of androgens also was observed. These findings suggest that the cortisol-induced inhibition of testicular development and the maturation of pituitary gonadotrophs are mediated by an effect on testicular androgen secretion. In this study, we combined cortisol treatment with a replacement of the testicular steroid hormones (testosterone and 11-oxygenated androgens) to investigate the role of these steroids in the cortisol-induced suppression of pubertal development. The effect of cortisol on spermatogenesis was independent of 11-ketotestosterone, whereas the effect on the pituitary was an indirect one, involving the testicular secretion of testosterone.

Evolutionary development of three gonadotropin-releasing hormone (GnRH) systems in vertebrates.

Gonadotropin-releasing hormone (GnRH) is the neuropeptide that links the brain to the reproductive system. Most vertebrate species express two forms of GnRH, which differ in amino acid sequence, localization, distribution, and embryological origin. The GnRH system in the ventral forebrain produces a species-specific GnRH form and projects toward the gonadotropic cell in the pituitary. The GnRH neurons of this system originate from the olfactory placode and migrate into the brain during early development. The other GnRH system is localized in a nucleus in the midbrain, where large cells express chicken-GnRH-II, of which the function is still unclear. In modern teleosts, a third GnRH system is present in the terminal nerve, which contains salmon GnRH. The three GnRH systems appear at different times during fish evolution. Besides the two accepted lineages in GnRH evolution (of conserved chicken GnRH-II in the midbrain and of mammalian GnRH or species-specific GnRH in the hypophysiotropic system), we propose a third lineage: of salmon GnRH in the terminal nerve.

Development of three distinct GnRH neuron populations expressing two different GnRH forms in the brain of the African catfish (Clarias gariepinus).

The early development of both the catfish gonadotropin-releasing hormone (cfGnRH)- and the chicken GnRH-II (cGnRH-II) system was investigated in African catfish by immunocytochemistry by using antibodies against the GnRH-associated peptide (GAP) of the respective preprohormones. Weakly cfGnRH-immunoreactive (ir) neurons and fibers were present at 2 weeks after hatching (ph) but only in the ventral telencephalon and pituitary. Two weeks later, cfGnRH fibers and neurons were also observed in more rostral and in more caudal brain areas, mainly in the preoptic area and hypothalamus. Based on differences in temporal, spatial, and morphologic appearance, two distinct cfGnRH populations were identified in the ventral forebrain: a population innervating the pituitary (ventral forebrain system) and a so-called terminal nerve (TN) population. DiI tracing studies revealed that the TN population has no neuronal connections with the pituitary. The cGnRH-II system is present from 2 weeks ph onward in the midbrain tegmentum and only their size and staining intensity increased during development. Based on the comparison of GnRH systems amongst vertebrates, we hypothesize that during fish evolution, three different GnRH systems evolved, each expressing their own molecular form: the cGnRH-II system in the midbrain, a hypophysiotropic GnRH system in the hypothalamus with a species-specific GnRH form, and a salmon GnRH-expressing TN population. This hypothesis is supported by phylogenetic analysis of known GnRH precursor amino acid sequences. We hypothesize, because the African catfish is a less advanced teleost species, that it contains the cfGnRH form both in the ventral forebrain system and in the TN population.

Gonadal steroids and the maturation of the species-specific gonadotropin-releasing hormone system in brain and pituitary of the male African catfish (Clarias gariepinus).

The effect of testosterone (T), 11-ketotestosterone (KT) and estradiol (E(2)) on the development of the catfish gonadotropin-releasing hormone system (cfGnRH) of male African catfish (Clarias gariepinus), at the onset of puberty [between 10 and 12 weeks post hatching (ph)] was investigated. The cfGnRH neurons, located in the ventral forebrain, were visualized by immunofluorescence and their numbers were determined and the amounts of cfGnRH-associated peptide (cfGAP) in the pituitary were measured by RIA. Steroid treatments did not significantly alter the numbers of immunoreactive GnRH neurons. However, T and E(2) caused an increase in the amount of GnRH, demonstrated by the intensity of the immunostaining of GnRH neurons and fibers in the brain and the amount of cfGAP in the pituitary. Treatment with KT, the main circulating androgen in adult male catfish, neither changed the number of cfGnRH neurons, nor elevated the cfGnRH content in the pituitary. In previous experiments with younger, prepubertal fish (2-6 weeks ph), T caused an elevation of the number of cfGnRH neurons to the same level as present in pubertal fish of 12-14 weeks. We conclude that the onset of puberty in the male African catfish coincides with the completion of the steroid-dependent structural maturation of the cfGnRH system in the brain. T and/or E(2), however, are still able to exert a positive influence on the amounts of cfGnRH during the later stages of pubertal development, thus still playing a role in the control of the cfGnRH system.

Gonadotropin-releasing hormone fibers innervate the pituitary of the male African catfish (Clarias gariepinus) during puberty.

The development of the catfish gonadotropin-releasing hormone (cfGnRH) fiber network in the pituitary of male African catfish (Clarias gariepinus) was investigated in relation to puberty. Double immunolabeling studied by confocal laser scanning microscopy revealed a concomitant development of gonadotropes and of pituitary cfGnRH innervation during the first wave of spermatogenesis. Catfish GnRH-immunoreactive fibers in the proximal pars distalis (PPD) of the pituitary were initially observed at the age of 10 weeks (onset of spermatogonial proliferation) and gradually reached the adult pattern at the age of 20 weeks (spermatozoa present in the testis). The content of cfGnRH-associated peptide (cfGAP, part of the prohormone) in the pituitary similarly increased during puberty. At the electron microscopical level, fibers containing cfGAP-ir granules came into close proximity of the gonadotropes at 18 weeks of age. In vitro studies indicated a progressively increasing basal and cfGnRH-stimulated luteinizing hormone (LH) secretion during pubertal development. The LH secretion patterns were similar in response to exogenous cfGnRH (0.1 microM) or to endogenous cfGnRH, the release of which was induced by forskolin (1 microM). Castration experiments demonstrated that the innervation of the pituitary with cfGnRH fibers continued after surgery, accompanied by an increase in the cfGAP levels. However, gonadotrope development was retarded, suggesting a differential regulation of the two maturational processes. Since testosterone stimulates both processes, other testicular factors may also be involved. Puberty-associated changes in LH release patterns appear to reflect changes in the GnRH sensitivity and in the pool of releasable LH, while availability of cfGnRH does not appear to be a limiting factor.

Regulation of steady-state luteinizing hormone messenger ribonucleic acid levels, de novo synthesis, and release by sex steroids in primary pituitary cell cultures of male African catfish, Clarias gariepinus.

Primary pituitary cell cultures from sexually mature adult male African catfish, Clarias gariepinus, were used to study the regulation of LH biosynthesis by sex steroids. The cell cultures were exposed to testosterone (T), estradiol (E(2)), or 5alpha-dihydrotestosterone (DHT), a nonaromatizable analogue of T, and to the likewise nonaromatizable 11-ketotestosterone (KT) and 11beta-hydroxyandrostenedione (OHA), physiologically relevant androgens in fish. Both T and E(2) elevated glycoprotein alpha (GPalpha) and LHbeta steady-state mRNA levels (quantified by RNase protection assay), de novo synthesis (metabolic incorporation of radioactive amino acids and subsequent immune precipitation of LH), and release of preferentially newly synthesized LH, while DHT had no effect. Inhibiting the aromatase activity abolished the stimulatory effects of T. The effects of E(2) on LH mRNA levels and de novo synthesis were dose dependent. Incubation with 10 ng/ml KT elevated GPalpha and LHbeta mRNA levels, while other concentrations of KT or all concentrations of OHA tested had no effect. The amount of newly synthesized LH, on the other hand, was decreased dose-dependently by OHA but not by KT. Since this OHA-induced decrease did not change the specific activity (dpm immune precipitable [(3)H]-LH/ng immune-reactive LH) of LH, we hypothesize that OHA exerted its effect by activating a crinophagic breakdown of secretory granules in catfish gonadotrophs. Electron microscopic examination of gonadotrophs after in vitro exposure to 50 ng OHA/ml revealed that breakdown organelles had increased in size significantly. We conclude that the balanced production of aromatizable (mainly stimulatory) and 11-oxygenated androgens (mainly inhibitory) may be an important factor in regulating the amounts of LH available for secretion in male African catfish.

Cloning and expression of the zebrafish germ cell nuclear factor.

Nuclear orphan receptors are DNA-binding proteins that share the domain structure of the nuclear hormone receptor superfamily, although their ligands are unknown. Members of the nuclear receptor family are involved in the regulation of various developmental and reproductive processes. We have identified such a nuclear orphan receptor in the zebrafish and named it zebrafish germ cell nuclear factor (zfGCNF) based on its high sequence homology to previously described mouse, human, and Xenopus laevis GCNF. Detailed sequence comparison of zfGCNF with mouse, human, and frog GCNF revealed high homologies in the domains conserved in the nuclear receptor family. Homology in the DNA-binding domain is 97% for frog and even 98.5% for mouse and human when compared to the zebrafish sequence. Homology in the E III subdomain of the transactivation/ligand-binding E domain is 100% when compared to the mouse and human sequences. Transcripts of different size were detected by Northern blot analysis in the zebrafish ovary, whereas, in the testis only one transcript was present. In situ hybridization revealed that zfGCNF was predominantly expressed in previtellogenic oocytes in the ovary and in spermatocytes in the testis.

Testosterone accelerates the development of the catfish GnRH system in the brain of immature African catfish (Clarias gariepinus).

The effects of two endogenous steroids on the maturation of the catfish GnRH and the chicken GnRH-II system in the African catfish were investigated. Immature fish (2 weeks of age, which is before sexual differentiation; thus male and female genotypes present) were fed with food pellets containing either testosterone (T), 11beta-hydroxyandrostenedione (OHA) or no steroid (control). After 2 and 4 weeks of treatment, the effects on the two GnRH systems were investigated immunocytochemically, using specific antibodies against the respective GnRH-associated peptides. By means of fluorescence microscopy the number of GnRH perikarya and the cell surfaces were determined. Confocal laser scanning microscopy was applied to verify spatial distribution and staining intensity. After 2 weeks of treatment no difference in any of the parameters between the groups was observed. However, 4 weeks T treatment resulted in significantly more cfGnRH-ir perikarya in the brain compared to the OHA and control groups. In addition, in the T group the number of immunoreactive fibers was markedly higher and the staining of the perikarya and axons was more intense. The distribution of cfGnRH-ir neurons over the ventral forebrain differed between the two age groups: in 4-week-old fish, the largest concentration of neurons was localized in the ventral telencephalon, while 2 weeks later the number of neurons in the supraoptic area had markedly increased, suggesting that the cfGnRH system is still undergoing developmental changes during this period. In 6-week-old fish the average volume of the cfGnRH perikarya (expressed as surface size in the microscopical sections) in both the OHA and the T group was significantly bigger than that in the control group. The cGnRH-II-ir neurons in the midbrain tegmentum showed strong immunoreactivity in all groups, both treated and nontreated. In contrast to the cfGnRH neurons, the staining intensity and the number of cGnRH-II neurons did not change after steroid treatment. The results of this study show that T is able to accelerate the development of the cfGnRH system, whereas OHA has only minimal effects; the cGnRH-II system develops independent from these steroids.

Differences in structure-function relations between nonmammalian and mammalian gonadotropin-releasing hormone receptors.

Mammalian gonadotropin-releasing hormone receptors (GnRH-Rs) differ from other G protein-coupled receptors in lacking the intracellular C-terminus and in showing an exchange of two otherwise highly conserved Asp (D) and Asn (N) residues in transmembrane domains (TMD) 2 and 7, respectively. However, the first GnRH-R characterized from a nonmammalian vertebrate, the African catfish, does contain an intracellular C-terminus and has D residues in TMD 2 and 7. The functional relevance of these structural features was analysed with D90N321, N90D321, N90N321 and C-terminally truncated mutant catfish GnRH-Rs. An antiserum raised against the recombinant extracellular domain of the wild-type catfish GnRH-R detected all mutant receptors at the cell surface of transiently transfected 293T cells. However, only the D90N321 mutant specifically bound GnRHs and activated signal transduction in response to GnRHs; all other mutants were inactive in both respects. We conclude that the catfish GnRH-R differs from the mammalian GnRH-Rs in that both the C-terminal domain and D90 in TMD 2 are important for receptor functioning.

Pituitary gonadotrophs are strongly activated at the beginning of spermatogenesis in African catfish, Clarias gariepinus.

Pituitary gonadotrophs were studied in male African catfish between 1 and 37 wk of age using antisera against the LH subunits for immunohistological and radioimmunological purposes, and cRNA probes for in situ hybridization. Immunoreactive material was already detectable at the earliest age examined. In juveniles, the signal for the common glycoprotein alpha subunit (GP alpha) was stronger than that for the LH beta subunit. Accordingly, an excess of radioimmunoassayable GP alpha 100 times that of LHbeta was recorded in the pituitary. Using in situ hybridization, the mRNAs were detected 7 (GP alpha) and 13 (LHbeta) wk after hatching. Detection of LHbeta mRNA coincided with a 300-fold increase in the pituitary content of LHbeta and intact LH, whereas GP alpha increased only 15-fold. The number of gonadotrophs per pituitary and the amount of LH per gonadotroph also increased strongly. The strong, initial increase in pituitary LH levels was always associated with the presence of spermatocytes. However, in a limited number of cases (3 out of 12 fish), the pituitary LH content was low despite the presence of spermatocytes. The number of gonadotrophs, the staining intensities (reflecting protein and mRNA), and the pituitary LH content kept increasing, although at a reduced rate, until completion of the first wave of spermatogenesis. In view of the excess of GP alpha over LHbeta, we conclude that expression of the two subunits is regulated in part by different mechanisms, and that expression of LHbeta is rate-limiting for the amount of intact LH. The strong activation of the gonadotrophs shortly after meiosis opens the possibility that a signal of testicular origin stimulates LH expression, in particular its beta subunit. In the absence of a FSH-like gonadotropin in catfish, we propose that LH covers all functions requiring gonadotropic regulation in the African catfish.

[A patient with a psychiatric disorder who refuses treatment of a somatic disease]. / Een patiënt met een psychiatrische stoornis die behandeling van een somatische aandoening weigert.

A woman aged 58 had been suffering for 11 years from a rodent ulcer to the face. The patient, who suffered from a delusional disorder associated with a personality disorder not otherwise defined, had all that time refused medical treatment. She was admitted by virtue of the Wet Bijzondere Opnemingen in Psychiatrische Ziekenhuizen (BOPZ; Bill on Compulsory Admission to Psychiatric Hospitals) because of 'major self-neglect with risk of death'; also, substitute permission was obtained from her son for somatic treatment by virtue of the Wet op de Geneeskundige Behandelingsovereenkomst (WGBO; Decree on the Medical Contract). It was found that the ulcer was no longer amenable to treatment.

Testicular responsiveness to gonadotropic hormonein vitro and Leydig and Sertoli cell ultrastructure during pubertal development of male African catfish (Clarias gariepinus).

The gonadotropin (GTH)-stimulated testicular androgen secretionin vitro and the ultrastructure of Leydig and Sertoli cells was studied during the pubertal development in male African catfish. Testicular weight increased from less than 1 mg in the ninth week of age to nearly 600 mg in the 28th week. Immature testes (stage I: spermatogonia) were highly sensitive to GTH and secreted very high amounts of androgens per mg of tissue. The secretion per mg tissue decreased gradually in stages II (spermatogonia and spermatocytes) and III (spermatogonia, spermatocytes, and spermatids), but precipitously in stage IV (all germ cell stages, including spermatozoa). However, due to the testicular weight gain, the total androgen output per pair of testes increased slightly in stage III and strongly in stage IV. The sensitivity to GTH decreased with the appearance of haploid germ cells in stage III. Leydig cells but not Sertoli cells showed the ultrastructural characteristics of steroid producing cells. Leydig cell morphology did not change in stages I-III, while in stage IV, more smooth endoplasmic reticulum was present. The ultrastructural characteristics of Sertoli cells did not change prominently. Thus, spermatogonial multiplication and spermatocyte formation takes place when the testicular steroidogenic system is highly active and responsive to GTH; whereas the differentiation of haploid germ cells is accompanied by a reduced responsiveness to GTH and by the secretion of several-fold lower androgen amounts per mg of tissue.

Expression and distribution of two gonadotropin-releasing hormones in the catfish brain.

The expression of prepro-catfish GnRH mRNA and prepro-chicken GnRH-II mRNA was investigated by means of in situ hybridization. The differential distribution of cells expressing the respective mRNAs was compared with the distribution of cells immunoreactive for (1) catfish (cf) GnRH and chicken (c) GnRH-II and (2) both GnRH-associated peptides (GAPs). It was found that the prepro-cfGnRH mRNA expressing cells were located in the ventral forebrain, with a similar distribution of the cfGnRH- and cfGAP-immunoreactive perikarya. The prepro-cGnRH-II mRNA expressing cells were exclusively located in the midbrain tegmentum, at the same position as a group of large cGnRH-II- and CIIGAP-immunoreactive perikarya. It was concluded that the peptidergic neurons in the ventral forebrain contain cfGnRH, whereas cGnRH-II perikarya are restricted to the midbrain. The proximal pars distalis of the pituitary, containing the gonadotropin cells, is innervated by fibers immunoreactive for both cfGnRH and cfGAP and originating from the cfGnRH neurons in the ventral forebrain. We could, however, not detect fibers innervating the pituitary that were immunoreactive for cIIGAP.

Pubertal development of male African catfish (Clarias gariepinus). Pituitary ultrastructure and responsiveness to gonadotropin-releasing hormone.

Pubertal development was studied in male African catfish by immunocytochemical examination of pituitary gonadotrophs and by monitoring the responsiveness of gonadotropin (GTH) secretion to salmon GnRH analogue (sGnRHa) in vitro. Experiments were carried out with fish from 9 to 28 wk of age. Fish were assigned to four groups, according to the stage of spermatogenesis: I, spermatogonia alone; II, spermatogonia and spermatocytes; III, spermatogonia, spermatocytes, and spermatids; IV, all germ cell stages, including spermatozoa. Basal and sGnRHa-stimulated secretion of the LH-like GTH II increased 3- to 4-fold from stage I to II and from stage II to III, whereas a 15-fold increase was recorded from stage III to IV. The ED50 values of sGnRHa varied between 0.08 and 0.49 nM, stages II and III being less sensitive. The highest dosage of sGnRHa (100 nM) led to a reduction of GTH secretion. In the first three stages, the pituitary secreted large amounts of free alpha-subunit while free GTH II beta-subunit was not detected at any stage of development. Antisera against GTH II and its alpha- and beta-subunits were used for immunocytochemical studies. In stages I and II, two subtypes of gonadotrophs, which differed in the size and labeling intensity of their secretory granules, were present. Both types of granules were immunopositive for the two subunits of GTH II. In stages III and IV, only gonadotrophs of the subtype with the larger granules were found. Globules and irregular, membrane-bound masses (IMs), probably arising through fusion of secretory granules, appeared in the gonadotrophs in stage III and became more prominent in stage IV. Globules and IMs were immunopositive for the beta-subunit but negative for the alpha-subunit. We conclude that the two subtypes of gonadotrophs represent different developmental stages of GTH II-producing cells, as they shared immunolabeling for the alpha- and the beta-subunits of GTH II. The scarcity of GTH II beta-subunit may be rate-limiting for the amount of intact GTH II available for secretion, particularly at early stages of development. In contrast, at more advanced stages when the readily releasable pool of GTH II has greatly increased, the amount of GTH II also appears to be controlled by modification or elimination of the alpha-subunit from globules and IMs.

Two gonadotropin-releasing hormones in the African catfish, Clarias gariepinus: localization, pituitary receptor binding, and gonadotropin release activity.

Two GnRH peptides have recently been identified in brain extracts of the African catfish, chicken-II GnRH ([His5,Trp7,Tyr8]GnRH, cGnRH-II) and catfish GnRH ([His5,Asn8]GnRH, cfGnRH). Using three experimental approaches, we investigated whether both peptides are involved in the regulation of pituitary gonadotropin secretion. First, the presence of cfGnRH and cGnRH-II in the pituitary was studied by biochemical and immunocytochemical techniques, as GnRH reaches the pituitary via axonal transport in teleost fish. Pituitary extracts contained cfGnRH- and cGnRH-II-immunoreactive material, showing the same HPLC retention times as the respective synthetic GnRH peptides; cfGnRH was present in 37-fold higher amounts than cGnRH-II. Using single and double labeling immunocytochemical techniques, both peptides were localized in the same peptidergic nerve fibers and often within the same secretory granules in the vicinity of the gonadotropes. Second, the two peptides were tested for their capacity to induce an increased secretion of the LH-like gonadotropin-II (GTH-II). In vivo studies showed that both GnRHs released GTH-II, but 100-fold higher cfGnRH than cGnRH-II doses were necessary to induce similar increases in circulating GTH-II levels. In vitro experiments using pituitary tissue fragments in a perifusion system also revealed a clearly higher GTH-II-releasing capacity of cGnRH-II compared to that of cfGnRH. Third, the peptides were tested for their ability to displace [125I]salmon GnRH analog ([D-Arg6,Trp7,Leu8,Pro9-NEt] GnRH, sGnRHa), a high affinity GnRH receptor ligand, from catfish pituitary membrane preparations. Chicken GnRH-II competed with [125I]sGnRHa for pituitary GnRH-binding sites, whereas cfGnRH did so only slightly. The present data show that cGnRH-II is the more potent GTH-II secretagogue, although a role for cfGnRH in the regulation of GTH-II secretion cannot be excluded. The high biological activity of cGnRH-II may be related to the regulation of GTH-II secretion surges, such as those associated with spawning, whereas cfGnRH may be involved in regulating moderate changes in GTH-II plasma levels. The peptides' potency differences appear to be related to their different binding affinities for the pituitary GnRH receptor.

GTH-cells in the pituitary of the African catfish, Clarias gariepinus, during gonadal maturation: an immuno-electron microscopical study.

In an ultrastructural immunocytochemical study we investigated the development of the gonadotropic cells in the pituitary of two to six months old male African catfish in relation to testicular development. In this period, pituitary and testicular tissue samples were collected on five occasions (groups I-V). Blood samples could only be taken from the fish in groups III-V. The testicular development was divided in three stages i.e., immature (only spermatogonia, group I), early (spermatogonia and spermatocytes, groups II and III) and advanced (all germ cell stages including spermatozoa, groups IV and V) spermatogenesis. 11-Ketotestosterone blood levels were low, except for the last group. Antisera were raised against the complete catfish α,ßGTH-II, as well as to the separate α- and ß-subunits of catfish GTH-II. In the proximal pars distalis of immature fish, undifferentiated cells, somatotrops, putative thyrotrops (pTSH) and putative gonadotrops (pGTH) were found. In the two latter, secretory granules were labeled with anti-αGTH, but not with anti-ßGTH-II. pTSH- and pGTH-cells were distinguished on the basis of the size of their secretory granules. During early spermatogenesis, two classes of putative gonadotrops could be distinguished. One type had the same immunocytochemical and ultrastructural characteristics as in immature fish; the secretory granules in the second cell type, which was more abundant, were also immunopositive for anti-ßGTH-II. The mean volume of the secretory granules in these GTH-II cells was three times larger than that in the early appearing pGTH-cells. In addition, the later appearing GTH-II cells contained large inclusions, known as globules. These structures labeled with anti-αßGTH-II and with anti-ßGTH-II, but not with anti-αGTH. It is assumed that the globules are involved in a differential storage and/or breakdown of the GTH-II subunits. During advanced spermatogenesis the two gonadotropic cell types could still be distinguished, but the early appearing pGTH-cell type was scarce. The present observations permit the conclusion that the early appearing cells may be GTH-I cells. However, definitive proof about their identity depends on the availability of antibodies or cDNA probes specific for GTH-I.

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.