FSH-, LH-, and TSH-expressing cells during development of Sparus aurata L. (Teleostei). An immunocytochemical study.

Follicle-stimulating hormone-like gonadotropin (FSH), luteinizing hormone-like gonadotropin (LH), and thyrotropin (TSH) cells were detected in adult and developing pituitary gland of gilthead seabream. Antisera obtained against the alpha- and beta-subunits of FSH (anti-My FSH) and the beta-subunit of LH (anti-My LHbeta), respectively, of the teleost Mediterranean yellowtail, and an antiserum against the beta-subunit of human TSH (anti-h TSHbeta), were applied to identify and follow these cells during ontogeny using light microscopy. FSH cells were immunoreactive to anti-My FSH serum, LH cells were immunoreactive to anti-My LHbeta and anti-My FSH sera, and TSH cells were immunoreactive to anti-h TSHbeta and anti-My FSH sera. In adult specimens, FSH and LH cells were located in both the proximal pars distalis (ppd) and the pars intermedia (pi) in strands or compact groups and as isolated cells. FSH cells were less numerous than LH cells. Some FSH and LH cells had a vacuolated appearance. TSH cells were mainly arranged as a mass in the anterior ppd, although some isolated cells could also be observed. FSH, LH, and TSH cells appeared at different times during development. FSH cells were observed for the first time in 22-day-old larvae and LH cells in juvenile specimens when the gonad was still undifferentiated. No vacuolated FSH and LH cells were present in larvae or juveniles. TSH cells were observed for the first time at hatching. As the fish developed, FSH, LH, and TSH cells progressively increased in number and showed the same distribution as in adult specimens.

Immunocytochemical demonstration of melanotropic and adrenocorticotropic cells from the gilthead sea bream (Sparus aurata L., Teleostei) by light and electron microscopy: an ontogenic study.

In the pituitary of gilthead sea bream, Sparus aurata, melanotropic (MSH) and adrenocorticotropic (ACTH) cells were identified at the light and electron microscopic levels using rabbit anti-synthetic alphaMSH (MSH) and anti-human ACTH (1-24) (ACTH) sera. The distribution of these cell types was followed from hatching to 48 months. The techniques used included the peroxidase anti-peroxidase (PAP) method, conventional electron microscopy, and an immunogold technique. Using PAP, MSH (immunoreactive to both anti-MSH and anti-ACTH) and ACTH (immunoreactive to anti-ACTH) cells were detected from hatching onward. These cells were distinguished ultrastructurally in 1-day-old larvae. Immunogold labeling was first detected in MSH cells in 5-day-old larvae, while ACTH cells were only immunogold labeled in adults. In newly hatched larvae, MSH cells were located from the middle to the posterior region of the adenohypophysis, while ACTH cells were found in the dorsoanterior region, next to the hypothalamus. At this age, both cell types were scarce. As the fish developed, these cell types progressively increased in number: MSH cells made up a layer surrounding the neurohypophysis (NH) in the pars intermedia (pi), whereas ACTH cells bordered the developing NH in the rostral pars distalis (rpd). From 82 days onward, a few MSH cells were observed in the proximal pars distalis (ppd) next to the pi and some ACTH cells were seen in the ppd next to the rpd. In adult specimens, both MSH and ACTH cells were adjacent to the stellate cells and showed processes and synaptic-like structures. MSH cells exhibited numerous round secretory granules with a granular content and of varying electron density and compactness. These granules were immunogold labeled with anti-MSH serum. Electron-dense secretory granules near the Golgi complex immunoreacted with anti-MSH, anti-ACTH, or with both antisera. ACTH cells exhibited round secretory granules with a homogeneous, high electron-dense core and a narrow, clear halo. These granules immunoreacted with anti-ACTH serum. The main ultrastructural features that characterize the MSH and ACTH cells of adults appeared early during ontogeny. Involutive MSH and ACTH cells were only observed in adult specimens.

Immunocytochemical and ultrastructural characterization of somatolactin cells from the gilthead sea bream (Sparus aurata L., Teleostei): an ontogenic study (from newly hatched to adults).

For the first time, somatolactin (SL) cells have been ultrastructurally identified and characterized during the ontogeny of gilthead sea bream, Sparus aurata, using specimens ranging in age from hatching to 15 months. The SL cells were identified by an immunogold method using anti-cod SL serum. The SL-immunoreactivity was mostly located on the secretory granules of the cells, although some vesicles of variable size and shape with a medium electron-dense content, and some irregular secretory granules and polymorphic or very irregular masses that can arise from the fusion of several secretory granules, also presented immunogold labeling. In adults, the SL cells were mainly found in the pars intermedia, where they were organized in discontinuous cell cords lying against the neurohypophysis or surrounding the neurohypophyseal branches. Some SL cells, however, appeared isolated or in small groups in the pars intermedia, in the proximal pars distalis and, rarely, in the rostral pars distalis. The SL cells were variable in shape, with processes directed towards the neurohypophysis or blood vessels, or intermingling among other adenohypophyseal cells. The secretory granules were mostly round, although some were oval, bilobate or pear-shaped, with a homogeneous, very electron-dense content and a narrow, dense or clear, halo. Different SL cell populations can be distinguished according to secretory granule size. Our findings indicate that SL is stored in the secretory granules and released by exocytosis. SL cells showing involutive features were only found in adults. SL cells can be ultrastructurally identified in one-day-old larvae although similar characteristics to those found in adults can be positively identified only after 4 days. Secretory granules increased in number, size and heterogeneity during development. Synaptic-like structures between axon terminals of the neurohypophysis and the SL cells were found in larvae from one-day-old onwards. In juveniles of 118 days of age, two different populations of secretory granules (immunogold-labeled and non-immunogold-labeled) can be found in the same or different SL cells, findings that suggest the existence of two different molecular forms of SL at this age. There was a clear increase in the complexity of the pituitary gland and in the heterogeneity of the SL cells during development, the latter observation probably reflecting different functional cell stages or production of SL molecules.

Identification of mammosomatotropes, growth hormone cells and prolactin cells in the pituitary gland of the gilthead sea bream (Sparus aurata L., Teleostei) using light immunocytochemical methods: an ontogenetic study.

Growth hormone (GH) and prolactin (PRL) immunoreactivities in the adenohypophysis of Sparus aurata specimens from newly hatched until 48-months-old were detected using the peroxidase-antiperoxidase method. GH cells and PRL cells, and cells that were immunoreactive to both GH and PRL antisera, called mammosomatotropes (MS cells), were found. This is the first report on the identification of MS cells in fish, which were found in newly hatched and older larvae and juvenile specimens. GH and PRL cells appeared from two days after hatching. MS cells were first located in the central region of the adenohypophysis and afterwards in the rostral pars distalis. The GH cells were first identified in the dorsal and ventral areas of the middle-posterior part, and the PRL cells in the ventral region of the middle-anterior part. Later, during development, the sequence of appearance of the GH cells was proximal pars distalis, pars intermedia and rostral pars distalis, while for the PRL cells sequence was rostral pars distalis, proximal pars distalis and pars intermedia. This expansion pattern could be due to a GH- and PRL-cell migration although independent cell differentiation may occur in each region. The present results suggest that GH and PRL cells arise from MS cells at the outset of pituitary development, while MS cells proceed from PRL cells in old larvae and juveniles.

Ontogeny of immunoreactive somatolactin cells in the pituitary of gilthead sea bream (Sparus aurata L., Teleostei).

This is the first report on the identification of somatolactin (SL) cells during the early developmental stages of the teleost fish Sparus aurata. The SL cells were followed from newly hatched until 46 months. SL cells were immunocytochemically identified at light microscopical level with anti-cod SL in the developing pituitary using the peroxidase-antiperoxidase method. SL cells first appeared in newly hatched specimens, in which the pituitary gland lacked the neurohypophysis. They were scarce and located from the middle to the posterior region of the adenohypophysis. As the fish developed, the cells progressively increased in number and surrounded the developing neurohypophysis, which could be distinguised from 12-day-old larvae onwards in the caudal region of the gland. From 51 days onwards, SL cells were found in a discontinuous layer surrounding the neurohypophysis branches that entered the pars intermedia as clustered or isolated cells among non-SL-immunoreactive cells of the pars intermedia, and in the proximal pars distalis. The somatolactin-immunoreactive cells are periodic acid-Schiff-positive only in the adult stages. These data confirm, previous findings concerning the presence of two molecular forms of SL, glycosylated and nonglycosylated, in this species.

Early organization of the pituitary gland in Sparus aurata L. (Teleostei). An ultrastructural study.

The cell organization of the pituitary gland and the relationship between neurohypophysis and adenohypophysis in early developmental stages of the gilthead sea bream, Sparus aurata, were studied by electron microscopy. In newly hatched larvae, the pituitary gland was embedded in the ventral floor of the diencephalon and separated from the hypothalamus by a continuous basal lamina. Elongated mesenchymal cells next to the ventral surface were observed. At this stage, there was no neurohypophysis and the adenohypophysis consisted of undifferentiated endocrine cells with small scarce secretory granules and a few stellate cells, with no distinctive zonation. An incipient neurohypophysis was present in 1-day-old larvae. The first evagination of the neurohypophysis into the adenohypophysis were observed in 2-day-old larvae and developed progressively with age, being deeper in the caudal zone. Two regions in the adenohypophysis, one anterior--the presumptive pars distalis--and one posterior--the presumptive pars intermedia--were found in 2-day-old larvae. Three regions (rostral and proximal pars distalis and pars intermedia) were clearly distinguishable in 4-day-old larvae. The ultrastructural features of the pituitary endocrine cells varied during gland differentiation, with the secretory granules gradually increasing in number and size, accompanying organelle development. Nevertheless, even in the oldest larvae studied (65 days), undifferentiated cells similar to those in the earliest stages were observed. The first blood vessels appeared in the neurohypophysis around 16 days after hatching. During early development, the pituitary gland progressively emerged from the ventral floor of the brain. By 16 days, the principal pattern of the pituitary gland architecture appeared to be established.