Coexpression of galanin and adrenocorticotropic hormone in human pituitary and pituitary adenomas.

Galanin is a neuropeptide that regulates the secretion of several pituitary hormones, including prolactin (PRL) and growth hormone (GH). Galaninlike immunoreactivity (Gal-IR) and galanin mRNA in the rat anterior pituitary is cell lineage specific, with predominant expression in lactotrophs and somatotrophs. The authors examined the cellular distribution of human Gal-IR in seven normal postmortem pituitaries and 62 pituitary tumors by immunoperoxidase staining. In contrast to the rat, Gal-IR in human anterior pituitaries was present in corticotrophs scattered throughout the gland, but not in lactotrophs, somatotrophs, thyrotrophs, or gonadotrophs. Distinct Gal-IR also was present in hyperplastic and neoplastic corticotrophs in 19 of 22 patients with Cushing's disease. In noncorticotroph cell tumors, unequivocal Gal-IR was present in 5 of 11 GH-secreting tumors associated with clinical acromegaly, 9 of 18 nonfunctioning pituitary adenomas, and 2 of 14 prolactinomas. Of these galanin-positive tumors, four of the five GH-secreting adenomas, six of the nine nonfunctioning adenomas, and both of the prolactinomas also contained adrenocorticotropic hormone immunoreactivity (ACTH-IR). Immunostaining and in situ hybridization on adjacent sections using an 35S-labeled probe complementary to human galanin mRNA demonstrated predominant galanin expression in normal corticotrophs. Immunoelectron microscopy confirmed the presence of Gal-IR in pituitary cells characteristic of corticotrophs in both normal and neoplastic pituitaries. Thus, as in the rat, galanin gene expression in the human pituitary is cell-type specific. Unlike the rat, however, human galanin gene expression is restricted to the corticotroph lineage. Studies of tumors confirmed the observed coexpression of galanin and adrenocorticotropic hormone. The divergent cell type specificity of galanin production in human and rat pituitaries reflects different patterns of gene activation in these two species. In addition, these results suggest that galanin in the human pituitary may participate locally in the regulation of the hypothalamic-pituitary-adrenal axis.     

Hypothalamic input is required for development of normal numbers of thyrotrophs and gonadotrophs, but not other anterior pituitary cells in late gestation sheep

To evaluate the hypothalamic contribution to the development of anterior pituitary (AP) cells we surgically disconnected the hypothalamus from the pituitary (hypothalamo-pituitary disconnection, HPD) in fetal sheep and collected pituitaries 31 days later. Pituitaries ( n = 6 per group) were obtained from fetal sheep (term = 147 ± 3 days) at 110 days (unoperated group) of gestation and at 141 days from animals that had undergone HPD or sham surgery at 110 days. Cells were identified by labelling pituitary sections with antisera against the six AP hormones. Additionally, we investigated the colocalization of glycoprotein hormones. The proportions of somatotrophs and corticotrophs were unchanged by age or HPD. Lactotrophs increased 80% over time, but the proportion was unaffected by HPD. Thyrotrophs, which were unaffected by age, increased 70% following HPD. Gonadotrophs increased with gestational age (LH+ cells 55%; FSH+ cells 19-fold), but this was severely attenuated by HPD. We investigated the possible existence of a reciprocal effect of HPD on multipotential glycoprotein-expressing cells. Co-expression of LH and TSH was extremely rare (< 1%) and unchanged over the last month of gestation or HPD. The increase of gonadotrophs expressing FSH only or LH and FSH was attenuated by HPD. Therefore, the proportions of somatotrophs, lactotrophs and corticotrophs are regulated independently of hypothalamic input in the late gestation fetal pituitary. In marked contrast, the determination of the thyrotroph and gonadotroph lineages over the same time period is subject to complex mechanisms involving hypothalamic factors, which inhibit differentiation and/or proliferation of thyrotrophs, but stimulate gonadotrophs down the FSH lineage. Development of a distinct population of gonadotrophs, expressing only LH, appears to be subject to alternative mechanisms.     

Glycoconjugate localization with lectin and PA-TCH-SP cytochemistry in rat hypophysis

Glycoconjugates were localized by light microscopy with lectin-peroxidase conjugates and by electron microscopy with the periodic acid-thiocarbohydrazide-silver proteinate (PA-TCH-SP) sequence in immunocyto-chemically or morphologically identified cell types in rat pituitary. Lectin histochemistry demonstrated sialic acid and glycoconjugates with N-glycosidically linked oligosaccharides in gonadotrophs, thyrotrophs, and corticotrophs. Galactose penultimate to sialic acid was observed mostly in gonadotrophs. The terminal galactose-N-acetylgalactosamine disaccharide was detected in a few gonadotrophs and in a moderate number of mammotrophs. Fucose was localized in only corticotrophs with two fucose-binding lectins and in thyrotrophs with another. Several different monosaccharides were seen in glycoconjugates in melanotrophs and in Herring bodies. Melanotrophs displayed heterogeneous staining with fucose-binding lectins. A small number of nonsecretory cells were also visualized in the pars distalis by virtue of their glycogen content. PA-TCH-SP staining revealed complex carbohydrates in secretory granules and some Golgi cisternae in all types of hormone-producing cells in the pars distalis except for the somatotrophs. Melanotrophs of pars intermedia exhibited stained secretory granules and irregular dense bodies containing a stained meshwork. Corticotrophs of the pars distalis lacked the latter bodies, although they from the same glycoprotein precursor hormone as melanotrophs. Lectin conjugates and the PA-TCH-SP sequence stained some groups of secretion granules in Herring bodies, possibly representing vasopressin-containing granules as well as other cell types in the pars nervosa.     

Light bodies in human pituitary adenomas

Summary Light bodies are large cytoplasmic granules originally described in the gonadotrophic cells of the rat pituitary gland. In order to determine whether similar bodies occur in the human anterior pituitary gland, 89 pituitary adenomas and periadenomatous tissue from 20 cases were examined by transmission electron microscopy. Double membrane bound bodies with filamentous internal structure identical to rodent light bodies were identified in 10 hormone-producing adenomas: 5 PRL, 1 PRL-GH, 2 GH, and 2 ACTH-producing tumours. No light bodies were found in the remaining 79 tumours nor in the pituitary cells in periadenomatous tissue from 20 cases. These results show that some human pituitary adenomas may contain light bodies identical to those seen in gonadotrophs of rat pituitary.Abbreviations PRL prolactin - GH growth hormone - ACTH adenocorticotropic hormone - FSH follicle-stimulating hormone - LH luteinizing hormone     

Immunoexpression of Androgen Receptor in the Nontumorous Pituitary and in Adenomas

Little information is available regarding androgen receptor immunoexpression (AR) in the normal and neoplastic human pituitary. Available experimental data links it to primarily gonadotroph cells. We undertook an immunohistochemical study of 41 autopsy-derived normal glands from patients of both sexes and all ages as well as 79 fully characterized pituitary adenomas of all types, the focus being upon AR expression in normal and neoplastic gonadotrophs. Nuclear AR immunoreactivity was noted in gonadotrophs and other normal adeno- and neurohypophysial cells. In addition to its presence in 74% of gonadotroph and 55% of null cell adenomas, lesser proportions of other adenoma types (adrenocorticotropic hormone 50%, prolactin 38%, growth hormone 33%) also exhibited AR immunoreactivity. No staining of thyroid-stimulating hormone adenomas was noted. The physiologic significance of our findings remains to be explored. The literature regarding AR expression in animal and human pituitaries is reviewed.     

Vasoactive intestinal peptide in the human pituitary gland and adenomas. An immunocytochemical study

Recent evidence indicates that vasoactive intestinal peptide (VIP) may be involved in normal pituitary function. Immunocytochemistry was used to localize VIP in human biopsied pituitary adenomas and postmortem anterior pituitary glands. Paraffin sections were immunostained for VIP with the avidin-biotin-peroxidase technique. Strong VIP-like immunoreactivity (VIP-LI) was observed in 16 of 17 prolactinomas, 12 of 14 growth hormone-secreting tumors associated with acromegaly, four of 12 ACTH-secreting tumors, and 14 of 18 nonfunctioning pituitary adenomas. In most cases, VIP was colocalized with the classical pituitary hormones. Six of the 18 nonfunctioning tumors had no demonstrable hormone immunoreactivity; five of these stained strongly for VIP, whereas one was negative. Of 18 normal anterior pituitaries, 12 showed strong diffuse staining for VIP throughout the gland. One pituitary with VIP-LI came from an individual who had undergone pituitary stalk transection. Double-immunoenzyme labeling and immunoelectron microscopy demonstrated VIP-LI in many lactotrophs, scattered thyrotrophs, corticotrophs, and in an occasional gonadotroph. These results suggest the following: 1) VIP is present in more than one cell type in normal and adenomatous human pituitaries; and 2) VIP may be involved in the function and development of pituitary tumors.     

Quantitative morphological analysis of the pituitary gland in protein-calorie malnourished rats

A quantitative analysis of the pituitary gland was conducted to ascertain the effects of protein-calorie malnutrition on the morphology of the somatotrophs, gonadotrophs, thyrotrophs, and corticotrophs. Male rats were fed a low, 8% protein diet from 20 to 50 days of age, while their age-matched controls were given a diet containing 27% protein. The hypophyses were then processed for light microscopic immunocytochemical staining using antibodies to growth hormone, the β subunits of luteinizing hormone and thyroid stimulating hormone, and adrenal corticotrophic hormone. The number of each cell type along with an evaluation of the cell, cytoplasmic, and nuclear areas was conducted using a computerized image analyzer. All of these parameters were reduced significantly in the somatotrophs as a result of the low protein diet, while in the gonadotrophs, the cell, cytoplasmic, and nuclear areas were similarly affected. Smaller cell number, cell area, and nuclear area were noted in the corticotrophs of the malnourished animals, while in the thyrotrophs, only the cell and nuclear areas were reduced. The data demonstrate that each pituitary cell type responds in a unique manner to undernutrition. © 1993 Wiley-Liss, Inc.     

Proliferation and differentiation of pituitary somatotrophs and mammotrophs during late fetal and postnatal periods

Proliferation of somatotrophs and mammotrophs in the rat pituitary during late fetal and postnatal periods up to 4 weeks after birth was quantitatively studied with the double immunostaining of bromodeoxyuridine and the hormones produced by them. Somatotrophs were first detected in 18.5-day fetuses and rapidly increased in number throughout the periods studied. The cells labeled with both anti-BrdU and anti-GH were few in number until shortly before birth and then increased conspicuously during the first 10 days after birth. Mammotrophs were detected at gestational day 19.5 but they were few until the second week after birth, when their number began to increase rapidly. The percentage of the number of the cells double-labeled with both anti-BrdU and anti-GH to all somatotrophs was 8.3% at the most. This was about the same as that of corticotrophs during the late fetal period and that of thyrotrophs in the early postnatal period. In contrast, the percentage of double-labeled cells to all mammotrophs was 3.8% as a maximum, which is lower than the values for somatotrophs, corticotrophs, or thyrotrophs, indicating a smaller contribution of mitosis to mammotroph proliferation. It is possible that this smaller contribution is compensated for by transdifferentiation of cells committed to become the somatotroph lineage. However, coexistence of GH and PRL was not observed in the present material.     

Cellular and functional interactions between gonadotrophs and lactotrophs in pituitary cell cultures

Lactotroph secretory activity is regulated by hypothalamic stimulating and inhibiting factors as well as peripheral endocrine hormones. In addition to this important control domain, the pituitary gland displays an intrinsic regulatory ability through autocrine and paracrine signals. To evaluate the role of gonadotrophs in the regulation of prolactin (PRL) secretion, a comparative study was performed applying two regulatory agents that operate through different physiological mechanisms: gonadotropin-releasing hormone (GnRH), which releases regulatory factors co-localized in secretory granules of gonadotrophs, stimulating PRL secretion from lactotrophs; and angiotensin II (AII), with direct effects on lactotroph secretion through specific receptors. In these studies performed in regular and purified primary pituitary cell cultures from female rats, the lactotrophs comprised the largest population of cells (about 51%), whereas gonadotrophs represented only a small fraction (3%) of the total pituitary cell count. In regular cell cultures treatments with AII and GnRH showed a similar secretory behavior, increasing PRL output 73% and 63%, respectively. The stimulation with GnRH and AII of cell cultures with purified lactotrophs and gonadotrophs provided comparable results, but the response of lactotrophs was significantly higher (106% and 138%, respectively) than that recorded in regular cell cultures. Simultaneous AII treatment with an antipeptide antagonist to AII receptor (AII-antipep) completely blocked the PRL release induced by AII. The co-incubation of cells with GnRH and AII-antipep suppressed the peak of PRL release caused by GnRH, confirming that AII is a paracrine agent released by gonadotrophs stimulated with GnRH. The different secretory behavior of lactotrophs treated with AII and GnRH in both regular and purified cell cultures is indicative of the degree of functional interactions between different pituitary cell types. The present study supplies morphological and functional information on the cell-to-cell interactions, which plays an important role in the intrinsic regulatory control of PRL secretion.     

Ghrelin increases intracellular Ca(2+) concentration in the various hormone-producing cell types of the rat pituitary gland

Ghrelin, isolated from the stomach as an endogenous ligand for the growth hormone secretagogue receptor (GHS-R), has potent growth hormone release ability in vivo and in vitro. Although GHS-R is abundantly expressed in the pituitary gland, there is no direct evidence of a relationship between hormone-producing cells and functional GHS-R in the pituitary gland. The aim of this study was to determine which anterior pituitary cells respond to ghrelin stimulation in male rats. We performed Fura-2 Ca(2+) imaging analysis using isolated pituitary cells, and performed immunocytochemistry to identify the type of pituitary hormone-producing cells. In Fura-2 Ca(2+) imaging analysis, ghrelin administration increased the intracellular Ca(2+) concentration in approximately 50% of total isolated anterior pituitary cells, and 20% of these cells strongly responded to ghrelin. Immunocytochemical analysis revealed that 82.9±1.3% of cells that responded to ghrelin stimulation were GH-immunopositive. On the other hand, PRL-, LH-, and ACTH-immunopositive cells constituted 2.0±0.3%, 12.6±0.3%, and 2.5±0.8% of ghrelin-responding pituitary cells, respectively. TSH-immunopositive cells did not respond to ghrelin treatment. These results suggest that ghrelin directly acts not only on somatotrophs, but also on mammotrophs, gonadotrophs, and corticotrophs in the rat pituitary gland.     

Fine structural features of secretion in adenomas of human pituitary gland

Ultrastructural investigation of 274 human pituitary adenomas and 39 nontumorous adenohypophyses revealed two distinct types of secretion. Exocytosis was characteristic of prolactin cell adenomas, mixed growth hormone-prolactin cell adenomas, acidophil stem cell adenomas, and nontumorous prolactin cells. The second type, termed "transmembrane effusion," was noted in corticotroph, thyrotroph, gonadotroph, undifferentiated cell adenomas, and oncocytomas, as well as nontumorous corticotrophs, thyrotrophs, and gonadotrophs. It differed from that of prolactin cells and resembled diacrine secretion of gastrointestinal gastrin cells and membrane release in the neurohypophysis. In adenomatous and nontumorous growth hormone cells, neither exocytosis nor transmembrane effusion were apparent, hence a third type of release is suggested. Electron microscopic study of release mechanisms is helpful in the differential diagnosis of pituitary adenomas, since discharge of secretory products is not identical in the various tumor types.     

Transdifferentiation of pituitary thyrotrophs to lactothyrotrophs in primary hypothyroidism: case report

Primary hypothyroidism causes adenohypophysial hyperplasia via stimulation by hypothalamic thyrotropin-releasing hormone (TRH). The effect was long thought to simply result in thyroid-stimulating hormone (TSH) and prolactin (PRL) cell hyperplasia, an increase in TSH and PRL blood levels with resultant pituitary enlargement, often mimicking adenoma. Recently, it was shown that transformation of growth hormone (GH) cells into TSH cells takes place in both clinical and experimental primary hypothyroidism. Such shifts from one cell to another with a concomitant change in hormone production are termed "transdifferentiation" and involve the gradual acquisition of morphologic features of thyrotrophs ("somatothyrotrophs"). We recently encountered a unique case of pituitary hyperplasia in a 40-year-old female with primary hypothyroidism wherein increased TSH production was by way of PRL cell recruitment. The resultant "lactothyrotrophs" maintained TSH cell morphology (cellular elongation and prominence of PAS-positive lysosomes) but expressed immunoreactivity for both hormones. No co-expression of GH was noted nor was thyroidectomy cells seen. This form of transdifferentiation has not previously been described.     

An immunoperoxidase study of a human pituitary adenoma associated with Cushing's syndrome

A large endocrine active pituitary adenoma causing a Cushing's syndrome was investigated for the presence of subunits of the corticotropin-lipotropin precursor by immunohistology. A quantitative study revealed immunoreactivity (ir) for ACTH in 87.1% of the adenoma cells, beta-lipotropin-ir in 77.1%, beta-endorphin-ir in 75.3%, alpha-MSH-ir in 22.9% and methionine-enkephalin-ir in 7.8%. The adjacent distal pituitary gland showed a six-fold increase of prolactin-ir cells indicating the release of biologically active endogenous opiates. The strong alpha-MSH-ir within the adenoma cells in contrast to those of the distal pituitary may signify that alpha-MSH was being secreted by the adenoma. The proportions of other endocrine cell types within the anterior pituitary were normal (3.1% corticotrophs, 49.4% somatotrophs, 8.2% gonadotrophs and 7.1% thyrotrophs). 0.5% of the cells of the distal pituitary and 0.1% within the adenoma were VIP-ergic, which may be due to a vasoregularitory system and/or be involved in prolactin release.     

Immunohistochemical localization of chromogranin in human hypophyses and pituitary adenomas

Chromogranin was demonstrated by immunohistochemistry in the cytoplasm of human beta-thyrotropin, human beta-follicle-stimulating hormone-, human beta-luteinizing hormone-, and human alpha-subunit-containing cells of the non tumorous human adenohypophyses. Some surgically removed human beta-thyrotropin-, human beta-follicle-stimulating hormone-, human beta-luteinzing hormone-, and human alpha-subunit-producing pituitary adenomas, as well as some null cell-adenomas, exhibited chromogranin immunoreactivity, whereas adenomas storing human growth hormone, human prolactin, or corticotropin were negative. Chromogranin immunopositivity was variable in extent and intensity; not every glycoprotein-producing cell could be immunostained in the nontumorous adenohypophysis and the majority of chromogranin-containing adenomas showed only focal positivity. No explanation can be offered for this variability. The demonstration of chromogranin by the avidin-biotin-peroxidase technique may be helpful in the immunohistochemical characterization of some glycoprotein hormone-producing pituitary adenomas, as well as null-cell adenomas of the human pituitary.     

Morphology of the pituitary gland in ferrets (Mustela putorius furo) with hyperadrenocorticism

Pituitary tumours are the cause of hyperadrenocorticism in a variety of species, but the role of the pituitary gland in hyperadrenocorticism in ferrets is not known. In this species, the disease is mediated by the action of excess gonadotrophins on the adrenal cortex and is characterized by an excessive secretion of sex steroids. In this study, the pituitary gland of four healthy control ferrets, intact or neutered, and 10 neutered ferrets with hyperadrenocorticism was examined histologically following immunohistochemical labelling for adrenocorticotrophic hormone, alpha-melanocyte-stimulating hormone, growth hormone, thyroid-stimulating hormone, luteinizing hormone, follicle-stimulating hormone, and prolactin. Immunohistochemistry revealed that somatotrophs, thyrotrophs and lactotrophs were the most abundant cell types of the pars distalis of the pituitary gland in the healthy ferrets. The distribution of corticotrophs was similar to that in the dog and man. In ferrets, as in dogs, the melanotrophic cell was almost the only cell type of the pars intermedia. Gonadotrophs were found in the pars distalis of neutered, but not intact ferrets. All the ferrets with hyperadrenocorticism had unilateral or bilateral alterations of the adrenal gland. In addition, in the pituitary gland of two of these ferrets a tumour was detected. These tumours were not immunolabelled by antibodies against any of the pituitary hormones, and had characteristics of the clinically non-functional gonadotroph tumours seen in man. In some of the other ferrets low pituitary immunoreactivity for gonadotrophic hormones was detected, which may have been due to the feedback of autonomous steroid secretion by the neoplastic transformation of the adrenal cortex. It is concluded that initially high concentrations of gonadotrophins resulting from castration may initiate hyperactivity of the adrenal cortex. The low incidence of pituitary tumours and the low density of gonadotrophin-positive cells in non-affected pituitary tissue in this study suggest that persistent hyperadrenocorticism is not dependent on persistent gonadotrophic stimulation.     

Remodeling of Hyperplastic Pituitaries in Hypothyroid us-Subunit Knockout Mice After Thyroxine and 1713-Estradiol Treatment: Role of Apoptosis

Hyperplasia of pituitary thyrotrophs is often associated with hypothyroidism. In this study, the effects of thyroxine and 17β-estradiol on thyrotroph hyperplasia was analyzed using a hypothyroid mouse model resulting from targeted disruption of the glycoprotein hormone α-subunit (αSU) gene, which leads to lack of functional thyroid-stimulating hormone (TSH), luteinizing hormone (LH), and follicle-stimulating hormone (FSH) and underdevelopment of the thyroid and gonads. Thyroxine replacement for 2 mo resulted in a decrease in the relative percent of thyrotrophs and an increase of lactotrophs and somatotrophs numbers to normal values. A twofold increase in the relative percent of gonadotrophs was observed compared to wild-type mouse pitutary. Treatment for 2 mo with 17β-estradiol led to an increase in lactotroph numbers to normal levels, but had no influence on thyrotroph hyperplasia. Rearrangement of the hyperplastic pituitary phenotype after hormonal replacement proceeded without any evidence of pituitary cell necrosis. A slight increase in apoptotic cell death was observed in hormone-treated pituitaries, and this was localized to TSH cells by double-labeling experiments. Chronic thyroxine treatment resulted in increased expression of Bcl-2 protein in hypertrophied pituitary cells, whereas 17β-estradiol increased expression of Bad protein in prolactin cells. These results suggest that apoptotic cell death is involved in reversal of thyrotroph hyperplasia in the presence of thyroid hormone. Thyroxine and 17β-estradiol may influence cell death in this model by regulating expression of the Bcl-2 protein family in a cell-type specific manner.     

Two types of secretory granules in gonadotrophs: discrimination by the simultaneous EM immunocytochemical localization of serotonin and beta-follicle stimulating hormone

The hypothesis that the secretory granules of mammalian gonadotrophs are heterogeneous was tested. Previous studies had shown that all of the granules contain beta-luteinizing hormone (beta-LH) immunoreactivity, and some contain beta-follicle stimulating hormone (beta-FSH) or 5-HT immunoreactivity. Moreover, differential release of beta-LH and beta-FSH has also been demonstrated. In the current study the pituitary glands of mice were investigated immunocytochemically at the ultrastructural level with antisera directed against human growth hormone (GH), beta-LH, beta-FSH, and 5-HT. The immunoreactivities of beta-LH, beta-FSH, and 5-HT were restricted to gonadotrophs. No 5-HT immunoreactivity was seen in somatotrophs, identified by the immunoreactivity of GH in the secretory granules of these cells. Antisera to beta-LH labeled all gonadotroph granules; however, anti-beta-FSH and anti-5-HT sera labeled only subsets of the granules. The proportion of granules labeled could not be increased by doubling the concentration of anti-beta-FSH serum. The incidence of double labeling of granules by antisera to beta-FSH and 5-HT was significantly less than that predicted from the incidence of granule labeling by either reagent alone. It is concluded that beta-FSH and 5-HT immunoreactivities do not co-exist in the same secretory granules of gonadotrophs; therefore, these granules are heterogeneous and there must be at least two types of granules. It is possible that the two types of granules may be responsive to different second messengers, thereby explaining the differential release of LH and FSH.     

Distribution of laminin in the murine pituitary

The distribution and cellular localization of the glycoprotein laminin were investigated by light and electron microscopic immunocytochemistry in the adult murine pituitary gland. Immunoblots confirmed that laminin was the only protein in the pituitary gland of the adult male mouse to react with antilaminin serum. Laminin immunoreactivity was demonstrated at the light microscopic level simultaneously with that of β-follicle stimulating hormone (β-FSH) and β-luteinizing hormone (β-LH). In addition to its distribution is basal laminae, laminin immunoreactivity was coincidently expressed in gonadotrophs with the immunoreactivities of β-FSH and β-LH. Electron microscopic immunocytochemistry was employed on aldehyde-fixed sections embedded in L.R. White. Sites of binding of primary antisera to laminin were identified with affinity-purified secondary antisera directly coupled to 20 nm particles of colloidal gold. Three antisera recognizing laminin were compared and found to result in an identical pattern of immunoreactivity. Laminin was found extracellulary only in formed basal laminae in all three lobes of the pituitary and was not found in extracellular matrices of connective tissue. Laminin immunoreactivity was also found intracellularly in gonadotrophs but in none of the other endocrine or non-endocrine cells of the anterior lobe. Within gonadotrophs, only secretory granules were labeled. The majority, but not all, secretory granules were labeled in each of the gonadotrophs examined, and the proportion of granules labeled with laminin could not be increased by doubling the concentration of anti-laminin serum. Laminin immunocreactivity segregated with the subset of secretory granules containing β-FSH. In contrast, laminin immunoreactivity was absent in the smaller subset of secretory granules that contain serotonin. No secretory granules were labeled within the endocrine cells of the intermediate lobe, nor within secretory granules of neural elements in the posterior lobe.