Ultrastructure,immunohistochemistry and hormone release of pituitary adenomas in relation to prolactin production

Summary Fifteen cases of pituitary adenoma, 14 of which were associated with hyperprolactinemia, were studied by observation and granule morphometry of electron micrographs, immunohistochemistry and sequential observation of in vitro release with regard to hormone production, storage and secretion. Adenoma cells of 6 cases with marked elevation of plasma prolactin were sparsely granulated, showed characteristic ultrastrucures including the presence of small secretory granules, well developed Golgi and rough membranes, misplaced exocytosis, and positive or negative immunostaining for prolactin. These adenomas also showed vigorous release of the hormone into the circulation and/or culture medium. In vitro studies showed that negative immunostaining of adenoma cells did not preclude the production and secretion of the hormone. One densely granulated adenoma containing cells with numerous lactotroph type granules showed moderate release of prolactin into the circulation. In an acromegalic case associated with both high plasma growth hormone and prolactin, some cells were shown by immunohistochemistry to store both hormones. There were 4 adenomas which could not be shown to produce, store and secrete prolactin by any method available.Abbreviations Used in this Paper ACTH adrenocorticotropic hormone - -MSH -melanocyte stimulating hormone - hGH human growth hormone - hPRL human prolactin - LH luteinizing hormone - FSH follicle stimulating hormone - TSH thyroid stimulating hormone - TRH Thyrotropin-releasing hormone This work was supported in part by Grants-in-Aid for Cancer Research (No. 50-14) and for Specific Diseases (Disorder of Hypothalamic and Pituitary System) from the Ministry of Health and Welfare, and for Cancer Research (No. 401034) from the Ministry of Education, Science and Culture, Japan     

In-vitro effects of bromocriptine on isolated pituitary adenoma cells. Ultrastructural and morphometrical studies

3 pituitary adenomas in hyperprolactinemia and 3 GH and prolactin producing tumours were analysed. The adenoma cells were prepared and held in suspension so that they could be treated with bromocriptine (10 ng and 100 ng). At different times after treatment (0.5, 60 and 90 minutes), the cells were fixed and prepared for conventional electronmicroscopy. Electron microscopic photographs were quantitatively analysed by the point counting method. The results were compared to those of an untreated control group. After bromocriptine influence, there was a decrease of the hormone secretion into the supernatant (2 of 3 prolactin producing adenomas). The prolactin secretion was unchanged in all 3 adenomas which produced prolactin and GH, but there was a decrease in the GH production in 1 of these cases. Ultrastructural morphometry revealed the following results: In prolactin producing adenomas, there was a decrease in the number of exocytoses, an increase in the volume density of lysosomes (2 cases) and an increase of the rough endoplasmic reticulum (1 case). The decrease of the "unorganized" cytoplasm was observed in all 3 cases, but was significant only in 1 case. There was a significant increase in secretory granules (1 case). In adenomas which produced prolactin and GH displayed a significant increase of the rough endoplasmic reticulum and of the granules. The outlines of the cellular membranes seemed smoother (1 case). The heterogeneous results may be interpreted as an expression of the reduced hormone secretion (secretory granules, lysosomes), some data are in accordance with the beginning of necrobiotic phenomena (rough endoplasmic reticulum). The decrease of the "unorganized" cytoplasm may be due to a shrinking process.     

Null cell adenoma of the human pituitary

Summary Among 343 surgically-removed pituitary adenomas, 56 tumors were unassociated clinically or biochemically with increased hormone secretion and contained no adenohypophysial hormones by the immunoperoxidase technique, except for 10 cases in which a few scattered cells showed positive immunostaining for -TSH or -FSH, -EH, prolactin and/or -subunit. These tumors were chromophobic adenomas with no PAS, lead hematoxylin or carmoisine positivity and electron microscopy failed to reveal their morphogenesis. The term null cell adenoma of the pituitary is proposed to designate this tumor type. This term recognizes the most obvious features of these tumors: the absence of markers which would permit the disclosure of their cellular origin. Null cells are also found in the nontumorous adeno-hypophysis, suggesting that null cell adenomas derive from preexisting nonneoplastic null cells. The question of whether pituitary null cells are hormonally inactive committed precursors, uncommitted stem cells or dedifferentiated cells remains to be elucidated.This work was supported in part by Grant MA-6349 of the Medical Research Council of Canada and Grant 1 R01 CA 21905-01 awarded by the National Cancer Institute, DHEW     

Light and electron microscopical morphometry of pituitary adenomas in hyperprolactinemia

Two highly differentiated acidophil prolactin-cell adenomas with hyperprolactinemia (group I), 8 large cell chromophobe adenomas with hyperprolactinemia (group II), and 2 small cell chromophobe adenomas (group III), one of which was combined with hyperprolactinemia, were studied immunohistologically. Morphometry was performed on the light- and electron microscopical level. The 11 active adenomas were immunohistologically positive for prolactin, the 12th adenoma with normal prolactin plasma level was negative for prolactin. Light microscopical morphometry displayed significantly more cells of smaller size in the "small cell chromophobe" adenomas, whereas the large cell chromophobe adenomas and the highly differentiated prolactin cell adenomas were not different. Ultrastructural morphometry demonstrated significant differences between highly differentiated prolactin cell adenomas (group I), and large cell chromophobe adenomas (group II). The latter contain smaller "relative volumes" of nucleoli and of secretory granules, whereas the rough endoplasmic reticulum, the Golgi fields and the nuclei were not different. Comparison of large cell chromophobe adenomas (group II), and small cell chromophobe adenomas (group III) revealed significantly larger relative volumes of nuclei and of mitochondria but smaller volumes of rough endoplasmic reticulum and of Golgi fields in the small cell chromophobe adenomas. Significant differences between the active and the inactive adenoma of small cell chromophobe type in the group III were not found. In spite of the low quantity of small cell chromophobe adenomas and of acidophil prolactin cell adenomas, our data demonstrate that there exist distinct and significant light microscopical and ultrastructural differences between the three adenoma types.(ABSTRACT TRUNCATED AT 250 WORDS)     

Adenoma of the human pituitary producing growth hormone and thyrotropin

Summary A pituitary adenoma removed by surgery from a 22-year-old man was studied by histology, immunocytology, transmission electron microscopy and immunoelectron microscopy. Clinically, the patient had acromegaly and euthyroidism with elevated blood GH concentrations. Blood TSH and T₄ levels were within the normal range. Histologically, the adenoma was chromophobic and exhibited no PAS, lead hematoxylin, aldehyde thionin or Grimelius silver positivity. By the immunoperoxidase technique GH, -TSH and -subunit but no PRL, ACTH, -endorphin, -FSH or -LH were demonstrated in the adenoma cells. Electron microscopy revealed adenoma cells which were similar to TSH cells and showed no resemblance to GH cells of nontumorous pituitaries or GH-secreting tumors. Immunoelectron microscopy demonstrated GH and -TSH in the secretory granules.It is concluded that pituitary adenomas composed of TSH-like cells may secrete GH, resulting in acromegaly. Production of GH by adenomatous TSH cells cannot be explained on the basis of the one cell- one hormone theory. The question is raised whether bihormonal or multihormonal clones, capable of synthesizing more than one hormone, exist in the human pituitary. These cells are apparently dormant under normal conditions, but in the course of neoplastic transformation may undergo functional dedifferentiation and acquire the ability to produce two or more different hormones.     

Pituitary oncocytoma. Indispensable role of electron microscopy in its identification

Two surgically resected pituitary adenomas that appeared to be chromophobe or poorly granulated acidophil adenomas by light microscopy were correctly identified as oncocytomas by electron microscopy. The tumor cells ahd markedly hyperplastic, moderately pleomorphic mitochondria in the cytoplasm of virtually all cells. Scattered secretory granules were displaced to the periphery of the cytoplasm but the secretion type of pituitary cell remained obscure. Histochemical and immunocytochemical methods imperfectly characterized these unusual tumors. Even though these neoplasms have been considered rare, they are now being recognized more often after ultrastructural study. Eventually their pathobiologic features may be better understood. One of our patients was 24 years old and is the youngest patient, to our knowledge, in whom a pituitary oncocytoma has been documented.     

Ultrastructural examination of the regeneration of the rat adenohypophysis after partial hypophysectomy

Summary Male Wistar rats were partially hypophysectomized and sacrificed at intervals of from 2 days to 1 year following the operation. The resected material was examined under the light microscope and the residual pituitary under the light and electron microscope. Neither regeneration nor an anatomical restoration of the adenohypophysis occurred even one year after partial hypophysectomy. An increased number of small chromophobe stem cells and juvenile chromophil cells were found in the residual pituitary. The amount of mitoses were not significantly increased.The ACTH, FSH and prolactin producing cells demonstrated electron microscopically distinct changes which were interpreted as signs of intensified activity. This can be seen as a functional regeneration to maintain vital pituitary function for the organism.Supported by the Sonderforschungsbereich 34 (Endocrinology) of the Deutsche Forschungsgemeinschaft     

Localization of prolactin in chromophobe pituitary adenomas: study of human necropsy material by immunoperoxidase technique.

In order to identify prolactin-producing tumours in human pituitary glands, 45 chromophobe adenomas, obtained from unselected necropsies, have been studied by various staining procedures including the immunoperoxidase technique for the demonstration of prolactin. The presence of immunoreactive prolactin was revealed in the cytoplasm of the tumour cells in six cases (13%), indicating that the occurrence of prolactin-producing adenomas is not rare. No correlations were established between tumours and clinical history. Two adenomas were detected in female and four in male patients. The age of the patients at necropsy ranged from 28 to 75 years. Three adenomas were associated with disseminated carcinoma, two with fatal liver disease, and one with diabetes mellitus, atherosclerosis, and pyelonephritis. Manifest endocrine symptoms were not disclosed, and endocrine investigations, including measurements of blood prolactin levels, were not undertaken. Thus, direct evidence is lacking as to whether or not these tumours were actively secreting prolactin. In the non-tumorous parts of the anterior lobes the number of prolactin cells was decreased in two cases, suggesting that prolactin released from the adenoma cells suppressed prolactin production in the non-tumorous pituitary. However, the number of prolactin cells of the non-tumorous adenohypophysis seemed to be unchanged in two and increased in another two cases. The present findings conclusively proved the existence of the prolactin-producing adenomas as a distinct entity. These tumours do not stain with acid or basic dyes, they are PAS or thionin negative, and do not contain immunoreactive growth hormone. Thus, by conventional staining procedures they are indistinguishable from other chromophobe adenoma types. Herlant's erythrosin and Brookes' carmoisine methods, claimed spedifically to stain prolactin cells, failed to provide reliable results, hence their use cannot be recommended in tumour identification. Immunoperoxidase staining of prolactin is the only technique which conclusively reveals the presence of immunoreactive prolactin in the cytoplasm of the tumour cells and permits diagnosis. It is proposed that this technique be introduced in pituitary morphological studies. Its application may lead to a better understanding of problems related to prolactin-producing tumours and their secretory activity.     

Electron microscopical morphometry of GH producing pituitary adenomas in comparison with normal GH cells

Summary GH producing adenomas of patients with acromegaly (undifferentiated acidophil adenomas and well differentiated GH cell adenomas) were studied at the ultrastructural level and analysed morphometrically by the point counting method. They were compared with identically prepared GH cells of normal pituitaries from patients undergoing surgery for metastasizing cancer of the prostate. In the well differentiated GH cell adenomas significantly more points were counted on nucleoli, unorganized cytoplasm, rough endoplasmic reticulum, immature secretory granules, Golgi areas and on the plasma membranes, than in normal GH cells. Comparison of normal GH cells with tumour cells in undifferentiated acidophil adenomas demonstrated significantly larger volumes of nuclei, rough endoplasmic reticulum, Golgi fields, immature secretory granules and of the cell membranes, and also of nucleoli and of the mitochondria. Secretory granules and lysosomes were observed more frequently than in normal GH cells. In a comparison of both adenoma types, the well differentiated acidophil adenomas contained significantly larger volumes of the unorganized cytoplasm, secretory granules and of cell membranes, whereas more points were counted on the rough endoplasmic reticulum and on the mitochondria in undifferentiated acidophil adenomas. The differences between the normal GH cells and the GH cell in undifferentiated adenomas (mainly larger nucleoli, larger volumes of the rough endoplasmic reticulum and the lower volumes of secretory granules) indicate a higher secretory activity in the adenomas. The significant differences between the well differentiated and the undifferentiated adenomas (mainly the increased volumes of mitochondria and of the unorganized cytoplasm in the undifferentiated tumours) indicate a lower grade of differentiation and may be interpreted as signs of increased proliferation.This publication contains results from the thesis submitted by Karin Rübenach-Gerz (Hamburg 1986)Dedicated to Prof. Dr. Klaus-Joachim Hempel on the occasion of his 60th birthday     

Prolactin-secreting adenomas. A light and electron microscopical study.

The microscopical and ultrastructural findings in twenty-five prolactin-secreting pituitary adenomas removed by transsphenoidal surgery have been analyzed and compared with previously published cases. Under the light microscope, these adenomas could easily be confused with chromophobe adenomas. However, in eight cases a small number of cells contained erythrosinophilic granules of the type found in prolactin cells. Electron microscopical study of the tumor cells showed scarce secretory granules frequently undergoing exocytosis, a prominent rough endoplasmic reticulum, and a large Golgi area containing immature granules. Cytoplasmic bundles and aggregates of filaments, as well as myelin figures and glycogen within the mitochondria were occasionally found. Comparison with prolactin cells during lactation, in pituitary autografts, and under in vitro stimulation shows that the tumor cells are actively secreting.     

Pituitary adenoma producing thyrotropin and prolactin

Summary A pituitary adenoma with suprasellar extension that had caused hyperthyroidism due to secretion of excess thyrotropin (TSH), as well as mild hyperprolactinemia, was studied with differential staining, immunocytochemistry and electron microscopy. Most cells of the tumor stained lightly with aldehyde thionin, which demonstrates the granules of normal thyrotrops, and immunocytochemically with antiserum to the hormone-specific chain of TSH. A minority of the cells was immunoreactive for prolactin. Electron microscopy revealed light cells interspersed with highly pleomorphic dark cells. Both were sometimes multinucleated, and contained variable numbers of small secretion granules, multiple Golgi complexes, and abundant endoplasmic reticulum.Supported by NIH grant AM-2463Recipient of NIH Research Career Award AM-13,576The technical assistance of Paul Hebl is gratefully acknowledged.     

Heterogeneity of secretory granules of silent pituitary adenomas

Silent pituitary adenomas were compared with hormonally active tumors taking into account the size, number, and ultrastructural characteristics of secretory granules (SG). The study group (a total of 79 primary pituitary adenomas) comprised 27 silent, 21 growth hormone (GH)-producing-, 16 prolactin (PRL)-producing-, 5 GH-PRL-producing- and 10 adrenocorticotropic hormone (ACTH)-producing adenomas. The SG of silent adenomas were significantly smaller than SG in endocrine active adenomas. All hormonally inactive tumors also contained small (mean, 94 nm) specific cytoplasmic granules, designated "silent adenoma granules" (SIG). The fine structural features of the SIG included: a flocculent, granular material occupying an eccentric position in a larger vesicle limited by a double membrane. In the silent adenomas this particular granule was present in up to 90% of the adenoma cells and constituted approximately 10 to 50% of the granules in each cell. These granules were not seen in hormonally active tumors and considered therefore diagnostic of silent pituitary adenomas.     

Argyrophil pituitary tumors showing TSH cells or small granule cells

Summary Among 74 histochemically and ultrastructurally studied pituitary adenomas, 12 apparently chromophobe tumors were characterized by the presence of numerous argyrophil cells. All these argyrophil adenomas failed to reveal presence of GH, prolactin or ACTH cells. Two tumors were found to consist of well granulated cells reacting intensely with anti-TSH antibodies and resembling TSH cells of the normal pituitary. The remaining argyrophil adenomas did not show TSH immunostaining and, with one exception, failed to react with an anti-HCG serum staining gonadotroph cells of human pituitary. They were composed of small, closely apposed cells with small compact or vesicular granules. These tumor cells seem to correspond to some small argyrophil cells found in non-neoplastic pituitary, which differ from TSH cells and from all other types of functionally identified adenohypophyseal cells.     

GH and PRL-producing pituitary adenoma with neuron-like differentiation

A pituitary adenoma with neuron-like differentiation in the sella turcica is reported. Sections of the tumor showed a mixture of adenoma cells, ganglionic cells, and neuropil-like structures by light microscopy. Both pituitary adenoma cells and large cells recognized as ganglionic cells by H&E were strongly immunoreactive for both growth hormone (GH) and prolactin (PRL), which indicated that these large cells had properties similar to those of pituitary adenoma cells. Furthermore, electron microscopy (EM) revealed characteristic low electron-dense secretory granules as well as GH-type large electron-dense secretory granules in adenoma cells, neuropils, and swollen bulbs of neuronal endings, which indicated that these three populations may be of the same origin. Furthermore, we could not find typical cell bodies of ganglionic cells by EM. These results are consistent with a hypothesis that attempts to explain the origin of the neuronal components by the neuronal differentiation of adenoma cells. Thus, the best designation of our tumor may be “pituitary adenoma with neuron-like differentiation.”     

垂体生长激素细胞腺瘤的电镜及免疫电镜观察

24 cases of growth hormone(GH)-producing pituitary adenomas were studied with electron microscopy and immunoelectron microscopy by protein A-gold complex, 6 cases were identified as densely granulated GH adenoma and 15 cases as sparsely granulated GH adenoma, among which 4 cases were proved by immunoelectron microscopy to be containing granules with prolactin(PRL) activity simultaneously. Intracytoplasmic fibrous bodies were often seen in the sparsely granulated cells anyhow, not all those cells with fibrous bodies possess the secretory granules with GH activity, and fibrous bodies were also detected in some PRL cells of certain mixed type adenoma. This suggests that fibrous bodies might not be the specific morphological feature of pituitary growth hormone cell adenomas.     

Alpha-subunit-producing pituitary adenomas

Summary Immunohistological techniques demonstrate the alpha-subunit of glycoprotein hormones in the majority of endocrine-inactive, undifferentiated pituitary adenomas and pituitary oncocytomas. In about one-fifth of endocrine-active adenomas, the alpha-subunit is produced in combination with either adrenocorticotropic hormone or prolactin, and it is found in combination with growth hormone in about half of those adenomas causing acromegaly.Pure alpha-subunit-producing, endocrine-inactive adenomas characteristically have small secretory granules that are destroyed by direct osmium fixation, but are well preserved after prefixation with glutaraldehyde. As only a few atypical prolactinomas show similar secretory granules, and as they display a positive reaction for the alpha-subunit only exceptionally, this ultrastructural feature can serve as a guide to differentiate such adenomas.     

The pathology of nonfunctional pituitary adenomas

The nonfunctional adenomas also known as undifferentiated, null cells, or nonsecretory adenomas are endocrinologically silent neoplasms of the anterior lobe of the pituitary gland. They constitute 50% of all pituitary adenomas in the present report. Most tumors are large, often growing beyond the confines of the sella turcica and characterized anatomically by displacement and compression of the adjacent sellar structures including the optic chiasm, hypothalamus, and third ventricle. Others may be truly invasive when they locally or diffusely infiltrate the adjacent structures. They may grow through the dura and the bone into the cranial cavity and/or the sphenoidal sinus and the nasopharynx or infiltrate one or both cavernous sinuses. Seventy-six adenomas were divided into 48 nononcocytic adenomas and 28 oncocytic adenomas or oncocytomas occurring in older patients. By light microscopy using conventional histologic stains, the majority of nononcocytic tumors were chromophobic. The oncocytomas were slightly acidophilic with a large granular cytoplasm. With the peroxidase-anti-peroxidase (PAP) method with anti-sera for the anterior pituitary hormones, the adenoma cells show no immunostaining. Ultrastructurally, the nononcocytic tumors possess a modest number of small secretory granules but no specific ultrastructural features. The oncocytic tumors are characterized by an excessive number of mitochondria in their cytoplasm. With the PAP method using cytochrome C oxidase antiserum, specific identification of mitochondria can be made. As the nonfunctional adenomas are devoid of anterior pituitary hormones they have been called "null cell" adenomas. However, most of the null-cell adenomas are positive for chromogranin. The diagnosis of nonfunctional adenoma can be suspected clinically when in the absence of signs of hypersecretion of pituitary hormones, there is radiologic evidence of ballooning of the sella and bulging of its diaphragm. An invasive adenoma can be detected by radiologic signs of destruction of the sella turcica and its boundaries or by neurosurgical intervention when there are findings of invasion of the dura, the parasellar, and suprasellar structures.     

Pituitary adenomas with hyperfunction of TSH

Summary In a collection of 564 surgically removed pituitary adenomas, 4 cases were found to have had elevated TSH plasma levels. One of these tumors (case 1) could be classified as a highly differentiated mucoid TSH cell adenoma presenting histochemical reactions typical of, as well as electron microscopical features identical to, normal TSH cells. Immunoenzymatic studies failed to demonstrate TSH in the tumor cells. Two further adenomas (case 2 and 3) were similarly structured in many areas, but showed regions of poorer differentiation in which cells with distinct pleomorphism, irregular secretory granules, increased numbers of ribosomes and a well developed rough endoplasmic reticulum were present. In 10% of the tumor cells GH could be demonstrated immunoenzymatically, but there was no TSH. The fourth adenoma was an undifferentiated acidophilic adenoma showing pleomorphic cells having slight acidophil and partly mucoid granulations. The ultrastructure showed convoluted nuclei, increased numbers of free ribosomes as well as abundant rough endoplasmic reticulum and secretory granules which were different in size and number but distinctly of the TSH cell type. Immunoenzymatically, TSH was found in some cells, with GH in more cells. Endocrinologically, elevated levels of GH were measured in cases 2, 3 and 4 with LH being increased in case 1. Clinical and morphological correlations are discussed.Supported by the Sonderforschungsbereich 34 (Endocrinology) of the Deutsche ForschungsgemeinschaftDedicated to Professor Dr. Gerhard Seifert on the occasion of his 60th birthday     

HGH,PRL and βHCG/βLH gene expression in clinically inactive pituitary adenomas detected by in situ hybridization

Summary Within our surgical collection clinically inactive pituitary adenomas represent 30.7% of all pituitary tumours. To characterize their endocrine activity we studied 40 clinically inactive pituitary adenomas with in situ hybridization (ISH) using cRNA probes labelled with³⁵S encoding growth hormone (GH), prolactin (PRL) and chorionic gonadotrophin (HCG). No tumour was associated with clinical evidence of elevated hormone secretion. A mild hyperprolactinaemia not correlated with hormone or the mRNA content of the cells was interpreted to be incidental in 11 patients. By histological analysis, immunohistochemistry (IH) and electron microscopy the adenomas were diagnosed as small cell chromophobic (n=16) and large cell chromophobic (n=8) adenomas, and oncocytomas (n=16). Gene expression of one or more hormones was identified by ISH in 18 of 40 adenomas in few cells. GH and PRL gene expression was rare (GH mRNA in 3 of 40 tumours and PRL mRNA in 8 of 40 tumours) whereas in 14 of 40 adenomasHCG/LH gene expression was identified in scattered cells. Five of 40 adenomas lacking hybridization signals revealed hormones by IH. The detection of mRNA was accompanied by positive immunostaining for the respective hormones in 72%. The combination of ISH and IH reveals good evidence that the hormones are synthesized in the tumours and not taken up from the serum and stored in the cells. The two methods used together permit a more precise analysis of tumour biology than each alone.Presented in part at the meeting on Non-secreting pituitary adenomas, Uppsala, Sweden, May 1990     

Pituitary choristoma composed of corticotrophs and adrenocortical cells in the sella turcica

A pituitary tumour composed of well-differentiated corticotrophs and adrenocortical cells is reported. Sections of the tumour revealed a mixture of small round cells with amphophilic or basophilic periodic acid-Schiff (PAS)-positive cytoplasm and large spherical and oval cells with abundant, granular, partly vacuolated PAS-negative cytoplasm. The small cells contained type 1 cytokeratin-positive microfilaments, numerous 250–500 nm endocrine-type secretory granules immunoreactive for adenocorticotropic hormone (ACTH) and -lipotropin. The large cells possessed ample cytoplasm filled with abundant vesicular smooth endoplasmic reticulum, numerous mitochondria possessing tubulovesicular cristae and frequent dense bodies. They lacked the features of pituitary endocrine cells or folliculostellate cells and were found to contain a panel of steroidogenic dehydrogenases and hydroxylases. The tumour was classified as a choristoma, in which two distinct cells types, corticotrophs and adrenocortical cells, were mixed. We suggest that, under continued ACTH stimulation, uncommitted stem cells may differentiate into adrenocortical cells. Alternatively, the presence of adrenocortical cells may be the result of heterotopia.