Human pituitary null cell adenomas and oncocytomas in vitro: effects of adenohypophysiotropic hormones and gonadal steroids on hormone secretion and tumor cell morphology.

Human pituitary null cell adenomas and oncocytomas are not associated with evidence of excess hormone secretion in vivo; their cellular derivation has not been clarified by morphologic investigation. In this study we examined 41 null cell adenomas and 58 oncocytomas in vitro to determine hormone release and its response to several adenohypophysiotropic hormones and gonadal steroids. In vitro, 96/99 tumors released LH, FSH, and/or alpha-subunit of glycoprotein hormones. TSH was released by 11 tumors. GH, PRL, and ACTH were found in small quantities in 11, 8, and 5 tumors, respectively. Only 3 tumors released no detectable hormones. Incubations with test substances were examined at 2- and 24-h periods for up to 72 h. All but 3 of 53 tumors showed marked and persistent increases in the release of LH, FSH, and/or alpha-subunit in response to GnRH in short and long duration experiments. Secretion of LH, FSH, or alpha-subunit was stimulated to more than 150% of control by TRH in 37/48 tumors, by CRH in 10/20, by GRH in 7/20. Estradiol, progesterone, and testosterone increased release of FSH, LH, and/or alpha-subunit in 23/32, 3/12, and 3/12 tumors, respectively, and reduced their release in 6/32, 5/12, and 7/12, respectively. In tumors which showed no response to gonadal steroids, GnRH in combination with estradiol, progesterone, or testosterone yielded the same result as GnRH alone; in tumors inhibited by gonadal steroids, GnRH in combination with one of those substances reduced the response to GnRH. No secretion of GH, PRL, ACTH, or TSH was detected after incubation with GRH, estradiol, CRH, or TRH except in the tumors which initially released GH, PRL, or TSH. Ultrastructural examination of cultured cells from 15 cases revealed morphologic alterations that correlated with changes in hormone release and could be quantified by morphometry. This study represents the largest analysis of hormone production and release in vitro and morphologic correlation of clinically nonfunctioning pituitary adenomas. The responsiveness of gonadotropin secretion by null cell adenomas and oncocytomas to GnRH and gonadal steroids resembles that of gonadotroph adenomas. However, the unexpected increases in gonadotropin release attributable to several other adenohypophysiotropic hormones and the release of multiple hormones suggests that null cell adenomas and oncocytomas may represent neoplasms derived from uncommitted or committed precursor cells that can undergo differentiation towards several cell lines.     

Analysis of hormone secretion by clinically nonfunctioning human pituitary adenomas using the reverse hemolytic plaque assay

The reverse hemolytic plaque assay was used to study hormone release in vitro by seven clinically nonfunctioning human pituitary adenomas associated with no clinical or biochemical evidence of hormone excess. Four of seven tumors were oncocytomas, one a null cell adenoma, and two gonadotroph adenomas based on immunocytochemical and ultrastructural features. In all seven tumors, plaques were formed with antiserum against beta FSH; four produced plaques for beta LH, and five for glycoprotein hormone alpha-subunit. The percentage of plaque-forming cells and the mean size of plaques were smaller than those of clinically functioning adenomas studied for comparison (five GH- and/or PRL-producing adenomas). These results correlated with those of hormone release in tissue culture, immunocytochemistry on paraffin secretions of the tumors, and immunocytochemistry after reverse hemolytic plaque assay. We conclude that clinically nonfunctioning pituitary adenomas release small quantities of hormones, primarily gonadotropins, and that hormone release is attributable to only a small percentage of tumor cells.     

Somatostatin regulation of glycoprotein hormone and free subunit secretion in clinically nonfunctioning and somatotroph adenomas in vitro.

There is increasing evidence that clinically nonfunctioning pituitary tumors produce and secrete glycoprotein hormone and/or free alpha- and beta-subunits. In addition, hypersecretion of free alpha-subunit occurs in up to 37% of patients with somatotroph adenomas. An understanding of glycoprotein hormone regulation is important in developing effective therapeutic strategies for patients with tumors associated with intact glycoprotein hormone and free subunit hypersecretion. We investigated glycoprotein hormone and free subunit secretion by somatostatin in primary dispersed cultures of pituitary tumor cells from 23 patients with pituitary adenomas. Fifteen tumors from patients with clinically nonfunctioning adenomas (group 1) and 8 tumors from patients with somatotroph adenomas and cosecretion of alpha-subunit (group 2) were studied. Cultures were incubated with control or somatostatin-supplemented media for 24 h. Media samples from group 1 tumors were assayed for intact glycoprotein hormones and free alpha- and beta-subunits secretion levels, while media samples from group 2 cultures were assayed for alpha-subunit and GH secretion levels. Significant (P less than 0.05-0.001) inhibition of secretion of 1 or more intact hormones and/or free subunits was found in 10 of the 15 group 1 tumors. SRIF[10(-7) M] suppressed intact gonadotropin secretion in 60% of FSH-producing tumors and 30% of LH-producing tumors. Media concentrations of FSH beta and LH beta were decreased in 31% and 50% of group 1 tumors, respectively, following somatostatin treatment in those tumors which secreted free beta-subunits. alpha-Subunit was secreted by 12 of the 15 tumors, but significant (P less than 0.02-0.01) inhibition by somatostatin was observed in only 2 tumors. In contrast, significant (P less than 0.05-0.001) inhibition of alpha-subunit in the somatotroph adenomas was found in 6 of the 8 tumors. Significant decreases in alpha-subunit were observed only in those tumors where GH was also significantly inhibited by somatostatin. We conclude that 1) somatostatin inhibits intact glycoprotein or free subunit secretion in the majority of clinically nonfunctioning pituitary tumors in vitro and 2) alpha-subunit secretion is suppressed in 17% and 69% of clinically nonfunctioning and somatotroph adenomas, respectively, consistent with a differential regulation of alpha-subunit by somatostatin in these two tumor types.     

Glycoprotein hormone alpha-subunit in pituitary adenomas.

Elevated serum glycoprotein hormone alpha-subunit (alpha-subunit) levels are seen in about one of six patients bearing pituitary adenomas. This finding has particular clinical significance in patients with nonfunctioning pituitary adenomas. Moreover, the measurement of alpha-subunit along with the calculation of the molar ratio between alpha-subunit and TSH, LH, or FSH is helpful in the diagnosis of glycoprotein hormone-secreting pituitary adenomas. Since serum alpha-subunit levels may vary greatly in several physiologic and pathologic conditions, care has to be taken to differentiate abnormal from normal states of alpha-subunit hypersecretion as well as to exclude causes of alpha-subunit overproduction only casually associated with the presence of pituitary tumors.     

Gonadotropin release by clinically nonfunctioning and gonadotroph pituitary adenomas in vivo and in vitro: relation to sex and effects of thyrotropin-releasing hormone, gonadotropin-releasing hormone, and bromocriptine

We studied in vivo hormone levels and in vitro hormone and subunit release in a group of 22 patients who were operated upon because of a clinically nonfunctioning or gonadotroph pituitary adenoma. In vivo, 5 of the 22 patients, all men, had hypersecretion of FSH, LH beta, or alpha-subunit. An elevated ratio of serum alpha-subunit to LH and FSH was found in 6 of 8 women in vivo, although in all 6 women serum LH, FSH, and alpha-subunit levels were low. LH, FSH, alpha-subunit, LH beta, or a combination of these glycoprotein hormones could be demonstrated in 19 of 22 cultured adenomas. We conclude that 1) virtually all clinically nonfunctioning adenomas contain or release gonadotropins or their subunits in vitro; 2) in vivo hypersecretion of these hormones and subunits occurs infrequently, and in this series only in men; 3) an elevated ratio of alpha-subunit to LH and FSH is frequently found in women and may prove to be a useful diagnostic tool; 4) responses to TRH and bromocriptine do not depend on baseline gonadotropin levels, either in vitro or in vivo, implying that the distinction between gonadotroph adenomas and adenomas without hypersecretion of gonadotropins in vivo is absent where hormone dynamics are concerned.     

The effects of bromocriptine, thyrotropin-releasing hormone, and gonadotropin-releasing hormone on hormone secretion by gonadotropin-secreting pituitary adenomas in vivo and in vitro

The characteristics and dynamics of hormone secretion in vivo and in vitro were investigated in six patients with gonadotropin-secreting pituitary adenomas. All six tumors secreted and contained FSH and different combinations of LH, beta-LH, and alpha-subunit. In addition, immunohistochemical examination of the pituitary tumor tissue showed staining with both LH and FSH in three and either LH or FSH in the other three tumors. TRH and GnRH stimulated hormone secretion in vivo and in vitro, and they also increased the hormone content of the cultured tumor cells. Bromocriptine significantly inhibited hormone release and reduced the hormone content of the tumor cells. In vivo, 2.5 mg bromocriptine significantly suppressed plasma hormone levels; the inhibiting effect on alpha-subunit concentrations was in general more marked than that on LH and FSH. We conclude that hormone release by gonadotropin-secreting pituitary adenomas can be stimulated by TRH and GnRH and inhibited by bromocriptine. Most of these tumors synthesize FSH, but there is a wide variation in the production of LH, beta-LH, and alpha-subunits. The sensitivity of hormone release to bromocriptine suggests that chronic therapy with this drug might have a beneficial effect on pituitary tumor size.     

GROWTH HORMONE SECRETING PITUITARY ADENOMAS ARE HETEROGENEOUS IN CELL CULTURE AND COMMONLY SECRETE GLYCOPROTEIN HORMONE α-SUBUNIT

Cell culture methods were used to assess whether human pituitary adenomas secreting GH and associated with clinical acromegaly also secreted the structurally unrelated glycoprotein hormone alpha-subunit. Thirty-two tumours, together with peri-adenomatous tissue from two of them and three normal pituitaries were studied. Anterior pituitary hormones were measured by radioimmunoassay and included PRL, TSH, LH, FSH, and ACTH, as well as GH and alpha-subunit. Normal pituitary tissues secreted all hormones assayed. All 32 tumours secreted GH ranging from 241 to 5556 ng/2 X 10(5) cells/24 h and 12 (37.5%) secreted alpha-subunit in amounts which could not be accounted for by cross-reaction of other hormones or contamination by normal pituitary tissue, and which ranged from 10.3 to 73.5 ng/2 X 10(5) cells/24 h. Ten other tumours also secreted alpha-subunit but in very small amounts, not exceeding 1.8 ng/2 X 10(5) cells/24 h. PRL was secreted from 21 tumours (66%), and small amounts of other hormones, chiefly LH and TSH, were occasionally secreted from tumours. These cell culture studies would suggest that pituitary adenomas causing acromegaly are hormonally heterogeneous and that PRL and glycoprotein alpha-subunit are commonly detected in addition to GH.     

Imbalanced follicle-stimulating hormone beta-subunit hormone biosynthesis in human pituitary adenomas.

Clinically nonfunctioning pituitary adenomas represent approximately 25% of all pituitary tumors. Recent studies using a number of in vitro techniques show that the majority of such tumors produce gonadotropins. Hypersecretion of uncombined gonadotropin subunits by these tumors has also been identified raising the possibility that gonadotropin biosynthetic alterations may occur in neoplastic pituitary tissue. To determine whether underlying intracellular biosynthetic alterations lead to imbalanced secretion of the gonadotropin subunits by such tumors, we investigated 1) steady state gonadotropin-subunit messenger ribonucleic acid (mRNA) levels in tumor tissue from 49 patients with clinically nonfunctioning adenomas, 2) secretion of gonadotropins in dispersed pituitary tumor cultures, and 3) serum concentrations of gonadotropins and free subunits. Northern blots of RNA extracted from surgically obtained pituitary tumor tissue were hybridized with complementary DNA probes for FSH beta, LH beta, and alpha-subunit, and quantitative analysis was done to compare alpha- and beta-subunit biosynthesis in individual tumors. Of these tumors, 47 contained sufficient RNA for Northern analysis and 77% of these tumors contained one or more of the gonadotropin-subunit mRNAs. Steady state alpha-subunit mRNA was detected in 57% of tumors, FSH beta mRNA in 49%, and LH beta in 1 (2%). We found FSH beta mRNA in excess of alpha-subunit mRNA in one-third of tumors, including 9 tumors where alpha-subunit mRNA was undetectable. In cultured cells, FSH beta was secreted in excess of alpha-subunit in 41% of tumors. For those tumors in which both mRNA and culture data were available, FSH beta mRNA and secreted subunit levels were in excess of alpha-subunit in 64% of tumors. We conclude that clinically nonfunctioning pituitary adenomas frequently synthesize excess FSH beta subunit relative to alpha-subunit. This finding is in contrast to previous data in normal pituitary or placental tissue where alpha-subunit is present in excess of beta-subunits at both the mRNA and protein levels. The free-beta-subunit hypersecretion identified in pituitary adenomas may be due to biosynthetic abnormalities intrinsic to neoplastic gonadotrophs.     

The relationship between steroidogenic factor 1 and DAX-1 expression and in vitro gonadotropin secretion in human pituitary adenomas

The orphan nuclear receptors, steroidogenic factor 1 (SF-1) and DAX-1, are involved in gonadotroph differentiation, and SF-1 has been shown to activate the LH-beta and glycoprotein hormone alpha-subunit (alpha GSU) gene promoters. Pituitary adenomas from 34 patients [13 somatotroph tumors, 4 prolactinomas, and 17 clinically nonfunctioning pituitary adenomas (NFPAs)] were enzymatically dispersed and cultured in vitro for 48 h. Tissue culture medium was collected and assayed for LH, FSH, and alpha GSU; messenger RNA was extracted from adherent cells, and expression of SF-1 and DAX-1 messenger RNA was determined by RT-PCR and verified by direct DNA sequencing. The presence of DAX-1 protein in tumor tissue was confirmed by immunocytochemistry. DAX-1 was demonstrated in all NFPAs, 7 of 13 somatotroph tumors and 0 of 4 prolactinomas. SF-1 expression occurred in 8 of 16 NFPAs, 4 of 12 somatotroph tumors, and 1 of 4 prolactinomas. LH secretion in vitro was greater in NFPAs that were SF-1 positive (P < 0.05). Neither FSH secretion nor alpha GSU secretion in vitro were significantly related to the expression of SF-1 or DAX-1. SF-1-positive somatotroph tumors immunostained positively for LH-beta and/or FSH-beta and secreted gonadotropins in vitro. SF-1 expression is associated with the in vitro secretion of LH by NFPAs. A proportion of somatotroph tumors also express SF-1 and DAX-1 and secrete gonadotropin hormones in vitro.     

Gonadotropin and alpha-subunit responses to chronic gonadotropin-releasing hormone analog administration in patients with glycoprotein hormone-secreting pituitary tumors

Pituitary tumors secreting intact glycoprotein hormones (LH, FSH, and TSH) and/or alpha-subunit are being increasingly recognized. Because chronic administration of GnRH analogs decreases gonadotropin secretion in normal subjects, we investigated gonadotropin and alpha-subunit responses to chronic GnRH analog administration in five men with glycoprotein hormone-secreting pituitary tumors. Two patients (patients A and B) received the GnRH agonist analog (D-Trp6-Pro9-NEt-LHRH) for 4 weeks as a daily sc dose (8 micrograms/kg.day). In both, secretion of LH and/or alpha-subunit increased markedly. Subsequently, three patients received a higher analog dose (32 micrograms/kg.day) for a longer duration (8 weeks). One patient with a LH- and FSH-secreting tumor (patient C) had a highly significant (P less than 0.001) fall in serum LH and FSH concentrations; however, alpha-subunit secretion increased. During a subsequent study, when this patient received a lower dose (8 micrograms/kg.day) for 8 weeks, gonadotropin suppression also occurred. In two additional patients who received this dose (32 micrograms/kg.day), it had a persistent agonist effect on FSH beta (patient D) and alpha-subunit secretion (patient E). A marked increase in alpha-subunit secretion occurred in all five patients, regardless of whether basal serum alpha-subunit concentrations were elevated. These patients received the GnRH analog at doses 2-8 times greater than those that suppress gonadotropin secretion in normal men. Serum LH and FSH concentrations decreased in only one patient with a gonadotropin-secreting adenoma. The serum LH and FSH responses to acute GnRH stimulation did not predict the gonadotropin responses to chronic GnRH analog administration. Thus, gonadotropin and alpha-subunit production by most pituitary adenomas is augmented during chronic GnRH analog administration, consistent with defective GnRH desensitization in the adenomatous tissue. Despite the heterogeneous gonadotropin responses to the GnRH analog in these patients, serum alpha-subunit levels increased in all patients, indicating dissociation in the secretion of intact gonadotropins and alpha-subunit.     

Luteinizing hormone-secreting pituitary tumor: biosynthetic characterization and clinical studies

Although gonadotropin-secreting pituitary adenomas are increasingly recognized, tumors secreting only LH are rare. Since gonadotropin production by pituitary adenomas may reflect imbalanced glycoprotein biosynthesis, we studied tumor LH and subunit biosynthesis and secretion in a patient with a LH- and alpha-subunit-producing pituitary tumor. Northern blot analysis of RNA from the tumor revealed the presence of mRNAs encoding both alpha- and beta-subunits of LH with a marked excess of the mRNA encoding LH beta. Analysis of tumor extracts by gel filtration chromatography confirmed an excess of free LH beta relative to free alpha-subunit. Clinical studies demonstrated that the secretion of LH and alpha-subunit by the tumor increased in response to the acute administration of LHRH (100 micrograms, iv) and decreased during a 4-h dopamine infusion (4 micrograms/kg X min). During a 4-week course of LHRH analog (D-Trp6-Pro9-NEt-LHRH) administration, given as a daily sc dose (8 micrograms/kg X day), serum LH and alpha-subunit concentrations increased 7- and 3-fold, respectively, consistent with a chronic agonist effect. Chronic administration of bromocriptine resulted in reduction of serum LH and alpha-subunit levels to normal.     

Normal and tumorous human gonadotropic cells

Gonadotropic cells are scattered in the anterior and tuberal lobes and make up 10 to 20% of the anterior pituitary cells. Having a morphofunctional plasticity, they secrete FSH and LH, most often simultaneously. These hormones are stored together in the granulations. In addition, under the action of regulating factors, especially GnRH, the cells can secrete one hormone or the other, or even the alpha subunit. Gonadotropic adenomas range third in frequency among operated pituitary adenomas (12% in our series). The diagnosis is based on the presence of at least 5% of immunoreactive cells with specific antibodies to gonadotropic hormones. These adenomas are distributed into 3 major types: FSH-LH adenoma, the most frequent one, FSH adenoma and alpha-subunit adenoma. The LH adenoma and the beta FSH and beta LH adenomas are very rare. Tumoral gonadotropic cells lose their morphofunctional differentiation. They also lose, to an extent varying according to the cases, their control mechanisms as well as their capacity of synthesis and excretion of both subunits. The alpha subunit, the oldest one in ontogeny, remains the most often and longest-secreted substance. There is a continuum from the gonadotropic adenoma with high plasma gonadotropins levels to the non-functioning adenoma.     

The immunocytochemical heterogeneity of silent pituitary adenomas

An immunocytochemical study was performed by the indirect peroxidase method on the pituitary tumour of 37 patients with clinical and biological signs of silent adenoma. Antisera were used against human PRL, human GH, ACTH1-24, human ACTH17-39, alpha-melanocyte stimulating hormone (alpha-MSH), human beta-endorphin, alpha-subunit of hCG (hCG-alpha), and beta-subunits of human LH (LH-beta), human FSH (FSH-beta) and human TSH (TSH-beta). Immunostaining in at least 5% of the tumour cell population, with one or more antisera, was present in 13 cases; hCG-alpha immunostaining was the one most frequently observed. Combined immunostaining was found in 7 cases. Exclusive immunostaining was present in 6 cases: 4 with hCG-alpha, 1 with ACTH1-24 and 1 with TSH-beta. It is concluded that a significant number of silent pituitary adenomas show a certain secretory pattern of pituitary hormones or subunits of glycoprotein hormones as revealed by the immunocytochemistry.     

The effects of activin on follicle-stimulating hormone secretion and biosynthesis in human glycoprotein hormone-producing pituitary adenomas

The effects of activin on pituitary FSH biosynthesis have been previously characterized using primary rat pituitary cultures; however, little is known of the effects of activin on FSH biosynthesis and secretion in human pituitary tissue. Production of intact glycoprotein hormones and free subunits is increasingly recognized in pituitary tumors; however, the regulation of gonadotropins in such tumors has not been addressed. We have investigated the effects of human recombinant activin on glycoprotein hormone biosynthesis and secretion in primary cultures of 12 human glycoprotein hormone-producing pituitary adenomas and compared this with the effects of activin in normal rat anterior pituitary cells. In 33% of the human pituitary tumors studied, significant (P less than 0.05) increases in FSH beta secretion occurred in response to incubation with 20 ng/mL activin for 24 h (19-287% stimulation), without changes in the production of intact FSH. A Northern analysis performed on cells derived from one tumor indicated that FSH beta mRNA levels increased 350% after activin treatments; however, FSH secretion did not parallel the mRNA changes. None of the human glycoprotein hormone-producing tumors significantly increased FSH secretion in response to activin. To validate the biological activity of recombinant human activin-A and to confirm time and dose conditions for the human tumor cultures, we also examined its ability to stimulate FSH production in rat pituitary cultures. Activin (20 ng/mL) added to the culture medium significantly increased FSH secretion and steady state levels of FSH beta mRNA after 24 h. These data indicate that some glycoprotein hormone-producing pituitary tumors treated with purified activin have discordant responses of intact gonadotropins and free subunit responses. In contrast to responses in normal rat gonadotrophs, FSH beta biosynthetic pathways may be uncoupled from intact FSH secretion in a subset of glycoprotein hormone-producing pituitary adenomas.     

Gonadotropin-releasing hormone regulates gonadotropin beta-subunit and chromogranin-B messenger ribonucleic acids in cultured chromogranin-A-positive pituitary adenomas

Chromogranin-A-positive pituitary adenomas include glycoprotein hormone-producing adenomas, null cell adenomas, and a few other pituitary adenomas. We studied the effects of GnRH, CRF, dexamethasone, and phorbol 12-myristate 13-acetate on FSH and LH secretion and on FSH beta and chromogranin-A and -B mRNA expression in 10 chromogranin-A-positive adenomas in vitro to analyze the regulation of FSH and chromogranin-A and -B expression in these neoplasms. Most adenomas responded to GnRH stimulation during 7 days in culture with a 2- to 10-fold increase in FSH and LH secretion and a 2- to 7-fold increase in FSH beta mRNA compared to control values. CRF and phorbol 12-myristate 13-acetate also stimulated FSH and LH secretion 2- to 5-fold in five of seven and three of three cases, respectively, during 7 days in culture. Dexamethasone stimulated both FSH and LH secretion in two of three cases as well as FSH beta mRNA in vitro in the one case examined. GnRH treatment consistently produced a 2-fold increase in chromogranin-B mRNA, but not in chromogranin-A mRNA, after 7 days of culture. These results indicate that many chromogranin-A-positive adenomas respond to GnRH and CRF in vitro by increased hormone secretion and that GnRH stimulation leads to increased amounts of FSH beta and chromogranin-B mRNAs. The differential response of chromogranin-A and -B mRNAs after GnRH stimulation indicates that the chromogranin genes are highly regulated in these tumors.     

Gonadotrophin secretion in vitro by cells of a pituitary tumour from a patient with multiple endocrine neoplasia type I

OBJECTIVE: The aim was to investigate the hormone secretory products of a pituitary tumour from a patient with multiple endocrine neoplasia type I (MEN I) utilizing cell culture and immunoassay techniques. DESIGN: Adenoma tissue was enzymically dispersed and established in cell culture. Medium was collected for hormone measurement after 2 days, and also after 24-hour periods during long-term culture. In addition, tissue fixed at surgery was analysed by immunocytochemistry and electron microscopy. PATIENT: The subject was a 59-year-old male with a clinical history characteristic of familial MEN I syndrome. MEASUREMENTS: Pituitary hormones in serum and culture medium were measured by fully characterized radioimmunoassays. RESULTS: Preoperative serum LH and FSH levels were normal, or slightly elevated, and there was a progressively blunted gonadotrophin response to GnRH throughout the 8 years prior to adenomectomy. TRH induced a small, paradoxical increase in serum gonadotrophin levels 2 weeks preoperatively. Post-operative pituitary hormone responses to standard stimulation tests showed an active normal pituitary. In vitro, the pituitary tumour cells secreted only gonadotrophins and glycoprotein hormone alpha-subunit. The fixed tumour tissue immunostained for alpha-subunit alone, and electron microscopy confirmed the presence of secretory granules with diameters of 100-280 nm. Gonadotrophin secretion continued throughout 77 days in long-term culture, but whilst LH was released at a steady rate, that of FSH transiently increased between days 29 and 48 in vitro. CONCLUSIONS: These data demonstrate that a pituitary tumour associated with the MEN I syndrome secreted gonadotrophins in vitro.     

Molecular aspects of pituitary tumorigenesis

Pituitary tumors, almost invariably adenomas, are of frequent occurrence, accounting for 10% to 15% of all the intracranial neoplasm. They are classified as microadenomas (< 10 mm) or macroadenomas (> 10 mm) and as secreting or clinically non-secreting (or not functioning) adenomas. These tumors are autonomously capable to release pituitary hormones such as the growth hormone (GH), prolactin (PRL), adrenocorticotropic hormone (ACTH), thyroid stimulating hormone (TSH), follicle-stimulating hormone (FSH) and luteinizing hormone (LH). The occurrence of metastases, characterizing a pituitary carcinoma, is exceedingly rare. However tumors with aggressive behavior, leading to local invasion, are relatively common. Although the pathogenesis of pituitary tumors is fully characterized, many molecular mechanisms of pituitary tumorigenesis had already been revealed. This review intends to describe advances in the understanding of the involved advances that have been made in the last decade concerning pituitary tumors progression, including the participation of oncogenes, tumor suppressor genes and growth factors.     

Follicle-stimulating hormone-secreting pituitary tumor with concomitant elevation of serum alpha-subunit levels

Hypersecretion of FSH and alpha-subunit was documented in a man with a pituitary adenoma that was previously diagnosed on clinical grounds as nonfunctioning who had been treated by transsphenoidal surgery and postoperative irradiation. Postoperatively, the patient had high serum FSH levels and normal serum, LH levels. Ten years after the surgery, immunostaining of the tumor revealed the presence of beta FSH, beta LH, and beta TSH in the cytoplasm of scattered adenoma cells, although not always in the same cells. LH levels were elevated during the middle portion of the 12 yr that this patient was followed. However, as LH immunoreactivity was shown (in specimens recently drawn) to be largely due to cross-reactivity in the alpha-subunit RIA, the high LH values may represent high alpha-subunit levels. The elevated FSH levels and alpha-subunit concentrations did not rise after GnRH administration. Thus, during the course of 12 yr, this patient's tumor hypersecreted FSH and alpha-subunit and possibly LH. The evolution of these events may represent the natural history of the tumor or the effects of the therapeutic modalities used. We conclude that adult men with pituitary tumors and complaints of hypogonadism should be evaluated for a FSH-secreting tumor.     

Bromocriptine increasingly suppresses the in vitro gonadotropin and alpha-subunit release from pituitary adenomas during long term culture

Prolonged treatment with bromocriptine may lead to a decrease in tumor size in patients with a gonadotroph, alpha-subunit-secreting, or clinically nonfunctioning pituitary adenoma. The effectiveness of the treatment, however, may depend on its duration. We investigated the effects of prolonged incubation with bromocriptine on the release and intracellular hormone and alpha-subunit concentrations in 10 such adenomas in vitro. The release of FSH, LH, alpha-subunit, or a combination of these was demonstrated in 7 tumors. Bromocriptine significantly suppressed this release in 6 tumors. In 5 tumors bromocriptine had an inhibitory effect on gonadotropin and/or alpha-subunit release which increased with duration of culture. Withdrawal of bromocriptine during the culture period led to a recovery of gonadotropin or alpha-subunit release in the 2 tumors in which it was tested. Intracellular hormone and alpha-subunit concentrations in 3 of 4 tumors cultured for 4 or more weeks were significantly lower in bromocriptine-treated than in untreated cells. We conclude that 1) bromocriptine can suppress the in vitro release of gonadotropins and alpha-subunit from the majority of clinically nonfunctioning, gonadotroph, and alpha-subunit-secreting pituitary adenomas; 2) during prolonged incubation of these tumors with bromocriptine, this drug has a time-dependent increasing inhibitory effect on the release and synthesis of gonadotropins and alpha-subunit, which eventually may lead to decreased intracellular concentrations of these glycoproteins.