Prevalence of alpha-subunit hypersecretion in patients with pituitary tumors: clinically nonfunctioning and somatotroph adenomas.

Hypersecretion of the pituitary glycoprotein hormone alpha-subunit has been reported in pituitary adenomas, particularly in clinically nonfunctioning tumors and somatotroph adenomas. However, the prevalence of such hypersecretion has not been precisely defined. Using both a new highly sensitive and specific monoclonal antibody assay and a polyclonal antibody assay, serum levels of free alpha-subunit were compared in 63 unselected patients with these tumors, 19 patients with acromegaly, and 95 normal controls. In all patients the monoclonal assay detected a significantly greater number of subjects with elevated alpha-subunit levels than did the polyclonal assay (21 vs. 14; P less than 0.01). Fourteen of the 63 patients with clinically nonfunctioning tumors (22%) had elevated serum alpha-subunit levels in the monoclonal assay vs. 11 (17%) in the polyclonal assay. Among the 19 patients with acromegaly, the prevalence was 7 (37%) and 3 (16%) using the monoclonal and polyclonal assays, respectively. Twenty-eight (44%) of the patients with clinically nonfunctioning pituitary adenomas were female. Eleven (39%) of the women were under 45 yr old, as were 10 (29%) of the men. We conclude that the prevalence of free alpha-subunit hypersecretion in patients with clinically nonfunctioning and somatotroph adenomas may be higher than previously recognized, and that a sensitive and specific monoclonal antibody free alpha-subunit assay may provide a useful tumor marker in these patients. The prevalence of clinically nonfunctioning pituitary tumors among younger men and women may also have been previously under-estimated.     

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.     

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.     

Glycoprotein hormone alpha-subunit production in somatotroph adenomas with and without Gs alpha mutations.

Activating mutations of the Gs alpha subunit have been identified in a subset of somatotroph adenomas. The mutant form of the Gs alpha subunit causes persistent activation of adenylyl cyclase and consequently results in high intracellular levels of cAMP. Because cAMP is known to stimulate the synthesis of the glycoprotein hormone (GPH) alpha-subunit as well as GH, we examined somatotroph tumors with and without Gs alpha mutations for GPH alpha-subunit production. GPH alpha-subunit production was assessed in vivo by measuring serum hormone levels and in vitro by analyzing hormone secretion by cultured pituitary tumor cells. DNA was extracted from the pituitary tumors of 26 acromegalic patients. The Gs alpha gene was amplified by the polymerase chain reaction and screened for mutations at codons 201 and 227 using oligonucleotide specific hybridization. Nine of the 26 tumors (35%) had point mutations at Arg 201. Seven of these tumors contained a CGT to TGT mutation (Arg to Cys) and 2 contained a CGT to CAT mutation (Arg to His). No mutations were detected at codon 227. There were no significant differences in age, sex distribution, tumor size, or serum levels of GH or insulin-like growth factor-1 between the groups of patients with or was Gs alpha mutations. The mean serum level of the free GPH alpha-subunit was 1.9-fold higher in the group with Gs alpha mutations (0.48 +/- 0.37 micrograms/L) than in patients without mutations (0.25 +/- 0.17) (P less than 0.05). In pituitary tumor cell culture, 75% of somatotroph tumors with Gs alpha mutations secreted free GPH alpha-subunit into the media compared with 45% of tumors without Gs alpha mutations. The amount of GPH alpha-subunit secretion was 12-fold greater in the group of tumors containing the Gs alpha mutation (P less than 0.05). Immunocytochemical detection of the free GPH alpha-subunit was similar in the two groups of patients with 75% positive for the GPH alpha-subunit in tumors with Gs alpha mutations and 67% positive in tumors without mutations (P = 0.69). We conclude that GPH alpha-subunit production occurs in somatotroph tumors with and without Gs alpha mutations. The increased levels of GPH alpha-subunit secretion in vivo and in vitro suggest that the Gs alpha mutation may increase the amount of preexisting GPH alpha-subunit biosynthesis in the tumors, perhaps via activation of the cAMP pathway.     

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.     

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.     

Value of alpha subunit assay in pituitary pathology]

We evaluated serum alpha-subunit concentrations in 72 patients bearing pituitary adenomas. We conclude that: 1) alpha-subunit hypersecretion is found in all patients with TSH secreting pituitary adenoma (n = 10). Two patients have a predominant secretion of alpha-subunit as compared to TSH secretion. 2) As concerns gonadotropin secreting pituitary adenomas (n = 3), all patient have elevated serum alpha-subunit levels with increased FSH and LT concentrations in 2 cases and 1 case respectively. 3) In prolactinomas (n = 14), alpha-subunit concentrations are not significantly different from that of normal subjects. 4) In 11 acromegalic patients, alpha-subunit hypersecretion is found in 2 patients only with GH-alpha and GH-PRL-alpha secreting pituitary adenomas. 5) Among 34 patients with nonsecreting adenomas, 8 have elevated alpha-subunit concentrations (24%). Positive immunocytochemical staining is found in 70% most often with gonadotropins (55%). Only a few pituitary tumors with positive alpha-subunit immunocytochemical staining have elevated serum alpha-subunit levels. At least, the measurement of basal circulating alpha-subunit levels is very useful in the follow-up of patients with nonsecreting adenomas. In our study, medical treatments including bromocriptine and somatostatin analogues have been found effective in patients with alpha-subunit hypersecretion. Further investigations are necessary to prove if such treatments could control tumoral growth and could prevent recurrences.     

Chronic somatostatin analog administration in patients with alpha-subunit-secreting pituitary tumors.

Glycoprotein hormone-producing (GPH) pituitary adenomas represent approximately 25% of all pituitary tumors. Elevated serum levels of intact GPHs or their free alpha- and beta-subunits have been demonstrated in patients with such tumors, and isolated hypersecretion of alpha-subunit has been reported to occur in 7% of patients. Somatostatin has been shown to decrease GPH subunit levels in cultured adenoma cells in vitro, and somatostatin receptors have been identified on the cell membranes of these tumors. We, therefore, investigated the effect of chronic somatostatin analog administration on hormone production and tumor size in six patients with GPH-producing macroadenomas and elevated serum alpha-subunit levels. Patients initially received native somatostatin as an iv 250-micrograms bolus at 0800 h, followed by a constant infusion of 2 mg over 4 h, and serum alpha-subunit concentrations were measured at 30-min intervals after baseline sampling for a total of 9 h. Patients then received a somatostatin analog, octreotide (100 micrograms, twice daily, sc) for 8 weeks. Serum alpha-subunit levels were determined weekly at 30-min intervals before and for 4 h after the 0800 h octreotide dose. Pituitary magnetic resonance imaging scans and visual field testing were assessed before and after the study. During the 4-h somatostatin infusion, four patients had a significant decrease in alpha-subunit levels (P < 0.05). During the 8-week chronic octreotide administration period, two patients had significant decreases in alpha-subunit levels of 34.6% and 26.7% (P = 0.03 and 0.01, respectively). One of these two patients had a small reduction in tumor size. Two patients whose serum alpha-subunit level did not significantly change while receiving octreotide had a reduction in tumor size or definite improvement in visual field abnormalities. Three patients received a maximum octreotide dose of 250 micrograms, three times daily. In one patient, there was a significant decrease in alpha-subunit levels by 45% (P = 0.0001) in association with a marked improvement in visual field abnormalities. In another such patient, continued administration of octreotide to a maximum dose of 250 micrograms, three times daily, was associated with a marked reduction in tumor size. Of the four patients who demonstrated significant decreases in alpha-subunit concentrations during the initial somatostatin infusion, three patients had a significant reduction in alpha-subunit levels while receiving octreotide. One patient who did not have a decrease in alpha-subunit levels during the somatostatin infusion demonstrated a small decrease in tumor size during higher dose octreotide treatment.(ABSTRACT TRUNCATED AT 400 WORDS)     

Serum alpha-subunit levels in patients with pituitary adenomas

OBJECTIVE: We investigated preoperative and postoperative serum alpha-subunit levels and the alpha-subunit response to TRH in patients with various types of pituitary tumour and correlated the data with histological findings in order to clarify the significance of alpha-subunit measurement in pituitary adenomas. PATIENTS: We examined 59 patients with pituitary tumours (22 with GH cell adenomas, 30 with clinically nonfunctioning adenomas and seven with other tumours) treated at Toranomon Hospital between 1996 and 1998. RESULTS: The basal alpha-subunit level was supranormal in six out of 22 (27%) patients with a GH cell adenoma and in nine out of 30 (30%) patients with a nonfunctioning adenoma. A paradoxical alpha-subunit response to TRH was found in seven out of 22 (32%) patients with a GH cell adenoma. These seven patients also showed a paradoxical GH response to TRH administration. In addition, paradoxical response to TRH was found in eight out of 30 (27%) patients with a clinically nonfunctioning adenoma. In contrast, patients with other types of pituitary tumour showed neither a supranormal alpha-subunit level nor a paradoxical response to TRH. The supranormal alpha-subunit level and the abnormal response to TRH were normalized in both GH cell adenoma and nonfunctioning adenoma patients after successful surgery. Immunohistochemical studies showed alpha-subunit positive cells in 51% of GH cell adenomas or nonfunctioning adenomas and there was a good concordance with the serum alpha-subunit levels in both GH cell adenoma and nonfunctioning adenoma patients. CONCLUSIONS: These findings suggest that supranormal serum alpha-subunit levels are mainly due to hypersecretion by the tumour itself, while the paradoxical alpha-subunit response to TRH is an associated phenomenon in patients with a GH cell adenoma or nonfunctioning adenoma. The alpha-subunit level and the response to TRH may be useful indicators for assessing the operative outcome, especially in nonfunctioning adenoma patients who have no other definite endocrine markers.     

Management of pituitary tumors in pregnancy

Pituitary tumors, usually adenomas, account for about 10-15% of all intracranial tumors. Their treatment, which includes surgery, medicine or radiotherapy, either isolated or in combination, aims to halt tumor growth or achieve tumor shrinkage, as well as control hormone hypersecretion or ensure hormone replacement. Such approaches have made pregnancy possible for women with pituitary adenomas. Medical therapy with dopamine agonists is the treatment of choice for most patients with prolactinomas, with surgery reserved for individuals resistant to drugs. On the other hand, surgery before conception is indicated as a first-line approach in patients with acromegaly, Cushing disease or clinically nonfunctioning pituitary macroadenomas. In these patient populations, medical therapy with somatostatin analogues (acromegaly) or drugs that target the adrenal glands, such as metyrapone and ketoconazole (Cushing disease), should be reserved for those in whom surgery is unsuccessful or contraindicated.     

Interferon-alpha-2a is a potent inhibitor of hormone secretion by cultured human pituitary adenomas.

Interferon-alpha (IFN alpha) may exert direct inhibitory effects on cell proliferation and on the production of different peptide hormones. We investigated the effect of IFN alpha on hormone production by 15 GH-secreting pituitary adenomas, 4 clinically nonfunctioning or gonadotroph pituitary adenomas, and 4 prolactinomas in vitro. In the GH-secreting pituitary adenoma cultures, a short term (72-h) incubation with IFN alpha (50-100 U/mL) significantly inhibited GH secretion in 3 of 7 cases and PRL secretion in 6 of 7 cultures. During prolonged incubation (14 days) with IFN alpha, GH and/or PRL secretion was significantly inhibited in 7 of 8 cultures (GH, 17-78% inhibition; PRL, 39-88% inhibition). In the clinically nonfunctioning or gonadotroph cultures, incubation with IFN alpha resulted in inhibition of the secretion of gonadotropins and/or alpha-subunit in all cases (27-62%), whereas in the prolactinoma cultures PRL secretion was inhibited by IFN alpha in all cases (37-76%). The effect of IFN alpha was additive to the inhibitory effects of the dopamine agonist bromocriptine (10 nmol/L) or the somatostatin analog octreotide (10 nmol/L). The inhibition of hormone secretion by IFN alpha was accompanied by inhibition of the intracellular hormone concentrations. The effect of IFN alpha was dose dependent, with an IC50 for inhibition of hormone secretion of 2.3 +/- 0.3 U/mL (n = 5), which is relatively low compared with the concentrations that are reached in patients treated with IFN alpha for various malignancies. In conclusion, the potent antihormonal effect of IFN alpha on cultured pituitary adenomas suggests that this drug might be of benefit in the treatment of selected patients with secreting pituitary adenomas. As treatment with IFN alpha is associated with considerable adverse reactions, studies with this drug should only be considered in inoperable, invasive aggressive, and dopamine agonist- and/or somatostatin analog-resistant functioning pituitary macroadenomas.     

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.     

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.     

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.     

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.     

Medical Therapy of Gonadotropin-Producing and Nonfunctioning Pituitary Adenomas

Clinically nonfunctioning pituitary adenomas are one of the most common types of pituitary tumors. Unless they present with symptoms related to local mass effect, most tumors are detected incidentally when imaging studies are performed for other reasons. Although clinically nonfunctioning, most of these tumors have evidence, in vitro, of gonadotropin hormone or glycoprotein subunit production. The gonadotropins or their monomer submits rarely cause clinically identifiable effects. When these tumors present as macroadenomas, often with associated mass effect and hypopituitarism, primary therapy is neurosurgery. The role for medical therapy will be reviewed here.     

Dopaminergic regulation of alpha-subunit secretion and messenger ribonucleic acid levels in alpha-secreting pituitary tumors

Glycoprotein hormone and/or subunit secretion has been increasingly recognized in patients with pituitary nonsecretory adenomas and alpha-subunit secretion has been reported to occur in 5-10% of all pituitary tumors. We investigated the dopaminergic regulation of alpha-subunit secretion in four patients with alpha-subunit secreting pituitary adenomas documented by serum and immunocytochemical studies. In three of the four patients there was a significant decrease in serum alpha-subunit concentrations during 6 weeks of bromocriptine administration. Tumor size decreased in two patients. In pituitary tumor cells from one patient cultured in vitro, dopamine caused a highly significant decrease in media alpha-subunit concentrations. To investigate whether dopaminergic regulation of alpha-subunit secretion occurs at a pre- or posttranslational level, messenger RNA (mRNA) from cultured tumor cells from one patient was analyzed by Northern blot techniques. A decrease in alpha-subunit mRNA occurred in cells incubated with 10(-10), 10(-8), and 10(-6) M dopamine. We conclude that dopamine suppressed pituitary tumor alpha-subunit secretion and mRNA levels. Dopamine agonists may be of benefit in the therapy of patients with such tumors.     

The novel somatostatin ligand (SOM230) regulates human and rat anterior pituitary hormone secretion

Currently available somatostatin analogs predominantly bind to the somatostatin receptor subtype (SSTR)2 subtype, and control GH and IGF-I secretion in approximately 65% of patients with acromegaly, their efficacy relating to receptor density and subtype expression. SOM230 is a somatostatin ligand with high affinity to four SSTR subtypes. In primary cultures of rat pituicytes, SOM230 dose-dependently inhibited GH release (P = 0.002) with an IC50 of 1.2 nM. Ten nanomoles SOM230 inhibited GH and TSH release by 40 +/- 7% (P < 0.001) and 47 +/- 21% (P = 0.09), respectively. No effect of SOM230 was observed on prolactin (PRL) or LH release. In cultures of human fetal pituitary cells, SOM230 inhibited GH secretion by 42 +/- 9% (P = 0.002) but had no effect on TSH release. SOM230 inhibited GH release from GH-secreting adenoma cultures by 34 +/- 8% (P = 0.002), PRL by 35 +/- 4% from PRL-secreting adenomas (P = 0.01), and alpha-subunit secretion from nonfunctioning pituitary adenomas by 46 +/- 18% (P = 0.34). In contrast, octreotide inhibited GH, PRL, and alpha-subunit from the respective adenoma by 18 +/- 12 (P = 0.39), 22 +/- 4 (P = 0.04), and 20 +/- 10% (P = 0.34). In all culture systems, no significant difference in the inhibitory action of SOM230, octreotide, and somatostatin 14 on hormone release was observed. SOM230, similar to somatostatin, has high-affinity binding to SSTR1, 2, 3, and 5 and, in keeping with this, has an equivalent inhibitory effect on pituitary hormone secretion. As a consequence of its broader binding profile, SOM230 is likely to find clinical utility in treating tumors resistant to SSTR-2-preferential analogs.     

Lentiviral vectors efficiently transduce human gonadotroph and somatotroph adenomas in vitro. Targeted expression of transgene by pituitary hormone promoters

Despite important advances in human therapeutics, no specific treatment for both non-functioning gonadotroph and resistant somatotroph adenomas is available. Gene transfer by viral vectors can be considered as a promising way to achieve a specific and efficient treatment. Here we show the possibility of efficient gene transfer in human pituitary adenoma cells in vitro using a human immunodeficiency virus (HIV)-type 1-derived vector. Using enhanced green fluorescent protein (eGFP) gene as a marker placed under the phosphoglycerate kinase (PGK) promoter, gonadotroph and somatotroph adenomas were transduced even with moderate viral loads. The expression started at day 2, reached a peak at day 5, and it was still present at day 90. For targeting somatotroph and gonadotroph adenomas, human growth hormone (GH) promoter (GH -481, +54 bp) and two fragments of the human glycoprotein hormone alpha-subunit promoter (alpha-subunit 1 -520, +33 bp, and alpha-subunit 2 -907, +33 bp) were tested. In gonadotroph adenomas, the percentage of identified fluorescent cells and the fluorescence intensity analyzed by fluorescence-activated cell sorting indicated that the strength of the alpha-subunit 1 and alpha-subunit 2 promoters were comparable to that of the PGK promoter. Primary cultures of rat pituitary cells showed that alpha-subunit 1 is more selective to thyreotroph and gonadotroph phenotypes than alpha-subunit 2. GH promoter activity appeared weak in somatotroph adenomas. The human GH enhancer did not increase the GH promoter activity at all but the human prolactin promoter (-250 bp) allowed 4-fold more fluorescent cells to be obtained than the GH promoter. Several cell lines appeared too permissive to test cell-specificity of pituitary promoters. However, on human non-pituitary cell cultures, the tested pituitary promoters seemed clearly selective to target endocrine pituitary phenotypes. This study gives a starting point for a gene-therapy program using lentiviral vectors to transfer therapeutic genes in human pituitary adenomas.     

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.