Clinical features, risk of mass enlargement, and development of endocrine hyperfunction in patients with adrenal incidentalomas: a long-term follow-up study.

PURPOSE: To evaluate the risk of mass enlargement and endocrine function modification in patients with adrenal incidentaloma (AI). METHODS: In this retrospective study, we examined clinical and hormonal characteristics of 310 patients with AI (200 females and 110 males; age: 58.3 ± 12.9 years), followed up for a median (interquartile range) of 31.4 months (13.0-78.6) and evaluated for possible modification in adrenal mass size and hormonal function. The hormonal evaluation included morning serum cortisol and plasma ACTH at 8 a.m., aldosterone, plasma renin activity/direct renin concentration, and 24-h urine metanephrines/normetanephrines. One microgram overnight dexamethasone suppression test (DST) was performed. Autonomous cortisol secretion (ACS) was diagnosed in the presence of cortisol after 1 mg DST > 5 µg/dl (138 nmol/l) or >1.8 and ≤5 µg/dl (50-138 nmol/l) and at least one of the following: (i) low ACTH; (ii) increased 24-h urinary-free cortisol; (iii) absence of cortisol rhythm; and (iv) post-LDDST cortisol level > 1.8 µg/dl (50 nmol/l). When there was no biochemical evidence of adrenal hormonal hyperactivity, AIs were classified as nonfunctioning (NFAIs). The mass was considered significantly enlarged when the size increase was more than 20% and at least 5 mm compared to baseline. RESULTS: At diagnosis, NFAIs were found in 209 patients, while ACS and overt adrenal hyperfunction were diagnosed in 81 and 20 patients, respectively. During follow-up, 3.3% and 1.5% of patients with NFAI developed subtle and overt endocrine hyperfunction, respectively, while a significant mass enlargement was observed in 17.7% of all AIs. The risk of developing ACS was significantly higher in patients with adenoma >28 mm (hazard ratio [HR] 12.4; 95% confidence interval [CI], 2.33-66.52, P = 0.003), in those with bilateral adrenal tumors (HR: 5.36; 95% CI, 1.17-24.48, P = 0.030), and with low/suppressed ACTH values (HR: 11.2, 95% CI 2.06-60.77; P = 0.005). The risk of mass enlargement was lower for patients in the fourth quartile of body mass index than those in the first quartile (HR 0.33; 95% CI, 0.14-0.78; P = 0.012). CONCLUSIONS: In patients with AI, the risk of developing hormonal hyperfunction and mass enlargement is overall low, although some tumor characteristics and anthropometric features might increase this risk. Taking account of all these aspects is important for planning a tailored follow-up in AI patients.

Disruption of the melanin-concentrating hormone receptor 1 (MCH1R) affects thyroid function.

Melanin-concentrating hormone (MCH) is a peptide produced in the hypothalamus and the zona incerta that acts on one receptor, MCH receptor 1 (MCH1R), in rodents. The MCH system has been implicated in the regulation of several centrally directed physiological responses, including the hypothalamus-pituitary-thyroid axis. Yet a possible direct effect of the MCH system on thyroid function has not been explored in detail. We now show that MCH1R mRNA is expressed in thyroid follicular cells and that mice lacking MCH1R [MCH1R-knockout (KO)] exhibit reduced circulating iodothyronine (T(4), free T(4), T(3), and rT(3)) levels and high TRH and TSH when compared with wild-type (WT) mice. Because the TSH of MCH1R-KO mice displays a normal bioactivity, we hypothesize that their hypothyroidism may be caused by defective thyroid function. Yet expression levels of the genes important for thyroid hormones synthesis or secretion are not different between the MCH1R-KO and WT mice. However, the average thyroid follicle size of the MCH1R-KO mice is larger than that of WT mice and contained more free and total T(4) and T(3) than the WT glands, suggesting that they are sequestered in the glands. Indeed, when challenged with TSH, the thyroids of MCH1R-KO mice secrete lower amounts of T(4). Similarly, secretion of iodothyronines in the plasma upon (125)I administration is significantly reduced in MCH1R-KO mice. Therefore, the absence of MCH1R affects thyroid function by disrupting thyroid hormone secretion. To our knowledge, this study is the first to link the activity of the MCH system to the thyroid function.

Thyroid hormone receptor α and regulation of type 3 deiodinase.

Mice deficient in thyroid hormone receptor α (TRα) display hypersensitivity to thyroid hormone (TH), with normal serum TSH but diminished serum T(4). Our aim was to determine whether altered TH metabolism played a role in this hypersensitivity. TRα knockout (KO) mice have lower levels of rT(3), and lower rT(3)/T(4) ratios compared with wild-type (WT) mice. These alterations could be due to increased type 1 deiodinase (D1) or decreased type 3 deiodinase (D3). No differences in D1 mRNA expression and enzymatic activity were found between WT and TRαKO mice. We observed that T(3) treatment increased D3 mRNA in mouse embryonic fibroblasts obtained from WT or TRßKO mice, but not in those from TRαKO mice. T(3) stimulated the promoter activity of 1.5 kb 5'-flanking region of the human (h) DIO3 promoter in GH3 cells after cotransfection with hTRα but not with hTRß. Moreover, treatment of GH3 cells with T(3) increased D3 mRNA after overexpression of TRα. The region necessary for the T(3)-TRα stimulation of the hD3 promoter (region -1200 to -1369) was identified by transfection studies in Neuro2A cells that stably overexpress either TRα or TRß. These results indicate that TRα mediates the up-regulation of D3 by TH in vitro. TRαKO mice display impairment in the regulation of D3 by TH in both brain and pituitary and have reduced clearance rate of TH as a consequence of D3 deregulation. We conclude that the absence of TRα results in decreased clearance of TH by D3 and contributes to the TH hypersensitivity.

Identification of TSH receptor mutations in three families with resistance to TSH.

OBJECTIVE: Genetic analysis of the TSH receptor gene in seven subjects with subclinical hypothyroidism (SH), in whom the diagnosis of autoimmune thyroid disease had been excluded by laboratory and instrumental techniques currently available. PATIENTS: Three families where different members (2 children and 5 adults) affected by SH were studied. GENETIC ANALYSIS: Genomic DNA was extracted from peripheral lymphocytes and the entire coding sequence of the TSHr gene was sequenced. pSVL-TSHr construct harbouring a Q8fsX62 insertion was obtained by site-directed mutagenesis. COS-7 cells transfected with wild-type and mutant receptor were used for binding studies, flow cytometry, and cyclic AMP (cAMP) determination. RESULTS: A four base pair (bp) duplication in position 41 (41TGCAins), leading to a premature stop of translation at codon 62 (Q8fsX62), was found to be heterozygous in the proband, the father and the sister in Family 1. In Family 2 the proband and the sister were heterozygous for the mutation D410N. In Family 3 the proband and the father were heterozygous for the mutation P162A. After transfection in COS-7 cells, the mutant receptor Q8fsX62 displayed a low expression at the cell surface, and a reduced response to bovine TSH (bTSH) in terms of cAMP production. CONCLUSIONS: We identified TSH receptor mutations in seven members of three families with subclinical hypothyroidism.

Low prevalence of thyrotropin receptor mutations in a large series of subjects with sporadic and familial nonautoimmune subclinical hypothyroidism.

Subclinical hypothyroidism of chronic autoimmune thyroiditis must be distinguished from the rare condition of thyroid resistance to TSH in which variable degrees of congenital insensitivity of the thyroid to a biologically active TSH molecule are present. We studied 42 subjects with slight to moderate elevations of circulating TSH and normal free thyroid hormone levels in whom the diagnosis of autoimmune thyroid disease had been excluded using the best of the currently available laboratory and instrumental techniques. In three families (A, B, and C), which included 8 of the 42 cases, other members besides the propositus were found to have isolated hyperthyrotropinemia. The entire coding regions of the TSH receptor (TSHr) gene were sequenced, and TSHr mutations were found in five subjects from families A and B. No mutations were identified in the two members of family C, in one member of family A, and in the 34 remaining cases of isolated hyperthyrotropinemia. A previously described P162A mutation was found in the proband (homozygous state), the son, and the mother of family A (both in the heterozygous state). A new inactivating heterozygous mutation was found in the proband and the mother of family B and consisted of the substitution of a leucine in place of a highly conserved proline at position 252 (L252P) in the extracellular portion of the TSHr. After transfection in COS-7 cells, the mutant L252P displayed a low expression at the cell surface and a reduced response to bovine TSH in terms of cAMP production. A structural defect of the mutant TSHr protein was probably responsible for the poor routing of the receptor to the cell membrane. In conclusion, in two of three families, but in none of 34 sporadic cases of isolated hyperthyrotropinemia, inactivating mutations of the TSHr were identified. The question of whether the latter cases represent subtle forms of autoimmune thyroiditis or might bear as yet unidentified genetic defects remains a matter of future studies.

Thyroglobulin in orbital tissues from patients with thyroid-associated ophthalmopathy: predominant localization in fibroadipose tissue.

UNLABELLED: One of the hypotheses that explains the pathogenesis of thyroid-associated ophthalmopathy (TAO) is that thyroglobulin (Tg) is transported through a retrograde lymphatic route to orbital tissues (OT), where it elicits autoimmune damage. In a previous study we demonstrated the presence of intact Tg of thyroid origin in OT from three patients with TAO. The present study was undertaken to investigate this issue further, by increasing the number of patients, by analyzing the distribution of Tg in OT, and by investigating possible relations between the presence of Tg in OT and the clinical features of patients. OT was obtained from seven patients with TAO who underwent decompressive orbitotomy via a transpalpebral approach. Patients were designated P10 to P16. Inflamed palpebral skin, retrobulbar fibroadipose tissue and extraocular muscle surgical samples were collected separately. Tissue extracts were prepared by homogenization and analyzed for the presence of Tg using two different techniques. We first performed immunoprecipitation experiments, in which a rabbit polyclonal anti-Tg antibody was used to capture Tg on protein A and a mouse monoclonal anti-Tg antibody was used to re-veal captured Tg by Western blotting. Intact 330-kd Tg was detected in retrobulbar fibroadipose tissue extracts from three patients (P10, P11, and P16), whereas no Tg was detected in retrobulbar fibroadipose tissue extracts from the remaining four patients. Tg was not detected in the extraocular muscle extracts from all patients studied. In addition, intact 330-kd Tg was found in the inflamed palpebral skin extract from one patient (P10). No Tg was detected in OT extracts from two patients without thyroid or eye disease and in abdominal adipose tissue extracts from two obese patients without thyroid or eye disease. We then searched for Tg by enzyme-linked immunosorbent assay (ELISA), using the same antibodies used for immunoprecipitation. Tg was detected in retrobulbar fibroadipose tissue extracts from four patients (P10, P11, P12, and P16) and in the inflamed palpebral skin extract from patient P10, in amounts ranging from approximately 125 to approximately 400 pg/microg of tissue protein. Again, Tg was not detected in extraocular muscle extracts. A positive gradient between Tg in OT and Tg in the serum was observed in patient P12. Using an ELISA approach, we found that Tg in OT from three TAO patients (P10, P11, and P12) contained thyroxine (T4) residues (mean T(4) CONTENT: 2.42 molecules per molecule of Tg), indicating that Tg had originated in the thyroid. Combining the results obtained in our previous and present study, we found a possible relation between the presence of Tg in OT and the previous treatment with radioiodine. Thus, of the seven patients (3 in the previous and 4 in the present study) in whose OT Tg was found, six had been treated with radioiodine, whereas of the three patients with no Tg in their OT none had been treated with radioiodine. In conclusion, Tg was found in OT extracts from patients with TAO by immunoprecipitation in three of seven cases and by ELISA in four of seven cases. Tg was found in retrobulbar fibroadipose tissue, but not in extraocular muscles. There was a relation between the presence of Tg in OT and the previous treatment with radioiodine. Our results support the hypothesis that Tg may play a role as a coantigen in the pathogenesis of TAO. Further studies are needed to investigate this possibility.

Benign nonfunctioning thyroid adenomas are characterized by a defective targeting to cell membrane or a reduced expression of the sodium iodide symporter protein.

Nodular thyroid disease is the most common endocrine disorder. Nonfunctioning thyroid nodules are identified by their low radioiodide uptake compared with the normal extranodular tissue, which, at thyroid scintiscan, produces the typical picture of a cold thyroid nodule. Previous in vitro studies demonstrated that the majority of nonfunctioning thyroid nodules have a specific defect in iodide transport that accounts for their failure to accumulate radioactive iodide in vivo. A defect in the expression or structure of the sodium iodide symporter (NIS) gene has been hypothesized as a possible cause of the impaired iodide trapping in nonfunctioning thyroid nodules. We studied 22 patients who were submitted to surgery for a solitary nonfunctioning thyroid nodule that originated in an otherwise normal gland. Thyroid scintigraphy was performed at 1, 2, 3, 4, 6, and 24 h after the oral administration of a tracer dose of 131I (iodine). All patients showed absence of 131I uptake in the nodule, with normal uptake in the extranodular tissue and in the contralateral thyroid lobe. Eight patients with toxic adenomas who underwent lobectomy were also included in the study. We first studied the expression of human NIS (hNIS) protein by immunohistochemistry in paraffin-embedded tissue sections using a specific anti-hNIS monoclonal antibody. Subsequently, we searched for somatic mutations of hNIS gene in nonfunctioning thyroid nodules. The level of hNIS expression was determined in both the nodules and the normal tissue from the same thyroid gland. In all functioning thyroid nodules (toxic adenomas), a high expression of hNIS protein was detected with respect to normal surrounding tissue. Similar to the normal thyroid tissue, follicular cells of toxic thyroid adenomas showed an exclusive expression of hNIS protein at the cell membrane. Fifty-four percent of benign nonfunctioning thyroid nodules overexpressed hNIS protein compared with the normal surrounding tissue, but in these nodules the hNIS protein failed to target the cell membrane, being mostly localized inside the cytoplasm. hNIS protein was not detected by immunohistochemistry in 46% of nonfunctioning nodules, whereas it was expressed in the surrounding unaffected thyroid tissue. Direct sequencing of the hNIS gene in all of the nonfunctioning nodules did not reveal major genetic alterations. A silent polymorphism (GCC/GCG codon 544, exon 13) was found in one nodule. In conclusion, the results obtained in this study show that two mechanisms contribute to the reduced radioiodide uptake typical of benign nonfunctioning thyroid nodules: 1) reduced expression of the hNIS protein, and 2) defective targeting of hNIS to the cell membrane.