A somatic gain-of-function mutation in the thyrotropin receptor gene producing a toxic adenoma in an infant

Mechanisms and Treatment Options for Hyperthyroid-Induced Osteoporosis: A Narrative Review

Normal thyroid hormone levels are crucial for the homeostasis of many metabolic cycles and processes throughout the human body. Thyroid dysfunction, such as thyrotoxicosis, can result from many different etiologies, including Graves' disease (GD), toxic multinodular goiter (MNG), and toxic adenoma. These hyperthyroid disease states can cause devastating complications and disease, including the disruption of the bone remodeling cycle and skeletal development, which can result in osteoporosis. Osteoporosis is characterized by a decrease in bone mineral density and a propensity for fragility fractures. In addition to patients with overt hyperthyroidism, studies have provided evidence of other high-risk patient demographics, such as individuals with subclinical hyperthyroidism and postmenopausal women, who may be at an increased risk for the development of secondary osteoporosis. The treatment of patients with hyperthyroid-induced osteoporosis often requires a multifaceted management plan that may be unique to each patient's situation. Antithyroid therapy is often the first step in treating this disease and may include thioamide medications. Radioactive iodine-131 therapy (RAI) and the surgical removal of the thyroid gland may also be reasonable approaches for restoring normal thyroid function. Following thyrotoxicosis mitigation, antiresorptive drugs such as bisphosphonates, calcitonin, and selective estrogen receptor modulators (SERMs) may be used to counteract decreased bone mineral density (BMD). Additionally, the implementation of vitamin D, calcium supplements, and weight-bearing exercise may also reduce bone loss. While the effects of thyroid stimulating hormone (TSH) and triiodothyronine (T3) on bone remodeling have been studied in the past, more research is needed to identify unknown mechanisms and develop future improved treatments for this condition.

Autonomous adenomas caused by somatic mutations of the thyroid-stimulating hormone receptor in children

In adults, autonomous adenomas of the thyroid causing hyperthyroidism are relatively common and are most often due to somatic mutations that increase the constitutive activity of the thyroid-stimulating hormone receptor (TSHR). By contrast, autonomous adenomas in hyperthyroid children are exceptional and reports of their clinical and molecular characteristics are few. We reviewed papers describing 16 autonomous adenomas due to a somatic mutation activating the TSHR and diagnosed in patients younger than 18 years, to which we added two of our own unpublished observations in a 4- and 8-year-old with the same TSHR mutation (c.CAG>CAC; p.Asp633His). This revealed that (a) autonomous adenomas occur more often in the right lobe (11 of 14 with available information) and the associated hyperthyroidism tends to be more severe, possibly reflecting the richer vascular supply of the right thyroid lobe, and (b) mutations found in benign adenomas in children have been associated with cancer in adults, suggesting that malignancy requires a second 'hit' at a later age.

Somatic mutations in 33 benign and malignant hot thyroid nodules in children and adolescents

Hot thyroid nodules (HTNs) in children are rare. Their reported malignancy rate is higher than in adults. However molecular data are rare. We present clinical and molecular data for 33 consecutive (29 benign and 4 malignant) HTNs. 17/29 Benign HTNs (59%) harbored somatic TSHR mutations. The most commonly observed mutation was M453T (in 8/29 samples). T632I and D633Y mutations were each detected twice. All other TSHR mutations were each found in one sample, including the new A538T mutation. One NRAS mutation was detected in a benign HTN with a M453T mutation. A PAX8/PPARG rearrangement was found in one malignant HTN. A T632I mutation was detected in one hot papillary thyroid carcinoma. The percentage of TSHR mutation positive HTNs in children and adolescents is within the range observed in adults. Contrary to adults, the M453T mutation is the predominant TSHR mutation in HTNs of children and adolescents. The increased malignancy rate of HTNs of children does not appear to be associated with RAS, BRAF, PAX8/PPARG and RET/PTC mutations.