Olga Kifor

BACKGROUND: The calcium-sensing receptor regulates the secretion of parathyroid hormone in response to changes in extracellular calcium concentrations, and mutations that result in a loss of function of the receptor are associated with familial hypocalciuric hypercalcemia. Mutations involving a gain of function have been associated with hypocalcemia in two kindreds. We examined the possibility that the latter type of mutation may result in a phenotype of familial hypocalcemia with hypercalciuria. METHODS: We studied six kindreds given a diagnosis of autosomal dominant hypoparathyroidism on the basis of their hypocalcemia and normal serum parathyroid hormone concentrations, a combination that suggested a defect of the calcium-sensing receptor. The hypocalcemia was associated with hypercalciuria, and treatment with vitamin D resulted in increased hypercalciuria, nephrocalcinosis, and renal impairment. Mutations in the calcium-sensing-receptor gene were identified by DNA-sequence analysis and expressed in human embryonic kidney cells (HEK-293). RESULTS: Five heterozygous missense mutations (Asn118Lys, Phe128Leu, Thr151Met, Glu191Lys, and Phe612Ser) were detected in the extracellular domain of the calcium-sensing-receptor gene and shown to cosegregate with the disease. Analysis of the functional expression of three of the mutant receptors in HEK-293 cells demonstrated shifts in the dose-response curves so that the extracellular calcium concentrations needed to produce half-maximal increases in total inositol phosphate in the cells were significantly (P=0.02 to P<0.001) lower than those required for the wild-type receptor. CONCLUSIONS: Gain-of-function mutations in the calcium-sensing receptor are associated with a familial syndrome of hypocalcemia with hypercalciuria that needs to be distinguished from hypoparathyroidism.

Most parathyroid adenomas and some pathological parathyroid glands from patients with primary parathyroid hyperplasia or severe uremic secondary/tertiary hyperparathyroidism show an elevated set-point [the extracellular Ca2+ concentration (Ca2+o) half-maximally inhibiting PTH secretion]. In the present study, we investigated whether expression of the Ca2+o-sensing receptor protein recently cloned from bovine parathyroid, a key component in Ca2+o-regulated PTH release, is altered in primary and uremic hyperparathyroidism. Using immunohistochemistry with specific antireceptor antibodies, we compared immunoreactivity of the receptor protein in 14 adenomas, biopsies of 24 normal glands from this same group of patients, and 8 hyperplastic parathyroid glands from 2 individuals with uremic hyperparathyroidism. The results show a substantial reduction in the intensity of immunostaining for the receptor protein that averaged nearly 60% for both adenomas and hyperplastic glands, as quantitated by image analysis. Although normal glands from normocalcemic controls were not available, the intensity of receptor staining in normal glands from patients with adenomas was comparable to that in normal bovine, rat, and mouse parathyroid glands. There was considerable variation in staining intensity among different pathological parathyroid glands, even in those from the same patient with secondary hyperparathyroidism. In addition, both adenomas and hyperplastic glands had, in some cases, isolated chief cells and groups of cells, sometimes around the periphery of an abnormal gland, with receptor staining equivalent to that of normal parathyroid cells, whereas the bulk of the cells in the same gland showed a marked decrease in staining. Thus, there is a variable, but substantial, reduction in the immunoreactivity of the Ca2+o-sensing receptor protein in both parathyroid adenomas and uremic hyperparathyroidism, as assessed by immunohistochemistry, that probably results from reduced expression of the receptor protein and may contribute to the increase in the set-point often observed in these patients.