Expression of a calcium-sensing receptor in a human medullary thyroid carcinoma cell line and its contribution to calcitonin secretion.

An extracellular Ca(2+)-sensing mechanism consisting of a G protein-coupled receptor linked to phosphoinositide turnover and inhibition of PTH secretion, has recently been identified in bovine parathyroid cells. In C cells, voltage-dependent L-type calcium channels are thought to be involved in calcium-sensing mechanisms, but evidence exists for additional calcium-sensing mechanisms, such as via a calcium-sensing receptor (CaSR). Using the human medullary C cell carcinoma cell line TT, which lacks L-type calcium channels, we found that Ca2+ or cations specific for the CaSR lead to the release of calcium ions from intracellular stores and to an increase in calcitonin secretion. By molecular cloning we isolated the complete protein-coding complementary DNA of a CaSR from human TT cells, which are derived from a human medullary thyroid carcinoma. The CaSR is derived from the same CaSR gene expressed in the parathyroid gland. In addition, TT cells contain an alternative receptor form of CaSR, CaSRb. These findings provide strong evidence for the presence of a functional CaSR in the human C cell line TT. This receptor contributes not only to the inhibition of PTH secretion in the parathyroid, but also to the stimulation of calcitonin secretion in C cells.

Activation of phospholipase C-gamma1 in human keratinocytes by hyperosmolar shock without enzyme phosphorylation.

Human keratinocytes are exposed to strong physical changes, and have the potentiality to react to external stimuli by switching on adaptation mechanisms. In hyperosmotically shocked keratinocytes a rapid and strong increase in calcium has been observed. We showed that this increase could not be prevented by growing the cells in medium devoid of calcium and in the presence of EGTA, indicating that the intracellular calcium increase was due to delivery from internal stores. Further, we observed an increased synthesis of dyacylglycerol and inositol trisphosphates after shock, suggesting that phospholipase C mediates both events. Our experiments demonstrated that osmotic shock in human keratinocytes leads to activation of phospholipase C-gamma1, as measured using an in vitro assay system. This activation is independent of protein tyrosine phosphorylation and corresponded to a relocation of the enzyme to perinuclear membranes as shown by immunofluorescence.