Calcium signaling regulates trafficking of familial hypocalciuric hypercalcemia (FHH) mutants of the calcium sensing receptor.

[familial hypocalciuric hypercalcemia]

Calcium -sensing receptors (CaSRs ) regulate systemic Ca (2 +) homeostasis . Loss -of-function mutations cause familial benign hypocalciuric hypercalcemia (FHH ) or neonatal severe hyperparathyroidism (NSHPT ). FHH /NSHPT mutations can reduce trafficking of CaSRs to the plasma membrane . CaSR signaling is potentiated by agonist-driven anterograde CaSR trafficking , leading to a new steady state level of plasma membrane CaSR , which is maintained , with minimal functional desensitization , as long as extracellular Ca (2 +) is elevated . This requirement for CaSR signaling to drive CaSR trafficking to the plasma membrane led us to reconsider the mechanism (s ) contributing to dysregulated trafficking of FHH /NSHPT mutants . We simultaneously monitored dynamic changes in plasma membrane levels of CaSR and intracellular Ca (2 +), using a chimeric CaSR construct , which allowed explicit tracking of plasma membrane levels of mutant or wild-type CaSRs in the presence of nonchimeric partners . Expression of mutants alone revealed severe defects in plasma membrane targeting and Ca (2 +) signaling , which were substantially rescued by coexpression with wild-type CaSR . Biasing toward heterodimerization of wild-type and FHH /NSHPT mutants revealed that intracellular Ca (2 +) oscillations were insufficient to rescue plasma membrane targeting . Coexpression of the nonfunctional mutant E 297 K with the truncation CaSRΔ 868 robustly rescued trafficking and Ca (2 +) signaling , whereas coexpression of distinct FHH /NSHPT mutants rescued neither trafficking nor signaling . Our study suggests that rescue of FHH /NSHPT mutants requires a steady state intracellular Ca (2 +) response when extracellular Ca (2 +) is elevated and argues that Ca (2 +) signaling by wild-type CaSRs rescues FHH mutant trafficking to the plasma membrane .