Regulation of Parathormone Secretion in Dispersed Cells
Shoback, Dolores M.   
University of California San Francisco, San Francisco, CA, United States

Primary hyperparathyroidism is characterized by reduced suppression, of PTH release by high Ca++ and increased parathyroid tissue mass. Low extracellular (EC) Ca++ maximally stimulates while high EC Ca++ inhibits PTH release. The regulation of PTH release by IC Ca++ is unusual. High EC Ca++ appears to suppress PTH release by increasing intracellular (IC) free Ca++. However, the IC mediators that transmit the hypocalcemic signal for maximal PTH release have not been identified. Phorbol esters which activate protein kinase C reverse the inhibitory effects of high EC Ca++ and stimulate PTH release. In other cells, polyphosphoinositide (PPI) turnover regulates secretion by generating two synergistic second-messengers -- diacylglycerol, an endogenous activator of protein kinase C, and inositol-1,4,5- triphosphate (IP3), a cellular Ca++-mobilizing compound. Thus, indirect studies suggest that PPI turnover in parathyroid cells activates two antagonistic pathways. We therefore propose to test the hypothesis that low Ca++-stimulated PTH release involves activation of C-kinase and that the generation of IP3 regulates the EC Ca++-induced rise in IC Ca++ thereby suppressing PTH release. To test this hypothesis, we will measure G-kinase activity and the breakdown products of PPI hydrolysis diacylglycerol and the inositol phosphates -- at different EC Ca++ concentrations. Activation of C-kinase will be assessed by 1) quantifying the translocation of Ca++-, phospholipid-dependent phosphotransferase activity from cytosolic to membrane fractions, and 2) comparing phosphorylation patterns from cells exposed to different EC Ca++, phorbol esters, and Ca++-ionophore. We will determine whether high EC Ca++ generates 1,4,5-IP3 and inositol-tetrakisphosphate (IP4), a proposed regulator of membrane Ca++ influx, and whether high EC Ca++ modifies the kinase responsible for producing IP4 from 1,4,5- IP3. We will then determine whether a GTP-binding protein couples changes in EC to increases in IC free Ca++. We will test this idea by measuring IC free Ca++ and PTH release after incorporation of GTP or a stable GTP analog into intact parathyroid cells or after pretreatment with pertussis or cholera toxins agents which ADP- ribosylate GTP-binding proteins and thus modify their activity. These studies should establish the role of PPI turnover and C- kinase in Ca++-regulated PTH release and may identify potential cellular defects involved in disordered regulation of PTH release by Ca++ characteristic of hyperparathyroidism.