Monoclonal antiparathyroid antibodies--tools for studies of the regulation of cytoplasmic calcium and function of parathyroid and other antibody-reactive cells

Regulation of Human Eosinophil Migration Across Lung Epithelial Monolayers by Distinct Calcium Signaling Mechanisms in the Two Cell Types

In asthmatic patients, eosinophils massively infiltrate the lung tissues and migrate through lung epithelium into the airways. The regulatory mechanisms involved are obscure. We studied the role of calcium in the migration of human eosinophils across monolayers of human lung epithelial H292 cell line cells induced by combined chemotactic solutions of platelet-activating factor and C5a. The transepithelial migration of eosinophils was attenuated by depletion of the external Ca2+ in the migration system, whereas the eosinophil migration itself was unaffected as evidenced by measuring eosinophil chemotaxis in the Boyden chamber in the absence of epithelial cells. Buffering of intracellular Ca2+ in eosinophils with 1,2-bis(o-aminophenoxy)ethane-N,N,N′,N′-tetraacetic acid tetra(acetoxymethyl) ester (BAPTA/AM) inhibited both eosinophil transepithelial migration and eosinophil chemotaxis in the Boyden chamber, suggesting the importance of intracellular Ca2+ in eosinophil transmigration. Although loading of BAPTA/AM or addition of thapsigargin to the epithelial cells effectively changed their cytoplasmic free Ca2+ concentrations, neither of these treatments affected transepithelial migration of eosinophils. Interestingly, addition of La3+ (0.2 mM) to epithelial cells suppressed eosinophil transmigration whereas addition of La3+ to eosinophils did not. Taken together, these results show the importance of Ca2+ in eosinophil migration across lung epithelium and support a distinctive regulatory role of intracellular and extracellular Ca2+ for the two cell types involved in this process; i.e., the transmigration of human eosinophils across a monolayer of lung epithelial cells is regulated by the intracellular Ca2+ in eosinophils, whereas the ability of the lung epithelial cell monolayer to allow eosinophil passage is dependent on the extracellular Ca2+.

Functional expression of the parathyroid cell calcium receptor in Xenopus oocytes

Various studies suggest the existence of a plasma membrane receptor on parathyroid cells that senses changes in the concentration of extracellular Ca2+. To test this hypothesis, Xenopus laevis oocytes were injected with poly(A)(+)-enriched mRNA from bovine parathyroid cells and examined for their ability to respond to increases in the concentration of extracellular Ca2+ or other polycations. Cytosolic Ca2+ concentrations were measured indirectly by recording Cl- currents through the endogenous, cytosolic Ca(2+)-activated Cl- channel. Increasing the concentration of extracellular Ca2+ (from 0.7 to 5 mM) or Mg2+ (from 0.8 to 10 mM) elicited oscillatory increases in the Cl- current. Responses to either divalent cation were not observed in oocytes injected with water or with mRNA prepared from HL-60 cells or rat liver. Responses elicited by extracellular Mg2+ persisted when extracellular Ca2+ was reduced to low micromolar levels. La3+, Gd3+, or neomycin B also evoked oscillatory increases in the Cl- current in oocytes under conditions of low extracellular Ca2+ levels. These extracellular polycations all cause the mobilization of intracellular Ca2+ in oocytes injected with parathyroid cell mRNA like they do in intact parathyroid cells. The injection of parathyroid cell mRNA thus confers on oocytes the ability to detect and respond to changes in the concentration of extracellular polycations. The data provide compelling evidence for the existence of a cell surface Ca2+ receptor protein(s) on parathyroid cells that regulates cellular function.

Extracellular calcium-dependent regulation of transmembrane calcium fluxes in murine keratinocytes

Because the level of extracellular Ca2+ is an important stimulus for differentiation of epidermal cells in vitro, we characterized the extracellular Ca(2+)-dependent transmembrane Ca2+ fluxes in BALB/MK mouse keratinocytes. Increasing levels of extracellular Ca2+, ranging from 0.07 to 1.87 mM, stimulated the rate of 45Ca2+ uptake into these cells 10- to 70-fold and doubled the rate of 45Ca2+ efflux. The divalent cations, Ni2+ and Co2+, were able to block the influx of Ca2+, but dihydropyridines and verapamil were not. Furthermore, 10 to 100 microM of the trivalent cation La3+ induced a dose-dependent 2- to 100-fold increase of Ca2+ uptake, independently of the level of extracellular Ca2+. These observations suggest that keratinocytes possess a cell-surface "Ca(2+)-receptor," activation of which stimulates the influx of 45Ca2+ through a type of voltage-independent, receptor-operated Ca2+ channels. Epidermal growth factor induced an accumulation of 45Ca2+ of a much smaller magnitude than elevations of the level of extracellular Ca2+, without a detectable increase of Ca2+ efflux. Thus, the divergent cellular responses of keratinocytes to EGF and extracellular Ca2+ may be due, in part, to the distinct changes in transmembrane Ca2+ fluxes that these two stimuli generate. Treatment of cells with type beta transforming growth factor led to a gradual 6-fold increase of the Ca(2+)-activated rate of Ca2+ uptake over a period of 4 hours, but reduced the Ca2+ efflux by approximately 50% within 10 minutes. Thus, type beta transforming growth factor apparently stimulates Ca2+ influx indirectly, but may control the differentiation of keratinocytes by direct inhibition of Ca2+ efflux pumps.

"Calcium receptors" on eukaryotic cells with special reference to the osteoclast

There is a growing list of cells that are capable of detecting and responding to changes in the concentration of extracellular calcium. The two classic examples of this behaviour are the calcitonin-secreting parafollicular cells of the thyroid and parathyroid hormone-secreting chief cells of the parathyroid gland. A more recent addition to this list is the renin-secreting juxtaglomerular cell of the kidney. Particularly intriguing has been independently the discovery by two laboratories, that the resorptive cell of bone, the osteoclast, is capable of detecting changes in ambient calcium. A common theme amongst all these so called "calcium-responsive" cells is that extracellular calcium increases elevate intracellular calcium levels, and this intracellular signal is either stimulatory or inhibitory to the functional response. But how these cells detect changes in the concentration of extracellular calcium, and how these recognition events are subsequently transformed into intracellular signals that regulate cell function are somewhat less clear. The commentary reveals some recent developments that seemingly provide insights into these mechanisms, with special reference to the osteoclast.