Store-operated Ca(2+) influx, suggested to be mediated via store-operated cation channel (SOC), is present in all cells. The molecular basis of SOC, and possible heterogeneity of these channels, are still a matter of controversy. Here we have compared the properties of SOC currents ( I(SOC)) in human submandibular glands cells (HSG) and human parotid gland cells (HSY) with I(CRAC) (Ca(2+) release-activated Ca(2+) current) in RBL cells. Internal Ca(2+) store-depletion with IP(3) or thapsigargin activated cation channels in all three cell types. 1 muM Gd(3+) blocked channel activity in all cells. Washout of Gd(3+) induced partial recovery in HSY and HSG but not RBL cells. 2-APB reversibly inhibited the channels in all cells. I(CRAC )in RBL cells displayed strong inward rectification with E(rev)(Ca) = >+90 mV and E(rev) (Na) = +60 mV. I(SOC) in HSG cells showed weaker rectification with E(rev)(Ca) = +25 mV and E(rev)(Na) = +10 mV. HSY cells displayed a linear current with E(rev) = +5 mV, which was similar in Ca(2+)- or Na(+)-containing medium. pCa/ pNa was >500, 40, and 4.6 while pCs / pNa was 0.1,1, and 1.3, for RBL, HSG, and HSY cells, respectively. Evidence for anomalous mole fraction behavior of Ca(2+)/Na(+) permeation was obtained with RBL and HSG cells but not HSY cells. Additionally, channel inactivation with Ca(2+) + Na(+) or Na(+) in the bath was different in the three cell types. In aggregate, these data demonstrate that distinct store-dependent cation currents are stimulated in RBL, HSG, and HSY cells. Importantly, these data suggest a molecular heterogeneity, and possibly cell-specific differences in the function, of these channels.
Disorders of human salivary glands resulting from therapeutic radiation treatment for head and neck cancers or from the autoimmune disease Sjögren syndrome (SS) frequently result in the reduction or complete loss of saliva secretion. Such irreversible dysfunction of the salivary glands is due to the impairment of acinar cells, the major glandular cells of protein, salt secretion, and fluid movement. Availability of primary epithelial cells from human salivary gland tissue is critical for studying the underlying mechanisms of these irreversible disorders. We applied 2 culture system techniques on human minor salivary gland epithelial cells (phmSG) and optimized the growth conditions to achieve the maintenance of phmSG in an acinar-like phenotype. These phmSG cells exhibited progenitor cell markers (keratin 5 and nanog) as well as acinarspecific markers-namely, α-amylase, cystatin C, TMEM16A, and NKCC1. Importantly, with an increase of the calcium concentration in the growth medium, these phmSG cells were further promoted to acinar-like cells in vitro, as indicated by an increase in AQP5 expression. In addition, these phmSG cells also demonstrated functional calcium mobilization, formation of epithelial monolayer with high transepithelial electrical resistance (TER), and polarized secretion of α-amylase secretion after β-adrenergic receptor stimulation. Taken together, suitable growth conditions have been established to isolate and support culture of acinar-like cells from the human salivary gland. These primary epithelial cells can be useful for study of molecular mechanisms involved in regulating the function of acinar cells and in the loss of salivary gland function in patients.
This study examined [Ca2+]i oscillations in the human salivary gland cell lines, HSY and HSG. Relatively low concentrations of carbachol (CCh) induced oscillatory, and higher [CCh] induced sustained, steady-state increases in [Ca2+]i and KCa currents in both cell types. Low IP3, but not thapsigargin (Tg), induced [Ca2+]i oscillations, whereas Tg blocked CCh-stimulated [Ca2+]i oscillations in both cell types. Unlike in HSG cells, removal of extracellular Ca2+ from HSY cells (i) did not affect CCh-stimulated [Ca2+]i oscillations or internal Ca2+ store refill, and (ii) converted high [CCh]-induced steady-state increase in [Ca2+]i into oscillations. CCh- or thapsigargin-induced Ca2+ influx was higher in HSY, than in HSG, cells. Importantly, HSY cells displayed relatively higher levels of sarcoendoplasmic reticulum Ca2+ pump (SERCA) and inositoltrisphosphate receptors (IP3Rs) than HSG cells. These data demonstrate that [Ca2+]i oscillations in both HSY and HSG cells are primarily determined by the uptake of Ca2+ from, and release of Ca2+ into, the cytosol by the SERCA and IP3R activities, respectively. In HSY cells, Ca2+ influx does not acutely contribute to this process, although it determines the steady-state increase in [Ca2+]i. In HSG cells, [Ca2+]i oscillations directly depend on Ca2+ influx; Ca2+ coming into the cell is rapidly taken up into the store and then released into the cytosol. We suggest that the differences in the mechanism of [Ca2+]i oscillations HSY and HSG cells is related to their respective abilities to recycle internal Ca2+ stores.
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