Cell Calcium Levels of Normal and Cystic Fibrosis Nasal Epithelium

SUMMARY1. Sodium absorption is the dominant ion transport process in conducting airways and is a major factor regulating the composition of airway surface liquid. However, little is known about the control of airway sodium transport by intracellular regulatory pathways.2. In sheep tracheae and human bronchi mounted in Ussing chambers under short circuit conditions, the sodium current can be isolated by pretreating tissues with acetazolamide (100 1uM) to inhibit bicarbonate secretion, bumetanide (100 /LM) to inhibit chloride secretion and phloridzin (200 #M) to inhibit sodium-glucose cotransport. This sodium current consists of amiloride-sensitive (57 %) and amilorideinsensitive (43 %) components.3. The regulation of the isolated sodium current by three second messenger pathways was studied using the calcium ionophore A23187 to elevate intracellular calcium, a combination of forskolin and the phosphodiesterase inhibitor zardaverine to elevate intracellular cyclic AMP, and the phorbol ester 12,13-phorbol dibutyrate (PDB) to stimulate protein kinase C.4. In sheep trachea, A23187 produces a dose-related inhibition of the sodium current with maximal effect (38 % of I.C) at 10 gm and IC50 1 fM. A. GRAHAM AND OTHERS sheep trachea. This was associated with a small, but significant, 6 % transient increase in ISc followed by a significant 4 % fall. Neither effect could be abolished by amiloride pretreatment. In human bronchi, a small decrease in I., which could not be distinguished from that occurring in controls was observed. 7. We conclude that elevating intracellular calcium and protein kinase C stimulation have marked inhibitory effects on sodium transport in sheep trachea and human bronchus. Stimulation of protein kinase A does not appear to have a major role in the regulation of sodium absorption in these tissues.

Section: Discussionsupporting

confidence: 62%

“…However, ionomycin produces very similar effects (Willumsen & Boucher, 1989) and has been shown to directly elevate intracellular calcium in human nasal epithelium (Murphy, Cheng, Yankaskas, Stutts & Boucher, 1988). No stimulation of cyclic AMP levels by A23187 was seen in our tissues.…”

Section: Discussionmentioning

confidence: 67%

Second‐messenger regulation of sodium transport in mammalian airway epithelia.

Graham

Steel

Alton

et al. 1992

“…The relative effects of recording from spherical cells should be similar with these two cell types, as they are of similar dimensions, but specific differences in intracellular influences on Fura-2 cannot be ruled out. For this reason, although the basal [Ca2+]i measured in our study is of the same order of magnitude as that reported by others (Murphy, Cheng, Yankaskas, Stutts & Boucher, 1988), absolute values obtained could only be taken as best available estimates. However, the relative changes in calcium concentration (expressed as a percentage of baseline) would be unaffected by the lack of absolute calibration standards.…”

Section: Effect Of Calcium Ionophore On Intracellular Free Calciumsupporting

confidence: 57%

Calcium regulation of ciliary beat frequency in human respiratory epithelium in vitro.

Benedetto

Magnus

Gray

et al. 1991

SUMMARY1. The changes in ciliary beat frequency (CBF) of human nasal respiratory epithelial cells were measured in vitro with a photometric technique following exposure to either 4-bromo-calcium ionophore A23187 (4-Br-A23187) or trifluoperazine (TFP), an inhibitor of calmodulin-sensitive calcium-dependent protein kinases. Changes in intracellular free calcium concentrations in response to 4-Br-A23187 were studied using a fluorescent dye (Fura-2).2. Addition of 10' M-4-Br-A23187 caused a time-dependent (P < 001) rise in CBF. The increment in CBF was statistically significant 10 min after challenge (+ 10 %; P < 0 01) and was sustained for at least 1 h, with maximal stimulation after 40 min (+ 18 %; P < 0-01).3. Exposure to 10' M-4-Br-A23187 caused an immediate increase in intracellular free calcium concentration, which preceded the rise in CBF.4. TFP (10' M) caused a reduction of baseline CBF (-10%; P < 001) and prevented the expected rise when the cells were subsequently exposed to 10' M-4-Br-A23187.5. We conclude that: (1) calcium ionophore stimulates the CBF of human respiratory cells; (2) this effect is mediated through a calmodulin-sensitive system, since it is abolished in the presence of TFP; (3) the same pathway appears to control the basal CBF of these cells, since TFP also decreases CBF.

“…This effect of isoprenaline was not observed in CF cell cultures pre-treated with amiloride. The failure of isoprenaline to increase apical membrane Clconductance 4-2 99 R. C. BOUCHER AND OTHERS does not result from an absence of adrenergic receptors, since isoprenaline stimulates cyclic AMP production equally well in CF and normal cultured nasal epithelial cells (Welsh & Liedtke, 1986;Murphy, Yankaskas, Stutts & Boucher, 1988).…”

Section: Pharmacological Agents/ion Substitutionmentioning

confidence: 99%

Evidence for reduced Cl‐ and increased Na+ permeability in cystic fibrosis human primary cell cultures.

Boucher

Cotton

Gatzy

et al. 1988

255

131

SUMMARY1. Employing a primary cell culture system and intracellular microelectrodes, we quantitated and compared the Na+ and Cl-pathways in apical membranes of normal and cystic fibrosis (CF) human airway epithelia.2. Like the transepithelial difference (PD) in situ, the PD of CF epithelia in culture (-27+4 mV, mean+S.E.M.; n = 28) exceeded the PD of normal epithelia (-10 +1 mV; n = 22). The raised PD principally reflected an increase in the rate of active transport (equivalent short circuit, Ieq) for CF epithelia (61 + 9 ,tA cm-2) as compared with normal epithelia (23 + 3 ,uA cm-2). No significant differences in transepithelial resistance were detected. 3. As indicated by ion replacement studies (gluconate for Cl), the apical membrane of normal cells exhibits an apical membrane Cl-conductance (Gc1) that can be activated by isoprenaline. CF cells do not exhibit an apical membrane GC1, nor can a GC1 be activated by isoprenaline.4. CF cells exhibited a larger amiloride-sensitive Ieq and amiloride-sensitive apical membrane conductance (GNa) than normal cells. Further, the amiloride-sensitive Ieq was increased by isoprenaline in CF but not normal airway epithelia.5. Equivalent circuit analysis yielded evidence for a more positive electromotive force (EMF) across the apical membrane and a more negative EMF across the basolateral membrane of CF cells as compared with normal cells. Baseline resistances of the apical (Ra) and basolateral (Rb) membranes did not differ for normal and CF cells.6. Estimates of the resistance of the paracellular path to ion flow (R.) by equivalent circuit analysis or ion substitution detected no differences in R. between CF and normal cells.7. We conclude that abnormalities in both cellular Cl-permeability (reduced) and Na+ permeability (increased) are characteristic of the cultured CF respiratory epithelial cell. These data suggest that a defect in the regulation of apical membrane permeabilities is a central feature of this disease.