Oscillations in ciliary beat frequency and intracellular calcium concentration in rabbit tracheal epithelial cells induced by ATP.

To investigate how Ca(2+) regulates airway ciliary activity, changes in ciliary beat frequency (CBF) and intracellular calcium concentration (Ca(2+)) of rabbit tracheal ciliated cells, in response to ATP, were simultaneously quantified with high-speed phase-contrast and fast fluorescence imaging. [ATP]<or= 1 microM induced an increase in Ca(2+) and CBF that declined to the initial basal levels and was followed by irregular brief increases in Ca(2+) and CBF. [ATP] > 1 but < 16 microM induced a similar increase in Ca(2+) and CBF but this was followed by oscillations in CBF and Ca(2+). The minimum CBF of the oscillations in CBF remained elevated above the basal rate while the minimum concentration of the Ca(2+) oscillations returned to the basal level. The minimum and maximum CBF of the oscillations in CBF were independent of the [ATP], whereas the frequency of the oscillations in CBF was dependent on the [ATP]. Similar oscillations in CBF and Ca(2+) were induced by ATP- gamma -S. Although ADP, AMP and adenosine induced a Ca(2+)-independent increase in CBF, neither ATP nor ATP- gamma -S induced an increase in CBF when the Ca(2+) increases were abolished by 20 microM BAPTA AM, a result suggesting that ATP hydrolysis was minimal. [ATP] >or=16 microM induced a sustained elevation in CBF and only a temporary, non-oscillating increase in Ca(2+). A similar response was induced by thapsigargin (2 microM). Flash photolysis of caged Ca(2+) (NP-EGTA) produced both transient and prolonged increases in Ca(2+) which were accompanied by transient and sustained increases in CBF, respectively. From these results, we propose that CBF can be increased by a direct Ca(2+) -dependent mechanism that generates the rapid increases in CBF associated with the oscillations or by an indirect Ca(2+)-dependent mechanism that is responsible for the sustained minimum increase in CBF.