Abstract
The role of the tyrosine kinase p60c-src on the gating of the cystic fibrosis transmembrane conductance regulator (CFTR) chloride channel was investigated with the cell-attached and excised patch clamp technique in conjunction with current noise analysis of recordings containing multiple channels per patch. Spectra of CFTR-generated current noise contained a low-frequency and a high-frequency Lorentzian noise component. In the cell-attached mode, the high-frequency Lorentzian was significantly dependent on the membrane potential, while the low-frequency Lorentzian was unaffected. Excision of forskolin-stimulated patches into ATP-containing solution significantly reduced the amplitude of the voltage-dependent high-frequency Lorentzian. Addition of the tyrosine kinase p60c-src to excised, active, CFTR-containing membrane patches increased mean currents by 54%, increased the corner frequency of the low-frequency Lorentzian, and recovered the high-frequency Lorentzian and its characteristics. Treatment with lambda-phosphatase inactivated src-induced currents and changes in gating. When active patches were excised under conditions in which patch-associated tyrosine phosphatases were blocked with sodium vanadate, the high-frequency gating remained relatively unchanged. The results suggest that CFTR's open probability and its voltage-dependent fast gate are dependent on tyrosine phosphorylation, and that membrane-associated tyrosine phosphatases are responsible for inactivation of the fast gate after patch excision.