The Ca(2+)-activated Cl(-) channels (CaCCs) are involved in a variety of physiological functions, such as transepithelial anion transport, smooth muscle contraction and olfaction. Recently, the question of the molecular identity of CaCCs has apparently been resolved with the identification of TMEM16A protein (also known as anoctamin-1). Expression of TMEM16A is associated with the appearance of Ca(2+)- and voltage-dependent Cl(-) currents with properties similar to those of native CaCCs. The putative structure of TMEM16A consists of eight transmembrane domains, with both the amino- and the carboxy-terminus protruding in the cytosol. TMEM16A is also characterized by the existence of different protein variants generated by alternative splicing. A close paralogue of TMEM16A, TMEM16B (anoctamin-2), is also associated with CaCC activity, although with different properties. The TMEM16B-dependent channels require higher intracellular Ca(2+) concentrations and have faster activation and deactivation kinetics. Expression of other anoctamins is devoid of detectable channel activity. These proteins, such as TMEM16F (anoctamin-6), may have different functions.

Previous reports point out to a functional relationship of the cystic fibrosis transmembrane conductance regulator (CFTR) and Ca(2+) activated Cl(-) channels (CaCC). Recent findings showing that TMEM16A forms the essential part of CaCC, prompted us to examine whether CFTR controls TMEM16A. Inhibition of endogenous CaCC by activation of endogenous CFTR was found in 16HBE human airway epithelial cells, which also express TMEM16A. In contrast, CFBE airway epithelial cells lack of CFTR expression, but express TMEM16A along with other TMEM16-proteins. These cells produce CaCC that is inhibited by overexpression and activation of CFTR. In HEK293 cells coexpressing TMEM16A and CFTR, whole cell currents activated by IMBX and forskolin were significantly reduced when compared with cells expressing CFTR only, while the halide permeability sequence of CFTR was not changed. Expression of TMEM16A, but not of TMEM16F, H or J, produced robust CaCC, which that were inhibited by CaCCinh-A01 and niflumic acid, but not by CFTRinh-172. TMEM16A-currents were attenuated by additional expression of CFTR, and were completely abrogated when additionally expressed CFTR was activated by IBMX and forskolin. On the other hand, CFTR-currents were attenuated by additional expression of TMEM16A. CFTR and TMEM16A were both membrane localized and could be coimmunoprecipitated. Intracellular Ca(2+) signals elicited by receptor-stimulation was not changed during activation of CFTR, while ionophore-induced rise in [Ca(2+)](i) was attenuated after stimulation of CFTR. The data indicate that both CFTR and TMEM16 proteins are separate molecular entities that show functional and molecular interaction.