Two important issues that can be addressed by animal models are disease pathogenesis and the testing of new treatments, including gene therapy. How closely these models mimic the relevant disorder in humans will determine their usefulness. This study examines how closely the characteristic bioelectric features of cystic fibrosis (CF) are reproduced in the airways and intestinal tract of the exon 10 insertional mutant mouse (cf/cf). In agreement with CF subjects these cf/cf mutant mice demonstrate the following: 1) reduced adenosine 3',5'-cyclic monophosphate-related chloride secretion throughout the respiratory and intestinal tracts both in vivo and in vitro, 2) calcium-related chloride secretion that is preserved in the airways but reduced in the intestine, and 3) a more negative nasal potential difference and increased amiloride response compared with wild-type animals, likely to relate to increased sodium absorption. In contrast to humans, sodium absorption is not increased in the small intestine and is reduced in the trachea of the cf/cf mice. We conclude that the majority of the salient electrophysiological features of CF required for studies of pathogenesis or testing of new treatments are present in these cf/cf mice.