Potassium is the most abundant cation in the organism and is crucial for excitability of neurones and muscle cells including cardiomyocytes. Plasma potassium is in the range of 3.5–5.0 mmol l−1 and, while only a small fraction of total body potassium is found in the plasma and the interstitial fluid, its regulation is critical to normal physiology mainly because, owing to the large intra- to extracellular potassium concentration gradient, small changes in extracellular potassium are reflected in large changes in excitability. The long-term maintenance of potassium balance depends principally on tightly regulated renal excretion of ingested potassium. Colonic potassium secretion, however, has long been known to contribute to overall potassium metabolism, and to respond to dietary hyperkalaemia and to aldosterone. The main elements of the mechanism of colonic potassium secretion have also been known for over two decades: active colonic epithelial potassium secretion requires uptake of potassium at the basolateral membrane via the sodium/potassium/chloride cotransporter and the sodium/potassium pump, and apical exit through a potassium conductance (Sweiry & Binder, 1989). In addition to this role in potassium homeostasis in health, the potassium secretory capacity of the colon is increased in disorders such as end-stage renal disease, where it might be interpreted as an adaptive mechanism (Sandle & Hunter, 2010). Recent years have seen great advances in our understanding of the molecular mechanisms of the intestinal transport process, thanks to the combined use of the tools of physiology and the genetic manipulation of the mouse genome. In the present issue of The Journal of Physiology, Sorensen et al. (2010) exploit two different knock-out animals, combined with judiciously chosen physiological and pharmacological tricks, to demonstrate that cAMP-dependent potassium secretion in the colon is mediated by the calcium-dependent large-conductance potassium channel known as BK. Moreover, they demonstrate that two different BK channel variants known to respond differentially to cAMP and resulting from alternative splicing are expressed in mouse colon, going some way to explain how a single channel type can underlie response of the epithelium to diverse stimuli. Previous work from Leipziger's group has demonstrated that the large-conductance, calcium-activated potassium channel BK encoded by Kcnma1 is responsible for the apical membrane conductance mediating potassium secretion across colon epithelium under basal conditions and in response to calcium agonists (Sausbier et al. 2006). In addition, they have provided evidence that the same BK channels mediate enhanced potassium secretion in mouse distal colon by increases in aldosterone induced by a high potassium diet. BK was detected in colon crypts by immunohistochemistry and an increase in its expression was seen in animals with a high potassium diet (Sorensen et al. 2008). Having demonstrated that BK channels mediate calcium-activated potassium secretion, Sorensen et al. (2010) now explore whether a potentially quite different mechanism of potassium secretion, namely that under the regulation of increases in cAMP, is also mediated by the BK channels. Some inkling that this might be the case comes from the observation that cAMP-dependent BK-like channel activity is present in rat colonic crypts (Perry & Sandle, 2009). The problem is not easy to attack using intact tissue as all along the intestine, and particularly in the colon, there is a large cAMP-dependent anion secretion that produces electrical signals of opposite sign from those associated with potassium secretion, making its isolation difficult. To overcome this hurdle Sorensen et al. (2010) utilise two mouse types: an animal deficient in the large-conductance, calcium-activated BK potassium channel encoded by Kcnma1 and a second, null for Cftr that is deficient in the cAMP-dependent apical membrane cystic fibrosis transmembrane regulator (CFTR) anion channel essential for chloride secretion. Classical Ussing chamber experiments and the use of adrenaline as a cAMP agonist acting through β-receptors, show the presence of potassium secretion in mouse colon. Potassium secretory current is masked by anion secretion, that Sorensen et al. (2010) get rid of by using CFTR knock-out animals, where only a sustained positive potassium current is seen in response to adrenaline. A similar current is obtained by subtraction using tissues from WT and BK-deficient animals revealing that adrenaline (and hence cAMP)-activated potassium secretion is mediated by this calcium-activated potassium channel. One might ask at this point what is a calcium-activated channel doing in a cAMP-mediated process?Sorensen et al. (2010) go on to show the presence of two C-terminal splice variants of BK in colon epithelium. These variants known as ZERO and STREX have opposite responses to intracellular increases of cAMP. While the ZERO variant is activated, the STREX variant is inhibited by cAMP (Tian et al. 2001). It is quite interesting that a ZERO variant increase in expression accounts for the total increase in messenger for BK in potassium-loaded mice. As a good paper should, this one by Sorensen et al. (2010) opens up more questions than it answers. For instance, what β-subunit accompanies the pore-forming BK subunits to support the observed sustained potassium secretion? Leipziger's laboratory had identified subunit 2 as the sole β-subunit in colon epithelium, a suitable partner to accompany the BK in the calcium-activated response, which is intense but of short duration. We, on the other hand have detected the presence of β-subunits 1 and 4 (Flores et al. 2007), which promote sustained BK-mediated currents. Are the STREX and ZERO variants expressed in the same cell type? This question is of particular relevance seeing that STREX exerts a powerful dominant negative effect on ZERO that is modulated in a complex way by cAMP-dependent phosphorylation (Tian et al. 2004). What is the mechanism by which aldosterone, if that is indeed the signal, regulates BK alternative splicing? These are all important questions that will no doubt be addressed in the future to improve our understanding of the colon as a potassium regulatory organ. The new results by Sorensen et al. (2010) represent a major progress in this quest.