Lateral intercellular space volume as a determinant of CFTR-mediated anion secretion across small intestinal mucosa.

Studies of full-thickness, small intestinal preparations have shown that maximal anion secretion [indexed by short-circuit current (I(sc))] during intracellular cAMP (cAMP(i)) stimulation is transient and followed by a decline toward baseline. Declining I(sc) is preceded by decreases in transepithelial conductance (G(t)), which in the small intestine reflects the lateral intercellular space (LIS) volume of the paracellular pathway. We hypothesized that decreases in LIS volume limit the magnitude and duration of cAMP(i)-stimulated anion secretion. Experimental manipulations to increase the patency of the LIS (assessed by G(t) and electron microscopy) were investigated for an effect on the magnitude of cAMP(i)-stimulated anion secretion (assessed by the I(sc) and isotopic fluxes) across murine small intestine. In control studies, changes of G(t) after cAMP(i) stimulation were associated with a morphological "collapse" of the LIS, which did not occur in intestine of CFTR-null mice. Removal of the outer intestinal musculature, exposure to a serosal hypertonic solution, or increased serosal hydrostatic pressure minimized reductions in G(t) and increased the cAMP(i)-stimulated I(sc) response. Increased I(sc) primarily resulted from increased Cl(-) secretion that was largely bumetanide sensitive. However, bumetanide-insensitive I(sc) was also increased, and similar increases occurred in the Na(+)-K(+)-2Cl(-) cotransporter (NKCC1)-null intestine, indicating that activities of non-NKCC1 anion uptake proteins are also affected by LIS volume. Thus LIS patency is an important determinant of the magnitude and duration of CFTR-mediated anion secretion in murine small intestine. Decreases in LIS volume may limit the pool of available anions to basolateral transporters involved in transepithelial secretion.