Paracellular phosphate absorption in rat colon: a mechanism for enema-induced hyperphosphatemia.

The mechanism of colonic phosphate absorption is not well defined. We measured unidirectional phosphate fluxes across rat distal colon epithelium in the absence of transepithelial electrochemical gradients. Steady-state mucosal-to-serosal flux (Jms) was not different from the serosal-to-mucosal flux (Jsm), generating no net flux (Jnet = Jms - Jsm, was not different from "0'). Simultaneous fluxes of mannitol, a paracellular probe, exhibited an identical flux pattern, suggesting that phosphate flux across the colonic epithelium may be mediated through the paracellular pathway. Tight junction permeability was increased with mucosal addition of taurodeoxycholate (TDC, 2 mM) which caused a prompt increase in transepithelial conductance from 7.03 +/- 0.35 to 13.88 +/- 0.35 mS/cm2 (p < 0.001). This was associated with an increase in Jsm, but no change in Jms, for mannitol, resulting in a net flux in the secretary direction. Identical TDC-induced changes were observed in phosphate fluxes, again suggesting phosphate permeation through the intercellular, mannitol pathway. A significant correlation was observed between the permeability of phosphate and the permeability of mannitol, measured both in the mucosal-to-serosal and the serosal-to-mucosal directions and under both control and experimental (mucosal TDC) conditions. Thus, colonic phosphate transport is mediated through the paracellular pathway and enema with high phosphate concentrations (1,760 times blood concentration), can trigger rapid and massive phosphate absorption through this diffusive pathway.

Role of parathyroid hormone in rat remnant kidney ammonium metabolism.

The role of parathyroid hormone (PTH) in ammonium metabolism in the rat remnant kidney was studied by examining the effects of parathyroidectomy (PTx) in rats with intact kidneys and with 5/6 nephrectomy (Nx). PTx in rats with intact kidneys caused a rise in urine pH and a decrease in urinary ammonium excretion without affecting in vitro ammonium production rate or the ammonium content in the cortex. Unexpectedly, the ammonium content in the medulla was markedly reduced by PTx so that the corticomedullary ammonium gradient was inverted. As compared to control rats, rats with 5/6 Nx had a lower urinary ammonium excretion rate, a higher in vitro ammonium production rate, and an increase in ammonium content in both cortex and medulla with reduced corticomedullary ammonium gradient. PTx in rats with 5/6 Nx led to a further decrease in urinary ammonium excretion, attenuated the increase in the in vitro ammonium production rate, and lowered the ammonium content in both cortex and medulla with inverted corticomedullary ammonium gradient. These effects of PTx in Nx rats were corrected by continuous PTH infusion with Alzet minipump. In summary, results from these studies indicate that PTH plays an important role in maintaining the urinary ammonium excretion. In rats with intact kidneys, PTH contributes to urinary ammonium excretion by increasing urinary acidification and medullary ammonium accumulation. In rats with reduced nephron mass, PTH enhances urinary ammonium excretion by stimulating ammonium production and retaining medullary ammonium in the remnant kidney.