Medullary Collecting Duct Acidification

The medullary collecting duct (MCD) from renal outer medulla possesses significant HCO3 absorptive capacity. In vitro microperfusion studies have shown that HCO3 absorption in this segment is carbonic anhydrase dependent, affected by peritubular and luminal chloride concentrations, is independent of the presence of Na or the presence of Na transport, and is stimulated by mineralocorticoid hormone. The present in vitro microperfusion studies defined regulatory influences on MCD acidification as assessed by acute changes in the extracellular K and HCO3 concentrations and pCO2. These studies showed that acute changes in the peritubular K concentration to either 0 mM K or 50 mM K have no significant effect on HCO3 absorption in MCD. Intracellular voltage recordings showed that elevation of peritubular K concentration from 5 to 50 mM produced only a 2.8 mV depolarization of the basolateral cell membrane of MCD cells. In addition, acute reduction of peritubular K from 5 to 0 mM had no significant effect on intracellular voltage. Studies that were designed to assess the effects of HCO3 concentration and pCO2 on acidification showed that acute reduction of peritubular HCO3 concentration from 25 to 5 mM (pH change from 7.4 to 6.8) increased lumen-positive voltage from 30.2±3.8 to 40.0±4.4 mV, and simultaneously increased net HCO3 absorption from 15.6±1.9 to 22.9±2.9 pmol* mm*min-'. Elevation of peritubular HCO3 concentration from 25 to 50 mM (pH change from 7.4 to 7.8) significantly decreased lumenpositive voltage from 33.8±2.4 to 26.7± 1.5 mV and Dr. Jacobson is the recipient of National Institutes of Health Research Career Development Award 1-KO1-AM-00537. Received for publication 23 January 1984 and in revised form 22 May 1984. simultaneously decreased net HCO3 absorption from 17.9±1.2 to 12.8±1.3 pmol *mm-' *min-'. In addition, acute reduction of peritubular pCO2 from 40 to <14 mmHg (final pH 7.8-7.9) significantly decreased lumenpositive voltage from 31±4.4 to 15.7±1.0 mV. Coincidentally, HCO3 absorption decreased significantly from 11.0±3.7 to 5.3±0.7 pmol *mm' * min-'. We conclude that: (a) alteration of peritubular K concentration from 0 to 50 mM in vitro does not affect HCO3 absorption in the MCD, and that this lack of effect appears to be related to a low basolateral cell membrane K conductance; (b) net HCO3 absorption and the associated lumen-positive voltage can be modulated by in vitro changes in peritubular HCO3 and pCO2 (or pH); and (c) the MCD perfused in vitro appears to be a good model for studying the mechanisms and regulation of distal nephron acidification.