AJP - Renal Physiology, Vol 249, Issue 5 636-F644, Copyright © 1985 by American Physiological Society
Evidence for a DCCD-sensitive component of proximal bicarbonate reabsorption
N. Bank, H. S. Aynedjian and B. F. Mutz
To examine the possible contribution of active H+ secretion mediated by
brush border enzymes to proximal tubule HCO-3 absorption, paired
reperfusions of surface proximal convoluted tubules were performed with the
inhibitor dicyclohexylcarbodiimide (DCCD). In control studies using a
solution devoid of HCO-3 but containing 5.5 mM glucose, 1 mM DCCD had no
effect on glucose or fluid (Na+) absorption, suggesting that this inhibitor
did not interfere with sodium entry at the brush border or mitochondrial
energy production (ATP synthesis). In experiments using a perfusion
solution containing 18-25 mM HCO-3, DCCD caused a fall in absolute CO2
absorption of approximately 15% under eucapneic conditions and 30% during
acute hypercapnia. One millimole per liter amiloride (an inhibitor of the
passive Na+-H+ exchanger) caused a 15% inhibition of CO2 absorption during
acute hypercapnia and a disproportionately large reduction in fluid (Na+)
absorption. The latter was not due to cell poisoning, since 1 mM amiloride
had no inhibitory effect on fluid or glucose absorption when a HCO-3-free
perfusion solution was used. Addition of 1 mM DCCD to a perfusion solution
containing either 10(-3) M amiloride or 10(-4) M acetazolamide caused a
significant inhibition of CO2 absorption compared with amiloride or
acetazolamide alone. The observations are consistent with the view that in
addition to passive Na+-H+ exchange, active transport mediated by either a
H+-ATPase or a redox-driven H+ pump in the brush border contributes
significantly to HCO-3 absorption in the proximal tubule.
