AUTOCRINE PARACRINE REGULATION OF RENAL NA+-PHOSPHATE COTRANSPORT BY DOPAMINE

We tested the hypothesis that dopamine (DA) acts as an autocrine/paracrine regulator of Na+-P(i) symport in proximal tubules, using opossum kidney (OK) cells as an in vivo model. Both DA and parathyroid hormone (PTH) increased adenosine 3',5'-cyclic monophosphate (cAMP) and inhibited Na+-gradient-dependent uptake of P-32 but not that of L-[H-3]-alanine. Incubation of OK cells with L-dopa, a DA precursor, resulted in accumulation of DA (7.4 nM), a ninefold increase of cAMP in the medium, and an inhibition (-10%) of Na+-P(i) uptake. Carbidopa, an inhibitor of aromatic-L-amino acid decarboxylase, prevented the formation of DA from L-dopa, the increase in cAMP, and the inhibition of Na+-P(i) cotransport. P(i)-replete OK cells produced more DA (+15%) from L-dopa than P(i)-deprived cells; however, the endogenous DA inhibited Na+-P(i) cotransport both in P(i)-deprived and in P(i)-replete cells. Thus OK cells can synthesize DA from L-dopa in a quantity sufficient to elicit both the maximum DA-stimulated cAMP accumulation and inhibition of Na+-P(i) cotransport in the same cell population. Our data, obtained on an in vitro system, support the hypothesis proposing that DA generated in proximal tubular cells can modulate, via cAMP, the Na+-P(i) symport in the same or adjacent cells. If present in the kidney, this pathway might represent an autocrine/paracrine system that can contribute to regulation of renal P(i) homeostasis.