We have examined the mitochondrial formation of NAD(P)H in rat adrenal glomerulosa cells. A short-term elevation of the K+ concentration from 3.6 to 8.4 mM induced a reversible increase in the formation of reduced pyridine nucleotides. Potassium applied after the addition of rotenone had no further effect, confirming that the redox signal was of mitochondrial origin. Inhibition of aldosterone synthesis by aminoglutethimide in K+-stimulated cells decreased the rate of decay of the NAD(P)H signal upon the termination of stimulation, indicating that the NADPH formed was consumed in aldosterone synthesis. When the NAD(P)H signal was measured simultaneously with the cytoplasmic free Ca2+ concentration ([Ca2+]i), elevation of the K+ concentration to 6.6 or 8.4 mM induced parallel increases in [Ca2+]i and NAD(P)H formation. The rates of increase and decrease of NAD(P)H were lower than for [Ca2+]i, confirming that the redox signal was secondary to the Ca2+ signal. Angiotensin II (100 pM-1 nM) induced an oscillatory NAD(P)H signal which usually returned to a lower baseline concentration, while a sustained signal with superimposed oscillations was observed at higher concentrations. Simultaneous measurements showed that NAD(P)H levels followed the [Ca2+]i pattern evoked by angiotensin II. Vasopressin (100 nM) also induced parallel oscillations of [Ca2+]i and NAD(P)H. A sustained rise in the extramitochondrial Ca2+ concentration to 1 microM induced a sustained elevation of the intramitochondrial Ca2+ concentration in permeabilized cells, as measured with rhod-2. A sustained rise in [Ca2+]i evoked by long-term stimulation with 8.4 mM K+ or 2.5 nM angiotensin II resulted in sustained NAD(P)H production. These Ca2+-dependent changes in the mitochondrial redox state support the biological response, i.e. aldosterone secretion by glomerulosa cells.