Identification of an ecto-nucleoside diphosphokinase and its contribution to interconversion of P2 receptor agonists.

The P2Y4 receptor is selectively activated by UTP. Although addition of neither ATP nor UDP alone increased intracellular Ca2+ in 1321N1 human astrocytoma cells stably expressing the P2Y4 receptor, combined addition of these nucleotides resulted in a slowly occurring elevation of Ca2+. The possibility that the stimulatory effect of the combined nucleotides reflected formation of UTP by an extracellular transphosphorylating activity was investigated. Incubation of cells with [3H]UDP or [3H]ADP under conditions in which cellular release of ATP occurred or in the presence of added ATP resulted in rapid formation of the corresponding triphosphates. Transfer of the gamma-phosphate from [gamma-33P]ATP to nucleoside diphosphates confirmed that the extracellular enzymatic activity was contributed by a nucleoside diphosphokinase. The majority of this activity was associated with the cell surface of 1321N1 cells, suggesting involvement of an ectoenzyme. Both ADP and UDP were effective substrates for transphosphorylation. Since ecto-nucleotidase(s) has been considered previously to be the primary enzyme(s) responsible for metabolism of extracellular nucleotides, the relative rates of hydrolysis of ATP, ADP, UTP, and UDP also were determined for 1321N1 cells. All four nucleotides were hydrolyzed with similar Km and Vmax values. Kinetic analyses of the ecto-nucleoside diphosphokinase and ecto-nucleotidase activities indicated that the rate of extracellular transphosphorylation exceeds that of nucleotide hydrolysis by up to 20-fold. Demonstration of the existence of a very active ecto-nucleoside diphosphokinase together with previous observations that stress-induced release of ATP occurs from most cell types indicates that transphosphorylation is physiologically important in the extracellular metabolism of adenine and uridine nucleotides. Since the P2Y receptor class of signaling proteins differs remarkably in their respective specificity for adenine and uridine nucleotides and di- and triphosphates, these results suggest that extracellular interconversion of adenine and uridine nucleotides plays a key role in defining activities in nucleotide-mediated signaling.