Regulation by nitric oxide of prostaglandin E synthesis and spontaneous motility in rat uterine tissue

Abstract

We explored the role of endogenous nitric oxide (NO) in the spontaneous motility of uterine tissue from pseudopregnant (psp) rats and the correlation between this action and the uterotonic prostaglandin (PG) E production. We worked in the early psp (on day 5 of psp), and in late psp (on day 8 and day 9). Treatment with N G-monomethyl- l-arginine l-NMMA (300 μM), a competitive nitric oxide synthase (NOS) inhibitor, did not modify isometric developed tension (IDT) and frequency of contractions (FC) on day 5 of psp; on day 8, tissue pretreated with l-NMMA showed an increase in the IDT and FC compared with controls, while on day 9 of psp, both IDT and FC showed a lower stability after treatment with the inhibitor. These data suggest that NO modulates uterine motility on day 8 (decreasing it) and on day 9 of psp (enhancing it). We also evaluated the total NOS activity and that of its isoforms at the three times mentioned, demonstrating that total NOS activity was higher on day 5 of psp and decreased with psp development. On day 5 of psp, calcium-dependent and calcium-independent NOS each forms around 50% of total NOS activity. On day 8 of psp, the calcium-dependent was the predominant NOS form, while on day 9 of psp, the uterine tissue showed a higher calcium-independent form of the enzyme. In view of the fact that we found an inhibitor effect of the endogenous NO in uterine contractility on day 8 of psp and an inverse action on day 9 of psp (enhancing uterine contractility), we suggest that the NOS calcium-dependent form could be responsible for uterine contractility in psp rats. Finally, we evaluated the relationship between endogenous NO and PGE production. We observed that on days 5 and 8 of psp, the L-NMMA (300 μM) treatment did not affect PGE production, but on day 9 of psp, the preincubation with the NOS inhibitor diminished PGE synthesis, suggesting that at this time endogenous NO can upregulate uterine PGE production. These results confirm that NO can modulate uterine motility by means of PGE production. In summary, we suggest that in uterine tissue from psp rats, the NO system can alternatively decrease or increase uterine contractions, this last effect by enhancing uterine PGE synthesis.