Tissue nitric oxide (NO) levels increase dramatically during ischemia, an effect that has been shown to be partially independent from NO synthases. Because NO is stored in tissues as S-nitrosothiols and because these compounds could release NO during ischemia, we evaluated the effects of buthionine sulfoximine (BSO; an intracellular glutathione depletor), light stimulation (which releases NO, decomposing S-nitrosothiols), and N-acetyl-L-cysteine (a sulfhydryl group donor that repletes S-nitrosothiols stores) on the changes in outer medullary NO concentration produced during 45 min of renal artery occlusion in anesthetized rats. Renal ischemia increased renal tissue NO concentration (ϩ223%), and this effect was maintained along 45 min of renal arterial blockade. After reperfusion, NO concentration fell below preischemic values and remained stable for the remainder of the experiment. Pretreatment with 10 mg/kg nitro-L-arginine methyl ester (L-NAME) decreased significantly basal NO concentration before ischemia, but it did not modify the rise in NO levels observed during ischemia. In rats pretreated with 4 mmol/kg BSO and L-NAME, ischemia was followed by a transient increase in renal NO concentration that fell to preischemic values 20 min before reperfusion. A similar response was observed when the kidney was illuminated 40 min before the ischemia. The coadministration of 10 mg/kg iv N-acetyl-L-cysteine with BSO ϩ L-NAME restored the increase in NO levels observed during renal ischemia and prevented the depletion of renal thiol groups. These results demonstrate that the increase in renal NO concentration observed during ischemia originates from thiol-dependent tissue stores. voltammetry; nitrosothiols; N-acetyl-L-cysteine; buthionine sulfoximine; photosensitive nitric oxide release IT HAS BEEN REPORTED THAT arterial ischemia produces an abrupt and significant increase in tissue nitric oxide (NO) concentration, which can last as long as ischemia is maintained and returns to preischemic levels during reperfusion. This phenomenon has been observed in kidney (27), liver (16), heart (40), gastric tissue (15), and brain (39); although its physiological relevance is unclear, it may generate the high levels of peroxynitrite anion formed during reperfusion when a burst of superoxide anion reacts with the high levels of NO accumulated during ischemia (21), thus contributing to reperfusion damage. The mechanism responsible for these increased NO levels during renal ischemia is unknown, although it seems to be partially insensitive to NO synthesis inhibition, at least in liver and kidney (16,27). This is not surprising because NO synthase (NOS) requires molecular oxygen. Therefore, during ischemia, NO must be released from other sources, such as tissue NO stores (22,26,31).In the presence of oxygen, NO is synthesized from Larginine through the action of NOS, and this gaseous hormone acts in the kidney by stimulating guanylyl cyclase and by inhibiting cytochrome P-450 (18). However, as soon as it is synthesized, NO avidly react...
