A new class of organic nitrates: investigations on bioactivation, tolerance and cross-tolerance phenomena.

BACKGROUND AND PURPOSE: The chronic use of organic nitrates is limited by serious side effects including oxidative stress, nitrate tolerance and/or endothelial dysfunction. The side effects and potency of nitroglycerine depend on mitochondrial aldehyde dehydrogenase (ALDH-2). We sought to determine whether this concept can be extended to a new class of organic nitrates with amino moieties (aminoalkyl nitrates). EXPERIMENTAL APPROACH: Vasodilator potency of the organic nitrates, in vitro tolerance and in vivo tolerance (after continuous infusion for 3 days) were assessed in wild-type and ALDH-2 knockout mice by isometric tension studies. Mitochondrial oxidative stress was analysed by L-012-dependent chemiluminescence and protein tyrosine nitration. KEY RESULTS: Aminoethyl nitrate (AEN) showed an almost similar potency to glyceryl trinitrate (GTN), even though it is only a mononitrate. AEN-dependent vasodilatation was mediated by cGMP and nitric oxide. In contrast to triethanolamine trinitrate (TEAN) and GTN, AEN bioactivation did not depend on ALDH-2 and caused no in vitro tolerance. In vivo treatment with TEAN and GTN, but not with AEN, induced cross-tolerance to acetylcholine (ACh)-dependent and GTN-dependent relaxation. Although all nitrates tested induced tolerance to themselves, only TEAN and GTN significantly increased mitochondrial oxidative stress in vitro and in vivo. CONCLUSIONS AND IMPLICATIONS: The present results demonstrate that not all high potency nitrates are bioactivated by ALDH-2 and that high potency of a given nitrate is not necessarily associated with induction of oxidative stress or nitrate tolerance. Obviously, there are distinct pathways for bioactivation of organic nitrates, which for AEN may involve xanthine oxidoreductase rather than P450 enzymes.

Mitochondrial aldehyde dehydrogenase (ALDH-2)--maker of and marker for nitrate tolerance in response to nitroglycerin treatment.

The hemodynamic and anti-ischemic effects of nitroglycerin (GTN) are rapidly blunted as a result of the development of nitrate tolerance. Long-term nitrate treatment also is associated with decreased vascular responsiveness caused by changes in intrinsic mechanisms of the tolerant vasculature itself. According to the oxidative stress concept, increased vascular superoxide and peroxynitrite production as well as an increased sensitivity to vasoconstrictors secondary to activation of protein kinase C as well as vascular NADPH oxidases contribute to the development of tolerance. Recent experimental work has defined new tolerance mechanisms, including inhibition of the enzyme that bioactivates GTN (e.g. mitochondrial aldehyde dehydrogenase [ALDH-2]) and mitochondria as potential sources of reactive oxygen species (ROS). GTN-induced ROS inhibit the bioactivation of GTN by ALDH-2. Both mechanisms impair GTN bioactivation, and now converge at the level of ALDH-2 to support a new theory for GTN tolerance and GTN-induced endothelial dysfunction. The consequences of these processes for GTN downstream targets (e.g. soluble guanylyl cyclase, cyclic guanosine monophosphate-dependent protein kinase) and toxic effects contributing to endothelial dysfunction (e.g. prostacyclin synthase inhibition and NO synthase uncoupling) are discussed. Tolerance and endothelial dysfunction are distinct processes which rely on different sources of ROS and there is good evidence for a crosstalk between these distinct processes. Finally, we will address the question whether ALDH-2 inactivation by nitroglycerin could be a useful marker for clinical nitrate tolerance and discuss the redox-regulation of this enzyme by oxidative stress and dihydrolipoic acid.