Targeting the heme-oxidized nitric oxide receptor for selective vasodilatation of diseased blood vessels
Johannes-Peter Stasch, … , Werner Müller-Esterl, Harald H.H.W. Schmidt
Johannes-Peter Stasch, … , Werner Müller-Esterl, Harald H.H.W. Schmidt
Published September 1, 2006
Citation Information: J Clin Invest. 2006;116(9):2552-2561. https://doi.org/10.1172/JCI28371.
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Research Article Cardiology

Targeting the heme-oxidized nitric oxide receptor for selective vasodilatation of diseased blood vessels

Abstract

ROS are a risk factor of several cardiovascular disorders and interfere with NO/soluble guanylyl cyclase/cyclic GMP (NO/sGC/cGMP) signaling through scavenging of NO and formation of the strong oxidant peroxynitrite. Increased oxidative stress affects the heme-containing NO receptor sGC by both decreasing its expression levels and impairing NO-induced activation, making vasodilator therapy with NO donors less effective. Here we show in vivo that oxidative stress and related vascular disease states, including human diabetes mellitus, led to an sGC that was indistinguishable from the in vitro oxidized/heme-free enzyme. This sGC variant represents what we believe to be a novel cGMP signaling entity that is unresponsive to NO and prone to degradation. Whereas high-affinity ligands for the unoccupied heme pocket of sGC such as zinc–protoporphyrin IX and the novel NO-independent sGC activator 4-[((4-carboxybutyl){2-[(4-phenethylbenzyl)oxy]phenethyl}amino) methyl [benzoic]acid (BAY 58-2667) stabilized the enzyme, only the latter activated the NO-insensitive sGC variant. Importantly, in isolated cells, in blood vessels, and in vivo, BAY 58-2667 was more effective and potentiated under pathophysiological and oxidative stress conditions. This therapeutic principle preferentially dilates diseased versus normal blood vessels and may have far-reaching implications for the currently investigated clinical use of BAY 58-2667 as a unique diagnostic tool and highly innovative vascular therapy.

Authors

Johannes-Peter Stasch, Peter M. Schmidt, Pavel I. Nedvetsky, Tatiana Y. Nedvetskaya, Arun Kumar H.S., Sabine Meurer, Martin Deile, Ashraf Taye, Andreas Knorr, Harald Lapp, Helmut Müller, Yagmur Turgay, Christiane Rothkegel, Adrian Tersteegen, Barbara Kemp-Harper, Werner Müller-Esterl, Harald H.H.W. Schmidt

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Figure 2

Effects of competitive porphyrins and the sGC Fe2+ /Fe3+ redox ratio on BAY 58-2667 binding to and activation of sGC.

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Effects of competitive porphyrins and the sGC Fe2+ /Fe3+ redox ratio on...
(A) Human sGC activity in the presence of BAY 58-2667 (filled squares), PPIX (filled circles), 10 μM BAY 58-2667 and various concentrations of PPIX (open squares), and 10 μM PPIX and various concentrations of BAY 58-2667 (open circles). Basal activity was 17 ± 3 nmol/mg/min. (B) Heme-free rat sGC activity in the presence of BAY 58-2667 (filled squares), PPIX (filled triangles), and 1 μM BAY 58-2667 and various concentrations of PPIX (open circles). Basal activity was 90 ± 7 nmol/mg/min. (C) Zn-PPIX (open squares), Fe2+-PPIX (filled circles), and Mn-PPIX (open circles) completely inhibited activation by 1 μM BAY 58-2667 (filled squares) of heme-free rat sGC. (D) Zn-PPIX displaced 3H–BAY 58-2667 (100 nM) from heme-free rat sGC. (E) Rat sGC activity in the presence of DEA/NO (filled triangles), BAY 58-2667 (open squares), BAY 41-2272 (filled circles), and BAY 41-2272 combined with 10 nM DEA/NO (open circles). (F) Rat sGC activity in the presence of 100 nM BAY 58-2667 (filled circles) combined with increasing concentrations of ODQ. Open triangles represent controls. (G) Binding of 100 nM 3H–BAY 58-2667 to sGC in the presence of increasing concentrations of ODQ. (HJ) Same conditions as EG but with heme-free rat sGC. Data are means ± SEM of 3–6 independent experiments performed in triplicate.