Nitrite-generated NO circumvents dysregulated arginine/NOS signaling to protect against intimal hyperplasia in Sprague-Dawley rats
Matthew J. Alef, Raghuveer Vallabhaneni, Evie Carchman, Sidney M. Morris Jr., Sruti Shiva, Yinna Wang, Eric E. Kelley, Margaret M. Tarpey, Mark T. Gladwin, Edith Tzeng, Brian S. Zuckerbraun
Matthew J. Alef, Raghuveer Vallabhaneni, Evie Carchman, Sidney M. Morris Jr., Sruti Shiva, Yinna Wang, Eric E. Kelley, Margaret M. Tarpey, Mark T. Gladwin, Edith Tzeng, Brian S. Zuckerbraun
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Research Article

Nitrite-generated NO circumvents dysregulated arginine/NOS signaling to protect against intimal hyperplasia in Sprague-Dawley rats

Abstract

Vascular disease, a significant cause of morbidity and mortality in the developed world, results from vascular injury. Following vascular injury, damaged or dysfunctional endothelial cells and activated SMCs engage in vasoproliferative remodeling and the formation of flow-limiting intimal hyperplasia (IH). We hypothesized that vascular injury results in decreased bioavailability of NO secondary to dysregulated arginine-dependent NO generation. Furthermore, we postulated that nitrite-dependent NO generation is augmented as an adaptive response to limit vascular injury/proliferation and can be harnessed for its protective effects. Here we report that sodium nitrite (intraperitoneal, inhaled, or oral) limited the development of IH in a rat model of vascular injury. Additionally, nitrite led to the generation of NO in vessels and SMCs, as well as limited SMC proliferation via p21Waf1/Cip1 signaling. These data demonstrate that IH is associated with increased arginase-1 levels, which leads to decreased NO production and bioavailability. Vascular injury also was associated with increased levels of xanthine oxidoreductase (XOR), a known nitrite reductase. Chronic inhibition of XOR and a diet deficient in nitrate/nitrite each exacerbated vascular injury. Moreover, established IH was reversed by dietary supplementation of nitrite. The vasoprotective effects of nitrite were counteracted by inhibition of XOR. These data illustrate the importance of nitrite-generated NO as an endogenous adaptive response and as a pathway that can be harnessed for therapeutic benefit.

Authors

Matthew J. Alef, Raghuveer Vallabhaneni, Evie Carchman, Sidney M. Morris Jr., Sruti Shiva, Yinna Wang, Eric E. Kelley, Margaret M. Tarpey, Mark T. Gladwin, Edith Tzeng, Brian S. Zuckerbraun

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Figure 3

Sodium nitrite increases NO generation.

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Sodium nitrite increases NO generation. (A) NO generation from injured c...
(A) NO generation from injured carotid arteries ex vivo demonstrated a significant increase with the addition of sodium nitrite (9.1 ± 0.44 pmol NO/min/mg protein) compared with vehicle-exposed vessels (0.9 ± 0.2 pmol NO/min/mg protein; *P < 0.01) even in the presence of the NOS inhibitor L-NAME. n = 4 arteries per group, each measured in triplicate. (B) NO generation from cultured SMCs demonstrated a significant increase with the addition of sodium nitrite (7.2 ± 1.4 pmol NO/min/mg protein) compared with vehicle (0.87 ± 0.14 pmol NO/min/mg protein; *P < 0.01). The results are the mean ± SEM for 3 independent experiments, with experiments performed in triplicate for each condition. (C) S-nitrosothiol–modified protein concentration in carotid arteries 4 weeks after injury demonstrated decreased S-nitrosothiol concentration compared with uninjured vessels (**P < 0.05). Oral sodium nitrite supplementation during days 15–28 increased S-nitrosothiol content in injured vessels (#P < 0.05 compared with non-nitrite injured vessels). n = 4 vessels per group. (D) Immunohistochemistry for S-nitrosocysteine (red) demonstrated minimal expression within the injured vessels of control rats versus the injured vessels of rats supplemented with nitrite. Scale bar: 50 μm.