BACKGROUND: Tetrahydrobiopterin (BH4) is an essential cofactor of endothelial nitric oxide synthase (eNOS). When BH4 levels are decreased, eNOS becomes uncoupled to produce superoxide anion (O2(-)) instead of NO, which contributes to endothelial dysfunction. Deoxycorticosterone acetate (DOCA)-salt hypertension is characterized by a suppressed plasma renin level due to sodium retention but manifests in eNOS uncoupling; however, how endogenous BH4 regulates blood pressure is unknown. GTP cyclohydrolase I (GTPCH I) is the rate-limiting enzyme for de novo BH4 synthesis. This study tested the hypothesis that endothelium-specific GTPCH I overexpression retards the progression of hypertension through preservation of the structure and function of resistance mesenteric arteries. METHODS AND RESULTS: During 3 weeks of DOCA-salt treatment, arterial blood pressure was increased significantly in wild-type mice, as determined by radiotelemetry, but this increase was attenuated in transgenic mice with endothelium-specific GTPCH I overexpression (Tg-GCH). Arterial GTPCH I activity and BH4 levels were decreased significantly in wild-type DOCA-salt mice, but both were preserved in Tg-GCH mice despite DOCA-salt treatment. Significant remodeling of resistance mesenteric arteries (approximately 100-microm outside diameter) in wild-type DOCA-salt mice exists, evidenced by increased medial cross-sectional area, media thickness, and media-lumen ratio and overexpression of tenascin C, an extracellular matrix glycoprotein that contributes to hypertrophic remodeling; all of these effects were prevented in DOCA-salt-treated Tg-GCH mice. Furthermore, NO-mediated relaxation in mesenteric arteries was significantly improved in DOCA-salt-treated Tg-GCH mice, in parallel with reduced O2(-) levels. Finally, phosphorylation of eNOS at serine residue 1177 (eNOS-S1177), but not its dimer-monomer ratio, was decreased significantly in wild-type DOCA-salt mice compared with sham controls but was preserved in DOCA-salt-treated Tg-GCH mice. CONCLUSIONS: These results demonstrate that endothelium-specific GTPCH I overexpression abrogates O2(-) production and preserves eNOS phosphorylation, which results in preserved structural and functional integrity of resistance mesenteric arteries and lowered blood pressure in low-renin hypertension.
BACKGROUND:Tetrahydrobiopterin (BH4) is an essential cofactor of endothelial nitric oxide synthase (eNOS). When BH4 levels are decreased, eNOS becomes uncoupled to produce superoxide anion (O2(-)) instead of NO, which contributes to endothelial dysfunction. Deoxycorticosterone acetate (DOCA)-salthypertension is characterized by a suppressed plasma renin level due to sodium retention but manifests in eNOS uncoupling; however, how endogenous BH4 regulates blood pressure is unknown. GTP cyclohydrolase I (GTPCH I) is the rate-limiting enzyme for de novo BH4 synthesis. This study tested the hypothesis that endothelium-specific GTPCH I overexpression retards the progression of hypertension through preservation of the structure and function of resistance mesenteric arteries. METHODS AND RESULTS: During 3 weeks of DOCA-salt treatment, arterial blood pressure was increased significantly in wild-type mice, as determined by radiotelemetry, but this increase was attenuated in transgenic mice with endothelium-specific GTPCH I overexpression (Tg-GCH). Arterial GTPCH I activity and BH4 levels were decreased significantly in wild-type DOCA-saltmice, but both were preserved in Tg-GCH mice despite DOCA-salt treatment. Significant remodeling of resistance mesenteric arteries (approximately 100-microm outside diameter) in wild-type DOCA-saltmice exists, evidenced by increased medial cross-sectional area, media thickness, and media-lumen ratio and overexpression of tenascin C, an extracellular matrix glycoprotein that contributes to hypertrophic remodeling; all of these effects were prevented in DOCA-salt-treated Tg-GCH mice. Furthermore, NO-mediated relaxation in mesenteric arteries was significantly improved in DOCA-salt-treated Tg-GCH mice, in parallel with reduced O2(-) levels. Finally, phosphorylation of eNOS at serine residue 1177 (eNOS-S1177), but not its dimer-monomer ratio, was decreased significantly in wild-type DOCA-saltmice compared with sham controls but was preserved in DOCA-salt-treated Tg-GCH mice. CONCLUSIONS: These results demonstrate that endothelium-specific GTPCH I overexpression abrogates O2(-) production and preserves eNOS phosphorylation, which results in preserved structural and functional integrity of resistance mesenteric arteries and lowered blood pressure in low-renin hypertension.
Authors: Surawee Chuaiphichai; Victoria S Rashbrook; Ashley B Hale; Lucy Trelfa; Jyoti Patel; Eileen McNeill; Craig A Lygate; Keith M Channon; Gillian Douglas Journal: Hypertension Date: 2018-05-29 Impact factor: 10.190
Authors: Kyle C McKenna; Kelly M Beatty; Rebecca C Scherder; Fuwang Li; Huanbo Liu; Alex F Chen; Arnab Ghosh; Dennis J Stuehr Journal: J Immunol Date: 2012-12-12 Impact factor: 5.422
Authors: Christopher Newton-Cheh; Toby Johnson; Vesela Gateva; Martin D Tobin; Murielle Bochud; Lachlan Coin; Samer S Najjar; Jing Hua Zhao; Simon C Heath; Susana Eyheramendy; Konstantinos Papadakis; Benjamin F Voight; Laura J Scott; Feng Zhang; Martin Farrall; Toshiko Tanaka; Chris Wallace; John C Chambers; Kay-Tee Khaw; Peter Nilsson; Pim van der Harst; Silvia Polidoro; Diederick E Grobbee; N Charlotte Onland-Moret; Michiel L Bots; Louise V Wain; Katherine S Elliott; Alexander Teumer; Jian'an Luan; Gavin Lucas; Johanna Kuusisto; Paul R Burton; David Hadley; Wendy L McArdle; Morris Brown; Anna Dominiczak; Stephen J Newhouse; Nilesh J Samani; John Webster; Eleftheria Zeggini; Jacques S Beckmann; Sven Bergmann; Noha Lim; Kijoung Song; Peter Vollenweider; Gerard Waeber; Dawn M Waterworth; Xin Yuan; Leif Groop; Marju Orho-Melander; Alessandra Allione; Alessandra Di Gregorio; Simonetta Guarrera; Salvatore Panico; Fulvio Ricceri; Valeria Romanazzi; Carlotta Sacerdote; Paolo Vineis; Inês Barroso; Manjinder S Sandhu; Robert N Luben; Gabriel J Crawford; Pekka Jousilahti; Markus Perola; Michael Boehnke; Lori L Bonnycastle; Francis S Collins; Anne U Jackson; Karen L Mohlke; Heather M Stringham; Timo T Valle; Cristen J Willer; Richard N Bergman; Mario A Morken; Angela Döring; Christian Gieger; Thomas Illig; Thomas Meitinger; Elin Org; Arne Pfeufer; H Erich Wichmann; Sekar Kathiresan; Jaume Marrugat; Christopher J O'Donnell; Stephen M Schwartz; David S Siscovick; Isaac Subirana; Nelson B Freimer; Anna-Liisa Hartikainen; Mark I McCarthy; Paul F O'Reilly; Leena Peltonen; Anneli Pouta; Paul E de Jong; Harold Snieder; Wiek H van Gilst; Robert Clarke; Anuj Goel; Anders Hamsten; John F Peden; Udo Seedorf; Ann-Christine Syvänen; Giovanni Tognoni; Edward G Lakatta; Serena Sanna; Paul Scheet; David Schlessinger; Angelo Scuteri; Marcus Dörr; Florian Ernst; Stephan B Felix; Georg Homuth; Roberto Lorbeer; Thorsten Reffelmann; Rainer Rettig; Uwe Völker; Pilar Galan; Ivo G Gut; Serge Hercberg; G Mark Lathrop; Diana Zelenika; Panos Deloukas; Nicole Soranzo; Frances M Williams; Guangju Zhai; Veikko Salomaa; Markku Laakso; Roberto Elosua; Nita G Forouhi; Henry Völzke; Cuno S Uiterwaal; Yvonne T van der Schouw; Mattijs E Numans; Giuseppe Matullo; Gerjan Navis; Göran Berglund; Sheila A Bingham; Jaspal S Kooner; John M Connell; Stefania Bandinelli; Luigi Ferrucci; Hugh Watkins; Tim D Spector; Jaakko Tuomilehto; David Altshuler; David P Strachan; Maris Laan; Pierre Meneton; Nicholas J Wareham; Manuela Uda; Marjo-Riitta Jarvelin; Vincent Mooser; Olle Melander; Ruth J F Loos; Paul Elliott; Gonçalo R Abecasis; Mark Caulfield; Patricia B Munroe Journal: Nat Genet Date: 2009-05-10 Impact factor: 38.330