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Genetic Polymorphisms Associated with Reactive Oxygen Species and Blood Pressure Regulation Abstract Hypertension is the most prevalent cause of cardiovascular disease and kidney failure but only about 50% of patients achieve adequate blood pressure control, in part, due to inter-individual genetic variations in the response to antihypertensive medication. Significant strides have been made toward the understanding of the role of reactive oxygen species (ROS) in the regulation of the cardiovascular system. However, the role of ROS in human hypertension is still unclear. Polymorphisms of some genes involved in the regulation of ROS production are associated with hypertension, suggesting their potential influence on blood pressure control and response to antihypertensive medication. This review provides an update on the genes associated with the regulation of ROS production in hypertension and discusses the controversies on the use of antioxidants in the treatment of hypertension, including the antioxidant effects of antihypertensive drugs. Introduction Hypertension is the most prevalent cause of cardiovascular disease and kidney failure1, but the prevention and treatment of hypertension are still a challenge2–4. According to the 2017 High Blood Pressure Clinical Practice Guidelines, in adults (≥20 years of age), a “doctor’s office” reading of 120-129 mm Hg for systolic blood pressure (SBP) even with less than 80 mm Hg for diastolic blood pressure (DBP), is considered as elevated BP2,3. An SBP of 130-139 mm Hg or a DBP of 80-89 is now considered as Stage 1 hypertension, while the previous definition of hypertension ≥140 SBP or ≥90 DBP is now considered as Stage 2 hypertension. In the general population, only about 50% of treated patients achieve adequate blood pressure control2,4. The poor efficacy of hypertension treatment and the inter-individual variations in the response to antihypertensive medications have many causes, including non-compliance, but genetic variations could be important contributory factors4,5. Reactive oxygen species (ROS) are inevitable by-products of aerobic existence6. Disturbance in the normal redox state of cells, either due to the overproduction of ROS or low production of antioxidants, can lead to oxidative stress and specific types of oxygen radicals, such as superoxide anion, H2O2 and hydroxyl radical, may damage all components of the cell, including proteins, lipids, and DNA7,8. The deleterious effects of ROS and their role in the pathogenesis of hypertension have been extensively demonstrated in experimental models8–10, but the benefits of antioxidant drug treatment in human hypertension are not clear8,10–12. This may be related to the fact that ROS are not always harmful; ROS are able to regulate the activity of cellular signaling pathways such as Ca2+ signaling13,14, and are involved in the regulation of several cells functions such as phenotypic modulation, migration and adhesion, vascular tone, apoptosis and sodium reabsorption between others13–18. The oxidative environment in the cell influences gene transcription, post-transcription, translation, and post-translation of proteins. Modifications of the oxidative status may eventually regulate the expression and activity of many proteins such as nuclear factor-kappaB, Nrf2, p38 mitogen-activated protein kinase, NH(2)-terminal Jun kinases/stress-activated protein kinases, hexosamines, and others13,19–27 evidencing that ROS may be essential for the normal function of cells and biological systems. Pharmacogenomics aims to individualize therapy based on the individual’s genetic profile. There are numerous endogenous oxidants and antioxidant proteins (Figure 1) in different organs, including the kidney, brain, and cardiovascular system, that keep a normal redox balance in the body. Genetic polymorphisms that affect the expression and activity of some of these pro-oxidant or antioxidant genes are associated with human hypertension (Table 1). These polymorphisms could influence the response to antihypertensive drugs, i.e., pharmacogenomics. This review provides an update on the genes associated with the regulation of ROS production in hypertension and discusses the controversies on the use of antioxidants in the treatment of hypertension, including the antioxidant effects of antihypertensive drugs. 1. Mechanisms by which ROS regulate blood pressure The role of oxidative stress in hypertension has been extensively studied and several mechanisms have been described by which ROS regulate blood pressure (Figure 1). 1.1. Endothelial damage: ROS cause endothelial dysfunction in blood vessels, including renal afferent arterioles and enhance the renal arteriolar vasoconstrictor response to angiotensin II9,10,12,13,22. Some of the benefits of superoxide scavengers in hypertension are caused by enhancement of vasodilation and an increase in renal arterial perfusion23. 1.2. Stiffening of vessels: Recent studies in humans have shown that aortic stiffening precedes the development of hypertension24. Mice with smooth muscle overexpression of p22phox, a component of NADPH oxidase, develop renal inflammation, fibrosis, and renal dysfunction, prior to the increase in blood pressure, supporting the notion that arterial stiffening induced by oxidative stress and inflammation causes hypertension25. 1.3 Glomerular damage: Glomerulonephritis without renal insufficiency can be associated with hypertension26. ROS can produce glomerular injury by damaging the podocytes, as has been described in Dahl salt-sensitive hypertensive rats27. The antioxidant tempol reduces glomerular sclerosis and proteinuria in these animals, supporting a role of ROS in the glomerular injury in Dahl salt-sensitive rats28. 1.4 Renin-angiotensin system: The development and progression of hypertension due to increased production of ROS have been related to renal vasoconstriction caused by an increase in renal afferent nerve activity and myogenic response and secretion of vasoconstrictor hormones, such as angiotensin II, endothelin-1, and thromboxane29. Angiotensin II increases ROS production, inflammation, and renal tubular ion and water transport, and decreases dopamine receptor expression and function, resulting in hypertension4,5,8,15–17,29–34 . Increasing oxidative stress is one mechanism by which angiotensin II causes renal dysfunction and tissue damage1,9,10,12,13,22,23,31–38. 1.5 NaCl retention: ROS can regulate ion transport16–18,23,35–64. Superoxide, produced by NADPH oxidase, enhances NaCl transport in the renal proximal tubule16,17,39,44,45,59, thick ascending limb of Henle41,46,48, and collecting duct18,47,48. The voltage-gated proton channel participates in the increased production of superoxide in the renal outer medulla of Dahl salt-sensitive rats46. It should be born in mind, however, that ROS can inhibit Na+/K+-ATPase and NHE3 activity in the renal proximal tubule48,50–53. 1.6 Inflammation: ROS activate pro-inflammatory transcription factors, such as NFκB and activator protein-1 and increase the expression of pro-inflammatory proteins65. ROS cause the activation, adhesion, and infiltration of inflammatory cells in tissues and organs, including the adipose tissue8,10,66. Immune cells, such as macrophages and granulocytes, release ROS to destroy engulfed bacterial or fungal pathogens and this could trigger oxidative stress67,68. Vascular stretch is associated with hypertension that could be related to an increase in ROS production and inflammation8,10,25,69,70. 1.7 Sympathetic nervous system: Renal ROS induce sympathetic activation in renovascular hypertension71; chronic antioxidant treatment reduces blood pressure in hypertension characterized by sympathoexcitation and renal oxidative stress71. Oxidative stress in the brain, specifically in the cardiovascular regulating center, causes hypertension72. 2. Genes associated with oxidative stress and blood pressure regulation. Table 1 lists the genes involved in redox balance that have been associated with hypertension. Table 1 also lists the single nucleotide polymorphisms (SNPs) that are associated with human hypertension, as well as the genes associated with oxidative stress and hypertension in animal models73–252. 2.1 Effects of antihypertensive drugs on oxidative stress Table 2 lists the antioxidant drugs shown to reduce blood pressure in humans and animal models of hypertension253–328. These antioxidants have different mechanisms of action and various combinations may have synergistic effects on the regulation of blood pressure. For example, the antihypertensive effect of the combination of zinc sulfate, ascorbic acid, α-tocopherol, and β-carotene may be due to an increase in the bioavailability of NO324. By contrast, antioxidant drugs such as vitamin E, under certain conditions, can also increase the blood pressure in mice325. Vitamin E at doses greater than 150 IU daily increases the risk of all-cause mortality in humans326. The combination of vitamin C and polyphenols has also been reported to increase blood pressure variability229, and the antioxidant properties observed in vitro may not be observed in vivo328. The effect of chemicals on ROS production and blood pressure is complex and not easily predictable. 2.2 Pharmacogenomics of antioxidant drugs Increased ROS production is involved in the pathogenesis of many1,5,8–17,22,23,25,28–44,48,57,60,62–64,68,71,72,86,89,92,104,138,140–154,162,163,173,189,197,210,214,218,219,221–233,236–244,246–252,262,263.270–273,278–280,295,305.329–331, but not all cases232–234 of hypertension. Deletion of the gene that encodes thioredoxin reductase 2 increases ROS production but blood pressure is actually decreased235. Nevertheless, genetic polymorphisms in pro-oxidant or antioxidant genes may affect the redox balance in the kidney, cardiovascular system, and brain (Figure 1), among others. Therefore, genetic polymorphisms may be involved in the inter-individual variability of the effects of antihypertensive medications. Many genes involved in ROS production and their polymorphisms associated with hypertension have been identified (Table 1). 2.2.1 Polymorphisms in Pro-oxidant Genes Angiotensinogen (AGT) is converted to angiotensin I by renin and angiotensin 1 to angiotensin II by angiotensin converting enzyme (ACE); angiotensin II induces oxidative stress by stimulation of NADPH oxidase activity15,22,23,29–31,36,37,42,47,48,56,57. Polymorphisms in AGT are associated with hypertension in humans78–83; a haplotype of human AGT gene containing −217A or −6G increases blood pressure in transgenic mice76,77. The NADPH oxidase (NOX) family has seven members which are classified into three groups: group 1 is comprised of NOX1, NOX2, NOX3, NOX4; group 2 has NOX5 as the only member, and group 3 is comprised of DOUX1 and DOUX248,332. Increased NOX activity is implicated in many disease states, including hypertension and renal disease5,10,15,23,25,29–32,36,47,48,56,57,125–147,332–344. p22phox (CYBA, cytochrome B-245 alpha chain) is a membrane-associated protein that plays a crucial role in the activation of NOX1, NOX2, NOX448, and NOX5333. Mutations of CYBA lead to autosomal recessive forms of chronic granulomatous disease334. Germline deletion of CYBA in mice335 or silencing of CYBA in Sprague-Dawley rats does not affect basal blood pressure but ameliorates angiotensin II-induced hypertension125,126. However, smooth muscle-specific overexpression of p22phox in mice increases blood pressure that is normalized in the offspring of dams crossed with Rag1−/− mice25. Polymorphisms in the CYBA promoter in the spontaneously hypertensive rat (SHR) increase the gene expression of CYBA336. Several polymorphisms of CYBA that could affect the production of ROS have also been reported in humans,334,. Some other CYBA gene variants are associated with decreased NOX2-dependent ROS generation but their association with blood pressure has not been studied128. Other CYBA gene variants are associated with increased ROS production and hypertension in several ethnic groups129,130,131,134–136,337. However, although CYBA 242C>T is associated with endothelial dysfunction, it is not associated with hypertension in an Asian-Indian population338. A meta-analysis found no association of CYBA 242C>T with hypertension134. CYBA 242C>T may be protective of coronary artery disease in an Asian population132 but increases the risk of diabetes mellitus133. In an Asian-Indian population, the haplotypes rs8854A/rs9932581G/rs4873C and rs8854G/rs9932581G/rs4873C are positively associated with increased blood pressure and oxidative stress while the haplotype rs8854G/rs9932581A/rs4873T is inversely correlated with blood pressure and oxidative stress339. NOX5 gene, which is present in humans but not rodents, is expressed to a greater degree than the other isoforms in renal proximal tubule cells from hypertensive humans340. Certain NOX5 SNPs have been reported to be associated with decreased (NOX5 77M>K) activity and ROS production341. However, mice with podocyte-specific human NOX5 expression develop renal disease and high blood pressure342. Genes that interact with NOXs have polymorphisms that may also be associated with increased ROS production and hypertension. For example, a polymorphism in the 3’UTR (rs11169571 [T>C] of the activating transcription factor 1 [ATF]) may be involved in essential hypertension by induction of NOX1 and increase in ROS production343. The minor T allele of rs6967221 in RAC1, one of the cytosolic components of NOX1, NOX2, and NOX3, is associated with a decreased systolic blood pressure response to high sodium intake152. Endothelin-1 (ET-1) is a potent vasoconstrictor which can increase ROS production by stimulation of NADPH oxidase activity344. A polymorphism of type A endothelin-1 receptor (rs5335, 70C>G) is associated with increased night-time blood pressure105. Polymorphism at rs9349379 in PHACTR1, a distal regulator of EDN1, is associated with a lower risk of hypertension345. Myeloperoxidase (MPO) produces hypochlorous acid (HOCl) and chloride anion (Cl−) (or equivalent) from H2O2 during the neutrophil’s respiratory burst. MPO released during chronic inflammation produces tissue damage and high MPO levels may exacerbate diseases associated with atherosclerosis. However, MPO-deficient mice unexpectedly have increased atherosclerosis, relative to their wild-type littermates346, indicating that the role of MPO in cardiovascular disease is still unclear or that this murine model may not reflect human disease. The −463G>A polymorphism located in the promoter region of the MPO gene has been associated with hypertensive nephrosclerosis in patients on dialysis120 and hypertension with or without carotid atherosclerosis in Chinese121,122. However, this polymorphism has been associated with a decreased risk of hypertension in Russian females123. Xanthine dehydrogenase (XDH), aka xanthine oxidoreductase (XOR) and xanthine oxidase (XO) are interconvertible single gene products. XDH is the primary form but is converted to XO irreversibly by proteolysis or reversibly by oxidation of Cys residues. XO catalyzes hypoxanthine or xanthine to form hydrogen peroxide and uric acid while XDH produces NADH347. In the blood, XDH exists mainly as XO242. XOD is extensively expressed in body organs, such as the liver, muscle, brain, and kidney348. XDH-mediated increase in ROS has been described in salt-sensitive hypertension and glucocorticoid induced hypertension242. In a Spanish cohort, −337G>A and 565+64T>C and their haplotypes were found to be associated with higher systolic and diastolic blood pressures and malondialdehyde242. The variation in uric acid production, as related to polymorphisms of XDH, increases the risk of hypertension240. Lipoxygenases catalyze the dioxygenation of polyunsaturated fatty acids to their corresponding hydroperoxy derivatives. Arachidonate 15-lipoxygenase (ALOX15) gene rs2664593 has been reported to be associated with air pollution and increased left ventricular mass349. A nonsynonymous polymorphism in ALOX12, 261R>Q, has been reported to be associated with essential hypertension and urinary levels of 12-hydroxyeicosatetraenoic acid (12(S)-HETE)350. Mice lacking macrophage 12/15 lipoxygenase are resistant to L-NAME and DOCA-salt hypertension351. Cyclooxygenase-2 (COX2, PTGS2) can produce ROS, which can increase cyclooxygenase expression and activity92. −765GC+CC genotypes of PTGS2 are inconsistently associated with chronic obstructive pulmonary disease that could be related to increased ROS production90,91. PTGS2 SNPs have been associated with increased high blood pressure in humans352. Germline deletion of Cox-2 in mice increases blood pressure353. The mitochondrion, which is one of the most important sources of ROS, has been extensively associated with oxidative stress and hypertension8,12,13,145,228. ROS-induced hypertension could involve the mitochondria in the brain72 and in the kidney354,355,356. Cytochrome P450 genes are important sources of ROS in the mitochondria, endoplasmic reticulum, and plasma membrane. P450 proteins are a family of hemoproteins that catalyze the oxygenation of a wide variety of compounds and, in general, is the terminal oxidase enzyme in the electron transfer chain in the mitochondria95. The efficiency of electron transfer depends on many conditions. For example, SNPs in the gene encoding Cytochrome P450 affect the regulation of ROS production and the redox balance357,358. SNPs in the cytochrome P450 gene family have also been associated with high blood pressure in several different populations 96,98,360,361 but protective in a North Americans 97. CYP-epoxygenase decreases renal sodium transport, in part, by inhibition of ENaC activity in the cortical collecting duct362. CYP17A1 (rs11191548) is associated with increased left ventricular mass in patients with hypertension and preserved left ventricular ejection fraction363. 2.2.2 Polymorphisms of antioxidant genes Oxidative stress can occur not only from an increase in pro-oxidant activity but also from impaired antioxidant activity. SNPs of genes that decrease antioxidant gene function/expression could induce oxidative stress and increase blood pressure. Our group and others have provided evidence for the importance of the antioxidant properties of dopamine receptors in the kidney in the regulation of renal sodium transport and blood pressure, as well as dopamine receptor-mediated non-renal mechanisms in the regulation of blood pressure5,16,32,38–40,62,64,165,170,173,174,178–188,364–367. Germline deletion of the DRD2 results in oxidative stress dependent-hypertension252. DJ-1 (Park7) and paraoxonase 2 (PON2)146,163 are involved in the antioxidant properties of the D2R in the kidney. Polymorphisms associated with deficiency of DRD2 expression are associated with essential hypertension in different populations171,172,174. PON1 SNPs (e.g., −108C>T, 192Q>R) are risk factors for endothelial dysfunction and hypertension212,213. Genetic depletion of DJ-1, a mitochondrial antioxidant368, results in renal oxidative stress and high blood pressure in mice163. Dysfunction of mitochondrial proteins that decrease ROS production (e.g., SOD2, UCP2 [vide infra]) may be involved in the target-organ damage associated with hypertension369. Polymorphisms in uncoupling protein 2 (UCP2), a mitochondrial gene with antioxidant properties, are associated with an increased risk for diabetic kidney disease370. In addition, a common human polymorphism of the UCP2 gene, −866 G>A, has been associated in hypertension239. Glutathione (GSH) is another antioxidant enzyme that plays a role in blood pressure regulation371. Glutathione S-transferases (GSTs) catalyze the conjugation of the reduced form of GSH. The GST superfamily constitutes up to 10% of the cytosolic protein in some mammalian organs372. Low blood level of GST-π concentration is predictive of the time of the onset of stroke373. The GSTA1*B allele is considered as a genetic risk factor for hypertension in Japanese374. The association between the GSTT1 null and hypertension was reported in Italian women but not men198 and GSTM1 null genotype with hypertension in Korean men and women199. The GST P1b-1b genotype causes prolonged exposure to ROS and increased risk of pre-eclampsia375; GSTP1 313A>G with preeclampsia in Maya-Mestizo women201. However, a meta-analysis showed no association of GSTM1 and GSTT1 polymorphisms and the risk of hypertension376. Glutathione peroxidases (GPXs) are important in the reduction of lipid hydroperoxides and H2O2 to water; GPX4 rs713041 (718T>C) may be a predictor of cerebral stroke in hypertensive Russians196. GPX3 s3828599 (T>C) is associated with hypertension in Han Chinese195. Heme oxygenase catalyzes the degradation of heme, resulting in the formation of iron, carbon monoxide, and biliverdin, which is subsequently converted to bilirubin by biliverdin reductase188. HO-1 short repeats (<25) are associated with lower risk of cardiovascular disease; HO-1 short repeats are associated with increased HO-1 activity206. Extracellular superoxide dismutase (EC-SOD, aka SOD3, Cu-Zn SOD) protects the tissues from oxidative stress by converting the toxic superoxide anion into less toxic hydrogen peroxide (H2O2)8–10,12,13,222,224,231–233,377. The T-A or T-A-C haplotype, rs13306703 and rs2536512 with or without 17998895 in SOD3 gene increases the risk for essential hypertension in a Japanese population190. By contrast, 172G>A (rs2536512) polymorphism, by itself, is associated with a decreased risk for hypertension in Spaniards230 but is not associated with hypertension in other populations233. Germline global deletion of SOD3 in mice causes oxidative stress and hypertension189. However, an earlier and later study by others did not find SOD3 knockout mice to be hypertensive but found them to have increased hypertensinogenic response to NO inhibition or angiotensin II infusion231,232. Catalase (CAT) catalyzes the conversion of H2O2 to water and oxygen. SNPs in the CAT gene promoter region, CAT-844 AA and CAT-262 CT or TT, have been associated with essential hypertension among Chinese157, smoking Russians154, Greeks155, but not African-Americans and Caucasians156. However, CAT haplotype [−844G,−89A,−20T] relative to the CAT haplotype [−844A,−89T,−20C] was predictive of a decrease in diastolic blood pressure after bariatric surgery in a French population378. In individuals with low-level lead exposure, CAT rs769217, C>T, is associated with increased blood markers of oxidative stress and hypertension379. By contrast, CAT rs1049982, −20 C>T, is associated with lower blood pressure230. In individuals with a family history of hypertension, 20-35% of the variation of plasma hydrogen peroxide may be due to genetic factors380, 381. The transcriptional coactivator peroxisome proliferator-activated receptor-gamma coactivator 1 alpha (PGC-1 α) is an important regulator of energy control382 and is a master regulator of manganese SOD2 and UCP-2, both of which are mitochondrial proteins with antioxidant properties383. Polymorphisms in PGC-1α gene have been associated with hypertension in several studies, in males with Gly482Ser+A1704G haplotype, but the 482SS is protective of hypertension in Caucasian males in two studies and females in one study215–217. These aforementioned studies show that SNPs of genes involved in redox balance are involved in blood pressure regulation. 3. Treatment of oxidative stress in humans with hypertension Despite the numerous studies demonstrating a role of oxidative stress in cardiovascular diseases and the beneficial effects of antioxidants in the treatment of hypertension in animal models (Table 2), it has been difficult to demonstrate a role of oxidative stress in the pathogenesis and treatment of hypertension in humans305,384. Indeed, oxidative stress may be the consequence and not the cause of hypertension in humans385. Several antioxidant drugs, such as vitamin C, vitamin D, vitamin E, and bardoxolone alone or in combination302–307,310–312,314–317,319,320,324,384,386 with other antioxidants have been shown to prevent the deleterious effects of oxidative stress or hypoxia in different cardiovascular and renal diseases, including hypertension but some with undesirable side effects308,309,318,325,326,327,387,388. A meta-analysis in 135,967 participants in 19 clinical trials showed that high doses of vitamin E increased mortality387. The authors of a more recent meta-analysis concluded that supplements with vitamin E decreased cardiovascular mortality risk and folic acid decreased the risk for cardiovascular disease, while β-carotene, eicosapentanoic acid, magnesium, selenium, vitamins D and K, and zinc did not show significant risk reduction of cause-specific death or cardiovascular disease388. Thiosulfate, a hydrogen sulfide donor, which can decrease oxidative stress, has been reported to improve vascular endothelial function in hypertensive humans389,390. Bardoxolone, a Nrf2 agonist that increases the expression of several antioxidants, was initially shown to improve renal function in humans with advanced chronic kidney disease and type 2 diabetes391,. However, it was withdrawn from further clinical trials because of serious adverse events, including heart failure and cardiovascular events, and mortality392,393. Antioxidant treatment with ascorbic acid was initially shown to lower blood pressure in a limited number of patients with hypertension394,395. However, larger studies have not found a clear beneficial effect of antioxidant vitamins on the development or control of blood pressure396,397. The combination of ascorbic acid and polyphenols actually resulted in a higher blood pressure variation327. Therefore, there is insufficient evidence to support the use of dietary supplements in the primary prevention of cardiovascular diseases388. However, the period of treatment and doses398 could be crucial in the beneficial or deleterious effects of antioxidant therapy. What is evident from these published data is that the effect of the ROS on the cardiovascular system is more complex than expected and innovative approaches must be formulated to resolve these discrepant results. 3.1 Antioxidant effect of antihypertensive drugs The ability of some angiotensin II type 1 receptor blockers305,399 and ACE inhibitors305,400 to reduce ROS production and oxidative stress is well known. The classical renin-angiotensin system increases ROS production22,23,31,34–37,56,57,64 and thus, the beneficial effects of some of the antihypertensive drugs may be due to their ability to inhibit NADPH activity. The sulfhydrylated ACE inhibitors (e.g., captopril, epicaptopril, and S-zofenopril but not enalaprilat, perindoprilat, or quinaprilat401,402) contain a thiol radical that per se has antioxidant properties and may prefer to scavenge general radicals rather than superoxide radicals400,401. Although, the antioxidant effect of sulfhydrylated ACE inhibitors has been ascribed to the thiol group, the vasodilatory effect of S-zofenopril may be due to hydrogen sulfide403. The antioxidant effects of other antihypertensive drugs, such as β adrenoceptor blockers305,404,405 and calcium channel blockers305,406 have been reported, as well. Hypertension and oxidative stress associated with chronic ethanol intake can be prevented by the β-adrenoceptor blocker, nebivolol407. Therefore, part of the beneficial effects of some antihypertensive drugs may due to their ability to decrease ROS production. However, a novel angiotensin II type 1 receptor blocker has been reported to induce oxidative stress in a hepatocellular cell line HepG2408. These disparate effects of anti-hypertensive drugs on ROS production and blood pressure regulation may be related to the fact that, as aforementioned, ROS have beneficial effects on cell function10,13–21. Anti-oxidants at high concentrations may have pro-oxidant effects409 and the excessive antioxidation could have deleterious consequences. For example, a small but continuous production of ROS expression during physical exercise enhances antioxidant defenses and induces the expression of antioxidant enzymes; vitamin C supplementation decreases the endurance capacity in humans and rats410 and diminishes some of the increased skeletal muscle adaptations following acute exercise411. While physiological doses of anti-oxidants may be beneficial, excessive antioxidation could have deleterious consequences because the “remodeling” of skeletal muscles with exercise is dependent on reactive oxygen and nitrogen signaling412. The duration of the antioxidant effects may also be transient. For example, the biomarkers of oxidative DNA damage were attenuated by daily consumption of blueberries for 4 weeks in pre- and stage 1-hypertensive postmenopausal women, however, these effects were not found after 8 weeks413. Increased production of mitochondrial ROS plays a role in the pathogenesis of diabetic nephropathy414 and hypertension355. However, ROS produced by NOX4 can induce endothelial angiogenesis and protect against chronic cardiac overload415. Moreover, diabetic complications are associated with a decrease in mitochondrial ROS production but may help in the preservation of renal glomerular function during hyperglycemia 416,417. Therefore, “normal” physiological levels of mitochondrial superoxide are important for healthy mitochondrial function418. The amount of ROS formed, type of ROS formed, i.e., superoxide versus H2O2, source, duration, and their subcellular locations may be determinants on the consequences of ROS production on cell function. It is universally accepted that a redox imbalance induced by an excessive and uncontrolled ROS production could have deleterious consequences on blood pressure regulation. However, the excessive intake or expression of antioxidants could also have delirious consequences on the cardiovascular system. 4. Conclusion Several genetic polymorphisms that affect pro-oxidant and antioxidant systems, directly or indirectly, are associated with hypertension. Antioxidants can reduce the blood pressure in humans and animal models of hypertension. Antihypertensive drugs can also have anti-oxidant effects. However, an indiscriminate decrease in ROS production can have deleterious consequences. ROS are involved in the regulation of essential cellular processes. Thus, the long-term administration of drugs with antioxidant properties may impair vital cellular function, resulting in undesirable side effects. Studies are needed to elucidate the role of pharmacogenomics in redox balance in the treatment of hypertension. Funding: These studies were supported in part by grants from the NIH, 5P01HL074940-11, 7R01DK039308-31, 5P01 HL068686-15, 5R01HL023081-35, and 2R01HL092196-10. Conflict(s) of Interest/Disclosure(s); None Figure 1. Genes associated with redox balance regulation and Hypertension. The presence of the SNPs in pro-oxidant and antioxidant genes could increase the ROS production in the brain, cardiovascular system, heart, and kidney to induce hypertension. Table 1. Genes associated with hypertension and oxidative stress in humans and/or animal models of hypertension. Genes associated with oxidative stress Associated with hypertension in animal models SNPs Associated with hypertension in humans Polymorphisms of pro-oxidant genes Activating transcription factor 1 (ATF1) rs11169571 [73] Aminopeptidase A (APA) Aminopeptidase-A (stop), rs2290105 [84, 85] Angiotensinogen (AGT) [37,76,77] −6G>A, −20A>C, −152A>G, −217G>A, rs5050 M235T (rs699) [78–83] Angiotensin II type 1 receptor (AGTR1) [86, 87] rs5186 (1166A>C) [84] Arachidonate 15-lipoxygenase (ALOX1){351] 261R>Q [350] Cycloxygenase-2 (COX2, PTGS2) −765G>C, rs2143417 [88–90] Cytochrome P450 [91–94] CYP2C8*3, CYP 450 2J2(−50G>T), CYP3A5*3 (rs776746) (Japanese), CYP3Ar5*1 (European- and African-Americans), CYP4A11 (rs1126742), CYP17A (rs11191548) [91,96–103,200,356–358] DNA-Binding Factor NFkB [104] Endothelin I rs5335 (70C>G), rs5370 (198G>T) [105,359] Hemojuvelin (HJV) rs16827043, rs7536827 [106] Interleukin-6 (IL-6) [107] rs1800795 (−174G>C), rs1800796 (−572C>G) [108–111] Interleukin-17A (IL-17A) [112] rs2275913 (G>A) [113] Iron regulatory protein (HFE) rs1799945 (63H>D) [114] Leptin (LEP) [115,116] II/I tetra nucleotide repeat, rs799039(G2548A) [117,118] Leptin receptor (LEPR) rs1137101 (223Q>R), rs1137100 (109K>R) [117–119] Myeloperoxidase (MPO) rs2333227(−463G>A) [120–124] NADPH oxidase p22phox (CYBA) [25,125,126] rs9932581 (930A>G), rs78935588 (640A>G) rs7195830 (49A>G), −675A>T rs4673 (242C>T), rs8854A, rs9932581G [127–139] NADPH oxidase 1 (NOX1) [140, 141] NADPH oxidase 2 (NOX2) [142–145] NADPH oxidase 4 (NOX4) [147] Neutrophil cytosol factor 2 (NCF2) rs12094228, rs16861188, and rs12066019 [148] Nitric oxide synthase 3 (NOS3) [149] 894G>T (rs1799983) [150,151] RAC1 rs6967221 [152] Xanthine dehydrogenase/oxidase (XDH) rs11904439, rs148756340 [240] Polymorphisms of antioxidant genes Catalase (CAT) [153] rs769214 (−844G>A), rs1001179 (−262C>T), −20C>T, rs769217 [154,155,157][230,279] Cystathione γ-lyase (CSE) [158–160] rs482843 [161] DJ-1 (PARK7) [162,163] [164] Dopamine 1 receptor (DRD1) [32,165] (−48A>G, −94G>A rs1799914, rs4867798) [166–170] Dopamine 2 receptor (DRD2) [32,252] rs6276, rs6277, rs1800497 [171–176] Dopamine 3 receptor (DRD3) [178–180] rs9880168 [169] Dopamine 4 receptor (DRD4) −521C>T, DRD4 long allele [182–184] Dopamine 5 receptor (DRD5) [185–188] No associations published Fibroblast growth factor 5 (FGF5) rs16998073 [192,193,200] Glutathione [197] Glutathione peroxidase (GPX1, GPX3, GPX4)) [194] rs713041 (718C>T) rs3828599 [195,196] Glutathione S-transferase Alpha 1 (GSTA1) GSTA1*B allele GSTA1*B allele +GSTM1 null [374] Glutathione S-transferase Mu 1 (GSTM1) GSTM1 nullGSTM1 + GSTT1 null [198,199,202][374] Glutathione S-transferase Mu 3 (GSTM3) −63A>C [203] Glutathione S-transferase Pi 1 (GSTP1) A313 [201] Glutathione S-transferase Theta 1 (GSTT1) GSTT1 null [198] Heme oxygenase-1 (HO-1) [204,205] <27 GT repeats rs9607267 [206] Heme oxygenase-2 (HO-2) [207] Kidney androgen-regulated protein (KAP) [208–210] Methylenetetrahydrofolate reductase (MTHFR) 677C>T [201,211] Nuclear factor (erythroid-derived 2)-like 2, also known as NFE2L2 (NRF2) [163] Paraoxonase 1 (PON1) 192Q>R, −108C>T [212,213] Paraoxonase 2 (PON2) [146] Peroxisome proliferator-activated receptor γ coactivator 1-α (PGC-α) [214] 482G>S, 482G>S+1704A>G haplotype [215–217] Sestrin 2 (SESN2) [218] Superoxide dismutase 1 (Cu-Zn SOD) [220–226] Superoxide dismutase 2 (Mn SOD) [219,227,228] [150] Superoxide dismutase 3 (EC SOD) [189,231,232] rs13306703 + rs2536512 +/− rs1799895 [190,230] Thioredoxin (TXN) rs2301241 (−793T>C) [230] Thioredoxin interacting protein (TXNIP) [234] Thioredoxin reductase (TXNRD2) [235] Uncoupling protein 2 (UCP2) [236–238] −866 G/A [239] Table 2. Antioxidant drugs that decrease blood pressure in humans with hypertension and animal models of hypertension. Antioxidant Species Mechanism of action References N-acetyl cysteine human, mouse, rat Direct antioxidant, precursor of cysteine reduced glutathione, breaks disulphides [243–247] Apocynin mouse, rat Prevents NADPH oxidase assembly [248–252] Allicin/Aliin/S-allylcysteine (garlic) human Reduces 8-hydroxy-2’deoxyguanosine, malondialdehyde, angiotensin II-generated ROS [253–256] L-arginine human, mouse, rat Substrate for NO production [257–259] Bardoxolone human, mouse, rat Nrf2 inducer [260,261] L-carnitine human, mouse, rat Key compound in the transport of long-chain fatty acids into mitochondria for β-oxidation [262,264–266] Catechins Black tea (theaflavin-polyphenol) rat Stimulates NO and H2S production, Decreases endothelin-1 and angiotensin II [267] Green tea (polyphenols) human Antioxidant, inhibits catechol-O-methyl transferase, NO release [267–269] Coenzyme Q10 human, mouse, rat Reduces mitochondrial superoxide production by increasing the efficiency of electron transfer from Complexes I and II down the mitochondrial electron transport chain [270–273] Curcurmin human, mouse, rat A herbal supplement used as a food additive with antioxidant properties at low concentrations, induces HO-1 [274–277] Hemin mouse, rat HO-1 inducer (can induce mitochondrial dysfunction) [278–280] Hesperidin human, rat Free radical scavenger and enhancer of antioxidant pathways via ERK/Nrf2, inhibits RAS [281–283] α-Lipoic acid human, mouse, rat Free radical scavenger and activator of anti-oxidant recycling [284–286] Melatonin human, rat Free radical scavenger and up-regulator of antioxidant enzymes. [287–290] Quercetin human, mouse, rat Free radical scavenger [291–294, 419, 420] Resveratrol human, mouse, rat Activator of sirtuins and PGC-1α, involved in stress response, and Nrf2 [295, 296, 421] Tempol human, mouse, rat Redox-cycling nitroxide and SOD mimetic [9,16,28,29,34,297,422] Troxerutin mouse, rat Flavonoid (hydroxyethylrutoside) with antioxidant properties [298,299] Vitamin C human, mouse, rat Free radical scavenger [11,300–306] Vitamin D human, mouse, rat Inhibits iron-dependent liposomal lipid peroxidation [10,307–319] Vitamin E human, mouse, rat Free radical scavenger, impairs ROS signaling 11,303,320–323]

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