Abstract
Nitric Oxide (NO) has important biological functions, and its production may be influenced by genetic polymorphisms. Since NO mediates the drug response, the same genetic polymorphism that alter NO levels may also impact drug therapy. The vast majority of studies in the literature that assess the genetic influence on NO-related drug response focus on NOS3 (which encodes endothelial nitric oxide synthase), however several other proteins are interconnected in the same pathway and may also impact NO availability and drug response. The aim of this study was to review the literature regarding genetic polymorphisms that influence NO in response to pharmacological agents located in genes other than NOS3. Articles were obtained from Pubmed and consisted of 17 manuscripts that assessed polymorphisms of the following targets: Arginases 1 and 2 (ARG1 and ARG2), dimethylarginine dimethylaminohydrolases 1 and 2 (DDAH1 and DDAH2), and vascular endothelial growth factor (VEGF). Here we analyze the main results of these articles, which show promising evidences that may suggest that the NO-driven pharmacological response is affected by more than the eNOS gene. The search for genetic markers may result in better understanding of the variability of drug response and turn pharmacotherapy involving NO safer and more effective.
Keywords: Nitric oxide; polymorphisms; drug response
Introduction
One of the main active molecules produced by endothelial cells is nitric oxide (NO), a small gaseous and lipophilic molecule, which acts in smooth muscle of vessels leading to vasorelaxation. NO is one of the most important molecules that regulate blood pressure and flow (Moncada and Higgs, 1993).
NO targets soluble guanylate cyclase, which is an enzyme responsible for converting guanosine triphosphate (GTP) into cyclic guanosine monophosphate (cGMP). Increasing levels of cGMP, in turn, activate Protein Kinase G (PKG), which will phosphorylate several targets, resulting in reduced cytoplasmatic calcium and vascular relaxation (Craven and DeRubertis, 1978; Poulos, 2006; Francis et al., 2010).
Nitric oxide is mainly produced by NO synthases (NOS), which catalyze the conversion of L-Arginine into L-Citruline and NO. There are three types of NOS: neuronal (nNOS, encoded by NOS1), inducible (iNOS, encoded by NOS2) and endothelial (eNOS, encoded by NOS3) (Kiechle and Malinski, 1993; Silva et al., 2011). The nNOS and eNOS enzymes are expressed in different cell types, including neurons and endothelial cells. Both enzymes are calcium-dependent constitutive isoforms, which increase their catalytic velocity in response to increases in calcium, through activation of calmodulin (CaM). On the other hand, iNOS is not constitutive, showing a marked upregulation in response to inflammation (Cinelli et al., 2020).
The NO pathway is complex and involves other enzymes upstream or downstream of the NO signal (Figure 1). For instance, Arginase 1 and Arginase 2 are enzymes that compete for the same substrate of NOS and may limit NO production (Caldwell et al., 2018). Besides that, there are methylated forms of L-Arginine that act as NOS inhibitors, such as asymmetrical dimethylarginine (ADMA), symmetrical dimethylarginine (SDMA) and monomethylarginine (L-NMMA) (Schepers et al., 2014). While the production of methylated forms of L-Arginine is very complex, and mainly due to degradation of proteins that had L-arg residues post-translationally modified, the clearance of these molecules is very well identified, being performed by dimethylarginine dimethylaminohydrolases types 1 and 2 (Valkonen et al., 2005), and by alanine-glyoxylate aminotransferase type 2 (Rodionov et al., 2014). Besides that, the Vascular Endothelial Growth Factor (VEGF), Hypoxia Inducible Factor 1 (HIF-1), acetylcholine, mechanical stretch on endothelial cells, and others are able to activate or upregulate NOS (Melincovici et al., 2018). The mentioned proteins and enzymes have genetic polymorphisms that may impact their action by altering their expression, activity, affinity to other ligands, and other consequences. Indeed, polymorphisms in ARG1, ARG2, DDAH 1, DDAH 2, AGXT 2 and VEGF were associated to altered risk for cardiovascular diseases, diabetes mellitus and preeclampsia (Leineweber et al., 2017). Moreover, there is evidence showing the association of polymorphisms in NO pathway genes with altered response to drugs (Cotta Filho et al., 2020), including those that involve NO in their pharmacological mechanism. The most obvious target for genetic association would be NOS3 gene, which has been largely explored, but other genes that participate in NO pathway will also impact NO availability and may also modulate risk for disease and drug response (Valkonen et al., 2005; Dobrian, 2012).
Schematic figure of the NO-cGMP pathway. NO is synthesized by eNOS, diffuses through the membrane and activates sGC, which in turn increases cGMP that leads to vasorelaxation. L-NMMA, ADMA and SDMA compete with L-Arginine and reduce NO synthesis. DDAH1 and 2 and AGXT2 metabolize these methylated forms of L-Arginine. Arginases limit the availability of L-Arginine. VEGF induces the expression of eNOS. NO, Nitric oxide; eNOS, Endothelial nitric oxide synthase; ADMA, Asymmetric Dimethylarginine; SDMA, Symmetric Dimethylarginine; L-NMMA, Monometilarginina Simetrica; DDAH, Dimethylarginine dimethylaminohydrolase; AGXT2, Alanine glyoxylate transaminase-2; sGC, Soluble guanylate cyclase; GTP, Guanosine triphosphate; cGMP, Cyclic guaninosine monophosphate; PKG-1, Proteína quinase-G 1; VEGF, Vascular endothelial growth factor; VEGFR, Vascular endothelial growth factor receptor; PI3K, Phosphoinositide-3-kinase; AKT/PKB, Protein kinase B.
Here we aimed to review the literature regarding genetic polymorphisms that influence drug response involving NO, but focusing studies that went beyond NOS3.
Literature search
Our search was based on Pubmed using the following search terms: Polymorphisms; Nitric oxide; Arginase 1;ARG1; Arginase 2; ARG2;Alanine glyoxylate transaminase-2; AGXT2; Dimethylarginine dimethylaminohydrolase-1;DDAH1;Dimethylarginine dimethylaminohydrolase-2 ;DDAH2; Asymmetric Dimethylarginine; ADMA;Symmetric Dimethylarginine; SDMA; Endothelial growth factor; VEGF; Soluble guanylate cyclase; sGC. These terms were searched in title and abstracts throughout the database. Figure 2 describes the selection process of articles included here. All articles were original and in English language, including polymorphisms of ARG1, ARG2, DDAH1, DDAH2 and VEGF and its association with drug response. As eNOS was extensively studied in other articles (Silva et al., 2011; Oliveira-Paula et al., 2017; Cozma et al., 2019; Cotta Filho et al., 2020), and given the idea proposed here of emphasizing what lies beyond NOS3, we excluded all references focusing only on NOS3. Besides, articles that focused on disease risk phenotypes were also excluded, except for targets not explored by pharmacogenetic studies (soluble guanylate cyclase and AGXT2). References of the included articles were double-checked to include new studies not identified originally by our Pubmed search. After the selection process, 17 articles were included and explored in this review.
The article selection process. Terms used on PubMed for Search Title/Abstract AND Crossing the terms listed in the method section.
Arginase 1 and Arginase 2
Arginase 1 (ARG1) and Arginase 2 (ARG2) are enzymes that catalyze the hydrolysis of L-arginine into L-ornithine and urea (Caldwell et al., 2018). The two arginase isoenzymes differ by tissue expression, subcellular localization, and immunological reactivity while maintaining 60% homology in protein sequence (Vockley et al., 1996). Since arginases use the same substrate as NOS, they compete and may limit NO synthesis by eNOS and nNOS through microcompartment exhaustion of L-Arginine (Romero et al., 2008). This effect is substantial and may explain the role of arginases in endothelial dysfunction observed in cardiovascular diseases (Romero et al., 2008; Johnson et al., 2015). ARG1 is located in the long arm of chromosome 6, while ARG2 is located on the long arm of chromosome 14, and both have polymorphisms with clinical importance.
Genetic influence of ARG1 and ARG2 in asthma treatment responsiveness
The vast majority of pharmacogenetic studies involving ARG1 and ARG2 concentrate on response to drugs used in asthma (Table 1 and Table 2). This is due to an increased activity of arginases in asthma pathogenesis, which in turn lead to reduced NO synthesis and obstruction of airways. Additionally, this leads to increased inflammation and remodeling of airways (Maarsingh et al., 2008).
Summary of studies that evaluated the association of polymorphisms in ARG1 with response to drugs.
Summary of studies that evaluated the association of polymorphisms in ARG2 with response to drugs.
The class of β-agonists is widely used in asthma treatment, with short-term acting β2 agonists usually used to promote ailment to the acute symptoms of bronchospasm, while long-term β2 are more often used along with inhaled corticosteroids in a chronic treatment. This class exerts therapeutic effects through activation of the β2 receptor, which is more expressed in smooth muscle cells of the lower respiratory tract. This results in an increase in cyclic adenosine monophosphate (cAMP) in the cellular milieu, which activates PKA and results in bronchodilation (Tse et al., 2011).
Genetic polymorphisms of ARG1 and ARG2 were associated with the risk to develop asthma (Li et al., 2006; Vonk et al., 2010) and the response to β2 agonists (Litonjua et al., 2008). An important study assessing this effect was a panel of 844 SNPs on 111 candidate genes, which reported an association of the rs2781659(A>G) of ARG1 with bronchodilator effectiveness both in children and adults (Litonjua et al., 2008). It was shown that carriers of variant G allele of the rs2781659 had a diminished response to the drug when compared to the wild type AA. Another study assessed the association of SNPs in ARG2 with response to β2agonists and anticholinergic bronchodilators (Vonk et al., 2010). It was shown that ARG1 rs2781667(C>T) T carriers had a reduced bronchodilator response to β2 agonists, while ARG2 rs7140310(T>G) and rs10483801 (C>A) variant alleles showed an increased response to the same drugs. No association was reported regarding anticholinergic bronchodilators (Vonk et al., 2010). Interestingly, the pharmacological response to asthma therapy is usually assessed by quantifying the forced expiratory volume in one second (FEV1). Inhaled corticoid therapy was more effective in the reduction of FEV1 of carriers of ARG1 rs2781667(C>T) variant T allele when compared to the CC genotype (Vonk et al., 2010). Contrasting previous results, another study reported no association of ARG1 rs2781659 (A>G) with bronchodilator response (Scaparrotta et al., 2019).
Further studies explored the trans interaction between genetic polymorphisms in the form of genotype interaction (Sy et al., 2012), with interesting results showed in a Chinese population. It was found that the interaction between ARG1 (rs2749935) and the Corticotropin Releasing Hormone Receptor 2 (CRHR2) (rs2190242) polymorphism could alter bronchodilator responsiveness in asthmatics. The results show that those patients classified as high risk (i.e. ARG1 rs2749935 AA or CC genotype with CRHR2 rs2190242 CC genotype) have better bronchodilator responsiveness than low-risk genotype carriers (i.e., ARG1 rs2749935 TA genotype with CRHR2 rs2190242 AA genotype) by generalized multifactor dimensionality reduction. Duan et al. (2011) assessed haplotypes formed by 4 SNP in ARG1: s2781659(A>G), rs2781663(T>A), rs2781665(A>T) e rs60389358(C>T). They compared three different haplotypes and showed that the variant haplotypes GATC and GATT responded worse than ATAC haplotype, containing all wild-type alleles. Interestingly, the authors performed in vitro studies with luciferase constructs and showed that ATAC transfected cells had an increase of 50% in luciferase expression when compared to the variant haplotypes GATC and GATT (Duan et al., 2011). This represents hard evidence that ARG1 polymorphisms impact gene expression and suggests a mechanism by which those polymorphisms may alter bronchodilator responsiveness.
The proposed mechanism of interaction between arginases and β2 adrenergic receptors involves NO and cGMP pathway. The ATAC haplotype would lead to increased expression of Arginase 1 (Duan et al., 2011), leading to lower availability of the substrate for NO synthesis. Consequently, this would lead to an increase in smooth muscle tonus in airways. When treated with bronchodilators, ATAC haplotype carriers would respond better to therapy, which is consistent with the concept of sensitization of the NO pathway (Cashen et al., 2002; Pereira et al., 2021). The idea is that when the NO-cGMP pathway is unstimulated, it would in turn increase its sensibility, since NO is needed tonically, even in small amounts. In this situation, stimuli that increase NO production and the machinery that respond to NO would respond in an increased intensity after an acute pharmacological stimulus. The opposite phenomenon also occurs when NO-cGMP is overstimulated, where it will reduce tissue responsiveness to chronic pharmacological stimulation (Cashen et al., 2002; Pereira et al., 2021). An example of this is the evidence that genetically engineered animals with eNOS knockout in aorta show an increased vasorelaxant effect in response to NO donors than wild type animals (Hussain et al., 1999), presumably by a sensitization of the NO-cGMP pathway. Up to date the evidence shown here is not used yet to tailor a personalized therapy for asthma.
Genetic influence of ARG1 and ARG2 in drug response in other diseases
Other groups explored the association of ARG1 and ARG2 polymorphisms with drug response in other contexts. Our group assessed the association between arginase 1 and 2 levels, activity and genetic polymorphisms in its genes with the responsiveness to the therapy of erectile dysfunction with a phosphodiesterase 5 (PDE5) inhibitor, Sildenafil (Lacchini et al., 2018). This drug acts downstream of NO signaling, enhancing the life span of the second messenger cGMP produced by soluble guanylate cyclase (which in turn is activated by NO). This is achieved by inhibiting PDE5, which is the main enzyme responsible for cGMP metabolization in cavernosal tissue. This allows for weaker stimuli to elicit an accumulation of cGMP with enough concentration to relax smooth muscle and initiate the erection process. Interestingly, it was shown that poor responders to Sildenafil that underwent prostate cancer surgery (more related to nerve damage) had an increased arginase activity in plasma, while poor responders of Sildenafil that were classified as clinical erectile dysfunction (more related to vascular dysfunction) showed an upregulation of Arginase 1 in plasma. Genotypes and haplotypes were assessed, including SNPs rs2781659 (A>G), rs2781667(C>T), rs2246012 (T>A) e rs17599586 (C>T) of ARG1 and rs3742879 (A>G) e rs10483801 (C>A) of ARG2. While no associations were found of the SNPs and haplotypes with Sildenafil responsiveness, we found that variant genotypes CT of rs2781667(C>T), AG of rs2781659(A>G) and CT+TT of rs17599586(C>T), as well as GTTT haplotype of ARG1, were associated with a reduced arginase activity on plasma in clinical erectile dysfunction group.
Another study focused on the same ARG1 and ARG2 SNPs, in the treatment with propofol (Oliveira-Paula et al., 2021). This drug is used as general anesthetic, and while it has a very short half-life, and patients recover conscience fast, this drug elicits an important blood pressure drop, which has many mechanisms, one of them involves the acute activation of NOS and NO production. Interestingly, this effect is sufficiently fast and intense to overcome the baroreflex, and blood pressure drops markedly. This is a special context in pharmacogenetics: since all counteracting mechanisms are exhausted and the cumulative response is fast, the subtle genetic effect on this phenotype may be more easy to observe, unraveling mild genetic effects that usually could be counteracted by physiological mechanisms. Indeed, it was shown in this study that ARG2 rs3742879 (A>G) AG+GG carriers had a reduced mean arterial pressure drop and a reduced increase in plasma nitrite 5 minutes after propofol anesthesia, when compared to AA carriers. On the other hand, CA carriers of the ARG2 rs10483801 (C>A), had a more intense mean blood pressure drop than CC wild-type carriers. At the same time, carriers of at least one variant allele of ARG2 rs10483801 (C>A) showed increased levels of plasma nitrite, which indicates a more intense NO production (Oliveira-Paula et al., 2021). While functional data are not available for these ARG2 polymorphisms, results suggest that alleles that lead to an increased function of ARG2 (which is highly expressed in endothelium) may lead to a reduction of L-Arginine availability in a compartmentalized fashion. This, in turn would lead to a diminished production of NO because of substrate exhaustion, leading thus to a reduced blood pressure drop following propofol stimuli. This is supported by animal model evidence. It was shown that the treatment with Simvastatin, L-citruline and arginase inhibitors were able to reduce vascular damage induced by Arginase 1 in animals (Romero et al., 2008). Besides, arginase inhibition was also able to reduce insulin resistance and prevent hypertension installment in animals (Peyton et al., 2018). Moreover, it was shown that coronary arterioles from diabetic patients would have their vasodilatory response to acetylcholine restored if a pretreatment with L-Arginine or arginases inhibitors was given (Beleznai et al., 2011). While very interesting, to date no clinical study assessed whether ARG1 and ARG2 SNPs would associate with diabetes end-organ damage, which is decurrent mostly by low oxygenation and oxidative stress induced by hypercontractility of peripheral vessels. However, it is important emphasize that in only three of seven articles revised there is a correlation between SNPs in ARG1 and response to drugs, so caution is needed when interpreting this information.
Endogenous inhibitors of eNOS
Asymmetrical dimethylarginine (ADMA), symetrical dimethylarginine (SDMA) and Monomethylarginine (L-NMMA) are methylated forms of L-Arginine. ADMA and L-NMMA are considered as endogenous inhibitors of eNOS, since they directly reduce activity of eNOS, iNOS and nNOS, while SDMA acts only indirectly (Bouras et al., 2013; Rochette et al., 2013).
Several studies linked ADMA to cardiovascular diseases (Bouras et al., 2013) and insulin resistance (Perticone et al., 2010). In disease states when ADMA is elevated, eNOS activity may be reduced by 30 to 70%, depending on the disease (Cardounel et al., 2007).
On the other hand, SDMA acts inhibiting a specific channel for L-Arginine, reducing its inflow into the cellular compartment (Rochette et al., 2013). Therefore, while plasma levels of L-Arginine may be within normality, endothelial cells have a reduced availability of L-Arginine and thus a reduced production of NO. The different forms of methylated arginine are metabolized by a mixed action of renal excretion and metabolism (Kielstein et al., 2006). In renal insufficiency, methylarginines excretion is reduced and both ADMA and SDMA accumulate in plasma. This represents a risk as increased levels of ADMA are associated with risk to develop renal diseases (Kielstein et al., 2006), as well as cardiovascular diseases (Emrich et al., 2018).
Few enzymes have the ability to metabolize methylated forms of L-Arginine: dimethylarginine dimethylaminohydrolases types 1 and 2 (DDAH1 and DDAH2) and Alanine-Glyoxylate aminotransferase type 2 (AGXT2) (Valkonen et al., 2005) (Schepers et al., 2014)
DDAH1 and DDAH2
DDAH1 and DDAH2 are responsible for metabolizing ADMA systemically. Both isoforms are widely expressed throughout different organs and tissues, however the localization differs between the two proteins (Leiper et al., 1999). DDAH1 is mainly expressed in liver, kidneys and tissues that express nNOS (Leiper et al., 1999; Mishima et al., 2004). On the other hand, DDAH2 is expressed by vascular endothelium (which also expresses eNOS) and immune cells (that express iNOS) (Tran et al., 2000). DDAH1 is encoded by the DDAH1 gene, located in the short arm of chromosome 1, region 22, while DDAH2 is encoded by DDAH2 gene, located in the short arm of chromosome 6, region 21.3 (Tran et al., 2000).
Genetic studies showed that polymorphisms in DDAH1 and DDAH2 are associated with changes in ADMA levels, and when these are elevated, there is an increased risk to develop cardiovascular diseases (Leineweber et al., 2017) (Table 3). Despite the fact that there is in the literature evidence of ADMA levels associating with altered responsiveness to statins and hypoglycemic drugs (Maas, 2005), the genetic influence involving DDAH1 and DDAH2 polymorphisms has not been explored yet.
Interestingly, the reduced expression or activity of DDAH induces endothelial dysfunction (Leiper et al., 2007), and animal models showed that this, in turn, may lead to disease such as erectile dysfunction (Masuda et al., 2002; Park et al., 2009). Azevedo and coworkers assessed whether genetic polymorphisms of DDAH1 (rs1554597 (T>C) and rs18582 (G>A)) and DDAH2 (rs805304 (C>A) and rs805305 (C>G)) were associated with two types of erectile dysfunction (ED), Clinical ED and postprostatectomy ED (Azevedo et al., 2017). Interestingly, rs18582 (G>A) A allele carriers had reduced ADMA levels, while the variant CC genotype carriers for rs1554597 (T>C), also showed reduced plasma levels of ADMA, both on clinical ED group (Azevedo et al., 2017) (Figure 3). When considering inclusion/exclusion criteria, Clinical ED is a phenotype that is enriched by vasculogenic ED, while the postoperative ED group is enriched by nerurogenic ED. Interestingly, in postprostatectomy patients, DDAH2 SNPs DDAH2 rs805304 (C>A) and rs805305 (C>G) that were not associated with changes in plasma levels of ADMA, associated with Sildenafil responsiveness. Interestingly, a Case-Control study regarding only Clinical ED, showed that DDAH1 haplotypes including rs1554597 (T>C) and rs18582 (G>A) were associated with changes in ADMA levels of Clinical ED patients, where TG carriers shown increased levels, while CA carriers shown reduced levels on ADMA in plasma (Brites-Anselmi et al., 2019). On the other hand, DDAH2 haplotypes were not associated with ADMA plasma levels, however did associate with plasma nitrite levels, whereas CC carriers had reduced nitrite levels and AG carriers shown increased nitrite levels in plasma (Brites-Anselmi et al., 2019). Taken together, these data suggest that both enzymes have different roles, DDAH1, mainly expressed in liver, being more responsible for ADMA clearance, while DDAH2 may be compartmentalized within endothelial cells, where while it may not affect plasma ADMA levels, it may impact nitric oxide synthesis, because it affects ADMA levels in the compartment where NO is synthesized. This could also help to explain DDAH2 SNPs associated with Sildenafil responsiveness. While it was already shown that DDAH genetic variability could impact ADMA plasma levels in other clinical settings (Leineweber et al., 2017), DDAH1 and 2 specific functions are yet to be tested in animal models to better understand the different physiological roles of both enzymes.
Possible future application of pharmacogenetic studies in clinical practice. Schematic figure, based on the results of Azevedo et al. (2017). DDAH2, Dimethylarginine dimethylaminohydrolase 2.
Vascular Endothelial Growth Factor
The Vascular Endothelial Growth Factor (VEGF) actions impact directly eNOS expression and NO bioavailability (Figure 1) (Yang et al., 2012). Interestingly, NO also regulates VEGF expression, therefore it is a reciprocal relationship (Lacchini et al., 2013). VEGF is encoded by a homonymous gene, located at chromosome 6, position p21. VEGF polymorphisms have been extensively studied in cancer in order to predict anticancer therapy outcome. In that setting VEGF signaling is crucial for tumor angiogenesis and growth, and therapies that target VEGF have the objective to limit blood flow to the tumor tissue. It was shown that colorectal cancer patients that were carriers of the TT genotype of the rs3025039 (located in the promoter, position -936) had better survival after treatment with Bevacizumab than their counterparts (Ulivi et al., 2015) (Table 4). This drug is a monoclonal antibody against VEGF that is used as an adjuvant therapy in certain types of cancer. Other polymorphisms in the same gene (rs699947, rs833061, rs2010963 e rs1570360) analyzed separately or in haplotype blocks did not associate with Bevacizumab responsiveness (Ulivi et al., 2015). Another study focusing on colorectal metastatic cancer showed an association of the -1498 C>T polymorphism with Bevacizumab responsiveness: TT carriers had increased progression-free survival after treatment when compared to CC carriers (Loupakis et al., 2011). Another interesting anticancer drug that targets VEGF is Sunitinib (Eechoute et al., 2012), which is a tyrosine kinase inhibitor with multiple targets, that acts on VEGF signaling by inhibiting VEGF receptors and resulting in less angiogenesis, less tumor growth and reduced metastasis (Ferrara et al., 2003). Because of the impact of VEGF on NO and its role in blood pressure control, one of the main adverse effects of Sunitinib is blood pressure increase. A study assessed the association of blood pressure increases and survival after sunitinib use in metastatic renal cell cancer patients (Eechoute et al., 2012). This retrospective study showed that carriers of the ACG haplotype (composed by rs699947, rs833061 e rs2010963 in VEGF gene) had increased systolic and mean arterial pressure after Sunitinib treatment. However, the same haplotype was also associated with increased survival, with a median survival time increase of 7.2 months (Eechoute et al., 2012). These results are consistent with the idea that ACG haplotype carriers had an increased inhibition of VEGF, and that this increased blood pressure, also reduced angiogenesis at the tumor site increasing survivability. Equivalent observations were reported, associating higher blood pressure to good responsiveness to Sunitinib (Gallagher et al., 2011; Rini et al., 2011; Szmit et al., 2012).
Summary of studies that evaluated the association of polymorphisms in VEGF with response to drugs.
As the evidence shows, VEGF polymorphisms may have an important role in blood pressure regulation. Interestingly, some anti-hypertensive drugs increase VEGF within their mechanism of action, such as Angiotensin Converting Enzyme Inhibitors (ACEi), and this may be important for the clinical response observed for these anti-hypertensive drugs (Li et al., 2008; Yazawa et al., 2011). It was shown that the blood pressure response to Enalapril, which is an ACEi, associated with polymorphisms in VEGF (Oliveira-Paula et al., 2015). Carriers of AA and CA genotypes for rs699947 and carriers of the AGG haplotype (composed by rs699947, rs1570360 e rs2010963) had more intense blood pressure drops after Enalapril treatment, when compared to CC genotype of rs699947 and CGG haplotype (Oliveira-Paula et al., 2015). This suggests that VEGF polymorphisms may affect blood pressure control in a large portion of hypertensive patients, since this drug is frequently used. In clinical erectile dysfunction, it was shown that rs699947 AA and CA genotype carriers and AGG haplotype carriers responded worse to Sildenafil (Lacchini et al., 2013). While the association with enalapril seems contrasting with the association with Sildenafil at a first glance, the authors discuss that since there is an important effect of tachyphylaxis in NO pathway, it could be possible that haplotypes and genotypes associated with chronic higher production of NO could in turn lead to a reduced cGMP accumulation following PDE-5 inhibition (Oliveira-Paula et al., 2015). Since Clinical ED has endothelial dysfunction as the limiting step in vasodilation, this may be more visible in this condition. Postoperative ED, on the other hand had an association of AA genotype of rs1570360 with worse Sildenafil responsiveness (Lacchini et al., 2013). Both polymorphisms implicated in this study are functional, and the variant allele shows reduced expression of VEGF (Shahbazi et al., 2002; Lambrechts et al., 2003). Altogether these results provide good evidence that VEGF polymorphisms may impact drug response, especially when considering vasodilation and angiogenesis mediated by this molecule.
Other pathways less explored
AGXT2
The AGXT2 enzyme is the main enzyme responsible for symmetrical dimethylarginine (SDMA) metabolism, and also responsible for around 16% of the ADMA intracellular metabolism (Schepers et al., 2014). SDMA, as discussed before, is a molecule involved in inhibiting NO synthesis, especially by inhibiting L-Arginine channels that are essential for providing adequate substrate for NO synthesis in endothelial cells. AGXT2 is encoded by a homonymous gene, located at 5p13.2 (Rodionov et al., 2014). Interestingly, polymorphisms in this gene were associated with increased risk to cardiovascular diseases, including associations with intermediate phenotypes, such as reduced enzyme activity, increased ADMA and SDMA and reduced NO biomarkers (Hu et al., 2016; Yoshino et al., 2021). There are functional SNPs in this gene, such as the rs37369 (A>G), that besides associated with changes in renal and liver clearance of ADMA, is also associated with a marginal increase in survival time in heart failure patients: A carriers survived more than GG carriers (Hu et al., 2016; Yoo et al., 2021). While these results show an exciting perspective in drug response prediction, there are no studies in the literature exploring this association with drug response.
Soluble Guanylate Cyclase
The Soluble Guanylate Cyclase (sGC) enzyme acts as an intracellular sensor of NO (Arnold et al., 1977). When in the presence of NO, sGC converts guanosine triphosphate (GTP) in cyclic guanosine monophosphate (cGMP) (Derbyshire and Marletta, 2012). sGC is the mediator for NO signaling, that begins with NO synthesis by NOS (Derbyshire and Marletta, 2012). Because of the well-established role of NO in the cardiovascular system, sGC is also mainly associated with cardiovascular diseases (Gheorghiade et al., 2013). sGC is a heterodimeric enzyme, consisting of alpha and beta subunits, which, in turn, have two main isoforms each: α1, α2, β1, β2 (Russwurm et al., 1998; Mergia et al., 2003). A large study including 2012 hypertensives and 2210 healthy controls assessed the association of hypertension with polymorphisms in chromosome 4, in a region comprising the genes GUCY1A3 to GUCY1B3 (which encode sGCα1 and sGCβ1, respectively). This included six SNP: rs3806777, rs3806782, rs3796576 and rs7698460 at GUCY1A3, as well as rs2229202 and rs1459853 at GUCY1B3 (Chen et al., 2019). Patients that carry the AA genotype of rs1459853 (G>A) had increased risk for hypertension than GG and GA carriers. When analyzing by age, it was shown that in adolescents, the TT genotype for rs2229202 (C>T) was associated with increased risk to hypertension and prehypertension when compared to CT and CC. Interestingly, no study assessed the association of these SNPs with drug response, although several drugs act through this gene product, such as NO donor vasodilators, for instance.
Conclusion and future perspectives
Despite the fact that there are few articles in the literature associating genetic polymorphisms in genes of the NO pathway (other than NOS3) with drug response, there is consistent evidence showing the importance of these genetic markers possibly affecting drug response and treatment outcome. It is interesting that the association of these polymorphisms with disease risk is much more explored and several markers that alter disease risk also were associated with drug response. This shows that there is a large potential in studying pharmacogenetics, especially when considering candidate pathways instead of candidate genes. This may also prove additional value when considering that most researchers nowadays prefer to study genome wide data. Pathway analysis may be complemented with biochemical biomarkers closely related with these pathways, which could also provide mechanistic insights on how these markers may affect these complex phenotypes. Large scale explorative analysis could be financially prohibitive or be experimentally limited if one considers genome wide data in parallel with proteomic and metabolomic data. Some biochemical biomarkers require specific pre-assay handling and/or preparation to be properly assessed, which may be overlooked in large scale analyses. Therefore, pathway genetic association studies have their own value and may be important to establish clinically important associations. While it is very clear that common SNPs may lead to subtle effects, not determining phenotypes, it is very interesting to see that results reported here are reproduced between different clinical settings (cancer, cardiovascular diseases, urological diseases) that are affected by NO availability. Albeit the large potential, there is still much to be studied in this field to provide reliable, sensible, precise and clinically relevant genetic markers with capabilities to personalize the drug regimen for each genetically unique patient.
Acknowledgments
This study was partially supported by scholarships from Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brasil (CAPES) - Finance Code 001 (A.E.) and Fundação de Amparo a Pesquisa do Estado de São Paulo(FAPESP Scholarship number: 20/11740-9, C.K.C.F).
References
- Angona A, Bellosillo B, Alvarez-Larrán A, Martínez-Avilés L, Camacho L, Pairet S, Fernández-Rodriguez MC, Ancochea A and Besses C (2013) Genetic predisposition to molecular response in patients with myeloproliferative neoplasms treated with hydroxycarbamide. Leuk Res 37:917-921.
- Arnold WP, Mittal CK, Katsuki S and Murad F (1977) Nitric oxide activates guanylate cyclase and increases guanosine 3’:5’-cyclic monophosphate levels in various tissue preparations. Proc Natl Acad Sci U S A 74:3203-3207.
- Azevedo AMM, Brites-Anselmi G, Pinheiro LC, de Almeida Belo V, Coeli-Lacchini FB, Molina CAF, de Andrade MF, Tucci S Jr, Hirsch E, Tanus-Santos JE et al (2017) Relationship between asymmetric dimethylarginine nitrite and genetic polymorphisms: Impact on erectile dysfunction therapy. Nitric Oxide 71:44-51.
- Beleznai T, Feher A, Spielvogel D, Lansman SL and Bagi Z (2011) Arginase 1 contributes to diminished coronary arteriolar dilation in patients with diabetes. Am J Physiol Heart Circ Physiol 300:H777-H783.
- Bouras G, Deftereos S, Tousoulis D, Giannopoulos G, Chatzis G, Tsounis D, Cleman MW and Stefanadis C (2013) Asymmetric Dimethylarginine (ADMA): A promising biomarker for cardiovascular disease? Curr Top Med Chem 13:180-200.
- Brites-Anselmi G, Azevedo AMM, Miyazaki AHL, Pinheiro LC, Coeli-Lacchini FB, de Andrade MF, Molina CAF, Tucci S, Hirsch E, Tanus-Santos JE et al (2019) DDAH1 and DDAH2 polymorphisms associate with asymmetrical dimethylarginine plasma levels in erectile dysfunction patients but not in healthy controls. Nitric Oxide 92:11-17.
- Caldwell RW, Rodriguez PC, Toque HA, Narayanan SP and Caldwell RB (2018) Arginase: A multifaceted enzyme important in health and disease. Physiol Rev 98:641-665.
- Cardounel AJ, Cui H, Samouilov A, Johnson W, Kearns P, Tsai A-L, Berka V and Zweier JL (2007) Evidence for the pathophysiological role of endogenous methylarginines in regulation of endothelial NO production and vascular function. J Biol Chem 282:879-887.
- Cashen DE, MacIntyre DE and Martin WJ (2002) Effects of sildenafil on erectile activity in mice lacking neuronal or endothelial nitric oxide synthase. Br J Pharmacol 136:693-700.
- Chen Y, Zhu L, Fang Z, Jin Y, Shen C, Yao Y, and Zhou C (2019) Soluble guanylate cyclase contribute genetic susceptibility to essential hypertension in the Han Chinese population. Ann Transl Med 7:620.
- Cinelli MA, Do HT, Miley GP and Silverman RB (2020) Inducible nitric oxide synthase: Regulation structure and inhibition. Med Res Rev 40:158-189.
- Cotta Filho CK, Oliveira-Paula GH, Pereira VCR and Lacchini R (2020) Clinically relevant endothelial nitric oxide synthase polymorphisms and their impact on drug response. Expert Opin Drug Metab Toxicol 16:927-951.
- Cozma A, Fodor A, Orasan OH, Vulturar R, Samplelean D, Negrean V, Muresan C, Suharoschi R and Sitar-Taut A (2019) Pharmacogenetic implications of eNOS polymorphisms (Glu298Asp, T786C, 4b/4a) in cardiovascular drug therapy. In Vivo 33:1051-1058.
- Craven PA and DeRubertis FR (1978) Restoration of the responsiveness of purified guanylate cyclase to nitrosoguanidine nitric oxide and related activators by heme and hemeproteins Evidence for involvement of the paramagnetic nitrosyl-heme complex in enzyme activation. J Biol Chem 253:8433-8443.
- Derbyshire ER and Marletta MA (2012) Structure and regulation of soluble guanylate cyclase. Annu Rev Biochem 81:533-559.
- Dobrian AD (2012) ADMA and NOS regulation in chronic renal disease: Beyond the old rivalry for l-arginine. Kidney Int 81:722-724.
- Duan QL, Gaume BR, Hawkins GA, Himes BE, Bleecker ER, Klanderman B, Irvin CG, Peters SP, Meyers DA, Hanrahan JP et al (2011) Regulatory haplotypes in ARG1 are associated with altered bronchodilator response. Am J Respir Crit Care Med 183:449-454.
- Eechoute K, van der Veldt AA, Oosting S, Kappers MH, Wessels JA, Gelderblom H, Guchelaar HJ, Reyners AK, van Herpen CM, Haanen JB et al (2012) Polymorphisms in endothelial nitric oxide synthase (eNOS) and vascular endothelial growth factor (VEGF) predict sunitinib-induced hypertension. Clin Pharmacol Ther 92:503-510.
- Emrich IE, Zawada AM, Martens-Lobenhoffer J, Fliser D, Wagenpfeil S, Heine GH and Bode-Böger SM (2018) Symmetric dimethylarginine (SDMA) outperforms asymmetric dimethylarginine (ADMA) and other methylarginines as predictor of renal and cardiovascular outcome in non-dialysis chronic kidney disease. Clin Res Cardiol 107:201-213.
- Ferrara N, Gerber H-P and LeCouter J (2003) The biology of VEGF and its receptors. Nat Med 9:669-676.
- Francis SH, Busch JL, Corbin JD and Sibley D (2010) cGMP-dependent protein kinases and cGMP phosphodiesterases in nitric oxide and cGMP action. Pharmacol Rev 62:525-563.
- Gallagher DJ, Al-Ahmadie H, Ostrovnaya I, Gerst SR, Regazzi A, Garcia-Grossman I, Riches J, Gounder SK, Flaherty AM, Trout A et al (2011) Sunitinib in urothelial cancer: Clinical pharmacokinetic and immunohistochemical study of predictors of response. Eur Urol 60:344-349.
- Gheorghiade M, Marti CN, Sabbah HN, Roessig L, Greene SJ, Böhm M, Burnett JC, Campia U, Cleland JG, Collins SP et al (2013) Soluble guanylate cyclase: A potential therapeutic target for heart failure. Heart Fail Rev 18:123-134.
- Hu X-L, Zhou J-P, Kuang D-B, Qi H, Peng L-M, Yang T-L, Li X, Zhang W, Zhou H-H and Chen X-P (2016) Considerable impacts of AGXT2 V140I polymorphism on chronic heart failure in the Chinese population. Atherosclerosis 251:255-262.
- Hussain MB, Hobbs AJ and MacAllister RJ (1999) Autoregulation of nitric oxide-soluble guanylate cyclase-cyclic GMP signalling in mouse thoracic aorta. Br J Pharmacol 128:1082-1088.
- Johnson FK, Peyton KJ, Liu XM, Azam MA, Shebib AR, Johnson RA and Durante W (2015) Arginase promotes endothelial dysfunction and hypertension in obese rats. Obesity (Silver Spring) 23:383-390.
- Kiechle FL and Malinski T (1993) Nitric oxide biochemistry pathophysiology and detection. Am J Clin Pathol 100:567-575.
- Kielstein JT, Salpeter SR, Bode-Boeger SM, Cooke JP and Fliser D (2006) Symmetric dimethylarginine (SDMA) as endogenous marker of renal function--a meta-analysis. Nephrol Dial Transplant 21:2446-2451.
- Lacchini R, Muniz JJ, Nobre YTDA, Cologna AJ, Martins ACP and Tanus-Santos JE (2013) VEGF genetic polymorphisms affect the responsiveness to sildenafil in clinical and postoperative erectile dysfunction. Pharmacogenomics J 13:437-442.
- Lacchini R, Muniz JJ, Nobre YTDA, Cologna AJ, Martins ACP and Tanus-Santos JE (2018) Influence of arginase polymorphisms and arginase levels/activity on the response to erectile dysfunction therapy with sildenafil. Pharmacogenomics J 18:238-244.
- Lambrechts D, Storkebaum E, Morimoto M, Del-Favero J, Desmet F, Marklund SL, Wyns S, Thijs V, Andersson J, van Marion I et al (2003) VEGF is a modifier of amyotrophic lateral sclerosis in mice and humans and protects motoneurons against ischemic death. Nat Genet 34:383-394.
- Leineweber K, Moosmang S and Paulson D (2017) Genetics of NO deficiency. Am J Cardiol 120:S80-S88.
- Leiper JM, Maria JS, Chubb A, MacAllister RJ, Charles IG, Whitley GS and Vallance P (1999) Identification of two human dimethylarginine dimethylaminohydrolases with distinct tissue distributions and homology with microbial arginine deiminases. Biochem J 343:209-214.
- Leiper JM, Nandi M, Torondel B, Murray-Rust J, Malaki M, O’Hara B, Rossiter S, Anthony S, Madhani M, Selwood D et al (2007) Disruption of methylarginine metabolism impairs vascular homeostasis. Nat Med 13:198-203.
- Li H, Romieu I, Sienra-Monge J-J, Ramirez-Aguilar M, Del Rio-Navarro BE, Kistner EO, Gjessing HK, Lara-Sanchez Idel C, Chiu GY and London SJ (2006) Genetic polymorphisms in arginase I and II and childhood asthma and atopy. J Allergy Clin Immunol 117:119-126.
- Li P, Kondo T, Numaguchi Y, Kobayashi K, Aoki M, Inoue N, Okumura K and Murohara T (2008) Role of bradykinin nitric oxide and angiotensin II type 2 receptor in imidapril-induced angiogenesis. Hypertension 51:252-258.
- Litonjua AA, Lasky-Su J, Schneiter K, Tantisira KG, Lazarus R, Klanderman B, Lima JJ, Irvin CG, Peters SP, Hanrahan JP et al (2008) ARG1 is a novel bronchodilator response gene: Screening and replication in four asthma cohorts. Am J Respir Crit Care Med 178:688-694.
- Loupakis F, Ruzzo A, Salvatore L, Cremolini C, Masi G, Frumento P, Schirripa M, Catalano V, Galluccio N, Canestrari E et al (2011) Retrospective exploratory analysis of VEGF polymorphisms in the prediction of benefit from first-line FOLFIRI plus bevacizumab in metastatic colorectal cancer. BMC Cancer 11:247.
- Lu T-M, Lin S-J, Lin M-W, Hsu C-P and Chung M-Y (2011) The association of dimethylarginine dimethylaminohydrolase 1 gene polymorphism with type 2 diabetes: A cohort study. Cardiovasc Diabetol 10:16.
- Ma Q, Wyszynski DF, Farrell JJ, Kutlar A, Farrer LA, Baldwin CT and Steinberg MH (2007) Fetal hemoglobin in sickle cell anemia: Genetic determinants of response to hydroxyurea. Pharmacogenomics J 7:386-394.
- Maarsingh H, Pera T and Meurs H (2008) Arginase and pulmonary diseases. Naunyn Schmiedebergs Arch Pharmacol 378:171-184.
- Maas R (2005) Pharmacotherapies and their influence on asymmetric dimethylargine (ADMA). Vasc Med 10:S49-S57.
- Masuda H, Tsujii T, Okuno T, Kihara K, Goto M and Azuma H (2002) Accumulated endogenous NOS inhibitors decreased NOS activity and impaired cavernosal relaxation with ischemia. Am J Physiol Regul Integr Comp Physiol 282:R1730-R1738.
- Melincovici CS, Boşca AB, Şuşman S, Mărginean M, Mihu C, Istrate M, Moldovan IM, Roman AL and Mihu CM (2018) Vascular endothelial growth factor (VEGF) - key factor in normal and pathological angiogenesis. Rom J Morphol Embryol 59:455-467.
- Mergia E, Russwurm M, Zoidl G and Koesling D (2003) Major occurrence of the new alpha2beta1 isoform of NO-sensitive guanylyl cyclase in brain. Cell Signal 15:189-195.
- Mishima T, Hamada T, Ui-Tei K, Takahashi F, Miyata Y, Imaki J, Suzuki H and Yamashita K (2004) Expression of DDAH1 in chick and rat embryos. Brain Res Dev Brain Res 148:223-232.
- Moncada S and Higgs A (1993) The L-arginine-nitric oxide pathway. N Engl J Med 329:2002-2012.
- Oliveira-Paula GH, Coeli-Lacchini FB, Ferezin LP, Ferreira GC, Pinheiro LC, Paula-Garcia WN, Garcia LV, Tanus-Santos JE and Lacchini R (2021) Arginase II polymorphisms modify the hypotensive responses to propofol by affecting nitric oxide bioavailability. Eur J Clin Pharmacol 77:869-877.
- Oliveira-Paula GH, Lacchini R and Tanus-Santos JE (2017) Clinical and pharmacogenetic impact of endothelial nitric oxide synthase polymorphisms on cardiovascular diseases. Nitric Oxide 63:39-51.
- Oliveira-Paula GH, Lacchini R, Fontana V, Silva PS, Biagi C and Tanus-Santos JE (2015) Polymorphisms in VEGFA gene affect the antihypertensive responses to enalapril. Eur J Clin Pharmacol 71:949-957.
- Park K, Lee DG, Kim SW and Paick J-S (2009) Dimethylarginine dimethylaminohydrolase in rat penile tissue: Reduced enzyme activity is responsible for erectile dysfunction in a rat model of atherosclerosis. Int J Impot Res 21:228-234.
- Pereira SC, Cotta Filho CK and Lacchini R (2021) The need for further studies examining the role of endothelial nitric oxide synthase polymorphisms in drug response. Pharmacogenomics 22:383-387.
- Perticone F, Sciacqua A, Maio R, Perticone M, Leone GG, Bruni R, Di Cello S, Pascale A, Talarico G, Greco L et al (2010) Endothelial dysfunction ADMA and insulin resistance in essential hypertension. Int J Cardiol 142:236-241.
- Peyton KJ, Liu XM, Shebib AR, Johnson FK, Johnson RA and Durante W (2018) Arginase inhibition prevents the development of hypertension and improves insulin resistance in obese rats. Amino Acids 50:747-754.
- Poulos TL (2006) Soluble guanylate cyclase. Curr Opin Struct Biol 16:736-743.
- Rini BI, Schiller JH, Fruehauf JP, Cohen EE, Tarazi JC, Rosbrook B, Bair AH, Ricart AD, Olszanski AJ, Letrent KJ et al (2011) Diastolic blood pressure as a biomarker of axitinib efficacy in solid tumors. Clin Cancer Res 17:3841-3849.
- Rochette L, Lorin J, Zeller M, Guilland J-C, Lorgis L, Cottin Y and Vergely C (2013) Nitric oxide synthase inhibition and oxidative stress in cardiovascular diseases: Possible therapeutic targets? Pharmacol Ther 140:239-257.
- Rodionov RN, Jarzebska N, Weiss N and Lentz SR (2014) AGXT2: A promiscuous aminotransferase. Trends Pharmacol Sci 35:575-582.
- Romero MJ, Platt DH, Tawfik HE, Labazi M, El-Remessy AB, Bartoli M, Caldwell RB and Caldwell RW (2008) Diabetes-induced coronary vascular dysfunction involves increased arginase activity. Circ Res 102:95-102.
- Russwurm M, Behrends S, Harteneck C and Koesling D (1998) Functional properties of a naturally occurring isoform of soluble guanylyl cyclase. Biochem J 335:125-130.
- Savelieva ON, Karunas AS, Fedorova YY, Murzina RR, Savelieva AN, Gatiyatullin RF, Etkina EI and Khusnutdinova EK (2020) The role of polymorphic variants of arginase genes (ARG1 ARG2) involved in beta-2-agonist metabolism in the development and course of asthma. Vavilovskii Zhurnal Genet Selektsii 24:391-398.
- Scaparrotta A, Franzago M, Marcovecchio ML, Di Pillo S, Chiarelli F, Mohn A and Stuppia L (2019) Role of THRB, ARG1, and ADRB2 genetic variants on bronchodilators response in asthmatic children. J Aerosol Med Pulm Drug Deliv 32:164-173.
- Schepers E, Speer T, Bode-Böger SM, Fliser D and Kielstein JT (2014) Dimethylarginines ADMA and SDMA: The real water-soluble small toxins? Semin Nephrol 34:97-105.
- Shahbazi M, Fryer AA, Pravica V, Brogan IJ, Ramsay HM, Hutchinson IV and Harden PN (2002) Vascular endothelial growth factor gene polymorphisms are associated with acute renal allograft rejection. J Am Soc Nephrol 13:260-264.
- Silva PS, Lacchini R, Gomes Vde A and Tanus-Santos JE (2011) Pharmacogenetic implications of the eNOS polymorphisms for cardiovascular action drugs. Arq Bras Cardiol 96:e27-e34.
- Sy HY, Ko FW, Chu HY, Chan IH, Wong GW, Hui DS and Leung TF (2012) Asthma and bronchodilator responsiveness are associated with polymorphic markers of ARG1 CRHR2 and chromosome 17q21. Pharmacogenet Genomics 22:517-524.
- Szmit S, Langiewicz P, Złnierek J, Nurzyński P, Zaborowska M, Filipiak KJ, Opolski G and Szczylik C (2012) Hypertension as a predictive factor for survival outcomes in patients with metastatic renal cell carcinoma treated with sunitinib after progression on cytokines. Kidney Blood Press Res 35:18-25.
- Tran CT, Fox MF, Vallance P and Leiper JM (2000) Chromosomal localization gene structure and expression pattern of DDAH1: Comparison with DDAH2 and implications for evolutionary origins. Genomics 68:101-105.
- Tse SM, Tantisira K and Weiss ST (2011) The pharmacogenetics and pharmacogenomics of asthma therapy. Pharmacogenomics J 11:383-392.
- Ulivi P, Scarpi E, Passardi A, Marisi G, Calistri D, Zoli W, Del Re M, Frassineti GL, Tassinari D, Tamberi S et al (2015) eNOS polymorphisms as predictors of efficacy of bevacizumab-based chemotherapy in metastatic colorectal cancer: Data from a randomized clinical trial. J Transl Med 13:258.
- Valkonen V-P, Tuomainen T-P and Laaksonen R (2005) DDAH gene and cardiovascular risk. Vasc Med 10:S45-S48.
- Vockley JG, Jenkinson CP, Shukla H, Kern RM, Grody WW and Cederbaum SD (1996) Cloning and characterization of the human type II arginase gene. Genomics 38:118-123.
- Vonk JM, Postma DS, Maarsingh H, Bruinenberg M, Koppelman GH and Meurs H (2010) Arginase 1 and arginase 2 variations associate with asthma asthma severity and beta2 agonist and steroid response. Pharmacogenet Genomics 20:179-186.
- Yang L, Guan H, He J, Zeng L, Yuan Z, Xu M, Zhang W, Wu X and Guan J (2012) VEGF increases the proliferative capacity and eNOS/NO levels of endothelial progenitor cells through the calcineurin/NFAT signalling pathway. Cell Biol Int 36:21-27.
- Yazawa H, Miyachi M, Furukawa M, Takahashi K, Takatsu M, Tsuboi K, Ohtake M, Murase T, Hattori T, Kato Y et al (2011) Angiotensin-converting enzyme inhibition promotes coronary angiogenesis in the failing heart of Dahl salt-sensitive hypertensive rats. J Card Fail 17:1041-1050.
- Yoo T, Joo SK, Kim HJ, Kim HY, Sim H, Lee J, Kim HH, Jung S, Lee Y, Jamialahmadi O et al (2021) Disease-specific eQTL screening reveals an anti-fibrotic effect of AGXT2 in non-alcoholic fatty liver disease. J Hepatol 75:514-523.
- Yoshino Y, Kumon H, Mori T, Yoshida T, Tachibana A, Shimizu H, Iga J-I and Ueno S-I (2021) Effects of AGXT2 variants on blood pressure and blood sugar among 750 older Japanese subjects recruited by the complete enumeration survey method. BMC Genomics 22:287.
- Zeng W-P, Zhang R, Li R, Luo J-F and Hu X-F (2017) Association of the endothelial nitric oxide synthase gene T786C polymorphism with in-stent restenosis in chinese han patients with coronary artery disease treated with drug-eluting stent. PLoS One 12:e0170964.
Publication Dates
-
Publication in this collection
14 Oct 2022 -
Date of issue
2022
History
-
Received
03 May 2022 -
Accepted
08 Sept 2022