Association of JAG1 gene polymorphism with systemic blood pressure in patients with obstructive sleep apnea: a prospective cohort study

Aim To assess the effects of single nucleotide polymorphisms (SNPs) on blood pressure control in patients with obstructive sleep apnea (OSA). Methods This prospective observational cohort study, conducted between 2004 and 2014, examined the associations of SNPs of JAG1, GUCY1A3-GUCY1B3, SH2B3, and NPR3-C5orf23 genes with systolic and diastolic blood pressure (SBP, DBP) in 1179 adults evaluated for OSA with overnight polysomnography. Genotyping was performed by unlabeled probe melting analysis. Results The patients were predominantly male (69.6%, mean age 52 ± 11 years, apnea-hypopnea index 34 ± 31 episodes/h). Only JAG1 genotype was associated with SBP and DBP: compared with AA homozygotes, G allele carriers (pooled GG and AG genotype) had significantly higher morning SBP (132 ± 19 vs 129 ± 18 mm Hg; P = 0.009) and morning and evening DBP (85 ± 11 vs 83 ± 10 mm Hg, P = 0.004; 86 ± 10 vs 84 ± 10 mm Hg, P = 0.012, respectively); the differences remained significant after the correction for multiple SNPs testing. In multivariate analyses, oxygen desaturation index and JAG1 genotype independently predicted morning SBP (P = 0.001, P = 0.003, respectively) and DBP (P < 0.001, P = 0.005, respectively), and evening SBP (P = 0.019, P = 0.048, respectively) and DBP (P = 0.018, P = 0.018, respectively). Conclusion This is the first replication study of the SNPs recently linked to arterial hypertension in general population by genome-wide association studies. Our findings suggest that JAG1 genotype is related to blood pressure control in OSA: G allele was associated with higher morning and evening SBP and DBP.

Blood pressure is a multifactorial trait. International guidelines for the management of arterial hypertension recognize obstructive sleep apnea (OSA) as the most prevalent cause of secondary hypertension (1) and the most important factor in drug-resistant hypertension (2). Increases in OSA severity are directly linked to increases in systolic and diastolic blood pressure (SBP, DBP) and to the odds for the development of arterial hypertension (3).
Another factor that profoundly affects blood pressure control is heredity. Approximate heritability of blood pressure ranges between 30%-50% (4). The material basis for this heritability is coded in two types of genetic variants: a) major-effect genetic variants that are responsible for rare familial hypertension syndromes, contributing to blood pressure increases at the level of several millimeters of mercury (mmHg), b) small-effect genetic variants that independently influence blood pressure at the level of up to 1 mm Hg for SBP and of up to 0.5 mm Hg for DBP (4,5). Small-effect genetic variants include repetition mutations, inversions, and, most importantly, single nucleotide polymorphisms (SNPs), which may occur throughout the genome in coding, non-coding, and regulator parts of genes. Several genome-wide association studies (GWASs) revealed signals in particular genetic loci linked to blood pressure control in general population and identified over 100 SNPs associated with either blood pressure increase or arterial hypertension (6). Nevertheless, the identified loci linked to blood pressure were seldom localized inside or close to regions with known function in blood pressure control. In contrast, most of the SNPs identified by GWASs were located next to genes with pleiotropic effects, such as prenatal cardiovascular development, interand intracellular signaling, hematopoiesis, or metabolism of natriuretic peptides (4). Moreover, several of the newly identified SNPs linked to blood pressure control were in previous studies associated with the increased risk of coronary artery disease (7).
Although GWASs recognized the effects of certain SNPs on blood pressure regulation in the general population (5)(6)(7), there is a paucity of data about the potential effects of these SNPs in patients with pre-existing medical conditions known to modify blood pressure control. The present study aimed to evaluate the associations between blood pressure and selected gene polymorphisms with GWAS-recognized effects on blood pressure control (rs3184504 of the SH2B3 gene, rs1327235 of the JAG1 gene, rs13139571 of the GUCY1A3-1B3 gene, and rs1173771 of the NPR3c5orf23 gene) in individuals referred to a sleep laboratory for OSA evaluation. The selection of four distinct SNPs was guided by several previous studies that identified the relationships between these polymorphisms and blood pressure, arterial hypertension, and coronary artery disease in general population as summarized by Waken et al (6).

Patients
In Apnea was defined as a reduction of airflow of ≥90% from the baseline with duration ≥10 s; hypopnea was defined as a reduction in airflow of ≥50% of baseline for ≥10 s, followed by a decrease in oxygen saturation for ≥3%, arousal, or both. Alternatively, hypopnea was identified if reduction of airflow ≥30% from the baseline was present and accompanied with a decrease in saturation ≥4%. Apnea/ hypopnea index (AHI) was defined as the total number of apneic and hypopneic events per hour of sleep. Oxygen desaturation index (ODI) was calculated as the number of episodes of reductions in oxygen saturation of ≥3% per hour of sleep, and arousal index was used as a marker of sleep fragmentation characterized as the number of arousals on EEG recording per hour of sleep.
Patients with AHI less than five episodes per hour had no OSA. In patients diagnosed with OSA, its severity was classified based on AASM guidelines, with AHI≥5 and <15 episodes/h labeled as mild OSA, AHI≥15 and <30 episodes/h as moderate OSA, and AHI≥30 episodes/h as severe OSA (9).

Blood pressure measurements
Blood pressure was measured in a sitting position by using a certified manometric device in the evening, immediately before the montage of polysomnographic leads after at least of 10 minutes of no physical effort (10), and in the morning after awakening before the removal of the leads. Systolic and diastolic blood pressure were measured three times by a trained nurse, and the mean value of the last two measurements was recorded. Manual sphygmomanometer (Welch Allyn type Gold Seriers DS66 Trigger Aneroids, Chicago, IL, USA) with annually certified accuracy of ±2.5% was used for all blood pressure measurements.

statistical analysis
Normality of the distribution was assessed by Kolmogorov-Smirnov test. The data are presented as mean ± standard deviation (SD). Differences between groups were analyzed using one way ANOVA for parametric variables and ANOVA on ranks for nonparametric variables. Holm-Sidak test was used for post hoc pair-wise comparisons between groups with different OSA severity. Differences in proportions between groups were analyzed with χ 2 test. A two-tailed P-value of <0.05 was considered significant for comparisons between groups with different OSA severity. The alleles of the selected SNPs that confer an increase in blood pressure were referenced according to the genome database in the project Ensebml GRCh38 (11). For comparisons between the respective genetic variants for each genotyped polymorphism, the cohort was divided into two groups (a dominant model): the first group comprised the individuals with one or more copy of the risky allele (ie, conferring an increase in blood pressure) and the second group comprised the homozygotes for the non-risky allele. Consequently, after applying the Bonferroni reverse-excess TGGGGACACAGCCAACCAT probe CTGCTGGTGCTTTGTGAATAAGTTGGTAT-Phos correction for 4 tested SNPs, a P-value of <0.0125 was considered significant (α = 0.05/4 = 0.0125). Graphic outputs of the blood pressure comparisons between genotype groups were created with SigmaPlot version 8 (SPSS, Chicago, IL, USA) and Microsoft Powerpoint (Redmond, WA, USA). Linear relationships between blood pressure and indices of OSA severity were analyzed by calculating the Pearson correlation coefficient. In multivariate analyses, multiple linear regression models were used with blood pressure as a dependent variable, and age, sex, body mass index (BMI), antihypertensive use, ODI, and genotype as independent variables. Associations in the linear regression models are presented as nominally significant (P < 0.05). All analyses were carried out using SPSS, version 14 (IBM, Chicago, IL, USA).

Cohort characteristics
The      association of selected genotypes with blood pressure Significant differences in SBP and DBP were observed between the genotype groups of polymorphism in the JAG1 gene. Alleles A and G of JAG1 gene polymorphism were distributed according to Hardy-Weinberg equilibrium. Sex distribution, age, BMI, AHI, ODI, antihypertensive medication use, and the proportion of patients according to OSA severity were similar in the two JAG1 genotype groups (Table 4).
We also examined the association of OSA severity with blood pressure in the distinct JAG1 polymorphism genotype groups. G allele carriers with severe OSA had significantly higher morning and evening SBP and DBP (P < 0.05 for all) than G allele carriers with no OSA. In addition, AA homozygotes with severe OSA had higher morning SBP and DBP (P < 0.05 for both), and evening SBP (P < 0.05) compared with AA homozygotes with no OSA (Table 5).
To further investigate the association of both intermittent hypoxia and JAG1 genotype with blood pressure control, we performed multivariate analyses using multiple linear regression models with each respective blood pressure value as a dependent variable and age, sex, BMI, use of antihypertensive medication, ODI, and JAG1 genotype as independent variables. Both ODI and JAG1 genotype were significant and independent predictors of morning and evening SBP and DBP (P < 0.05 for both, Table 6). Introducing AHI instead of ODI as an index of OSA severity in multivariate linear models yielded similar results (data not shown). Finally, we also analyzed a potential independent association of an interaction term JAG1 genotype*ODI with blood pressure by adding the interaction term to the previous models. Nevertheless, the JAG1 genotype*ODI interaction term was not a significant predictor of either SBP or DBP in any of the models.
No significant associations between the further three tested SNPs (SH2B3, GUCY1A3-GUCY1B3, and NPR3c5orf23) and blood pressure were observed (Table 7).

dIsCUssIon
The present genetic association study revealed that among patients with suspected OSA, carriers of the risky G allele of the rs1327235 polymorphism of JAG1 gene had significantly higher morning SBP and DBP, and evening DBP than AA homozygotes. The association of JAG1 genotype with blood pressure was independent of age, sex, BMI, and use of antihypertensive medication. Moreover, our data indicate that OSA severity has deleterious effects on blood pressure independently of the effect carried by the JAG1 genotype. Previously, several GWASs reported links between JAG1 genotype and increased SBP and DBP, and higher odds of hypertension and coronary artery disease in the general population (5,13). In individuals of European descent, effect size estimate of coded allele G  was 0.340 mm Hg for SBP, 0.302 mm Hg for DBP, and 0.034 in odds for hypertension (5). Furthermore, Wain et al (13) reported a relationship between rs1327235 and the mean arterial pressure and pulse pressure in healthy individuals.
Our study is the first to replicate the GWAS-documented association between the rs1327235 polymorphism of the JAG1 gene and blood pressure control, and to suggest that the rs1327235 polymorphism of JAG1 gene may be involved in blood pressure regulation in patients with OSA.
The prevalence of hypertension in OSA ranges from 30 to 85%, while the prevalence of OSA among hypertensive patients is 40% (14). The association between OSA and hypertension is independent of confounders such as obesity, smoking, or alcohol intake (15). Increasing severity of sleep apnea is proportional to the increase in blood pressure and incidence of hypertension (15). Moreover, OSA has been identified as a prevalent underlying condition in drug-resistant hypertension (2,16). An important mediator for systemic hypertension in patients with OSA is chronic intermittent hypoxia (15). This type of hypoxia contributes to additional factors related to increases in blood pressure: sympathetic activation, blunted baroreflex sensitivity (17), increased chemosensory activity of the carotid body (18), and endothelial dysfunction (19). In the studied cohort, the differences in blood pressures between the JAG1 genotype groups were 2.0-4.5 mm Hg for SBP and 0.9-3.5 mm Hg for DPB across different OSA severity groups. Interestingly, in a GWAS, the mean estimated effect size of singular polymorphism was 0.5 mm Hg for DBP and 1.0 mm Hg for SBP (5). Therefore, the differences observed in our study exceeded the average of the expected effect size for a singular polymorphism. On the other hand, differences in blood pressures attributed to a singular gene polymorphism in our and other studies (5) are lower than the reported effect size of mutations in familial hypertensive syndromes, which was 10 mm Hg for SBP (4). In the present study, the differences in SBP and DBP between patients with severe OSA and those without OSA were up to 9 and 6 mm Hg, respectively. These results are comparable to those observed by Peppard et al (15) in their landmark prospective study.
Several genetic association studies have reported links between genetic background and arterial hypertension in OSA. Lavie et al (20) reported that OSA patients with haptoglobin phenotype 2-2 had increased susceptibility to hypertension compared with OSA patients with haptoglobin phenotype 2-1. Riha et al (21) demonstrated an association between tumor necrosis factor-alpha polymorphism and OSA severity; nevertheless, no relationship between tumor necrosis factor-alpha polymorphism and hypertension was observed. Considering the crucial role of sympathetic nervous system activation in the OSArelated arterial hypertension, genetic background of β 2adrenergic receptor was also investigated: heterozygosity for the β 2 -adrenergic receptor was associated with a lower rate of post-myocardial infarction survival in patients with OSA and a high cardiovascular risk profile. However, functionally relevant polymorphisms of β2-adrenergic receptor did not modify blood pressure induced by OSA (22). In another study, β 1 -adrenergic receptor gene Arg389Arg genotype was associated with an increased prevalence of hypertension in individuals with mild OSA (23). The results on the role of angiotensin-converting enzyme gene insertion/ deletion (I/D) polymorphism in blood pressure in patients with OSA yielded conflicting results. While in one study, the D allele of the I/D polymorphism was linked with central obesity but not with OSA or hypertension (24), in another it was associated with hypertension only (25). Interestingly, Patel et al (26) observed a protective effect of D allele against hypertension in severe OSA, and Boström (27) reported a significant interaction between OSA and I/D polymorphism and the prevalence of hypertension in OSA.
Our study was the first to analyze, in patients with OSA, the potential role of polymorphisms originally identified in GWASs as being significant in blood pressure regulation in general population. Therefore, our results on the associations between the JAG1 gene polymorphism and morning and evening SBP and DBP in patients with OSA confirm and extend the previous results on the role of JAG1 genotype in blood pressure control. JAG1 gene is localized on chromosome 20. It codes jagged 1 protein that serves as a ligand for multiple Notch receptors. Notch signaling is an evolutionary conserved short-range intercellular pathway with a role in many essential processes, such as cell fate determination during embryonic development, vascular morphogenesis, angiogenesis, phenotypic switching, and vascular remodeling after injury (28).
Recently, JAG1 has been implicated in the pathogenesis of pulmonary arterial hypertension by aggravating pulmonary vascular remodeling both in animal studies (29) and in patients with tetralogy of Fallot and pulmonary stenosis (30). Mechanisms underlying the association between JAG1 genotype and systemic hypertension might parallel those observed in pulmonary hypertension, but experimental data for this hypothesis are lacking. Of note, a human clinical condition with autosomal dominant heritability, termed Alagille syndrome, involves both major frameshift mutations of JAG1 gene and systemic arterial hypertension (31). Nevertheless, direct pathophysiological links between JAG1 genotype and blood pressure control remain to be elucidated.
The main strength of our study is a distinct cohort of patients who underwent full attended polysomnography, which is a fundamental method in diagnosing sleep disordered breathing. Nevertheless, several limitations to the current study need to be also acknowledged. First, only a minority of the genetic variants significantly associated with SBP, DBP, and hypertension in GWAS was near a gene with a recognized role in blood pressure control (4). Moreover, the effect size of each individual variant is very small, and even collectively, the 29 variants explain only 1%-2% of SBP and DBP variance (5). This may clarify the lack of associations between blood pressure and three of the four SNPs tested in the present investigation; further studies in much larger cohorts are needed to analyze such potential associations in more detail. Second, although our results suggest a role for the JAG1 gene in blood pressure control in patients with OSA, investigation of the underlying mechanisms of the observed association was beyond the scope of the present study. Therefore, the present results should be considered hypothesis-generating, and further studies are needed to analyze the relationships between the JAG1 gene polymorphism and blood pressure control in OSA in more detail.
In conclusion, the present study suggests that the risky G allele in the JAG1 genotype is associated with higher morning and evening SBP and DBP in patients referred to sleep laboratory for the evaluation of suspected OSA. Largescale genetic studies are needed to elucidate the impact of susceptibility polymorphisms that contribute to hypertension in such patients. declaration of authorship all authors conceived and designed the study; IP, VH, LK, Itr, and JZ acquired the data; all authors analyzed and interpreted the data; IP, VH, LK, JZ, ITk, RT, and PJ drafted the manuscript; all authors critically revised the manuscript for important intellectual content; all authors gave approval of the version to be submitted; all authors agreed to be accountable for all aspects of the work.