Background
Atrial fibrillation (AF) is the most common arrhythmia worldwide, and type 2 diabetes (T2D) is an independent risk factor for AF [
1]. The exact mechanisms underlying the increased risk of AF in T2D patients are not fully elucidated, but are thought to involve structural and electrical remodeling of atria, inflammation, oxidative stress, and glycemic fluctuation [
2]. Currently, the prevalence of diabetes in China has rapidly increased over the past decade, and has been ranked top one around the world [
3]. The incidence of AF is then increasing with the diabetes epidemic. More Studies indicated that the risk of cardioembolic stroke (CS) is increased when both conditions coexist, becoming a major public health problem in China. Although optimal glycemic management and integrated control of these reversible risk factors (e.g., unhealthy diet, smoking, physical inactivity, obesity, and obstructive sleep apnea syndrome, dyslipidemia, etc.) have been related to lower incidence of AF and CS, the benefit could be dampened or offset by inherently greater genetic risk [
4]. Here, early genetic risk evaluation of individual’s at greater risk of AF and CS will provide a possible strategy for precision prevention of AF and CS in patients with T2D.
It is well known that the occurrence and development of T2D is associated with renin–angiotensin–aldosterone system (RAAS) activation [
5], and through entire chain of diabetic related cardiovascular events (e.g., AF [
6]). Angiotensin-converting enzyme 2 (
ACE2), as a key negative regulator of the RAAS, hydrolyze respectively angiotensin I/II (Ang I/II) into Ang (1–9)/Ang (1–7), and Ang (1–7) further acts on the Mas receptor, forming the ACE2/Ang(1–7)/Mas axis. The axis not only maintains blood glucose homeostasis via improving sensitivity to insulin but also promotes cardiovascular protection by vasodilation, anti-proliferation, anti-oxidative stress, anti-inflammatory, anti-fibrosis, and anti-thrombosis, which against the biological effects of the classic ACE/Ang II/AT1R axis [
7]. In experimental AF models, the expression of atrial
ACE2 was decreased in association with overexpression of atrial Ang II and the development of atrial structural remodeling [
8]. In contrast, atrial overexpression of
ACE2 improved cardiac fibrosis, electrical remodeling, and its related AF inducibility [
9]. These results suggested that ACE2 now has become a new target for prevention of AF and CS.
ACE2 is one of the major candidate genes for AF genetic susceptibility. The ACE2 gene sequence is highly polymorphic and high degree of genetic heterogeneity, manifesting the characteristics of geographical-, ethnic- and gender-specific genetic diversity [
10]. Many studies showed the relationship between ACE2 SNPs and the upstream cause of AF as mentioned above. Patel et al
. [
11] reported that 3
ACE2 variants (e.g., rs2074192, rs4240157 and rs4646188) were related to the risk of diabetes related HTN in Australian Caucasians. Chaoxin et al
. reported that
ACE2 rs2285666 variant was associated with CAD among patients with T2D in South China [
12]. Recent study by Liu et al
. [
13] confirmed that 8
ACE2 SNPs (e.g., rs233575, rs879922, rs2074192, rs1978124, rs4646188, rs2048683, rs4646156 and rs4240157) were not only linked to moderate to high risk of T2D but also with higher risk of hypertension and dyslipidemia in Uygur patients with T2D. These results suggested that there was a potential link between ACE2 variants and AF due to the common genetic basis. Indeed, Feng et al
. [
14] observed that with
ACE2 rs6632677 increased the structural AF risk in male Han Chinese, which 15.7% participants in the study had diabetes. Wang et al
. [
15] also found that the male Han Chinese carrying T-allele of
ACE2 rs2106809 was is associated with lone AF and adverse cardiac events (e.g., stroke). Luo et al
. [
10] reported that 3
ACE2 SNPs (e.g., rs4646155, rs4240157 and rs4830542) were correlated with the risk of hypertension induced AF in South Xinjiang. However, the relationship of ACE2 gene polymorphism with AF and CS is not fully understood in Uygur patients with T2D. Accordingly, in present study we evaluated the relationships of
ACE2 gene variants with AF and CS among diabetic patients in Uygurs.
Discussion
AF and CS among patients with T2D are a growing public health issues that has received increasing attention. Current treatment and prevention strategies for AF among T2D patients are mainly focused on glucose-lowering therapies, restoration and maintenance of sinus rhythm (e.g., drugs, cardioversion or catheter ablation), heart rate control and stroke prevention [
2]. The occurrence of AF and CS can be reduced by treatment by those measures for T2D patients. However, as far as the early prevention and control of AF and CS are concerned, clinical evaluation of genetic risk is an important link in comprehensive management of AF in diabetes that cannot be ignored [
21]. Like diabetes, recent genetic studies indicated that there is also an obvious genetic predisposition for the occurrence of AF [
22]. It is noted that the prevalence of T2D in China has the characteristics of ethnic diversity (e.g., Uygur) [
23], and there may also be ethnic differences in AF. Thus, early identification and assessing the heritability of AF will provide a novel possible strategy for the prevention and control of AF among T2D patients in Uygurs.
This is the only study to investigate possible relationships between
ACE2 polymorphisms and AF among Uygur patients with T2D. Our previous research reported that there are 8
ACE2 variants related to the risk of diabetes [
13]. However, the data showed in this study suggest that only the diabetes risk related
ACE2 rs4646188 was further correlated with high risk AF (RR = 2.37, Table
1) and CS (RR = 2.58, Table
2) in participants with T2D via a median follow-up of 6.8 years. Indeed, Patel et al
. [
11] reporting that Caucasian T2D patients carrying TT genotype of the loci was associated HTN. Pan et al
. [
20] recently report that subjects carrying T-allele of
ACE2 rs4646188 were not only related to high HTN risk but also to increased dyslipidemia risk include elevated serum levels of triglyceride (TRIG), total cholesterol (TC) and low-density lipoprotein cholesterol (LDL-C) as well as decreased serum high-density lipoprotein cholesterol (HDL-C).
ACE2 rs4646188 was not only linked to with the upstream causes of AF (e.g., HTN, dyslipidemia and diabetes) but also to the downstream complications (e.g., stroke [
10]). Similar phenomenon were also seen at the other
ACE2 SNP such as rs2285666, which was linked to higher HTN [
24] and stroke [
25] risk in northern Han Chinese, but the loci seem to play lesser roles in T2D [
26] and lone AF [
15] risk. These results suggested that there is ethnic difference between Uygurs and Hans in the relationship between
ACE2 variants and AF.
It is well known that atrial structural and electrical remodeling are important elements for the occurrence and maintenance of AF. The macroscopic phenotype of atrial structural remodeling is left atrial enlargement (LAE), which has been considered to be an independent predictor of AF [
27]. In Coronary Artery Risk Development in Young Adults (CARDIA) [
28], the presence of T2D at baseline was related to larger LAD via a 20-year follow-up. In this study we found that the only 3 T2D risk related
ACE2 mutations (e.g., rs2074192, rs4240157 and rs4646188) were further correlated with increased LAD in T2D patients (Table
3 and Additional file
1: Table S5). Our results are partially accordant with a recent studies as follows: rs2074192 was associated with left ventricular remodeling in hypertensive patients [
29], and rs4240157 was linked to left ventricular remodeling among Austrian in MONICA Augsburg Echocardiographic Substudy [
30]. The
ACE2 rs4240157 was also correlated with larger LAD in Uygur patients with HTN while rs4646188 was not [
10]. What’s more important, LAE is an independent predictor of stroke and systemic embolism in patients with AF or in sinus rhythm [
31,
32].
Besides atrial structural remodeling, atrial electrical remodeling also acts a primary role in occurrence and development of AF. The mechanism of atrial electrical remodeling can be divided into heterogeneity of action potential duration (APD) and electrical conduction abnormalities, involving in specific ion channels remodeling (e.g., sodium and potassium), which were affected by changes in serum sodium [
33,
34] and potassium [
35] concentrations. In this study we also found not all AF risk related
ACE2 mutations were related to changes of serum sodium/potassium concentrations.
ACE2 rs4240157 was only linked to elevated serum sodium levels among in Uygur patients with T2D, and rs2074192 was only associated with decreased serum potassium levels. Uygur patients with high diabetes risk genotype of
ACE2 rs4646188 were associated with both the higher serum sodium and lower serum potassium levels. Indeed, studies have reported that elevated serum sodium levels and hypokalemia are a risk factor for postoperative atrial fibrillation [
36]. The other 4 diabetes risk related
ACE2 variants (
e,g., rs2074192, rs2048683, rs4646156 and rs879922) were not related to AF risk. T2D subjects with the high diabetes risk genotypes of the 4
ACE2 mutations were associated with higher serum sodium levels it had nothing to do with lower serum potassium levels (Additional file
1: Table S6). These phenomena indicated that the simultaneous changes of serum sodium/potassium concentration is more conducive to the occurrence of AF under the ACE2 mutations related genetic background, and the changes in serum potassium may be more important than changes in serum sodium for AF susceptibility. Our results suggested that
ACE2 rs4646188 could be involved in atrial electrical remodeling by mediating the changes of serum sodium/potassium concentrations, thereby leading to T2D patients present with an increased susceptibility to AF.
Numerous evidences have implicated inflammation as central mediators of T2D induced atrial structural and electrical remodeling. HsCRP, as a key biomarker of inflammation, has been not only related to diabetes but also to the occurrence, maintenance and recurrence of AF [
37] as well as left atrial thrombus formation [
38]. However, clinical trials on evaluating the efficacy of anti-inflammatory drugs (e.g., colchicine, corticosteroids, statins and omega-3 unsaturated fatty acids) in prevention of AF were inconsistent [
39]. Besides the differences in anti-inflammatory drugs used, these findings indicate that it is essential to determine appropriate populations (high inflammation risk) with anti-inflammatory treatment. In present study we further found that T2D subjects carrying the high diabetes and AF risk genotype of rs4646188 had significantly increased plasma HsCRP levels (Table
5) and CS risk. In addition, T2D subjects with the greater diabetes risk genotypes of
ACE2 rs1978124 had higher inflammation level (Additional file
1: Table S7) and CS risk, but it was not related to AF risk. These results indicated that inflammation acts an important role for occurrence and development of AF from the perspective of atrial remodeling and its induced thrombus formation, but the ionic basis (especially serum potassium) of maintain AF trigger AF seems more important.
Even though a poor understanding of the exact molecular mechanisms of
ACE2 variants on increased AF risk in patients with diabetes, accumulated evidence suggested that activation of RAAS triggers a series of events (e.g., left atrial remodeling, inflammation and thromboembolism) contributing to AF. The common clinical profile (e.g., obesity, dyslipidemia and HTN, etc.) of the T2D subjectscreates the perfect environment for AF to occur, and the essence is metabolic disorder [
40], which is the initiating factor for RAAS activation [
41]. Diabetes induced activation of the ACE/Ang II/AT1R axis can promote cardiomyocyte and endothelial cell apoptosis, fibrosis, oxidative stress generation and inflammation [
41], that leads to cardiac remodeling and creates a favorable condition for AF occurrence.
ACE2 is an important component of RAAS, may be equally or even more important than ACE in regulating the cardiac balance of the RAAS, particularly in the setting of diabetes [
42]. Indeed, recent study indicated that increased ACE2 serum level was linked to higher risk of total death, cardiovascular events (e.g., myocardial infarction, heart failure and stroke) and diabetes [
43]. The role of
ACE2 variants in AF remains unclear, and it could be assumed that it is due to the ACE2/ACE axis imbalance.
ACE2 deficiency leads to increased tissue and circulating levels of Ang II under status of T2D [
44].
ACE2 SNPs rs2106809 and rs2074192 have been associated with reduced circulating Ang (1–7) [
45]. These results suggested that the
ACE2 SNPs may directly or indirectly result in circulating activation of RAAS. Our findings found that
ACE2 rs4646188 were significantly linked to RAAS activation (e.g., ACE, ANG I/ II and ALD), partially consistent with previous research.
Limitations
The major disadvantages of the study were as follows: firstly, due to the sample size (N = 547), large-scale subgroup analysis based on comparing the intensity of association between diabetic and non-diabetic patients will further demonstrate the importance of ACE2 in T2D patients. Secondly, Bonferroni correction was executed to correct significance thresholds, but false-positive results may still occur. Thirdly, the complex associations between genotype (ACE2 variants) and phenotype (AF and its related CS) to ultimately predict trait heritability remains a primary challenge of modern genetics. The exosome-derived microRNAs (exo-miRs) are one of the main classes of non-coding RNAs, and play a critical role as bridge that links genetic and environment factors. Functional characterization of the effects of genetic variants on differentially expressed exo-miRs related signaling pathways will undoubtedly facilitate our understanding of the associations between genotypes and phenotypes, needing further research. Therefore, results must be interpreted carefully.
Future directions
ACE2 variants rs4646188 could be a promising genetic predisposition marker for the risk of AF and CS among diabetic patients in Uygurs. Early genotype identification of the loci could provide a time window for targeted prevention and treatment of AF and CS in Uygur diabetes with large-scale prospective study.
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