Associations of miR-146a, miR-149, miR-196a2, and miR-499 Polymorphisms with Ischemic Stroke in the Northern Chinese Han Population

Xiaoyan Zhu; Rongyao Hou; Aijun Ma; Shaonan Yang; Xudong Pan

doi:10.12659/MSM.909935

. 2018 Oct 15;24:7366–7374. doi: 10.12659/MSM.909935

Associations of miR-146a, miR-149, miR-196a2, and miR-499 Polymorphisms with Ischemic Stroke in the Northern Chinese Han Population

Xiaoyan Zhu ^1,^A,^B,^C,^D,^E,^F,^*, Rongyao Hou ^2,^A,^B,^C,^D,^E,^F,^*, Aijun Ma ^3,^B,^C,^D,^F, Shaonan Yang ^3,^B,^C,^D, Xudong Pan ^3,^A,^D,^G,^✉

PMCID: PMC6198714 PMID: 30321140

Abstract

Background

Recently, miR-146a C>G, miR-149 T>C, miR-196a2 T>C and miR-499 A>G polymorphisms have been associated with susceptibility to many diseases, including ischemic stroke (IS). However, results have been reported inconsistency in IS, especially in the Chinese population. This study aimed to investigate the polymorphisms of the 4 miRNAs and IS risk in the Chinese population.

Material/Methods

We used a case-control study to explore these associations in 396 patients with IS and 378 healthy controls. According to TOAST standards, the selected patients were divided into subgroups: the large artery atherosclerosis (LAA) subgroup and the small artery occlusion (SAO) subgroup. The method of polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) was used to detect the genotypes.

Results

The miR-146a C>G polymorphism was remarkably different (CC vs. CG+GG: P=0.027; CC+CG vs. GG: P=0.020; C vs. G: P=0.006). The miR-149 T>C polymorphism was also remarkably different (TT vs. TC+CC: P=0.017; TT+TC vs. CC: P=0.020; T vs. C: P=0.004). The miR-146a and miR-149 polymorphisms were also remarkably different in the LAA subgroup (P<0.05). However, we did not find an association of miR-196a2 T>C or miR-499 A>G polymorphisms with IS (P>0.05); we did not find any association in the LAA subgroup or the SAO subgroup (P>0.05).

Conclusions

Our study suggested that miR-146a C>G and miR-149 T>C polymorphisms might remarkably increase the risk of IS, which might be mainly associated with an increased risk in LAA stroke; however, the miR-196a2 T>C and miR-499 A>G polymorphisms might not be associated with IS risk in the northern Chinese Han population.

MeSH Keywords: Adams-Stokes Syndrome; Genes, vif; MicroRNAs

Background

Worldwide, stroke is the second leading cause of disability and death [1]. In China, the annual mortality rate of stroke is about 1.6 million, approximately 157 per 100 000, and it has become the main cause of death and adult disability [2]. The incidence rate was reported to be the highest (486 per 100 000) in northern China, whereas in southern China, the incidence was significantly lower (136 per 100 000) [2]. Ischemic stroke (IS) is the most important type of stroke. IS is a multifactorial disease, which is influenced by many environmental and genetic factors. Environmental risk factors of IS include age, sex, body mass index (BMI), smoking, hyperlipidemia, diabetes, and hypertension [2]. Single-nucleotide polymorphisms (SNPs) have played crucial roles in the development of IS. Recent studies have found that many gene polymorphisms have been shown to be obviously associated with the IS risk, such as CC11, paraoxonase 1 (PON1), angiotensin converting enzyme (ACE), and methylenetetrahydrofolate reductase (MTHFR), and that these gene polymorphisms could affect inflammatory reaction and promote the occurrence of atherosclerosis (AS) [3–5].

Many studies have shown that the microRNAs (miRNAs) are related to human diseases such as metabolism, differentiation, apoptosis, and AS [6,7]. MiRNAs are small noncoding RNA molecules of 21 to 24 nucleotides which have been proven to be negative regulators controlling diverse biological processes; inhibiting their translation and/or stability can regulate about one-third of the human genes [8]. Recent studies have indicated that miRNAs have participated in the pathogenesis of AS, including endothelial integrity, lipid metabolism, inflammatory response, and extracellular matrix remodeling [9,10]. Several miRNAs have been found to be useful as biomarkers for the prognosis with IS in humans, including miR-21 and miR-24 [11]. MiRNAs play important roles in the pathophysiology of AS both in vivo and in vitro. For example, the low expression of miR-181 in the aortic intima of ApoE^−/− mice with a high fat diet might promote the formation of AS [12]. The downregulation of miR-149 in osteo-arthritism chondrocytes can be correlated to increased expression of proinflammatory cytokines [13]. In our previous study, miR-126 expression was found to be significantly downregulated in atherosclerotic ApoE^−/− mice, and we found that atorvastatin might exert its anti-inflammatory effects by upregulating the expressions of miR-126 in vivo [14].

In recent years, it has been shown that miRNAs polymorphisms could influence the processing and maturity of miRNAs, which might influence the occurrence and/or prognosis of a disease. Recently, the polymorphisms miR-146a C>G, miR-196a2 T>C, miR-149 T>C, and miR-499 A>G have been associated with susceptibility to a variety of diseases, including IS [15,16]. The polymorphisms miR-146a C>G, miR-149 T>C, miR-196a2 T>C, and miR-499 A>G have been remarkably associated to regulation of tumor necrosis factor-α (TNF-α) [17], methylenetetrahydrofolatereductase (MTHFR) [18], annexin A1 (ANXA1) [19], and C-reactive protein (CRP) [20]. The 4 miRNAs targets have been related to inflammation pathways and/or thrombosis in the circulation system. TNF-α, MTHFR, ANXA1, and CRP have been related to AS and thrombosis [20–23]. The associations of these 4 known gene polymorphisms with IS risk has been reported, however, the reported results have been inconsistency, especially in the Chinese population [24,25]. So further research is needed on the associations among these 4 miRNAs polymorphisms with IS risk, especially the associations with the subtypes of large artery atherosclerosis (LAA) and small artery occlusion (SAO) in the Chinese population.

In our present study, we sought to research the associations of the aforementioned 4 miRNAs polymorphisms with IS risk, as well as analyze the 2 subtypes LAA and SAO in the northern Chinese Han study population.

Material and Methods

Participants

A case-control study design was used; the study included 396 patients with IS and 378 controls. The patients were recruited from the Department of Neurology, the affiliated Hiser hospital, and the affiliated hospital of Qingdao University from September 2013 and March 2016, if they were from the northern Chinese Han population and met the study criteria. The diagnosis of IS met the criteria approved at the Fourth National Cerebrovascular Disease Conference in 1995. At least 2 clinically experienced physicians made the final diagnosis through the characteristics of clinical syndrome, brain computed tomography (CT), and magnetic resonance imaging (MRI). The patients with IS were excluded if IS was caused by transient ischemic attack, hemorrhagic cerebral infarction, cardiogenic cerebral embolism, tumors, cardiovascular malformations, peripheral arterial occlusive disease, trauma, drugs, blood or infectious diseases, or they had been taking lipid-lowering drugs within the last half of the year. According to the Trial of Org 10172 in Acute Stroke Treatment (TOAST) system, the selected patients were divided into 2 subgroups: the LAA subgroup and the SAO subgroup. The participants in the control group were healthy individuals recruited during a physical health examination in the Hiser hospital; they were matched with the patients by age, sex, race, and region and they were without medical history of IS and/or coronary heart disease. The study was performed with the approval of the ethics committee of the 2 hospitals. Clinical information from the study population included BMI, hypertension, diabetes, drinking, and smoking.

Plasma lipid measurements

Approximately 3 mL samples of fasting blood were collected from each study participant. Serum levels of total cholesterol (TC), triglyceride (TG), high-density lipoprotein cholesterol (HDL-c), and low-density lipoprotein cholesterol (LDL-c) were analyzed.

DNA extraction and genotyping

We extracted genomic DNAs by using a DNA extraction kit (TianGen Biotech Beijing Co., Ltd., China) following the manufacturer’s instructions. We used PCR- RFLP assays to analyze the polymorphisms. The sequences of primers for PCR are shown from Sangon Biotech Co., Ltd. (Shanghai) in Table 1. The reactivation condition of PCR was as follows (for example, miR-146a): 94°C predenaturation for 3 minutes; 35-cycle reaction (94°C for 1 minute, 65°C for 45 seconds, 72°C for 1 minute); 72°C for 2 minutes; 4°C preservation. The annealing temperatures of miR-196a2, miR-499I, and miR-149 were 56°C, 65°C, and 58°C respectively. According to the online software analysis of endonuclease, the restriction enzymes were selected, which were Sac I (miR-146a C>G), Msp I (miR-149 T>C), Bcl I (miR-196a2 T>C), and Pvu II (miR-499 A>G) respectively.

Table 1.

Sequences of PCR primers and product length of PCR.

SNPS	Sequences of PCR primers	Product length of PCR
miR-146a (rs2910164)	F: 5′-CATGGGTTGTGTCAGTGTCAGAGCT-3′ R: 5′-TGCCTTCTGTCTCCAGTCTTCCAA-3′	147bp
miR-196a2 (rs11614913)	F: 5′-CCCCTTCCCTTCTCCTCCAGATA-3′ R: 5′-CGAAAACCGACTGATGTAACTCCG-3′	149bp
miR-499 (rs3746444)	F: 5′-CAAAGTCTTCACTTCCCTGCCA-3′ R: 5′-GATGTTTAACTCCTCTCCACGTGATC-3′	146bp
miR-149 (rs2292832)	F: 5′-TGTCTTCACTCCCGTGCTTGTC-3′ R: 5′-GCCCGAAACACCCGTAAGATAT-3′	250bp

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Statistical analysis

We used SPSS statistical software version 12.0 for the statistical analysis. Continuous variables were displayed as mean ±SD. The χ² goodness of fit test was adopted to test the deviation of genotypes distribution in the study population from Hardy-Weinberg equilibrium (HWE). We used odds ratio (OR) and 95% confidence intervals (95%CI) to assess the relativity between each allele and genotype distribution frequencies. A multivariate logistic regression was used to assess the relevance by the adjustment of the full risk factors. P<0.05 was considered to be obviously statistical significance.

Results

The characteristics of the participants are shown in Table 2. The patients with IS and the control participants were not remarkably different in age, gender, BMI, or the levels of TC and TG (P>0.05). However, the patients with IS were significantly different in smoking, drinking diabetes, hypertension, and the levels of HDL-c and LDL-c (P<0.001).

Table 2.

Baseline characteristics of the enrolled population.

Characteristics	Control (n=378) (%)	Ischemic stroke			P₁	P₂	P₃
Characteristics	Control (n=378) (%)	LAA (n=268) (%)	SAO (n=128) (%)	Total (n=396) (%)	P₁	P₂	P₃
Age, y (mean ±SD)	63.31±4.84	63.88±4.8	63.68±4.35	63.74±4.49	0.542	0.255	0.200
Gender (n, %)					0.122	0.603	0.812
Male	202 (53.4)	150 (56)	65 (50.8)	215 (54.3)
Female	176 (46.6)	118 (44)	63 (49.2)	181 (45.7)
Smoking (n, %)					<0.001	<0.001	<0.001
No	327 (86.5)	192 (71.6)	91 (71.1)	283 (71.5)
Yes	51 (13.5)	76 (28.4)	37 (28.9)	113 (28.5)
Drinking (n, %)					0.005	<0.001	<0.001
No	323 (85.4)	206 (76.9)	89 (69.5)	295 (74.5)
Yes	55 (14.6)	62 (23.1)	39 (30.5)	101 (25.5)
Hypertension (n, %)					<0.001	<0.001	<0.001
No	328 (86.8)	179 (66.8)	83 (64.8)	262 (66.2)
Yes	50 (13.2)	89 (33.2)	45 (35.2)	134 (33.8)
Diabetes (n, %)					<0.001	<0.001	<0.001
No	349 (92.3)	219 (81.7)	104 (81.2)	323 (81.6)
Yes	29 (7.7)	49 (18.3)	24 (18.8)	73 (18.4)
BMI	24.25±1.07	24.1±1.12	24.26±1.07	24.21±1.09	0.946	0.160	0.550
Lipedema (mean ±SD, mmol/L)
TG	1.50±0.41	1.54±0.6	1.56±0.76	1.56±0.71	0.143	0.326	0.140
TC	4.49±0.88	4.69±0.99	4.41±0.89	4.60±0.97	0.008	0.389	0.104
HDL-c	1.24±0.18	1.03±0.23	1.1±0.25	1.08±0.24	<0.001	<0.001	<0.001
LDL-c	2.88±0.34	3.01±0.46	2.93±0.4	2.98±0.44	<0.001	0.199	<0.001

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P₁ – LAA vs. Control; P₂ – SAO vs. Control; P₃ – total vs. control.

Subgroup analyses were carried out according to LAA and SAO subtypes. Compared with the control group, we did not find a remarkable difference in age, gender, BMI, or TG in the LAA and SAO subgroups (P>0.05); however, there were remarkable differences in drinking, smoking, hypertension, and diabetes (P<0.05). The levels of HDL-c in the LAA and SAO subgroups were remarkably lower (P<0.05). The level of LDL-c in the LAA subgroup was remarkably higher (P<0.001); however, there was no remarkable difference in the SAO subgroup compared with the control group (P>0.05). The level of TC in the LAA subgroup was remarkably higher (P<0.05); however, there was no remarkable difference in the SAO subgroup compared with the control group (P>0.05). There were no remarkable differences in TG between the 2 subgroups and the control group (P>0.05).

We investigated the miR-146a C>G, miR-196a2 T>C, miR-499 A>G, and miR-149 T>C polymorphisms in IS patients and control participants (Table 3). The 4 miRNAs genotype frequencies of the control group were consistent with the HWE (miR-146a C>G, P=0.512; miR-196a2 T>C, P=0.354; miR-499 A>G, P=0.910; miR-149 T>C, P=0.720). We evaluated the miRNAs genotype frequencies after adjusting for age, gender, hypertension, diabetes, BMI, smoking, drinking, TC, TG, HDL-c, and LDL-c by multivariate logistic regression analyses. Compared with the control group, the miR-146a C>G polymorphism was remarkably different (CC vs. GG: OR was 1.86, 95% CI was 1.19–2.88, P=0.006; CC vs. CG+GG: OR was 1.39, 95% CI was 1.04–1.86, P=0.027; CC+CG vs. GG: OR was 1.62, 95% CI was 1.08–2.42, P=0.020; CC vs. CG vs. GG: OR was 1.34, 95% CI was 1.09–1.65, P=0.006; C vs. G: OR was 1.33, 95% CI was 1.09–1.64, P=0.006). The miR-149 T>C polymorphism was remarkably different between the IS patients and the control groups (TT vs. CC: OR was 2.00; 95% CI was 1.22–3.28, P=0.006; TT vs. TC+CC: OR was 1.42, 95% CI was 1.07–1.88, P=0.017; TT+TC vs. CC: OR was 1.75, 95% CI was 1.09–2.82, P=0.020; TT vs. TC vs. CC: OR was 1.37, 95% CI was 1.11–1.7, P=0.004; T vs. C: OR was 1.37, 95% CI was 1.11–1.7, P=0.004). There were no statistical differences in the polymorphisms of miR-196a2 T>C and miR-499 A>G between the IS patients and control groups (P>0.05). According to TOAST classification, we further assessed the effects of each miRNA polymorphism to the IS risk in the LAA and SAO subtypes. Our study found that the miR-146a C>G polymorphism in the LAA subtype was remarkably different compared with the control group (CC vs. GG: OR was 2.04, 95% CI was1.26–3.3, P=0.004; CC vs. CG+GG: OR was 1.51, 95% CI was 1.08–2.09, P=0.015; CC+CG vs. GG: OR was 1.7, 95% CI was 1.1–2.63, P=0.018; CC vs. CG vs. GG: OR was 1.41, 95% CI was 1.09–1.82, P=0.008; C vs. G: OR was 1.4, 95% CI was 1.12–1.76, P=0.003); however, there was no remarkably difference between the SAO subtype and the control group (P>0.05). The miR-149 T>C polymorphism was remarkably different between the LAA subtype and the control group (TT vs. CC: OR was 2.47; 95% CI was 1.45–4.21, P=0.001; TT vs. TC+CC: OR was 1.7, 95% C was 1.23–2.34, P=0.001; TT+TC vs. CC: OR was 1.98, 95% CI was 1.19–3.27, P=0.008; TT vs. TC vs. CC: OR was 1.57, 95% CI was 1.23–1.99, P<0.001; T vs. C: OR was 1.55, 95% CI was 1.23–1.96, P<0.001); however, there was not a remarkable difference between the SAO subtype and the control group (P>0.05). Compared with the control group, there were no statistical differences in the polymorphisms of miR-196a2 T>C and miR-499 A>G in the LAA and SAO subgroups (P>0.05) (Table 4).

Table 3.

Associations of miR-146a C>G, miR-196a2 T>C, miR-499 A>G, and miR-149 T>C polymorphisms between IS risk and control groups.

Genotypes	Control (n,%)	IS (n,%)		OR (95% CI)		P
miR-146a (C>G)
CC	154 (40.7)	131 (33.1)		1
CG	179 (47.4)	194 (49)		1.27 (0.94, 1.74)		0.125
GG	45 (11.9)	71 (17.9)		1.86 (1.19, 2.88)		0.006
CC vs. (CGG)				1.39 (1.04, 1.86)		0.027
(CC+CG) vs. GG				1.62 (1.08, 2.42)		0.020
CC vs. CG vs. GG				1.34 (1.09, 1.65)		0.006
C	487 (64.4)	456 (57.6)		1
G	269 (35.6)	336 (42.4)		1.33 (1.09, 1.64)		0.006
miR-196a2 (T>C)
TT	110 (29.1)	112 (28.3)		1
TC	196 (51.9)	205 (51.8)		1.03 (0.74, 1.43)		0.872
CC	72 (19)	79 (19.9)		1.08 (0.71, 1.63)		0.723
TT vs. (TC+CC)				1.04 (0.76, 1.42)		0.801
(TT+TC) vs. CC				1.06 (0.74, 1.51)		0.752
TT vs. TC vs. CC				1.04 (0.85, 1.27)		0.728
T	416 (55)	429 (54.2)		1
C	340 (45)	363 (45.8)		1.04 (0.85, 1.27)		0.734
miR-499 (A>G)
AA	249 (65.9)	255 (64.4)		1
AG	116 (30.7)	123 (31.1)		1.04 (0.76, 1.41)		0.825
GG	13 (3.4)	18 (4.5)		1.35 (0.65, 2.82)		0.421
AA vs. (AG+GG)				1.07 (0.79, 1.44)		0.666
(AA+AG) vs. GG				1.34 (0.65, 2.77)		0.434
AA vs. AG vs. GG				1.09 (0.85, 1.39)		0.524
A	614 (81.2)	633 (79.9)		1
G	142 (18.8)	159 (20.1)		1.09 (0.84, 1.4)		0.521
miR-149 (T>C)
TT	190 (50.3)		165 (41.7)		1
TC	158 (41.8)		179 (45.2)		1.31 (0.97, 1.76)		0.081
CC	30 (7.9)		52 (13.1)		2.00 (1.22, 3.28)		0.006
TT vs. (TC+CC)					1.42 (1.07, 1.88)		0.017
(TT+TC) vs. CC					1.75 (1.09, 2.82)		0.020
TT vs. TC vs. CC					1.37 (1.11, 1.7)		0.004
T	538 (71.2)		509 (64.3)		1
C	218 (28.8)		283 (35.7)		1.37 (1.11, 1.7)		0.004

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OR – adjusted odds ratio; 95% CI – 95% confidence interval. OR based on the risk factors, including age, sex, hypertension, diabetes, BMI, smoking, drinking, TC, TG, LDL-c, and HDL-c.

Table 4.

Associations of miR-146a C>G, miR-196a2 T>C, miR-499 A>G, and miR-149 T>C polymorphisms between the subgroups and the control group.

Genotypes	Control n (%)	LAA			SAO
Genotypes	Control n (%)	n (%)	OR (95% CI)	P	n (%)	OR (95% CI)	P
miR-146a (C>G)
CC	154 (40.7)	84 (31.3)	1		47 (36.7)	1
CG	179 (47.4)	134 (50)	1.37 (0.97, 1.94)	0.074	60 (46.9)	1.1 (0.71, 1.7)	0.675
GG	45 (11.9)	50 (18.7)	2.04 (1.26, 3.3)	0.004	21 (16.4)	1.53 (0.83, 2.82)	0.174
CC vs. (CG+GG)			1.51 (1.08, 2.09)	0.015		1.19 (0.78, 1.79)	0.422
(CC+CG) vs. GG			1.7 (1.1, 2.63)	0.018		1.45 (0.83, 2.55)	0.193
CC vs. CG vs. GG			1.41 (1.09, 1.82)	0.008		1.2 (0.9, 1.62)	0.218
C	487 (64.4)	302 (56.3)	1		154 (60.2)	1
G	269 (35.6)	234 (43.7)	1.4 (1.12, 1.76)	0.003	102 (39.8)	1.2 (0.9, 1.6)	0.222
miR-196a2 (T>C)
TT	110 (29.1)	75 (28)	1		37 (28.9)	1
TC	196 (51.9)	139 (51.9)	1.04 (0.72, 1.5)	0.833	66 (51.6)	1 (0.63, 1.59)	0.996
CC	72 (19)	54 (20.1)	1.1 (0.7, 1.74)	0.684	25 (19.5)	1.03 (0.57, 1.86)	0.916
TT vs. (TC+CC)			1.06 (0.75, 1.49)			1.01 (0.65, 1.57)	0.967
(TT+TC) vs. CC			1.07 (0.72, 1.59)	0.728		1.03 (0.62, 1.71)	0.904
TT vs. TC vs. CC			1.05 (0.84, 1.32)	0.686		1.01 (0.76, 1.36)	0.923
T	416 (55)	289 (53.9)	1		140 (54.7)	1
C	340 (45)	247 (46.1)	1.05 (0.84, 1.31)	0.693	116 (45.3)	1.01 (0.76, 1.35)	0.925
miR-499 (A>G)
AA	249 (65.9)	172 (64.2)	1		83 (64.8)	1
AG	116 (30.7)	83 (30.9)	1.04 (0.74, 1.46)	0.84	40 (31.2)	1.03 (0.67, 1.6)	0.879
GG	13 (3.4)	13 (4.9)	1.45 (0.66, 3.2)	0.36	5 (3.9)	1.15 (0.4, 3.33)	0.791
AA vs. (AG+GG)			1.08 (0.78, 1.5)	0.656		1.05 (0.69, 1.59)	0.832
(AA+AG) vs. GG			1.43 (0.65, 3.14)	0.371		1.14 (0.4, 3.27)	0.805
AA vs. AG vs. GG			1.1 (0.84, 1.45)	0.491		1.05 (0.73, 1.5)	0.792
A	614 (81.2)	427 (79.7)	1		206 (80.5)	1
G	142 (18.8)	109 (20.3)	1.1 (0.84, 1.46)	0.487	50 (19.5)	1.05 (0.73, 1.5)	0.792
miR-149 (T>C)
TT	190 (50.3)	100 (37.3)	1		65 (50.8)	1
TC	158 (41.8)	129 (48.1)	1.55 (1.11, 2.17)	0.010	50 (39.1)	0.93 (0.61, 1.42)	0.719
CC	30 (7.9)	39 (14.6)	2.47 (1.45, 4.21)	0.001	13 (10.2)	1.27 (0.62, 2.57)	0.514
TT vs. (TC+CC)			1.7 (1.23, 2.34)	0.001		0.98 (0.66, 1.46)	0.92
(TT+TC) vs. CC			1.98 (1.19, 3.27)	0.008		1.31 (0.66, 2.6)	0.437
TT vs. TC vs. CC			1.57 (1.23, 1.99)	<0.001		1.04 (0.76, 1.42)	0.796
T	538 (71.2)	329 (61.4)	1		180 (70.3)	1
C	218 (28.8)	207 (38.6)	1.55 (1.23, 1.96)	<0.001	76 (29.7)	1.04 (0.76, 1.42)	0.795

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OR – adjusted odds ratio; 95% CI – 95% confidence interval. OR based on the risk factors, including age, sex, hypertension, diabetes, BMI, smoking, drinking, TC, TG, LDL-c, and HDL-c.

Discussion

In the present study, our purpose was to evaluate the associations of miR-146a, miR-149, miR-196a2, and miR-499 polymorphisms with the risk of IS in the northern Chinese Han population. Our findings showed that the polymorphisms of miR-146a C>G and miR-149 T>C might remarkably increase the risk of IS in the northern Chinese Han population, which might be mainly associated with the LAA stroke risk. However, the polymorphisms of miR-196a2 T>C and miR-499 A>G might not be associated with the risk of IS in the northern Chinese Han population.

A previous study found that miRNAs were involved in various crucial biological pathological processes and could regulate about 30% of human genes expression [26]. The SNPs or genetic mutations of miRNAs existing in pre-miRNAs can affect the expression of mature miRNAs, and can then cause mutative miRNAs expression and lead to the occurrence of diseases [27]. The SNPs of miRNAs are closely related to many diseases including AS, hyperlipidemia, and coronary heart disease (CHD) [28,29].

In recent years, many studies found that miR-146a C>G polymorphism was closely related to the susceptibility of atherosclerotic diseases. In an Iranian population, miR-146a C>G polymorphism was associated with an increased susceptibility to CHD [30]. The gene polymorphism of miR-146a C>G was associated with an increased risk of CHD in the Chinese population, which might occur through influencing the expression level of the mature miR-146a [29]. Jeon et al. found that miR-146a C>G polymorphism was significantly increased the risk of IS and the G allele could increase the risk, which was significantly associated in the LAA and SAO subgroups in the South Korean population [31]. In the Chinese population, the results of the study were inconsistent. The studies by Huang and Zhu et al found that the polymorphism of miR-146a C>G could significantly increase the risk of IS and the G allele could increase the risk of disease in the northern Chinese Han population [24,32]. Our study also found that miR-146a C>G polymorphism remarkably increased the risk of IS, and the G allele could increase the risk in the northern Chinese Han population, especially in the LAA subgroup. Another study found that miR-146a C>G polymorphism could affect miR-146a, IRAK-1, TRAF6, and TNF-α expression levels and was associated with susceptibility to CHD [33]. The miR-146a G allele was associated with decreased mature miR-146a level, which was associated with susceptibility to breast and ovarian cancers [34]. However, other studies by Liu and Luo found no statistical difference between the polymorphism of miR-146a C>G and the IS risk in the southern Chinese Han population [25,35]. In addition, studies have found that the polymorphism of miR-149 T>C could affect the function and level of the mature miR-149 [18,36]. MTHFR is a target gene of miR-149, which plays an important role in the occurrence and development of AS [18]. One study found that the polymorphism of miR-149 T>C can affect the metabolic pathway of MTHFR by influencing the function and level of mature miR-149, and then further change the level of MTHFR to increase the susceptibility of CHD [18]. One study has shown that the polymorphism of miR-149 T>C can significantly increase the risk of IS by influencing the plasma level of homocysteine, which could influence the plasma level of homocysteine to increase the risk of IS in the Chinese population [37]. Our study found that the polymorphism of miR-149 T>C was obviously related to the risk of IS, and the C allele might be a risk factor in the northern Chinese Han population. We further found that the polymorphism of miR-149 T>C could significantly increase the risk of IS in the LAA subgroup. However, other studies found no correlation between IS risk and the genetic polymorphisms of miR-149 T>C in the southern Chinese Han population and South Korean population [25]. Our study found that the polymorphisms of miR-146a C>G and miR-149 T>C were associated with the LAA subtype of IS. The possible reason could be that the 2 genetic polymorphisms are mainly related to AS, and AS is the most important factor in the occurrence of LAA stroke [38]. The target gene of miR-196a2 is ANXA1, and elevated level of miR-196a2 can lead to decreasing the levels of ANXA1 mRNA, and protein [19]. ANXA1 plays an important role in the migration and adhesion of neutrophils and monocytes in the process of atherosclerosis, and also plays an important role in the anti-inflammatory response signaling pathway [23]. The miR-196a2 T allele has been associated with decreased mature miR-196a2 level [39]. The polymorphism of miR-196a2 T>C was found to be associated with susceptibility to cancer [40]. However, our study found that the polymorphisms of miR-196a2 T>C might not be associated with IS in the Chinese Han population. In the LAA and SAO subgroups, an association was also not found. Similarly, no association was found between the polymorphism of miR-196a2 T>C and the risk of IS, including in the Korean and Chinese populations [31,32]. However, one study found that the polymorphism of miR-196a2 T>C was associated with susceptibility to CHD [41]. Therefore, the polymorphism of miR-196a2 T>C might have distinct influence on different organs of atherosclerotic diseases; these findings need to be studied in further research. The polymorphism of miR-499 A>G has been shown to be related to the decrease of plasma CRP concentrations [20]. It could change the level and function of mature miR-499 expression and affect the combination of target gene and mature miR-499 [42]. The polymorphism of miR-499 A>G has been associated with susceptibility to CHD [43]. There have been fewer reports on the association of the polymorphism of miR-499 A>G with IS, and study results have been inconsistent. Studies have found that the polymorphism of miR-499 A>G was correlated with IS, and the G allele could remarkably increase the risk of IS in the Chinese population [25,35]. However, other studies found there were no associations between the polymorphism of miR-499 A>G with IS, including in the Korean and Chinese populations [24,31]. Similarly, our study did not find remarkable associations between the gene polymorphism of miR-499 A>G and IS, including in the LAA and SAO subgroups. The results of the aforementioned other studies were different in different ethnic groups, different regions, different countries, and different experimental design; therefore, different study findings might be found.

There were certain limitations in the present study. First, the potential for selective bias was inevitable in this case-controlled study. Second, the study was a single population study with a limited sample size, so the results still need be confirmed in multicenter, different populations, races, and larger samples. Third, the pathological mechanism underlying the gene polymorphisms of miR-146a and miR-149 with IS risk is still unclear, so further research will be needed to study the related functions of miR-146a and miR-149 with IS risk.

Conclusions

In conclusion, this present study showed that the polymorphisms of miR-146a C>G and miR-149 T>C might be related to a remarkable increase of IS risk, which might be mainly associated with LAA stroke; however, the polymorphisms of miR-196a2 T>C and miR-499 A>G might not be related to the risk of IS in the northern Chinese Han population.

Footnotes

Source of support: This study was supported by the National Natural Sciences Foundation of China (No. 81571112)

Conflicts of interest

None.

References

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[b1-medscimonit-24-7366] 1.Feigin VL, Lawes CM, Bennett DA, et al. Worldwide stroke incidence and early case fatality reported in 56 population-based studies: A systematic review. Lancet Neurol. 2009;8:355–69. doi: 10.1016/S1474-4422(09)70025-0. [DOI] [PubMed] [Google Scholar]

[b2-medscimonit-24-7366] 2.Liu L, Wang D, Wong KS, et al. Stroke and stroke care in China: huge burden, significant workload, and a national priority. Stroke. 2011;42:3651–54. doi: 10.1161/STROKEAHA.111.635755. [DOI] [PubMed] [Google Scholar]

[b3-medscimonit-24-7366] 3.Liang C, Ni G, Ma J, et al. Impact of tag single nucleotide polymorphisms (SNPs) in CCL11 gene on risk of subtypes of ischemic stroke in Xinjiang Han populations. Med Sci Monit. 2017;23:4291–98. doi: 10.12659/MSM.905942. [DOI] [PMC free article] [PubMed] [Google Scholar]

[b4-medscimonit-24-7366] 4.Bersano A, Ballabio E, Bresolin N, et al. Genetic polymorphisms for the study of multifactorial stroke. Hum Mutat. 2008;29:776–95. doi: 10.1002/humu.20666. [DOI] [PubMed] [Google Scholar]

[b5-medscimonit-24-7366] 5.Huen K, Yousefi P, Stree K, et al. PON1 as a model for integration of genetic, epigenetic, and expression data on candidate susceptibility genes. Environ Epigenet. 2015;1:1–11. doi: 10.1093/eep/dvv003. [DOI] [PMC free article] [PubMed] [Google Scholar]

[b6-medscimonit-24-7366] 6.Kosik KS. The neuronal microRNA system. Nat Rev Neurosci. 2006;7:911–20. doi: 10.1038/nrn2037. [DOI] [PubMed] [Google Scholar]

[b7-medscimonit-24-7366] 7.Ying SY, Lin SL. Intron-mediated RNA interference and microRNA biogenesis. Methods Mol Biol. 2009;487:387–413. doi: 10.1007/978-1-60327-547-7_19. [DOI] [PubMed] [Google Scholar]

[b8-medscimonit-24-7366] 8.Feinberg MW, Moore KJ. MicroRNA regulation of atherosclerosis. Circ Res. 2016;118:703–20. doi: 10.1161/CIRCRESAHA.115.306300. [DOI] [PMC free article] [PubMed] [Google Scholar]

[b9-medscimonit-24-7366] 9.Rink C, Khanna S. MicroRNA in ischemic stroke etiology and pathology. Physiol Genomics. 2011;43:521–28. doi: 10.1152/physiolgenomics.00158.2010. [DOI] [PMC free article] [PubMed] [Google Scholar]

[b10-medscimonit-24-7366] 10.Tan JR, Koo YX, Kaur P, et al. microRNAs in stroke pathogenesis. Curr Mol Med. 2011;11:76–92. doi: 10.2174/156652411794859232. [DOI] [PubMed] [Google Scholar]

[b11-medscimonit-24-7366] 11.Zhou J, Zhang J. Identification of miRNA-21 and miRNA-24 in plasma as potential early stage markers of acute cerebral infarction. Mol Med Rep. 2014;10:971–76. doi: 10.3892/mmr.2014.2245. [DOI] [PubMed] [Google Scholar]

[b12-medscimonit-24-7366] 12.Sun X, He S, Wara AKM, et al. Systemic delivery of microRNA-181b inhibits nuclear factor-kappaB activation, vascular inflammation, and atherosclerosis in apolipoprotein E-deficient mice. Circ Res. 2014;114:32–40. doi: 10.1161/CIRCRESAHA.113.302089. [DOI] [PMC free article] [PubMed] [Google Scholar]

[b13-medscimonit-24-7366] 13.Santini P, Politi L, Vedova PD, et al. The inflammatory circuitry of miR-149 as a pathological mechanism in osteoarthritis. Rheumatol Int. 2014;34:711–16. doi: 10.1007/s00296-013-2754-8. [DOI] [PubMed] [Google Scholar]

[b14-medscimonit-24-7366] 14.Pan X, Hou R, Ma A, et al. Atorvastatin upregulates the expression of miR-126 in apolipoprotein e-knockout mice with carotid atherosclerotic plaque. Cell Mol Neurobiol. 2017;37:29–36. doi: 10.1007/s10571-016-0331-x. [DOI] [PMC free article] [PubMed] [Google Scholar]

[b15-medscimonit-24-7366] 15.Ryan BM, Robles AI, Harris CC. Genetic variation in microRNA networks: The implications for cancer research. Nat Rev Cancer. 2010;10:389–402. doi: 10.1038/nrc2867. [DOI] [PMC free article] [PubMed] [Google Scholar]

[b16-medscimonit-24-7366] 16.Jeon YJ, Choi YS, Rah H, et al. Association study of microRNA polymorphisms with risk of idiopathic recurrent spontaneous abortion in Korean women. Gene. 2012;494:168–73. doi: 10.1016/j.gene.2011.12.026. [DOI] [PubMed] [Google Scholar]

[b17-medscimonit-24-7366] 17.El Gazzar M, Church A, Liu T, et al. MicroRNA-146a regulates both transcription silencing and translation disruption of TNF-alpha during TLR4-induced gene reprogramming. J Leukoc Biol. 2011;90:509–19. doi: 10.1189/jlb.0211074. [DOI] [PMC free article] [PubMed] [Google Scholar]

[b18-medscimonit-24-7366] 18.Wu C, Gong Y, Sun A, et al. The human MTHFR rs4846049 polymorphism increases coronary heart disease risk through modifying miRNA binding. Nutr Metab Cardiovasc Dis. 2013;23:693–98. doi: 10.1016/j.numecd.2012.02.009. [DOI] [PubMed] [Google Scholar]

[b19-medscimonit-24-7366] 19.Luthra R, Singh RR, Luthra MG, et al. MicroRNA-196a targets annexin A1: a microRNA-mediated mechanism of annexin A1 downregulation in cancers. Oncogene. 2008;27:6667–78. doi: 10.1038/onc.2008.256. [DOI] [PubMed] [Google Scholar]

[b20-medscimonit-24-7366] 20.Yang B, Chen J, Li Y, et al. Association of polymorphisms in pre-miRNA with inflammatory biomarkers in rheumatoid arthritis in the Chinese Han population. Hum Immunol. 2012;73:101–6. doi: 10.1016/j.humimm.2011.10.005. [DOI] [PubMed] [Google Scholar]

[b21-medscimonit-24-7366] 21.Ursini F, Leporini C, Bene F, et al. Anti-TNF-alpha agents and endothelial function in rheumatoid arthritis: A systematic review and meta-analysis. Sci Rep. 2017;7:5346. doi: 10.1038/s41598-017-05759-2. [DOI] [PMC free article] [PubMed] [Google Scholar]

[b22-medscimonit-24-7366] 22.Trabetti E. Homocysteine: MTHFR gene polymorphisms, and cardio-cerebrovascular risk. J Appl Genet. 2008;49:267–82. doi: 10.1007/BF03195624. [DOI] [PubMed] [Google Scholar]

[b23-medscimonit-24-7366] 23.Parente L, Solito E. Annexin 1: More than an anti-phospholipase protein. Inflamm Res. 2004;53:125–32. doi: 10.1007/s00011-003-1235-z. [DOI] [PubMed] [Google Scholar]

[b24-medscimonit-24-7366] 24.Huang S, Zhou S, Zhang Y, et al. Association of the genetic polymorphisms in pre-microRNAs with risk of ischemic stroke in a Chinese population. PLoS One. 2015;10:e0117007. doi: 10.1371/journal.pone.0117007. [DOI] [PMC free article] [PubMed] [Google Scholar]

[b25-medscimonit-24-7366] 25.Luo HC, Luo QS, Wang CF, et al. Association of miR-146a, miR-149, miR-196a2, miR-499 gene polymorphisms with ischemic stroke in a Chinese people. Oncotarget. 2017;8:81295–304. doi: 10.18632/oncotarget.18333. [DOI] [PMC free article] [PubMed] [Google Scholar]

[b26-medscimonit-24-7366] 26.Lewis BP, Burge CB, Bartel DP. Conserved seed pairing, often flanked by adenosines, indicates that thousands of human genes are microRNA targets. Cell. 2005;120:15–20. doi: 10.1016/j.cell.2004.12.035. [DOI] [PubMed] [Google Scholar]

[b27-medscimonit-24-7366] 27.Saunders MA, Liang H, Li WH. Human polymorphism at microRNAs and microRNA target sites. Proc Natl Acad Sci USA. 2007;104:3300–5. doi: 10.1073/pnas.0611347104. [DOI] [PMC free article] [PubMed] [Google Scholar]

[b28-medscimonit-24-7366] 28.Schober A, Weber C. Mechanisms of MicroRNAs in Atherosclerosis. Annu Rev Pathol. 2016;11:583–616. doi: 10.1146/annurev-pathol-012615-044135. [DOI] [PubMed] [Google Scholar]

[b29-medscimonit-24-7366] 29.Xiong XD, Cho M, Cai XP, et al. A common variant in pre-miR-146 is associated with coronary artery disease risk and its mature miRNA expression. Mutat Res. 2014;761:15–20. doi: 10.1016/j.mrfmmm.2014.01.001. [DOI] [PubMed] [Google Scholar]

[b30-medscimonit-24-7366] 30.Bastami M, Ghaderian SM, Omrani MD, et al. MiRNA-related polymorphisms in miR-146a and TCF21 are associated with increased susceptibility to coronary artery disease in an Iranian population. Genet Test Mol Biomarkers. 2016;20:241–48. doi: 10.1089/gtmb.2015.0253. [DOI] [PubMed] [Google Scholar]

[b31-medscimonit-24-7366] 31.Jeon YJ, Kim OJ, Kim SY, et al. Association of the miR-146a, miR-149, miR-196a2, and miR-499 polymorphisms with ischemic stroke and silent brain infarction risk. Arterioscler Thromb Vasc Biol. 2013;33:420–30. doi: 10.1161/ATVBAHA.112.300251. [DOI] [PubMed] [Google Scholar]

[b32-medscimonit-24-7366] 32.Zhu R, Liu X, He Z, et al. miR-146a and miR-196a2 polymorphisms in patients with ischemic stroke in the northern Chinese Han population. Neurochem Res. 2014;39:1709–16. doi: 10.1007/s11064-014-1364-5. [DOI] [PubMed] [Google Scholar]

[b33-medscimonit-24-7366] 33.Ramkaran P, Khan S, Phulukdaree A, et al. miR-146a polymorphism influences levels of miR-146a, IRAK-1, and TRAF-6 in young patients with coronary artery disease. Cell Biochem Biophys. 2014;68:259–66. doi: 10.1007/s12013-013-9704-7. [DOI] [PubMed] [Google Scholar]

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PERMALINK

Associations of miR-146a, miR-149, miR-196a2, and miR-499 Polymorphisms with Ischemic Stroke in the Northern Chinese Han Population

Xiaoyan Zhu

Rongyao Hou

Aijun Ma

Shaonan Yang

Xudong Pan

Abstract

Background

Material/Methods

Results

Conclusions

Background

Material and Methods

Participants

Plasma lipid measurements

DNA extraction and genotyping

Table 1.

Statistical analysis

Results

Table 2.

Table 3.

Table 4.

Discussion

Conclusions

Footnotes

References

ACTIONS

PERMALINK

RESOURCES

Cite

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PERMALINK

Associations of miR-146a, miR-149, miR-196a2, and miR-499 Polymorphisms with Ischemic Stroke in the Northern Chinese Han Population

Xiaoyan Zhu

Rongyao Hou

Aijun Ma

Shaonan Yang

Xudong Pan

Abstract

Background

Material/Methods

Results

Conclusions

Background

Material and Methods

Participants

Plasma lipid measurements

DNA extraction and genotyping

Table 1.

Statistical analysis

Results

Table 2.

Table 3.

Table 4.

Discussion

Conclusions

Footnotes

References

ACTIONS

PERMALINK

RESOURCES

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