Apolipoprotein E Gene Polymorphism and Coronary Artery Disease Risk Among Patients in Northwest China.

PURPOSE: The association between apolipoprotein E (ApoE) gene polymorphisms and the risk of coronary artery disease (CAD) among different populations has been assessed in numerous previous studies, but the results remain inconclusive. The present study aimed to determine the role of ApoE genotypes in CAD risk and the interrelationships between lipid profiles and ApoE alleles and genotypes among the population of northwest China. PATIENTS AND METHODS: This study was performed on 308 patients with CAD and 308 control participants. ApoE gene polymorphism was analysed using the polymerase chain reaction and hybridization.
RESULTS: The findings indicated that the frequencies of ε3/ε4 genotype and ε4 allele frequency were significantly higher in patients with CAD than in the control participants. ε2 carriers had significantly lower total cholesterol (TC), low-density lipoprotein cholesterol (LDL-C) and triglycerides (TG) levels than did ε3 or ε4 carriers among the control participants. However, our study found no significant differences in plasma lipoprotein levels between ɛ2, ɛ3 and ɛ4 carriers in patients with CAD. Moreover, ε4 carriers had significantly higher ApoB, ApoB/ApoA-I levels and significantly lower ApoE levels in both patients with CAD and control participants. ε4 allele presence was associated with a nearly two-fold higher CAD risk. After adjusting for other established risk factors, ε4 allele was an independent risk factor for CAD. After stratified by age (≤ 60 years and >60 years), ε4 allele was indicated to increase the CAD risk 3.3-fold in elderly patients with CAD, but not in young patients with CAD. After stratified by sex, ε4 allele was not a risk factor in females and males patients with CAD.
CONCLUSION: This study provides evidence that the ε4 allele, drinking, smoking, hypertension, and TG and ApoE levels are independent risk factor for CAD among patients in northwest China.

Introduction

CAD is a diseases with one of the highest morbidities and mortalities worldwide.1 Despite great advances in the clinical management of CAD, atherosclerosis pathogenesis, which underlies CAD, is not fully understood. CAD is a multifactorial disease that results from interactions between genetic variants and environmental factors such as diet, smoking and exercise. Dyslipidemia is known to be a major risk factor for CAD development.2 Lipoproteins play a major role in the development and pathogenesis of atherosclerotic cardiovascular diseases in humans. Plasma lipoprotein levels are largely genetically determined by apolipoprotein.3 Mutations apolipoprotein gene encoding may result in impaired lipoprotein clearance. Genetic variation may therefore be the main determinant of variation between individuals regarding the susceptibility to CAD.4

ApoE is an important plasma protein involved in metabolism and transport of lipids including TC and TG. The polymorphic human ApoE gene, located on chromosome 19q13.2 and SNPs at positions 112 (rs429358) and 158 (rs7412), causes three different alleles (ε2, ε3 and ε4) to encode the major ApoE isoforms ApoE2, ApoE3 and ApoE4, respectively. Numerous studies have indicated that these ApoE gene polymorphisms affect lipoprotein clearing and lipid profiles, which may be responsible for CAD; however, the findings have been inconsistent.2,5

ApoE gene polymorphisms affect lipoprotein clearing and lipid profile, and also the development of CAD.6,7 Lipid metabolism is influenced by ApoE genotypes. A previous study found that ε4 carriers can increase CAD risk by approximately 42%.8 ε4 carriers tend to have higher TC and low-density lipoprotein cholesterol (LDL-C) levels, and exhibit a worse response to statin treatment than do ε2 carriers.9 The distribution of ApoE allele frequencies varies between racial groups, with Europeans and African-Americans having a high ε4 frequency and Asians having low frequencies of both ε2 and ε4.2 Furthermore, no published studies have investigated the relationship between ApoE polymorphism and CAD risk in northwest China. The present study therefore aimed to determine the role of ApoE genotypes in CAD risk and the interrelationship between lipid profiles and ApoE alleles and genotypes among the population of northwest China.

Methods

Participants

This study recruited 616 individuals, which consisted of 308 CAD patients (males: females=223:85) and 308 individuals with non CAD (males: females=208:100) as healthy controls. Patients and controls involved in this study were collected in First Affiliated Hospital of Xi’an Jiao Tong University from May 2018 to May 2019; Ages ranged from 15 to 93 years. All subjects were unrelated Han Chinese and residents living in Northwest China. CAD was defined as stenosis of ≥ 50% in the left main coronary artery, the left anterior descending artery, the left circumflex coronary artery, the right coronary artery or the main branch of the coronary artery. The control groups included participants without stenosis confirmed by coronary angiography and healthy individuals without cardiovascular diseases identified by physical examination. Hypertension was defined as a blood pressure of ≥140/90 mmHg or currently receiving hypertension treatment. Diabetes mellitus was defined as fasting glucose ≥7.0 mmol/L, or current treatment with oral hypoglycemic agents or insulin. Exclusion criteria included liver disease, and relevant brain lesions detected on MRI. This study was conducted in accordance with the Declaration of Helsinki, approved by the Ethical Committee of the First Affiliated Hospital of Xi’an Jiao Tong University, and we also got the informed consent of each patients.

DNA Extraction and Genotyping

Blood samples (approximately 4 mL) were collected from study populations and stored in tubes containing ethylene diamine tetraacetic acid (EDTA). Genomic DNA was extracted from peripheral blood using a commercial isolation kit (Sinochips Bioscience Co., Ltd., Zhuhai, Guangdong, China) and stored at −20°C. The genotypes of ApoE were detected by a commercially available kit (Sinochips Bioscience Co., Ltd., Zhuhai, Guangdong, China). According to the manufacturer’s instructions. PCR was performed:

50°C for two minutes, pre-denaturation at 95°C for 15 minutes, followed by 45 cycles at 94°C for 30 seconds and 65°C for 45 seconds. After PCR amplification, the PCR products were then reversely hybridized with gene chip technology. Finally, a gene chip scanner was used to interpret the data.

Statistical Analyses

All statistical analysis were performed using SPSS version 16.0. Data are presented as means ± standard deviation for continuous variables and as numbers and percentages for categorical variables. Differences between each group were performed using Student’s t-test for continuous variables, and Pearson’s χ2 test for categorical variables.

The association between disease and risk factors were screened by univariate logistic regression analysis, and odds ratio (OR), with 95% confidence intervals (CI) was adjusted by multivariate binary logistic regression. ApoE genotype and allele frequencies were tested for Hardy-Weinberg equilibrium by chi-square test. All tests were two-sided and a P value < 0.05 was considered.

Results

Baseline Clinical Characteristics of the Study Participants

Table 1 lists the demographic and clinical characteristics of all participants included in this study. There were 308 control participants (208 males and 100 females aged 56.91±14.03 years, mean±SD) and 308 patients with CAD (223 males and 85 females, age 57.76 ± 12.38 years). The age and sex distributions did not differ significantly between the two groups (P=0.423 and 0.187, respectively). Regarding clinical characteristics, smoking, drinking, diabetes mellitus and hypertension prevalence differed significantly between the patients with CAD and the control participants, as did high-density lipoprotein (HDL), TG, creatinine (Cr), ApoA-I and ApoE levels (all P < 0.05). However, there were no significant differences in the TC, LDL-C, ApoB and ApoB/ApoA-I levels between the two groups (all P > 0.05).

Table 1

Characteristics of the Study Population

Characteristics	Controls(n=308)	CAD(n=308)	P value
Age(years)	56.91±14.03	57.76±12.38	0.423a
Males/Females	208/100	223/85	0.187b
Smoking	105(30.09%)	145(47.08%)	0.001b
Drinking	62(20.13%)	106(34.42%)	<0.001b
Diabetes	76(24.68%)	104(33.77%)	0.013b
Hypertension	151(49.03%)	206(66.88%)	<0.001b
TC	3.79±0.84	3.77±1.08	0.773a
HDL	1.01±0.26	0.95±0.20	0.003a
LDL-C	2.27±0.74	2.21±0.98	0.447a
TG	1.48±0.88	1.69±1.21	0.021a
Cr	64.12±20.97	67.50±18.20	0.041a
ApoA-I	1.16±0.20	1.12±0.19	0.009a
ApoB	0.77±0.21	0.76±0.24	0.645a
ApoB/ApoA-I	0.68±0.21	0.70±0.24	0.375a
ApoE	38.20±14.97	35.14±15.85	0.018a

Notes: aP values were calculated by Student’s t-tests. bP values were calculated from two-sided chi-square test.

Abbreviations: CAD, coronary artery disease; TC, total cholesterol; HDL, high-density lipoproteins; LDL-C, low-density lipoprotein cholesterol; TG, triglyceride; Cr, creatinine.

ApoE Polymorphism and CAD Risk

The distributions of ApoE genotypes and alleles are listed in Table 2. The ApoE genotype frequency distributions in patients with CAD and control participants were concordant with the expectations of the Hardy-Weinberg equilibrium (χ2 = 1.35 and P = 0.85, and χ2 = 6.41 and P = 0.17, respectively). In patients with CAD and controls participants, ε3/ε3 accounted for 66.6% and 74.7% of all genotypes, respectively, followed by the ε3/ε4 (18.2% and 9.1%, respectively), ε2/ε3 (13.0% and 12.7%), ε2/ε4 (1.3% and 2.3%), ε4/ε4 (0.6% and 0.6%) and ε2/ε2 (0.3% and 0.6%), in which ε3 allele was the most common (82.1% and 85.6%), followed by ε4 (10.4% and 6.3%) and ε2 (7.5% and 8.1%). The distributions of ApoE genotypes and alleles significantly differed between patients with CAD and the control participants (χ2=11.93 and P=0.04, and χ2=7.72 and P=0.02, respectively).

Table 2

The Distributions of Genotypes and Alleles of the ApoE Gene in the CAD Patients and Controls

Genotype, n (%)	CAD Patients(n=308)	Controls(n=308)	OR (95% CI)	Pa	χ2	Pb
ε2/ε2	1(0.3%)	2(0.6%)	0.498(0.045,5.525)	0.563	11.93	0.04
ε2/ε3	40(13.0%)	39(12.7%)	1.029(0.642,1.651)	0.904
ε2/ε4	4(1.3%)	7(2.3%)	0.556(0.164,1.953)	0.361
ε3/ε3	205(66.6%)	230(74.7%)	0.675(0.476,0.957)	0.027
ε3/ε4	56(18.2%)	28(9.1%)	2.222(1.369,3.608)	0.001
ε4/ε4	2(0.6%)	2(0.6%)	1.000(0.140.7.145)	1.000
HWE	χ2 = 1.35, P = 0.85	χ2 = 6.41, P = 0.17
Alleles, n (%)
ε2	46(7.5%)	50(8.1%)	0.914(0.602,1.386)	0.671	7.72	0.02
ε3	506(82.1%)	527(85.6%)	0.777(0.573,1.054)	0.104
ε4	64(10.4%)	39(6.3%)	1.715(1.133,2.597)	0.010

Notes: ap and OR (95% CI) values were calculated by logistic regression adjusted for age, gender, and traditional cardiovascular risk factors. bp values were calculated from two-sided chi-square tests or Fisher’s exact tests.

Abbreviations: CAD, coronary artery disease; HWE, Hardy-Weinberg equilibrium.

Patients with CAD had a significantly lower ε3/ε3 frequency (odds ratio [OR] = 0.68, 95% confidence interval [CI] = 0.48–0.96, P= 0.027) than did the control participants. Patients with CAD had significantly higher ε3/ε4 (OR =2.22, 95% CI = 1.37–3.61, P=0.001) and ε4 allele (OR = 1.72, 95% CI = 1.13–2.60, P = 0.01) frequencies than did the control participants (Table 2).

Stratified analysis was further used to explore the effects of sex and age on the relationships. We analysed ApoE genotype frequencies in patients with CAD and control participants according to age (dichotomized into ≤60 years and >60 years), which indicated that ε3/ε4 frequency was significantly higher in patients with CAD (≤60 years and >60 years old) than in the healthy control participants. ε4 frequency was significantly higher in young patients with CAD (age ≤60 years) than in the control participants, whereas no marked difference was indicated between elderly patients with CAD and the controls. Subsequent analysis of the data stratified by sex indicated that neither male nor female patients with CAD exhibited significant differences in genotype and allele frequencies compared with the control participants of both sexes (Table 3).

Table 3

Stratified Analyses Between ApoE Polymorphism and Risk of CAD

				Genotype, n (%)					Alleles, n (%)
		ε2/ε2	ε2/ε3	ε2/ε4	ε3/ε3	ε3/ε4	ε4/ε4	ε2	ε3	ε4
Age≤60	CAD (n=189)	1(0.5%)	27(14.3%)	2(1.1%)	124(65.6%)	33(17.5%)	2(1.1%)	31(8.2%)	308(81.5%)	39(10.3%)
	Control(n=182)	1(0.5%)	24(13.2%)	4(2.2%)	135(74.2%)	17(9.3%)	1(0.5%)	30(8.2%)	311(85.4%)	23(6.3%)
	OR (95% CI)	0.963(0.060,15.508)	1.097(0.607,1.983)	0.476(0.086,2.631)	0.664(0.425,1.039)	2.053(1.099,3.835)	1.936(0.174,21.535)	0.995(0.589,1.680)	0.750(0.508,1.108)	1.706(0.997,2.917)
	P-value	0.979	0.766	0.441	0.09	0.023	0.584	0.975	0.167	0.049
Age>60	CAD(n=119)	0(0.0%)	13(10.9%)	2(1.7%)	81(68.1%)	23(19.3%)	0(0.0%)	15(6.3%)	198(83.2%)	25(10.5%)
	Control(n=126)	1(0.8%)	15(11.9%)	3(2.4%)	95(75.4%)	11(8.7%)	1(0.8%)	20(7.9%)	216(85.7%)	16(6.3%)
	OR (95% CI)	1.008(0.992,1.024)	0.908(0.412,1.998)	0.701(0.115,4.270)	0.696(0.398,1.217)	2.505(1.162,5.398)	1.008(0.992,1.024)	0.780(0.390,1.562)	0.825(0.506,1.346)	1.731(0.900,3.330)
	P-value	0.330	0.843	0.698	0.256	0.025	0.330	0.599	0.456	0.097
Males	CAD (n=223)	1(0.4%)	30(13.5%)	1(0.4%)	149(66.8%)	40(17.9%)	2(0.9%)	33(7.4%)	368(82.5%)	45(10.1%)
	Control(n=208)	1(0.5%)	23(11.1%)	8(3.8%)	146(70.2%)	29(13.9%)	1(0.5%)	33(7.9%)	344(82.7%)	39(9.4%)
	OR (95% CI)	0.932(0.058,15.004)	1.250(0.700,2.232)	0.113(0.014,0.908)	0.855(0.569,1.285)	1.349(0.802,2.271)	1.873(0.169,20.814)	0.927(0.561,1.532)	0.987(0.694,1.405)	1.085(0.691,1.703)
	P-value	0.961	0.449	0.014	0.451	0.258	0.604	0.768	0.944	0.724
Females	CAD (n=85)	0(0.0%)	10(11.8%)	3(3.5%)	56(65.9%)	16(18.8%)	0(0.0%)	13(7.6%)	138(81.2%)	19(11.2%)
	Control(n=100)	1(1.0%)	14(14.0%)	3(3.0%)	68(68.0%)	13(13.0%)	1(1.0%)	19(9.5%)	163(81.5%)	18(9.0%)
	OR (95% CI)	1.010(0.990,1.030)	0.819(0.344,1.952)	1.183(0.232,6.020)	0.909(0.492,1.680)	1.552(0.699,3.444)	1.010(0.990,1.030)	0.789(0.377,1.649)	0.979(0.579,1.654)	1.272(0.645,2.511)
	P-value	0.355	0.652	0.839	0.760	0.278	0.355	0.527	0.937	0.487

Notes: P and OR (95% CI) values were calculated by logistic regression adjusted for age, gender, and traditional cardiovascular risk factors.

Abbreviation: CAD, coronary artery disease.

Comparing the Clinical Data of Different ApoE Alleles Between the CAD Group and Control Participants

Tables 4 and 5 list the associations between serum lipid profiles and allelic carrier statuses (ε2, ε3 and ε4 groups). ε2 and ε4 were considered to have opposite roles in lipid metabolism, and so participants with the ε2/ε4 genotype were excluded. In the control participants, ε4 carriers had significantly higher levels of TC, LDL-C, TG, ApoB and ApoB/ApoA-I, and lower levels of ApoE than did ε2 carriers. However, ApoE polymorphisms did not significantly impact the levels of TC, HDL, LDL-C and TG in patients with CAD. Moreover, ε4 carriers had significantly higher levels of ApoB, ApoB/ApoA-I and lower levels of ApoE than did ε2 carriers; ε2 carriers also had lower, ApoB/ApoA-I and ApoE levels than did ε3 and ε4 carriers among patients with CAD.

Table 4

Relationships Between Serum Lipid Profile and ApoE Allele in Control Participants

Lipid Level (mmol/L)	ε2(ε2ε2+ε2ε3) n=41	ε3(ε3) n=230	ε4(ε3ε4+ε4ε4) n=30	P a	P b	P c	P d
TC	3.61±0.67	3.80±0.86	4.01±0.82	0.182a	0.235	0.038	0.159
HDL	1.04±0.21	1.01±0.25	1.03±0.25	0.383a	0.592	0.854	0.622
LDL-C	1.82±0.58	2.13±0.80	2.27±1.01	0.020a	0.386	0.001	0.038
TG	1.41±0.59	1.44±0.83	1.83±0.82	0.824a	0.015	0.015	0.037
Cr	61.86±15.54	64.38±19.98	66.94±27.53	0.448a	0.533	0.337	0.583
ApoA-I	1.20±0.19	1.15±0.19	1.17±0.17	0.121a	0.510	0.558	0.265
ApoB	0.67±0.22	0.77±0.20	0.92±0.22	0.006a	0.001	0.000	0.000
ApoB/ApoA-I	0.58±0.24	0.69±0.19	0.79±0.19	0.004a	0.014	0.001	0.000
ApoE	48.52±15.93	36.06±12.87	39.53±11.45	0.000a	0.163	0.012	0.000

Notes: ap values obtained when comparing ε2 subjects with ε3 subjects. bp values obtained when comparing ε4 subjects with ε3 subjects. cp values obtained when comparing ε2 subjects with ε4 subjects. dp value shows the differences compared between groups (ε2, ε3, ε4).

Abbreviations: CAD, coronary artery disease; TC, total cholesterol; HDL, high-density lipoproteins; LDL-C, low-density lipoprotein cholesterol; TG, triglyceride; Cr, creatinine.

Table 5

Relationships Between Serum Lipid Profile and ApoE Allele in CAD Patients

Lipid Level (mmol/L)	ε2(ε2ε2+ε2ε3) n=41	ε3(ε3) n=230	ε4(ε3ε4+ε4ε4) n=30	P a	P b	P c	P d
TC	3.64±1.06	3.77±1.09	3.88±1.09	0.491	0.463	0.255	0.531
HDL	0.96±0.21	0.96±0.19	0.94±0.20	0.838	0.650	0.630	0.865
LDL-C	2.06±0.91	2.21±1.01	2.34±1.00	0.398	0.363	0.148	0.378
TG	1.82±0.98	1.66±1.31	1.69±0.72	0.478	0.857	0.543	0.772
Cr	68.01±17.71	66.87±17.66	69.75±16.21	0.707	0.265	0.614	0.532
ApoA-I	1.15±0.21	1.12±0.17	1.09±0.18	0.245	0.316	0.110	0.238
Apo B	0.69±0.23	0.76±0.24	0.81±0.23	0.059	0.191	0.009	0.037
ApoB/ApoA-I	0.61±0.23	0.70±0.25	0.75±0.23	0.036	0.136	0.002	0.015
ApoE	50.33±21.48	33.29±14.13	30.26±7.62	0.000	0.128	0.000	0.000

Notes: ap values obtained when comparing ε2 subjects with ε3 subjects. bp values obtained when comparing ε4 subjects with ε3 subjects. cp values obtained when comparing ε2 subjects with ε4 subjects. dp value shows the differences compared between groups (ε2, ε3, ε4).

Abbreviations: CAD, coronary artery disease; TC, total cholesterol; HDL, high-density lipoproteins; LDL-C, low-density lipoprotein cholesterol; TG, triglyceride; Cr, creatinine.

Logistic Regression Analysis of the Risk of CAD in the Northwest Population

Univariate analysis indicated that the risk factors of smoking, drinking, diabetes mellitus, hypertension, low levels of HDL, ApoA-I and ApoE and high levels of TG and Cr were significantly associated with the presence of CAD (P<0.05). We also performed a multivariate logistic regression analysis, which indicated that ε4 allele (OR =0.965, 95% CI = 0.949–0.981; P=0.000), drinking, smoking, hypertension, TG and ApoE levels were significant and independent risk factors for CAD (Table 6). After stratifying by age (≤60 years and >60 years) and sex, multivariate logistic regression analysis was performed. This indicated that ε4 was a significant and independent risk factor for elderly patients with CAD (age >60 years: OR = 3.30, 95% CI = 1.10–9.86, P = 0.033), but not for young (age ≤60 years: OR = 1.43, 95% CI = 0.69–2.96, P = 1.427), female (OR = 1.15, 95% CI = 0.36–3.65, P = 0.817) or male (OR = 1.30, 95% CI = 0.71–2.38, P = 0.403) patients with CAD (Table 7).

Table 6

Logistic Regression Analysis of the Risk of CAD in Northwest of China Population

Variables	P- value	OR (95% CI)
Age	0.064	1.014(0.999–1.028)
Drinking	0.045	1.555(1.010–2.395)
Smoking	0.018	1.609(1.084–2.388)
Hypertension	0.000	1.988(1.386–2.853)
TG	0.000	1.625(1.280–2.132)
ApoE	0.000	0.965(0.949–0.981)
ε4	0.032	1.826(1.055–3.163)

Abbreviations: CAD, coronary artery disease; TG, triglyceride.

Table 7

Multiple Logistic Regression Analysis for CAD Patients and Control Subjects

ε4
	OR (95% CI)	P-value
Age≤60	1.427(0.688, 2.959)	1.427
Age>60	3.295(1.101, 9.862)	0.033
Males	1.295(0.706, 2.376)	0.403
Females	1.147(0.360, 3.650)	0.817

Abbreviation: CAD, coronary artery disease.

Discussion

CAD is a complex multifactorial disease modulated by multiple genetic and environmental factors, and contributes greatly to global morbidity and mortality. With changes to lifestyle and extensions to lifespan, the CAD prevalence is increasing sharply in China.10

ApoE is a 34 kDa protein consisting of 299 amino acids responsible for lipid metabolism, and participates in TG transport and cholesterol metabolism.11 Previous studies have demonstrated how ApoE polymorphisms could affect ApoE gene transcription and cholesterol and TG levels, thus altering atherosclerosis progression, which is the main underlying pathology of CAD.12 Additional studies have also suggested ApoE may also increase the risk of CAD through the interaction with the antioxidative and immune system.13 Numerous previous studies have demonstrated that ApoE genotypes and allele frequencies vary significantly across different populations.14,15 The ε3 allele is predominant in all populations, and ε2 is thought to induce some effects protecting against CAD.12 ε4 has been identified across Europe at different frequencies, gradually decreasing from north to south. For example, the frequency of ε4 ranges from more than 22% in Finland and Greenland to less than 7% in Greece and Italy.16,17 Epidemiological studies conducted in Asia (Iran, India, Singapore, Japan, China and Saudi Arabia) also found that ε3 is the most prevalent subtype (87%), while ε2 and ε4 have low prevalence rates in Asian countries.16 The order of frequencies of ApoE alleles in China is ε3 >ε4 >ε2, but there are also some other variations between north and south areas.14

The present study investigated the prevalence of polymorphisms and ApoE frequency among patients with CAD in northwest China. The ApoE genotypes frequencies in the CAD group were 0.3%, 13.0%, 1.3%, 66.6%, 18.2% and 0.6% for ε2/ε2, ε2/ε3, ε2/ε4, ε3/ε3, ε3/ε4 and ε4/ε4, respectively; the corresponding frequencies in the control participants were 0.6%, 12.7%, 2.3%, 74.7%, 9.1% and 0.6%. In patients with CAD and control participants, ε3 had the highest frequency (82.1% and 85.6%, respectively), while those for ε2 and ε4 were 7.5% and 8.1%, 10.4% and 6.3%, respectively, which were consistent with previous local and foreign research results.2,14 Our study indicated that ε4 was significantly more common in patients with CAD than in the control group. We also found that ε4 increased the CAD risk 1.9-fold overall, and 3.3-fold among elderly patients with CAD but not in young patients with CAD of both sexes. These results were consistent with those of previous studies.18 While the association between ApoE polymorphisms and CAD risk in different populations have been assessed in numerous studies, the results remain inconclusive.2,18

ApoE is a plasma glycoprotein associated with lipid transport and cholesterol homeostasis. The precise cellular mechanisms which are responsible for the differences between ε2, ε3 and ε4 are not fully understood, but ε4 has a somewhat higher affinity for the LDL receptor than ε3, while ε2 bind less well to the receptor-only 2% of normal activity, which results in different plasma lipoprotein profiles.19 ε4 is associated with elevated levels of TC, LDL-C, TG and ApoB, lower plasma levels of ApoE, and an increased CAD incidence.20,21 A large meta-analysis demonstrated that ε2 carriers have a 20% lower CAD risk compared with ε3 or ε4 carriers.22 The present study found that the patients in the CAD group had higher TG levels and lower HDL levels. Furthermore, logistic regression analysis indicated that TG level is a strong independent risk factor for CAD (OR = 1.652, 95% CI=1.280–2.132, P < 0.001). High HDL levels have been well documented to exert a protective effect on CAD, and low plasma HDL elevated plasma TG levels are associated with an increased CAD risk.23,24 Our results indicated that ε2 carriers had lower TC, LDL-C and TG levels than did ε3 or ε4 carriers among the control participants. However, no significant differences were found between ɛ2, ɛ3 or ɛ4 carriers and plasma lipoprotein levels among patients with CAD. This is consistent with some previous studies25,26 but conflicts with others.27 The associations between ApoE genetic polymorphisms with lipid profiles have been widely studied among patients with CAD, although they remain controversial.14 The results of varied exposures due to racial, genetic and environmental factors are likely to influence the effects of ApoE polymorphism on blood lipid profiles. Moreover, most of the present patients with CAD were already receiving lipid-lowering therapy at the time of inclusion, which might explain the lack of a significant correlation between serum lipid profiles and ApoE alleles in patients with CAD.

ApoA-I is a major structural and functional component of HDL, and is considered to play an essential role in reducing CAD risk.28 ApoB is the main apolipoprotein of chylomicrons and LDL-C, and may contribute to atherogenesis.29 The ApoB/ApoA-I ratio was found to be associated with CAD risk.30,31 Recent prospective studies indicated that low ApoA-I levels, high ApoB levels and the ApoB/A-I ratio may be even better predictors of CAD risk than traditional lipid parameters.32,33 However, there are also some conflicting data in the literature.34 In the present study, the CAD group had significantly lower ApoA-I levels than the control group, while ApoB levels and the ApoB/ApoA-I ratios did not differ significantly between the two groups. However, no significant difference was observed in ApoA-I levels among ɛ2, ɛ3 and ɛ4 carriers, and ApoB/ApoA-I ratios and ApoB levels were significantly lower in ɛ2 carriers than in ɛ3 or ɛ4 carriers in both groups. These results were consistent with those reported previously for other populations.35 We also observed that ɛ4 carriers had a significantly lower ApoE in both groups, which was consistent with previous findings of the ApoE level being highest in ɛ2 carriers and lowest in ɛ4 carriers.19,36

Limitations of This Study

First, As this is a large retrospective study, so it is difficult to exclude the influence of diet, activities and drugs on blood lipid level, which may lead to certain bias. Second, We cannot exclude that undetected significant differences between ApoE allele and lipid profile may because of the small sample size and lack statistical power.

Conclusions

In conclusion, our study suggested that ɛ4 allele is associated with increased risk of CAD in Northwest of China population. Stratified analysis confirms that this elevated risk in individuals aged ≤60 years old. After stratified by age and gender, multivariate logistic regression model analysis showed that ε4 was a significant and independent risk factors in elderly CAD patients (age >60). In addition, ɛ4 allele is associated with elevated TC, LDL-C, TG, ApoB and ApoB/ApoA, while ɛ2 allele is related to increased ApoE level. Therefore, ApoE genotyping may be clinically useful to help identify individuals at high risk of CAD and suggesting strategies for preventive measures and curative therapies.