Abstracting and Indexing

  • PubMed NLM
  • Google Scholar
  • Semantic Scholar
  • Scilit
  • CrossRef
  • WorldCat
  • ResearchGate
  • Academic Keys
  • DRJI
  • Microsoft Academic
  • Academia.edu
  • OpenAIRE
  • Scribd
  • Baidu Scholar

The Correlation Between ApoE Genetic Polymorphism and Serum Lipid Levels

Article Information

Yishu Tang*, Yang Yang

Department of Laboratory Medicine, The First Affiliated Hospital of Chongqing Medical University, Chongqing, People’s Republic of China

*Corresponding Author: Yishu Tang,  Department of Laboratory Medicine, The First Affiliated Hospital of Chongqing Medical University, Chongqing, People’s Republic of China, Tel: +86 23 89012735;

Received: 02 April 2018; Accepted: 05 April 2018; Published: 09 April 2018

Citation: Yishu Tang, Yang Yang. The Correlation Between ApoE Genetic Polymorphism and Serum Lipid Levels. Cardiology and Cardiovascular Medicine 2 (2018): 039-043.

View / Download Pdf Share at Facebook

Abstract

Objective: To explore the correlation between apolipoprotein E genetic polymorphism and serum lipid levels.

Methods: The genechips method was adopted to detect the ApoE genotype in people undergoing physical examination.The serum lipid levels were compared among the populations with different ApoE genotypes.

Results: The ApoE gene showed the polymorphic distribution in populations,in which the distribution frequency of E3 allele was highest,the population containing E2 allele had higher triglyceride level in serum, the population containing E4 allele had higher total cholesterol level in serum.

Conclusion: The ApoE gene presents the polymorphic distribution in populations. The E2 allele is correlated with serum high triglyceride level. The E4 allele correlated with serum high total cholesterol level.

Keywords

ApoE; Genetic Polymorphism

Article Details

Untitled Document

1. Introduction
Apolipoprotein E (ApoE) was the major apolipoprotein in the serum.ApoE played the crucial role in the lipid metabolism,which was the key part of very low-density lipoprotein (VLDL), high-density lipoprotein(HDL) and chylomicrons [1-3]. The recent study showed that triacylglycerol (TAG) hydrolysis mediated by lipoprotein lipase in VLDL. The surface material containing phospholipids, free cholesterol and ApoE and ApoCs (CII and CIII) were also evolved in the process [2]. The released components were received by HDL, so the new HDL-sized ApoE-containing molecule are also induced. Decreased HDL particles or abnormalities in their structure is correlated to unfavorable changes in the features of VLDL remnants [3].

ApoE encoding gene was located in the 19th chromosome, including 4 exons and 3 introns. The exon includes 3 alleles, named E2, E3 and E4, which generated 6 phenotype (E2/E2, E3/E3, E4/E4, E2/E3, E2/E4, E3/E4). Its genetic polymorphism is an important genetic factor affecting lipid metabolism. The studies showed approximately 14-17% variation of plasma cholesterol concentration can be associated with genetic polymorphism [4-7]. Echeverria et al reported the impact of 13 polymorphisms of nine genes affecting lipid metabolism [8].

At present, more and more studies on the relationship between ApoE gene polymorphism and lipid metabolism were reported. The purpose of the research was to provide valuable data about diagnosis and treatment of abnormal lipid metabolism and disease in Chongqing.

2. Methods
2.1 Research population
A total of 327 people (172 male and 155 female) was recruited from January to September of 2017 in The First Affiliated Hospital of Chongqing Medical University.  All the patients were negative for hypertension, the disease from liver, kidney and internal secretion. This study was approved by the Institutional Review Board (IRB) committee of The First Affiliated Hospital of Chongqing Medical University. Written consent given by the patients was waived by the approving IRB. Anticoagulation with EDTA was applied in vitro to detect ApoE gene polymorphism .The serum was applied to detect serum lipid.

2.2 Blood lipid detection methods
Total cholesterol (TC) and triglyceride (TG) were measured with enzymatic assay (Roche Company). High-density lipoprotein cholesterol (HDLC) and low-density lipoprotein cholesterol (LDLC) were using direct method (Roche Company). ApoA1, ApoB, ApoE, and Lp(a) were tested using immunoturbidimetry (provided by WAKO Co., Ltd, Japan).

2.3 ApoE gene polymorphism analysis
The nucleic acid was extracted from anticoagulation blood and PCR amplification. Once combined with a hybridization buffer (Sinochips Corporation), the products were placed in a BioMixer chip hybridization instrument (Sinochips Corporation) for hybridization. Then products were put in a slidewasher 8 chip dry cleaning instrument (Sinochips) for washing and drying. Finally, the chip was placed in chip identification system for scanning and interpretation (Sinochips Corporation).

2.4 Statistical analysis
The number of groups between the use of t-test or analysis of variance, composition than with the Chi-square test, correlation analysis using Spearman rank correlation analysis.

3. Results
3.1 ApoE genotype and allele distribution rate
In the recruited people, the E3 allele of ApoE gene has the highest distribution rate, so the rate of E3/E3 genotype was the highest (Table 1). Compared to the male, the distribution rate of ApoE allele and genotype of female was no statistically different (P>0.05).

Sex

n

ApoE genotype

ApoE allele

E2/E2

E3/E3

E4/E4

E2/E3

E2/E4

E3/E4

E2

E3

E4

Male

172

3(1.7)

119(69.2)

2(1.2)

23(13.4)

6(3.5)

19(11.0)

32(14.5)

161(73.2)

27(12.3)

Female

155

3(1.9)

102(65.8)

3(1.9)

30(19.4)

5(3.2)

12(7.7)

38(18.8)

144(71.3)

20(9.9)

Table 1: ApoE genotype and the allele distribution rate

3.2 ApoE gene polymorphism and serum lipid levels
In order to study the pure effects of alleles E2 and E4 on blood lipids, E2/E4 type was removed and divided into three groups according to different genotypes: E2/E2+E2/E3, E3/E3, and E3/E4+E4/E4. The Table 2 showed that the levels of TC, TG and LDLC in ApoE genotype E3/E4 + E4/E4 were significantly higher in hemodialysis group (P<0.05).


Gene type

n

TC (mM)

TG (mM)

HDL-C (mM)

LDL-C (mM)

ApoA1 (g/L)

ApoB (g/L)

ApoE (mg/L)

Lp(a) (mg/L)

E2/E3+E2/E2

59

3.41±0.57

1.31±0.59

1.09±0.11

1.87±0.65

1.12±0.14

0.85±0.31

35±11

335±159

E3/E3

221

3.87±0.52

1.59±0.49

1.01±0.17

2.08±0.65

1.08±0.21

0.95±0.21

37±10

205±143

E4/E4+E3/E4

36

4.21±0.61

2.01±0.74

1.25±0.63

2.31±0.71

1.37±0.29

0.91±0.22

45±6

266±4

P

0.046*

0.008*

0.052

0.024*

0.095

0.647

0.017*

0.086

*P<0.05

Table 2:  The blood fat level in the people with different ApoE genotype (X±S)

4. Discussion
Lipoid and neutral fat were included in blood fat. The most ingredient of blood fat was TG and cholesterol. Abnormal blood lipid refers to the abnormal serum lipid metabolism, included the increased TC, TG, LDL-C and HDL-C.

The ApoE gene contained 3 major alleles, which consisted of 6 genotypes.The previous study reported that the frequency of E3 alleles was the highest. E3/E3 genotype was the most common type in the population. There were significant regional and racial differences in gene polymorphism.The frequency of  E3 alleles was 80% in Chinese population, which was similar to the Japanese, but the frequency of European was less than  80% [9]. The frequency of genotypes was depended on the racial and regional differences[10]. ApoE has played an important role in the transport, storage, utilization and excretion of lipids. The affinity between the ApoE2 and LDL receptor was low, so the VLDL residue in ApoE2 was eliminated slowly. Then the LDL receptor was up-regulation, which induced the LDL-C level decreased and hypocholesterolemia. Otherwise, the VLDL residue in ApoE4 was eliminated quickly to decrease LDL receptor, which induced LDL-C increased and hypercholesterolemia [11]. Therefore, most studies demonstrated E2 allele was beneficial mutations and E4 allele was adverse mutation. The mutations of the ApoE allele was induced by the adjustment of the diet [12]. The study demonstrated that E2 could decrease the TC level,but E4 was correlated to higher TC level to induce  hyperlipidemia [13].

In conclusion, our study demonstrated ApoE gene polymorphism was related to the level of serum lipid level. The genotype induced the abnormal index of serum lipid level. ApoE gene polymorphism was also related to the diseases like coronary heart disease, hyperlipidemia, cerebral infarction. We should reinforce early detection, rapid diagnosis, and standardize therapy, in order to reduce the risk of the diseases related to abnormal lipid metabolism.

5. Acknowledgements
This work was supported by a grant from the National Natural Science Foundation of China (No 81501818 of Yishu Tang) and the National Key Clinical Specialties Construction Program of China.

6. Conflict of interest
The authors declare no conflicts of interest.

References

  1. Chmurzynska A, Malinowska AM, Twardowska-RajewskaJ, Gawecki J. Elderly women: homocysteine reduction by short-term folic acid supplementation resulting in increased glucose concentrations and affecting lipid metabolism (C677T MTHFR polymorphism). Nutrition 29 (2013): 841-844.
  2. Cwiklinska A, Gliwinska A, Senderowska Z, Kortas-Stempak B, Kuchta A, Dabkowski K, Jankowski M. Impact of phosphatidylcholine liposomes on the compositional changes of VLDL during lipoprotein lipase (LPL)-mediated lipolysis. Chem Phys Lipids 195 (2016): 63-70.
  3. Rideout TC, Movsesian C, Tsai YT, Iqbal A, Raslawsky A, Patel MS. Maternal Phytosterol Supplementation during Pregnancy and Lactation Modulates Lipid and Lipoprotein Response in Offspring of apoE-Deficient Mice. J Nutr 145 (2015): 1728-1734.
  4. Walden CC, Hegele RA. Apolipoprotein E in hyperlipidemia. Ann Intern Med 120 (1994): 1026-1036.
  5. Dallongeville J, Lussier-Cacan S, Davignon J. Modulation of plasma triglyceride levels by apoEphenotype: a meta-analysis. J Lipid Res 33 (1992): 447-454.
  6. Konialis C, Spengos K, Iliopoulos P, Karapanou S, Gialafos E, Hagnefelt B, Vemmos K, et al. The APOE E4 Allele Confers increased risk of ischemic stroke among Greek carriers. Adv Clin Exp Med 25 (2016): 471-478.
  7. Lahoz C, Schaefer EJ, Cupples LA, Wilson PW, Levy D, Osgood D, Parpos S, et al. Apolipoprotein E genotype and cardiovascular disease in the Framingham Heart Study. Atherosclerosis 154 (2001): 529-537.
  8. Echeverria P, Guardiola M, Gonzalez M, Vallve JC, Bonjoch A, Puig J, Clotet B, et al. Association between polymorphisms in genes involved in lipid metabolism and immunological status in chronically HIV-infected patients. Antiviral Res 114 (2015): 48-52.
  9. Borinskaia SA, Kalina NR,Sanina ED, et al. Polymorphism of the apolipoprotein E gene (ApoE) in the populations of Rissia and neigbring countries. Genentika 43 (2007): 1434-1440.
  10. Liang S, Pan M, Geng HH, et al. Apolipoprptein E polymorphism in normal Han Chinese population:frequency and effect on lipid parameters. Mol Biol Rep 36 (2009): 1251-1256.
  11. Vaarhorst AA, Beekman M, Suchiman EH, et al. Lipid metabolism in long-lived families:the Leiden Longevity Study. Age (Dordr) 33 (2001): 219-227.
  12. Eisenberg DT, Kuzawa CW, Hayes MG. Worldwide allele frequencies of the human apolipoprotein E gene: climate, local adaptations,and evolutionary history. Am J Phys Anthropol 143 (2010): 100-111.
  13. Chauhary R, Likidlilid A, Peerapatdit T, et al.Apolipoprotein E gene polymorphism:effects on plasma lipids and risk of type 2 diabetes and coronary artery disease. Cardiovasc Diabetol 11 (2012): 36-39.

Journal Statistics

Impact Factor: * 3.5

CiteScore: 2.9

Acceptance Rate: 74.36%

Time to first decision: 10.4 days

Time from article received to acceptance: 2-3 weeks

Discover More: Recent Articles

Grant Support Articles

© 2016-2024, Copyrights Fortune Journals. All Rights Reserved!