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Cardiology & Current Research

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Received: January 01, 1970 | Published: ,

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Abstract

High density lipoprotein (HDL) is protective against atherosclerosis. Adenosine tri-phosphate Binding Cassette transporter subfamily A class 1 (ABCA1) mediates the first step of reverse cholesterol transport i.e. efflux of cholesterol and phospholipid to Apolipoprotein A1 (ApoA1) and HDL formation. The present study aimed at analysing ABCA1 gene and protein expression in peripheral blood mononuclear cells (PBMNCs) of healthy individuals with HDL cholesterol (HDL-C) levels below normal as per NCEP criteria. Group 1 included twenty seven healthy subjects with normal HDL-C levels and normal triglyceride levels and Group 2 included twenty eight healthy subjects with low HDL-C but normal triglyceride levels. ABCA1 gene expression was high by 65.0 % while ABCA1 protein was significantly low by 17.5% of Group 2 as compared to Group 1. Thus up-regulation of ABCA1 protein failed to translate into ABCA1 protein. This implies some defect at translational and post translational level which needs to be further explored.

Keywords: reverse cholesterol transport, apolipoprotein a1, peripheral blood mononuclear cells

Abbreviations

HDL, high density lipoprotein; ABCA1, adenosine tri-phosphate binding cassette transporter subfamily A class 1; Apo A1, apolipoprotein A1; HDL-C, HDL cholesterol; CAD, coronary artery disease; PBMNCs, peripheral blood mononuclear cells

Introduction

Peripheral cells obtain their cholesterol from combination of synthesis and uptake from low density lipoproteins (LDL). Most peripheral cells are not able to catabolize cholesterol but transport excess cholesterol from peripheral tissues back to liver, the process called "reverse cholesterol transport" (RCT). This is the only way by which cholesterol homeostasis is maintained in vivo The first step of RCT is uptake of cellular cholesterol by the high density lipoprotein (HDL). A key regulator of this uptake is ATP-Binding Cassette transporter A1 (ABCA1).1,2 It mediates the cellular efflux of phospholipid and cholesterol across cell membranes to lipid-poor Apolipoprotein A1 (ApoA1), the major Apo in HDL. Thus it plays a significant role in HDL metabolism and lipid clearance thereby decreasing the risk of atherosclerosis.3,4 ABCA1 mRNA is expressed in leukocytes and macrophages, besides placenta, liver lung and adrenal gland.5

Insufficient cholesterol efflux may be a consequence of inadequate movement of intracellular cholesterol, too low HDL concentration in the extracellular fluid or impaired ability of these particles to accept cholesterol. The function of ABCA1 as a key regulator of HDL became apparent in 1999 when loss of ABCA1 gene function was determined to be the cause of Tangier’s disease who exhibited extremely low levels of HDL-cholesterol (HDL-C) and increased incidences of premature coronary artery disease (CAD).6-8 Inadequate transport of cholesterol and phospholipids out of cells leads to accumulation of intracellular sterol and the subsequent development of foam cells, a hallmark of atherosclerotic plaque.9 Studies with ABCA1 transgenic and knock-out mice have indicated association of overexpression with high HDL-C levels and deletion with atherosclerosis.10-12

HDL imparts anti-oxidative, anti-inflammatory, and anti-thrombotic functions.13,14 In the last few decades studies have shown that a low level of HDL-C is a powerful and independent risk factor for CAD even with a normal total plasma cholesterol levels.15-17 As ABCA1 is critical in HDL formation, the present study was carried out to analyse the expression of ABCA1 gene of peripheral blood mononuclear cells (PBMNCs) at mRNA and protein levels in healthy individuals with low HDL-C.

The study population included healthy individuals with systolic blood pressure/diastolic blood pressure (SBP/DBP) = 135/85 mmHg or less, with normal ECG and carotid Doppler, with no risk factors of CAD (except alchol consumption), triglyceride levels <200mg/dl, not on any lipid lowering drug or clinical symptoms of any other organic disease. Their blood sample was collected after overnight twelve hour fast. Those subjects with fasting glucose levels >110 mg/dl, serum transaminases, Blood Urea Nitrogen, Creatinine levels, lipid profile and complete blood count beyond normal range or abnormal ECGs or Carotid Doppler, were excluded. As per the selection criteria in each group, subjects were recruited in study only after obtaining their informed consent. Information regarding their demographic status, clinical history, family history and medications if any were noted down in detail. The ethical committee of Sir H. N. Hospital and Research Centre approved the study protocol. These subjects were further divided into two groups. In Group 1 healthy individuals with normal HDL-C levels were included and in Group 2 healthy individuals with low HDL-C levels were included (Males <40mg/dl or 1.0mmol/L and females <50mg/dl or 1.3mmol/L) as per NCEP criteria.18 In Group 1 five out of 27 and in Group 2 six out of 28 were consuming alcohol occasionally. The details of ABCA1 Gene Expression analysis by Quantitative Real-Time PCR using Taqman Assay and ABCA1 Protein estimation by Enzyme Linked Immunoabsorbent Assay (ELISA) has been described elsewhere.19 The expression of ABCA1 mRNA was quantitated using comparative Ct method as described in PE User Bulletin 2 and calculated as 2-delta delta Ct. The Ct value being a numerical value, the change of ABCA1 mRNA transcript (gene expression) of Group 2 is unit less and expressed as percentage relative to that of Group 1. ABCA1 protein is expressed as OD at 450nm of 50 µg/ml of total cell protein extract. Results are expressed as mean ± SD for parametric variables and median and quartiles for non-parametric data variable. The anlaysis of significance of difference between two groups was performed by student’s Unpaired‘t’- test. Bivariate correlations were evaluated by Pearson correlation. A p value <0.05 was considered statistical significant. Analyses were performed using statistical software SPSS (version 21.0, Chicago, IL).

The demographic and biochemical data is depicted in Table 1. Group 1 and 2 subjects were age and BMI matched. Total cholesterol (TC) levels in Group 2 were marginally less by 12.3% (p<0.01) while HDL-C levels (35.7%, p<0.001) were significantly low with TC to HDL Cholesterol ratio (34.2%, p<0.001) and LDL-cholesterol (LDL-C) to HDL-C ratio (40.6%, p<0.001) high as compared to Group 1. Significant low levels of Apolipoprotein A1 (Apo A1) (20.7%, p<0.001) and high in ApoB/A1 ratio (22.3%, p<0.05) were also observed in Group 2 as compared to Group 1. LDL-C and triglyceride levels were not significantly different between two groups. ABCA1 gene expression of Group 2 was compared against age, gender and BMI matched individuals of Group 1. The ABCA1 gene expression of Group 2 was more by 65% then Group 1 (Figure 1). The mean absorbance of ABCA1 protein of Group 2 was significantly low by 17.5% (p<0.0001) as compared to healthy individuals with normal HDL-C level (Group 1) (Table 2). Pearson correlation (r) analysis of overall data demonstrated significant positive correlation of ABCA1 Protein with HDL-C (r=0.393, p=0.003) and Apo A1 (0.401, p=0.002) while negative correlation with LDL-C/HDL-C (r=-0.350, p=0.009) and TC/ HDL-C (r=-0.342, p=0.011).

Parameters

Group 1 [N=27]

Group 2 [N=28]

Male: Female

17:10

22:06

Age [Years]

45.8±12.8

40.1NS±9.96

Body Mass Index (BMI) [kg/m2]

24.2±3.67

24.4 NS±3.89

Waist : Hip

0.89±0.06

0.91 NS±0.06

SBP [mmHg]

121.9±8.2

117.9 NS±7.1

DBP [mmHg]

79.5±5.1

77.2 NS±5.81

Fasting Sugar [mg/dl]

98.4±18.0

91.3 NS±8.00

Total Cholesterol (TC) [mg/dl]

188.2±28.0

165.1**±32.8

HDL-Cholesterol (HDL-C) [mg/dl]

46.6±10.1

29.9***± 4.01

TC/HDL-C

4.15±0.77

5.57***±1.10

Triglycerides [mg/dl]

98.2±32.7

112.8 NS±48.0

Very Low Density Lipoprotein –Cholesterol (VLDL-C) [mg/dl]

19.6± 6.53

22.6 NS± 9.6

Low Density Lipoprotein –Cholesterol (LDL-C) [mg/dl]

122.0±23.2

112.6 NS±30.3

LDL-C/HDL-C

2.71±0.68

3.81***±1.05

Apolipoprotein A1 (Apo A1) [g/L]

1.15±0.25

0.91***±0.15

Apolipoprotein B (Apo B) [g/L]

1.05±0.24

1.03 NS±0.28

ApoB/ApoA1

0.94±0.28

1.15*±0.32

Table 1 Demographic data
***p<0.001, **p<0.01, *p<0.05, NS, non-significant

Parameters

Group 1 [N=27]

Group 2 [N=28]

Relative ABCA1 Expression 2-delta delta Ct

1

1.65 (0.73/3.07) (65.0 % ­)

ABCA1 Protein Expression [OD at 450nm of 50 µg/ml of total cell protein extract]

0.80± 0.09

0.66***±0.11 (17.5% ¯)

Table 2 ABCA1 gene and protein expression
***p<0.001, **p<0.01, *p<0.05, NS, non-significant

Figure 1 ABCA1 gene expression.

Considering the roles played by HDL in preventing atherosclerosis and thrombosis, there is always curiosity to know the basal status of ABCA1 gene and protein expression in association with peripheral HDL-C levels. A report by Guan et al did demonstrate increased mRNA expression of ABCA1 in circulating mononuclear cells stimulated by simvastatin and in turn improvement in RCT.20 Albrecht et al explored the role of leukocyte ABCA1 gene expression and indices of glycemia in normal and diabetic patients and demonstrated inverse association between ABCA1 gene expression and fasting glucose concentration.21 However, an association between basal ABCA1 expression of PBMNCs and HDL-C levels in healthy individuals with low HDL-C has not been explored. The present study was therefore designed to analyse the basal ABCA1 gene expression of PBMNCs of healthy individuals with low HDL-C and compare with healthy individuals normal HDL-C as per NCEP.21 criteria (18). Screening of healthy subjects was done very carefully through rigorous protocol involving fasting lipid profile, ECG and Carotid Doppler, to find any atherosclerotic symptoms. Subjects of any group were excluded if had triglycerides >200mg/dl or were prescribed any hypolidemic drugs or suffering from any other disease.

ABCA1 controls the first step of RCT which is rate-limiting step in HDL particle formation i.e. efflux of intracellular cholesterol to ApoA1 from peripheral cells. In the present study, expression of ABCA1 gene was increased in healthy individuals with low HDL-C while ABCA1 protein was decreased significantly as compared to controls. Thus increase in ABCA1 gene expression was not translated into increase in protein content and ABCA1 protein levels of individuals with low HDL-C levels did not increase proportionate to that of healthy individuals. Similar finding has been reported by Albrecht et al in their study on ABCA1 gene and protein expression in atherosclerotic tissues.22 They have demonstrated that despite significant up-regulation of ABCA1 mRNA, ABCA1 protein was markedly reduced in advanced carotid atherosclerotic lesions showing discordance between ABCA1 gene and protein expression.22 However, they have reported no differences in leukocyte ABCA1 mRNA expression of patients with atherosclerosis as compared to controls.22 Similar finding has been reported in AMI patients with and without type 2 diabetes.19 While Deminia et al (2011) have demonstrated decreased ABCA1 mRNA expression of PBMNCs in patients with atherosclerosis.23 However, mRNA levels do not necessarily reflect protein expression. In the present study, in healthy subjects with low HDL-C, rise in ABCA1 gene expression in PBMNCs suggests an effort by cells to compensate ABCA1 transcript but it was not converted into protein levels.

Conclusion

ABCA1 controls the rate-limiting step in HDL particle formation and is therefore an attractive molecular target for raising HDL-C levels and as protection against atherosclerosis. In the present study up-regulation of ABCA1 protein failed to translate into ABCA1 protein. This implies that pharmacological targeting of ABCA1 gene expression pathway may not achieve the anticipated atherosclerotic protective effect and suggests some defect at translational and post translational level which needs to be further explored.

Acknowledgments

The authors acknowledge Sir H. N. Medical Research Society for financial support. Sir H. N. Hospital and Research Centre, Mumbai, and Rajawadi Hospital, Mumbai, for enrolling the patients in our study. Authors express sincere gratitude towards Reliance Life Sciences Centre, Navi Mumbai, for their permission to use Real Time PCR System. We gratefully acknowledge Ms. Anika Seth, Reliance Life Sciences, Navi Mumbai for her technical expertise.

Conflicts of interest

There were no financial interest or conflict of interest.

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