Significance of ABCA1 in human carotid atherosclerotic plaques

  • Authors:
    • Heang-Fang Liu
    • Ke-Fei Cui
    • Jian-Ping Wang
    • Min Zhang
    • Ya-Pei Guo
    • Xue-Yuan Li
    • Chao Jiang
  • View Affiliations

  • Published online on: May 15, 2012     https://doi.org/10.3892/etm.2012.576
  • Pages: 297-302
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Abstract

The ATP-binding cassette transporter A1 (ABCA1) is an important effector in the regulation of cholesterol efflux from cells. In this study, we assessed the role of ABCA1 in human carotid atherosclerotic plaques (CAPs). We found that ABCA1 and retinoid X receptor α (RXRα) mRNAs were significantly increased in the atherosclerotic plaques compared to control arteries. The increased ABCA1 mRNA correlated with that of RXRα in plaques. According to the modified American Heart Association plaque classification, atherosclerotic specimens were assigned to three grades, and ABCA1 and RXRα mRNA levels were compared across plaques of different grades. Resultantly, plaques of grade Ⅱ and Ⅲ exhibited higher mRNA levels than grade Ⅰ, but there was no difference in mRNA levels between plaques of grade Ⅱ and Ⅲ. By contrast, ABCA1 and RXRα protein levels were notably reduced in plaques relative to control tissues. Similarly, plaques of grade Ⅱ and Ⅲ exhibited lower ABCA1 and RXRα protein levels than grade Ⅰ, and there was no difference in protein levels between plaques of grade Ⅱ and Ⅲ. Our findings suggest that decreased ABCA1 protein plays a key role in the pathogenesis of CAP; the regulation of ABCA1 may be mediated by RXRα and ABCA1 mRNA levels may serve as an indicator for plaque stability.

Introduction

Carotid atherosclerotic plaque (CAP) is a predominant established risk factor for stroke, which is associated with high morbidity and mortality (1). Although the development of carotid plaques is influenced by environmental factors, such as elevated blood pressure and serum lipoprotein abnormalities (2), studies have been increasingly focusing on the genetic causes associated with the formation of atherosclerosis. ATP-binding cassette transporter 1 (ABCA1) has been recognized as a major mediator in the initial step of the reverse cholesterol transport, and was shown to facilitate the efflux of cholesterol and phospholipids to lipid-poor apolipoproteins (apo)A-I and apoE from peripheral cells, resulting in the formation of nascent or pre-high-density lipoprotein (HDL) (3,4). Such a cholesterol efflux process prevents the accumulation of cholesterol or oxidative low-density lipoprotein (LDL) in peripheral cells, including macrophages within the arterial wall and, therefore, reduces the accumulation of atherosclerotic plaque.

ABCA1 deficiency was indentified to be responsible for Tangier disease and familial HDL deficiency. These conditions are characterized by low levels of HDL, excessive deposition of cholesteryl esters in tissue macrophages and an increased risk for atherosclerotic disease (5). The underlying mechanism is thought to result from the failure of ABCA1 to transport cholesterol and phospholipids out of cells to form complexes with apolipoproteins to generate HDL (6). The intracellular sterol accumulation and subsequent development of foam cells may, as a result, lead to the atheromatous plaque. Due to its important role in atherosclerosis, increasing attention has been focused on ABCA1, so that therapeutic interventions are introduced to regulate its expression and therefore reduce the development of atherosclerosis.

The expression and significance of ABCA1 have been well reported in animals with ABCA1 overexpression or inactivation (7), as well as in individuals with ABCA1 gene deficiency due to gene mutations (8). Although the systemic effects of loss of function have been well investigated in patients with ABCA1 deficiency, few studies have addressed in detail the possible effect of the transporter on plaque complication in localized atherosclerosis in the absence of familial gene mutations. Identification of the ABCA1 expression in localized lesions may provide new insights into local genetic determinants of atheromatous disease without mutations in the gene and therefore the development of new therapeutic strategies.

In this study, we assessed the expression of the ABCA1 gene and protein in human CAPs and compared it to human arteries obtained from normal controls. Also, we classified the plaques into three grades according to the American Heart Association (AHA) and characterized the ABCA1 expression in the CAPs of different grades. Furthermore, to gain further insight into the regulatory mechanism underlying ABCA1 expression, we determined the expression of one of its key regulators, retinoid X receptor α (RXRα).

Materials and methods

Patients and specimens

We collected CAPs from 48 patients undergoing carotid endarterectomy for symptomatic (transient ischemic attacks, minor strokes) or asymptomatic stenosis >70% confirmed by MR angiography or conventional arteriography. All patients underwent detailed history assessment and a physical examination at baseline that included routine blood biochemistry tests, electrocardiography, chest radiography, ultrasound cardiography, transcranial Doppler sonography, carotid CEMRI, computed tomography, MRI and magnetic resonance angiography of the brain. In addition, the presence of vascular risk factors as well as previous antihypertensive, statin and antiplatelet treatments were recorded (Table I). We also collected 10 inferior mesenteric arteries dissected from colectomy specimens of subjects having elective operation as normal controls. The control patients were assessed for the absence of symptomatic atherosclerotic disease by history and examination.

Table I.

Clinical characteristics of the patients and controls.

Table I.

Clinical characteristics of the patients and controls.

PatientsControls
No.4810
Age (years)56.2±7.355.9±10.1
Gender (male/female)34/147/3
Smokers264
Diabetes120
Hypertension303
Coronary artery disease140
Family history of IHD222
Treatment
  Aspirin201
  Clopidogrel20
  Warfarin40
  Statins140

[i] IHD, ischemic heart disease.

The endarterectomy specimens included the atheromatous plaque, the adjacent intima and the medial layers. The collected 48 specimens were assigned to three grades according to the modified AHA classification (9): 14 cases of grade I (type I and II), which was defined as a diffuse intimal thickening or small eccentric plaque without calcification; 22 cases of grade II (type III and IV), which was described as plaque with a lipid or necrotic core surrounded by fibrous tissue with possible calcification; 12 cases of grade III (type V and VI), presenting complex plaques with a possible surface defect, hemorrhage or thrombus. The control arteries were of full-thickness and consisted of the adventitial layer. Plaques and control arteries were frozen immediately in liquid nitrogen and stored at −80°C until further processing. Sections from control arteries were stained with H&E and assessed by a histopathologist for evidence of age-related atheromatous change.

The study was approved by the Medical Ethics Committee of the Fifth Affiliated Hospital of Zhengzhou University, and informed consent was obtained from each patient.

Reverse transcriptase-polymerase chain reaction (RT-PCR)

The ABCA1 and RXRα mRNA expression levels were determined using semi-quantitative RT-PCR. Total RNA was isolated from freshly isolated pulverized frozen tissue (∼25 mg) with TRIzol reagent (Invitrogen) and solubilized in RNAase-free water. The first-strand cDNA was synthesized from 2 μg of total RNA with PrimeScript Reverse Transcriptase (Takara Bio). The sequences of the specific primers used are shown in Table II. Specific primers for glyceraldehyde-3-phosphate dehydrogenase (GAPDH; Clontech) were added as a control. PCR was carried out by incubating each cDNA sample with primers (0.5 μM each), Blend Taq polymerase (1.25 units; Takara Bio) and a deoxynucleotide. For ABCA1, PCR was run for 35 cycles with 30 sec/94°C denaturation, 40 sec/52°C annealing and 45 sec/72°C elongation. For RXRα, PCR was run for 38 cycles with 30 sec/94°C denaturation, 45 sec/58°C annealing and 40 sec/72°C elongation. Reactions were performed in triplicate and in a total volume of 25 μl. PCR products were electrophoresed on 1% agarose gels. Bands were stained with ethidium bromide (Sigma) and detected with a LAS-3000 mini CCD camera (Fuji Film). The Eagle Eye II analyzer (USA) was used to determine the optical density (OD) of target and reference mRNA. The mRNA levels were recorded as the relative value of the OD of the target gene to that of GAPDH.

Table II.

Sequences of the primers for PCR.

Table II.

Sequences of the primers for PCR.

Forward primer sequenceReverse primer sequenceProduct fragment (bp)
ABCA1 5′-GGGAGGCTCCCGGAGTT-3′ 5′-GTATAAAAGAAGCCTCCGAGCATC-3′302
RXRα 5′-GTATAAAAGAAGCCTCCGAGCATC-3′ 5′-GCGGCGCCTCCAGCATCTCCATA-3′800
GAPDH 5′-TGATGACATCAAGAAGGTGGTGAA-3′ 5′-TCCTTGGAGGCCATGTAGGCCAT-3′238
Western blotting

The content of ABCA1 and RARα protein was detected by western blot analysis. The frozen tissues were pulverized and sonicated in RIPA lysis buffer (Santa Cruz). After centrifugation at 14,000 x g for 30 min at 4°C, 30 μg of the supernatants was separated on 10% SDS-polyacrylamide gel and transferred onto Immobilon-P transfer membrane (Millipore). After being blocked with 5% skim milk, the membrane was incubated with the primary ABCA1 antibody (dilution at 1:1,000; Abcam) or the primary RARα antibody (dilution at 1:1,000; Millipore) at 4°C overnight. Membranes were then treated with anti-rabbit secondary antibody conjugated with horseradish peroxidase (dilution at 1:1,000; Santa Cruz). Complexes on the membranes were then visualized using the Super Signal West Dura Extended Duration Substrate (Pierce Biotechnology Inc.), photographed and analyzed with the Eagle Eye II analyzer. The relative value of the absorbance value of the target protein to the reference protein was recorded.

Statistical analysis

Results are presented as the means ± SEM. Statistical analysis was performed with SAS 9.0. Gender differences between patient and control groups were assessed using the χ2 test. Comparisons in the ABCA1 and RXRα expression between patients and controls were performed using the Student’s t-test or ANOVA. Relations between the ABCA1 and RXRα mRNA were evaluated using Pearson correlations. Differences were considered to denote statistical significance at P<0.05.

Results

Patient demographics

The demographic characteristics of the patients and controls are presented in Table I. There was no significant difference between patients and controls in terms of gender, symptomatic carotid disease, individual or combined risk factors, treatment or coexistence of other vascular disease (Table I).

Expression of ABCA1 mRNA in carotid plaques

Table III summarizes the results for ABCA1 and RXRα mRNA levels in CAPs and control arteries. As expected, ABCA1 mRNA was significantly increased in the plaques compared to controls (Fig. 1). When we compared ABCA1 mRNA expression across plaques of different grades, we found higher ABCA1 mRNA levels in plaques of grade II and III compared to those of grade I (Table III, Figs. 2 and 3). However, ABCA1 mRNA in plaques of grade III was not significantly higher than that of grade II (Table III). To explore the potential underlying mechanism, the RXRα mRNA levels were also determined and correlated to the ABCA1 mRNA expression. As a result, we found a parallel evolving pattern between RXRα and ABCA1 mRNA expression. Furthermore, a significant association between ABCA1 and RXRα mRNA expression levels was observed in the plaques (Fig. 4A), but no correlation was found in the control arteries (Fig. 4B), suggesting the coordinative actions between ABCA1 and RXRα mRNA in the plaques.

Table III.

Expression of ABCA1 and RXRα mRNA in plaques and control arteries.

Table III.

Expression of ABCA1 and RXRα mRNA in plaques and control arteries.

ABCA1 mRNARXRα mRNA
Plaques
  Grade I (n=14)0.67±0.05a0.67±0.03a
  Grade II (n=22) 0.97±0.05a,b 0.95±0.05a,b
  Grade III (n=12)0.77±0.04a0.74±0.04a
Control arteries (n=10)0.37±0.040.39±0.04

a p<0.05 vs. control arteries;

b p<0.05 vs. control arteries.

Expression of ABCA1 protein in carotid plaques

Table IV summarizes the results for ABCA1 and RXRα protein levels in CAPs and control arteries. In contrast to mRNA levels, ABCA1 protein was significantly reduced in the plaques as compared to control arteries (Figs. 5 and 6, Table IV). The plaques of grade II and III exhibited lower ABCA1 protein levels than those of grade I. However, no difference was found in ABCA1 protein levels in plaques of grade II and III (Table IV). A similar evolving pattern was observed in the RXRα protein expression. In the plaques, the RXRα protein levels were significantly reduced as compared to control arteries. Although the RXRα protein levels were significantly lower in plaques of grade II and III compared to grade I, there was no difference between plaques of grade II and III (Table IV).

Table IV.

Expression of ABCA1 and RXRα protein in plaques and control arteries.

Table IV.

Expression of ABCA1 and RXRα protein in plaques and control arteries.

ABCA1 proteinRXRα protein
Plaques
  Grade I (n=14)0.26±0.04a0.31±0.05a
  Grade II (n=22) 0.16±0.05a,b 0.18±0.03a,b
  Grade III (n=12)0.20±0.04a0.27±0.04a
Control arteries (n=10)0.53±0.030.57±0.04

a p<0.05. vs. group B;

b p<0.05. vs. control arteries.

Discussion

In this study, we showed that in CAPs, both ABCA1 and RXRα mRNA levels were significantly increased compared to control arteries, and a parallel correlation between the mRNA levels of both genes was found. In these atherosclerotic tissues, ABCA1 and RXRα mRNA levels in both grade II and III were notably higher than those in grade I, but no significant difference was found in mRNA levels between grade II and III. Despite the up-regulation of mRNA expression, ABCA1 and RXRα protein levels were notably decreased in atherosclerotic plaques. Furthermore, although the plaques of grade I exhibited lower ABCA1 and RXRα protein levels, there was no difference in the levels of both proteins between plaques of grade II and III. These findings seem to be important for improving our understanding of the physiological roles of ABCA1 in localized atherosclerosis without gene mutations, and thus raise the possibility of further new therapeutic interventions targeted at ABC transporters in atherosclerosis.

ABCA1 is a membrane transporter abundant in macrophages that utilize ATP as a source of energy to transport various molecules across membranes; its origin and pathological significance in atherosclerotic tissues was identified in animal studies of ABCA1 inactivation and human gene ABCA1 mutations (10). In these studies, loss of ABCA1 gene function was shown to play a key role in lipid deposition and its sequelae (7,8). In the present study, however, we found a significant increase in ABCA1 gene expression in atherosclerotic tissues. In fact, mRNA levels did not precisely reflect protein expression and, particularly for ABCA1, there was a significant discordance between ABCA1 mRNA and protein levels, implying that post-transcriptional regulation plays a major role in ABCA1 protein expression (11). Since we determined the mRNA and protein levels by analyzing the same specimen, we speculated that, in the control arteries, the presence of ABCA1 protein reflected the expression of the gene. In the CAP specimens, however, markedly lower levels of ABCA1 protein were found compared to control tissues. These findings suggested that, although the ABCA1 transcription was significantly increased in atherosclerotic tissues, its protein expression was not increased, but reduced, in agreement with results published by Albrecht et al (12).

We showed that the plaques of grade II and III exhibited higher ABCA1 mRNA and lower protein levels than those of grade I. In terms of plaque composition, plaques of grade II and III consist of a lipid or necrotic core, which makes them unstable (13). Thus, ABCA1 may serve as an important marker for plaque instability. However, we found no significant difference in both mRNA and protein levels between plaques of grade II and III, suggesting that the unstable plaques may share a similar pattern in ABCA1 distribution. Taking into account that ABCA1 is mainly located in macrophages within the atheromatous lesion (14), the different ABCA1 expression patterns in plaques of different grades may be associated with the composition and microenvironment of the atherosclerotic lesions.

Atherosclerotic plaque is a dynamic structure composed of lipids, cells and extracellular matrix (15). In unstable atherosclerotic lesions (grade II and III), macrophages tend to accumulate large amounts of sterols (16). Increased intracellular sterol concentration in macrophages promotes ABCA1 mRNA expression not only in a time- and dose-dependent fashion (17,18), but also by activating nuclear receptors, such as LXR and RXRα (1921), which may explain the lower mRNA levels in plaques of grade I. Although the accumulated sterol has also been shown to up-regulate ABCA1 protein expression in a dose-dependent fashion (17), it accelerates the ABCA1 degradation in macrophages in a direct and indirect way to a greater extent (22). The sterol-rich environment inside the plaque is amplified by the low ABCA1 levels (23), which in return degrade the ABCA1 protein. Furthermore, ABCA1 has been shown to contain a PEST sequence that enhances protein degradation (24). The similar ABCA1 distribution pattern in plaques of grade II and III may be attributed to the similar composition of the three constituents (15).

The retinoid X receptor (RXR) is a pleiotropic nuclear receptor transcription factor that regulates the expression of its target genes. RXR expressed in macrophages plays an important role in plaque physiology, as it activates and suppresses the ABCA1 gene expression in a RXR-responsive element-dependent manner (25). Previous studies have shown that ABCA1 transcription is stimulated by retinoid X and the LXR receptor (25), and that the induction of ABCA1 expression reflected that of LXRα (12,26). In this study, we found that in atherosclerotic plaques, the ABCA1 and RXRα mRNA levels were significantly elevated, and a parallel increase in mRNA levels of both genes was observed. The observed up-regulation of ABCA1 and RXRα mRNA may be associated with the increased oxysterol concentration in the plaque. The ABCA1 protein may be the key factor that modulates the cholesterol homeostasis in macrophages. The increased degradation of ABCA1 protein in the plaques could result in decreased lipid efflux, accumulation of oxysterol and the stimulation of regulatory pathways through RXRα.

In summary, our findings demonstrate that the ABCA1 protein was notably reduced in atherosclerotic plaques, whereas the ABCA1 and RXRα mRNA levels were significantly increased. The failure of ABCA1 mRNA to translate into ABCA1 protein suggests that new interventions should be targeted at the transcriptional up-regulation of ABCA1 and its protein stabilization. Our results also show that the unstable atherosclerotic plaques exhibited higher ABCA1 mRNA levels, proposing the ABCA1 mRNA as a potential biomarker of a particular subgroup of unstable carotid plaques.

Acknowledgements

This study was supported by grants from the Zhengzhou Committee of Science and Technology (No. 083SGY2612-9).

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August 2012
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Spandidos Publications style
Liu H, Cui K, Wang J, Zhang M, Guo Y, Li X and Jiang C: Significance of ABCA1 in human carotid atherosclerotic plaques. Exp Ther Med 4: 297-302, 2012
APA
Liu, H., Cui, K., Wang, J., Zhang, M., Guo, Y., Li, X., & Jiang, C. (2012). Significance of ABCA1 in human carotid atherosclerotic plaques. Experimental and Therapeutic Medicine, 4, 297-302. https://doi.org/10.3892/etm.2012.576
MLA
Liu, H., Cui, K., Wang, J., Zhang, M., Guo, Y., Li, X., Jiang, C."Significance of ABCA1 in human carotid atherosclerotic plaques". Experimental and Therapeutic Medicine 4.2 (2012): 297-302.
Chicago
Liu, H., Cui, K., Wang, J., Zhang, M., Guo, Y., Li, X., Jiang, C."Significance of ABCA1 in human carotid atherosclerotic plaques". Experimental and Therapeutic Medicine 4, no. 2 (2012): 297-302. https://doi.org/10.3892/etm.2012.576