Detection of IgG-bound lipoprotein(a) immune complexes in patients with coronary heart disease.

BACKGROUND: LDL-immune complexes (IC) have a powerful pathogenic role for inducing foam cell formation in vitro more efficiently than any other known mechanism. Studies have also shown that plasma LDL-IC concentration is a powerful marker for the development of atherosclerosis. The structure, fatty acid composition and antioxidant concentrations of Lp(a) and LDL are quite similar. The same oxidation pattern has also been described for both lipoproteins. Modified forms of Lp(a), some resembling oxidized Lp(a), have been identified in human atheromatous lesions. The existence of autoantibodies against MDA-Lp(a) in vivo is also presented. Therefore, we suppose that Lp(a) might trigger an immune response leading to the production of autoantibodies and subsequently to the formation of immune complexes. This study examined the existence of IgG-bound Lp(a)-IC and investigated its value as a risk factor for the development of atherosclerosis. METHODS: We developed two "sandwich" ELISAs for measuring plasma Lp(a)-IC and LDL-IC concentrations, using anti-human IgG(Fab) as the capture antibody, and quantitating with monoclonal anti-apo(a) or anti-apoB enzyme conjugate. Their concentrations were studied in 160 patients with coronary heart disease (CHD) and 290 control subjects. RESULTS: Plasma TC, LDL-C, TG and apoB concentrations in CHD patients were all significantly increased, whereas HDL-C and apoAI concentrations were decreased. The Lp(a) concentrations in the patients with CHD were also significantly different from those of control (262.4+/-220.0 vs. 211.3+/-199.4 mg/l, P<0.005). Plasma Lp(a)-IC (2.24+/-1.71 vs. 1.62+/-1.50 AU, P<0.0001) and LDL-IC (2.77+/-1.29 vs. 1.40+/-0.92 AU, P<0.0001) concentrations in patients with CHD were both significantly higher than those of control. The relationships between Lp(a)-IC, LDL-IC concentrations and other lipid traits in all the studied subjects (n=450) were carried out. LDL-IC concentrations were positively correlated with LDL-C, apoB, TC, TG and Lp(a) concentrations, while negatively correlated with HDL-C and apoAI concentrations, respectively. Similarly, Lp(a)-IC concentrations were positively correlated with Lp(a), LDL-C, apoB and TC concentrations, while negatively correlated with HDL-C and apoAI concentrations, respectively. Furthermore, a significantly positive relation between LDL-IC and Lp(a)-IC concentrations was also found (r=0.313, P<0.0001). CONCLUSIONS: We report the existence of Lp(a)-IC in both the plasma of patients with CHD and control subjects. Lp(a)-IC concentration increases in the CHD patients.

CETP gene mutation (D442G) increases low-density lipoprotein particle size in patients with coronary heart disease.

BACKGROUND: Small, dense low-density lipoprotein (LDL) in subjects with the atherogenic pattern B has been established as a risk factor of atherosclerosis. Cholesteryl ester transfer protein (CETP) plays an important role in the transfer and exchange of cholesteryl esters and triglycerides between the lipoprotein classes of human plasma. It has been shown that CETP can also change the particle size of high-density lipoprotein (HDL) and LDL subfractions in vitro. Previous clinical studies about CETP gene mutations mainly focused on abnormalities in HDL, few involved those in LDL. OBJECTIVES: To investigate the effect of the D442G mutation in the CETP gene on major peak size of LDL particles in patients with coronary heart diseases (CHD). METHODS: D442G mutation in the CETP gene was detected using the PCR-RFLP. LDL particles sizes were analyzed by 2-16% nondenaturing polyacrylamide gradient gels in CHD patients with D442G mutation in the CETP gene. RESULTS: Six heterozygotes and one homozygote were found to have the D442G mutation among 200 CHD patients. The frequency of this mutation was 3.5%. The major peak size of LDL in patients with gene mutation (n=7) was significantly larger than that in patients without the mutation (n=40) (26.92 +/- 0.79 nm vs. 25.71 +/- 0.66 nm, respectively; P<0.01). All the patients with the gene mutation expressed pattern A, whereas only about half of the patients without the mutation expressed this pattern. The patients with gene mutation had decreased plasma CETP concentration, while increased concentration of HDL-C and apolipoprotein A-I compared with controls. CONCLUSIONS: CETP gene mutation (D442G) increases LDL particle size. This suggests that CETP play an antiatherogenic role.

Cholesteryl ester transfer protein levels and gene deficiency in Chinese patients with cardio-cerebrovascular diseases.

OBJECTIVE: To detect cholesteryl ester transfer protein (CETP) levels, frequencies of CETP D442G and I 14A mutations and characteristics of abnormal lipids in patients with cardio-cerebro vascular diseases. METHODS: Ninety-four myocardial infarction (MI) patients, 110 stroke patients and 335 healthy controls were selected. The CETP concentration was determined using ELISA. The CETP activity was measured using a substrate of (14)C-radiolabeled discoidal bilayer particles. The CETP gene mutations were detected by PCR-RFLP. RESULTS: The CETP concentrations in the MI and stroke group, were higher than those in the controls. The gene mutation frequencies of D442G in the MI, stroke and control group were 3.5%, 3.6% and 5%, respectively, and the frequencies of I 14A were 1.05%, 0.91% and 1%, respectively. One case of D442G homozygote was detected in the healthy group. The frequency of two CETP gene mutations showed no significant difference among the patients and controls. The CETP concentration and activity in subjects with CETP mutations were one-third of those in the control group. The level of HDL-C, apo-A1 increased in the mutation subjects, while the TG level decreased. CONCLUSIONS: The CETP level increased significantly in patients with cardio-cerebrovascular diseases. The carriers of CETP deficiency had CETP and lipid abnormalities.