Lipoprotein (a), low-density,intermediate-density lipoprotein,and blood pressure in a young male population

Summary Both hypercholesterolemia and hypertension are risk factors for atherosclerotic vascular disease, and elevated cholesterol levels occur more frequently than expected in patients with hypertension. Elevated levels of intermediate-density lipoproteins (IDL) and low-density lipoproteins (LDL) were shown to be atherogenic, and LDL, comprising the major cholesterol-carrying fraction in human plasma, are structurally related to lipoprotein (a) [Lp(a)], a further risk factor for atherosclerosis. In the present study we investigated 200 male employees (mean age 26±7 years) to determine whether the relationship of IDL and Lp(a) to systemic blood pressure is similar to the reported correlations between total and LDL cholesterol and systemic blood pressure. To this end blood pressure was measured several times in each individual, and lipids, lipoprotein-cholesterol, apolipoprotein B (apo B), and Lp(a) were determined in fasting serum. IDL cholesterol and apo B, the main protein component of IDL and LDL correlated with blood pressure. However, levels of Lp(a) correlated neither with systolic or diastolic blood pressure nor with lipoprotein cholesterol, body weight, or age. Although IDL and Lp(a) are considered lipoprotein risk factors for atherosclerosis, levels of Lp(a), unlike IDL, are not related to blood pressure, body weight, or age. Our data suggest different metabolic and pathophysiological mechanisms of the risk factors, IDL, LDL, and Lp(a).Abbreviations VLDL very low density lipoprotein - IDL intermediate-density lipoprotein - LDL low-density lipoprotein - ApoB Apolipoprotein B - Lp(a) lipoprotein (a) - BMI body mass index Dedicated to Prof. Dr. N. Zöllner on the occasion of his 70th birthday     

Apolipoprotein(a) phenotypes and lipoprotein(a) concentrations in patients with hyperthyroidism

Lipoprotein(a) [Lp(a)] is a low-density lipoprotein (LDL) particle in which apolipoprotein B-100 (apoB) is attached to a glycoprotein called apolipoprotein(a) [apo(a)]. Apo(a) has several genetically determined phenotypes differing in molecular weight, to which Lp(a) concentrations in plasma are inversely correlated. High plasma levels of Lp(a) are associated with atherosclerotic diseases. It is therefore of interest to study whether factors other than the apo(a) gene locus are involved in the regulation of Lp(a) concentrations. We measured plasma concentrations of Lp(a) and other lipoproteins and determined apo(a) phenotypes in 31 patients with hyperthyroidism, before and after the patients had become euthyroid by treatment. The mean concentration of LDL cholesterol rose from 2.67 to 3.88 mmol/l (P<0.01), apoB rose from 0.79 to 1.03 g/l (P<0.01), and the median Lp(a) concentration increased from 9.74 to 18.97 mg/dl (P<0.01) on treatment. Lp(a) concentrations were inversely associated to the size of the apo(a) molecule both before (P< 0.01) and after treatment (P<0.01). The increase in Lp(a) was significant patients with high molecular weight apo(a) phenotypes (n = 9; P<0.01) and in patients with low molecular weight apo(a) phenotypes (n=16; P< 0.01), but not in those with apo(a) null types (n = 6; P = 0.5). The low levels LDL cholesterol and apoB in untreated hyperthyroidism may result from increased LDL receptor activity. The increase in Lp(a) levels were not correlated with the increase in LDL cholesterol or apoB. Most other clinical evidence indicates that the LDL receptor is not important in Lp(a) catabolism, and we suggest that the low Lp(a) levels seen in thyroid hormone excess are caused by an inhibition of Lp(a) synthesis.Abbreviations Lp(a) lipoprotein(a) - apo(a) apolipoprotein(a) - apoB apolipoprotein B-100 - LDL low-density lipoprotein - HDL high-density lipoprotein - TG triglycerides - T ₄ thyroxine - T ₃ triiodothyronine - TSH thyrotropin     

LDL-unbound apolipoprotein(a) and carotid atherosclerosis in hemodialysis patients

High lipoprotein{a) [Lp(a)] plasma concentrations, which are genetically determined by apo(a) size polymorphism, are directly associated with an increased risk for atherosclerosis. Patients with end-stage renal disease (ESRD), who show an enormous prevalence of cardiovascular disease, have elevated plasma concentrations of Lp(a). In recent studies we were able to show that apo(a) size polymorphism is a better predictor for carotid atherosclerosis and coronary artery disease in hemodialysis patients than concentrations of Lp(a) and other lipoproteins. Less than 5% of apo(a) in plasma exists in a low-density lipoprotein (LDL)-unbound form. This “free” apo(a) consists mainly of disintegrated apo(a) molecules of different molecular weight, ranging from about 125 to 360 kDa. LDL-unbound apo(a) molecules are elevated in patients with ESRD. The aim of this study was therefore to investigate whether the LDL-unbound form of apo(a) contributes to the prediction of carotid atherosclerosis in a group of 153 hemodialysis patients. The absolute amount of LDL-unbound apo(a) showed a trend to increasing values with the degree of carotid atherosclerosis, but the correlation of Lp(a) plasma concentrations with atherosclerosis was more pronounced. In multivariate analysis the two variables were related to neither the presence nor the degree of atherosclerosis. Instead, the apo(a) phenotype took the place of Lp(a) and LDL-unbound apo(a). After adjustment for other variables, the odds ratio for carotid atherosclerosis in patients with a low molecular weight apo(a) phenotype was about 5 (p < 0.01). This indicates a strong association between the apo(a) phenotype and the prevalence of carotid atherosclerosis. Finally, multivariate regression analysis revealed age, angina pectoris and the apo(a) phenotype as the only significant predictors of the degree of atherosclerosis in these patients. In summary, it seems that LDL-unbound apo(a) levels do not contribute to the prediction of carotid atherosclerosis in hemodialysis patients. However, this does not mean that “free”, mainly disintegrated, apo(a) has no atherogenic potential.     

Apolipoprotein E phenotype and lipoprotein(a) in familial hypercholesterolaemia implication for lipoprotein(a) metabolism

The mechanisms regulating plasma levels of lipoprotein(a) [Lp(a)] are largely unknown. A two- to three-fold increase in Lp(a) levels in patients with familial hypercholesterolaemia (FH) has implied that LDL receptor activity may be an important factor in determining plasma Lp(a) levels, as it is in determining low-density lipoprotein (LDL) cholesterol concentration. Common apolipoprotein E (apoE) variants also affect plasma LDL cholesterol levels. We therefore examined the effect of the common apoE variants on plasma Lp(a) levels in 149 patients with heterozygous FH. Patients with the apoE₂ allele (n = 11) had significantly higher plasma levels of LDL cholesterol compared to those with a apoE₃E₃ phenotype, while patients with the apoE₄ isoform had similar levels. However, there was a significant effect of the apoE₂ allele in lowering Lp(a) levels, compared to the apoE₃E₃ group. The median Lp(a) concentration in patients possessing an apoE₂ isoform was 13.1 mg/dl below the median, while in those with an apoE₄ allele the median Lp(a) levels were 4.13 mg/dl higher. There was a marked inverse correlation between plasma Lp(a) and LDL cholesterol concentration in the FH patients carrying the apoE₂ allele. Our data imply that difference in Lp(a) levels observed between FH patients with different apoE isoforms does not result from altered clearance of Lp(a) via the LDL receptor pathway, and suggest that apoE mediated hepatic up-take, or conversion, of remnant particles may be determining Lp(a) production rate.Abbreviations apo apoprotein - CHD coronary heart disease - FH familial hypercholesterolaemia - HDL high-density lipoprotein - LDL low-density lipoprotein - Lp(a) lipoprotein(a)     

Clinical features of type III hyperlipoproteinemia: analysis of 64 patients

Summary The clinical and biochemical characteristics of type III hyperlipoproteinemia are described in 64 patients (35 males and 29 females). Homozygosity for apolipoprotein E2, the presence of an abnormally cholesterol-rich very low density lipoprotein fraction (-VLDL) and an elevated ratio of very low density lipoprotein cholesterol to plasma triglycerides (>0.3; normal ratio about 0.2) were the basis for the diagnosis. Mean serum cholesterol and triglyceride concentrations at the first visit in the clinic were 426 ± 221 and 719 ±996 mg/dl, respectively. The mean age at diagnosis of the disorder was 49 years in males and 53 years in females. There was a high prevalence of obesity (72%), xanthomas (42%), and atherosclerosis (39%), especially peripheral vascular disease (31%). Early and correct diagnosis of this familial lipoprotein disorder seems necessary because of the prompt and beneficial response to therapeutic interventions.Abbreviations Apo apolipoprotein - BMI body mass index - CAD coronary artery disease - HDL high-density lipoproteins - HLP hyperlipoproteinemia - HMG CoA 3-hydroxy-3-methylglutaryl coenzyme A - LDL low-density lipoproteins - Lp(a) lipoprotein (a) - PVD peripheral vascular disease - TG triglycerides - VLDL very low density lipoproteins     

Genetic-epidemiological studies of apolipoprotein(a) polymorphism and its significance in nephrological diseases and type I diabetes mellitus

Lipoprotein(a) is a highly atherogenic particle. The plasma concentrations of this lipoprotein are strongly related to a genetically determined size polymorphism of apolipoprotein(a). This article reviews some pathogenetic characteristics of the apolipoprotein(a) polymorphism besides its known effect on the lipoprotein(a) plasma concentrations. Those are the relation of the apolipoprotein(a) phenotype with atherogenesis, the apolipoprotein(a) phenotype-specific elevation of lipoprotein(a) in hemodialysis patients and the advantages of this polymorphism for the atherosclerosis risk evaluation in high-risk patients. It furthermore discusses the observed association between the low molecular weight apolipoprotein(a) phenotype and Type I diabetes mellitus.     

Treatment of patients with familial defective apolipoprotein B-100 with pravastatin and gemfibrozil: a two-period cross-over study

Thirty patients with familial defective apolipoprotein B-100 were treated in a two-period (8 weeks each) cross-over study with pravastatin and gemfibrozil. Cholesterol, LDL cholesterol, and apo B were reduced by 20–25% (P < 10^–4) by pravastatin and by 4–6% by gemfibrozil (pravastatin vs. gemfibrozil:P < 10^–4). Response to pravastatin was variable and not correlated to gender, age, or apo E genotype. Gemfibrozil lowered triglycerides by 25% (P < 10^–4) and raised HDL cholesterol by 11%. The effects of pravastatin on these two interrelated variables were significantly smaller. Both drugs increased Lp(a) significantly by about 10%. The LDL cholesterol lowering effect of pravastatin in patients with FDB is similar to that observed in patients with familial hypercholesterolemia.Abbreviations FDB familial defective apolipoprotein B-100 - LDL low density lipoprotein - VLDL very low density lipoprotein - HDL high density lipoprotein - LDL-R low density lipoprotein receptor - HMG CoA -hydroxy--methyl-glutaryl coenzyme A - FH familial hypercholesterolemia - TG triglycerides - apo B apolipoprotein B-100 - apo Al apolipoprotein Al - apo E apolipoprotein E - Lp(a) lipoprotein(a) - PCR polymerase chain reaction Correspondence to: P.S. Hansen     

Vascular accumulation of Lp(a): in vivo analysis of the role of lysine-binding sites using recombinant adenovirus

Despite the importance of lipoprotein(a) [Lp(a)] as an atherogenic risk factor, very little information, especially from in vivo studies, is available concerning which structural features of apo(a) contribute to the interactions of Lp(a) with the vessel wall and its proatherogenic properties. Nearly all the proposed and proven activities of apolipoprotein(a) [apo(a)] focus on its high degree of sequence homology with plasminogen and the possibility that structural features shared by these two molecules contribute to the atherogenesis associated with high Lp(a) plasma levels in humans. In these studies, we examined the properties of three forms of Lp(a) differing at postulated lysine-binding domains contained in the constituent apo(a). We used the recombinant adenoviral gene delivery system to produce apo(a) in the plasma of human apoB transgenic mice, resulting in high levels of Lp(a) similar to those found in the plasma of humans. By comparison of in vitro lysine-binding properties of these forms of Lp(a) with measurements of Lp(a) vascular accumulation in the mice, we have demonstrated that lysine-binding defective forms of Lp(a) have a diminished capacity for vascular accumulation in vivo.     

Lipoprotein (a) in patients on hemodialysis

Lipoprotein (a) [Lp(a)] may produce thrombogenic effects by modulating the fibrinolytic system. Elevated levels of Lp(a) have also been associated with an increased risk for atherosclerosis. Because atherosclerosis is more prevalent among patients with end-stage renal disease, the role of Lp(a) among patients on hemodialysis is analyzed. Twenty patients were studied. Lp(a) was measured before and after a hemodialysis session and before the following session. Between the first and second measures there was no statistical difference but when first and third measures were compared, a statistical difference (increase) was found. In conclusion, changes in Lp(a) levels were found and perhaps these changes are related to the episodic inflammation affecting patients on hemodialysis. The significance of these changes and the role in accelerating atherosclerosis in patients with end-stage renal disease are unknown.     

Apolipoprotein(a) isoform-specific changes of lipoprotein(a) after kidney transplantation

The atherogenic lipoprotein(a) (Lp(a)) is significantly increased in patients with kidney disease. Some studies in hemodialysis patients described this increase to be dependent on the genetic apolipoprotein(a) (apo(a)) isoforms. Only patients who express high molecular weight (HMW) apo(a) isoforms but not those with low molecular weight (LMW) isoforms show a relative increase of Lp(a) when compared to healthy controls matched for apo(a) isoforms. However, this was not confirmed by all studies. We therefore prospectively investigated the changes of Lp(a) deriving from each apo(a) isoform in heterozygotes following kidney transplantation. Lp(a) concentrations were measured by ELISA. To calculate the isoform-specific concentrations and the changes of Lp(a) deriving from each isoform, we densitometrically scanned the apo(a) bands from immunoblots before and after transplantation in 20 patients expressing two apo(a) isoforms. Of these, 10 patients expressed both an LMW and an HMW apo(a) isoform. The other 10 patients expressed only HMW isoforms. Densitometric scanning of apo(a) bands and calculation of isoform-derived Lp(a) concentrations clearly demonstrated that the decrease of Lp(a) following kidney transplantation is caused by changes in the expression of HMW apo(a) isoforms. In some patients, we observed an almost complete disappearance of the HMW apo(a) isoform after transplantation. This study clearly demonstrates that the changes of Lp(a) plasma concentrations in kidney disease depend on the genetically determined size of apo(a). This provides evidence for an interaction of apo(a) genetic variability and kidney function on Lp(a) concentrations.     

Lipoprotein(a): risk factor for atherosclerotic vascular disease important to take into account in practice

Coronary artery disease is a leading cause of death in France. Some of its risk factors are well identified such as age, smoking, high blood pressure and dyslipidemia, but some others such as lipoprotein (a) (Lp(a)) are still under investigation. Lp(a) is an LDL-like particle to which is linked an apolipoprotein (a). The latter shows a high sequence homology with plasminogen that gives Lp(a) thrombogenic properties in addition to its atherogenic capacity. Many epidemiological studies have shown that a high plasma level of Lp(a) is a risk factor for coronary, cerebral and peripheral atherosclerosis. Out of thirteen prospective studies, ten have confirmed this result. The negative results from the three remaining studies were probably due to either the inadequate storage of the samples or the preventive drug treatment given to the patients during the studies and to the lack of standardization of Lp(a) assays. More over it has been shown that beside high plasma Lp(a) level, the presence of a low molecular weight Apo(a) isoform is also related to a higher incidence of coronary artery disease. This review of the literature clearly demonstrates the relationship between Lp(a) and atherosclerosis, and the need to measure Lp(a) in order to better evaluate the risk of atherosclerotic vascular disease especially in patients with a hyper LDLemia an early cardio- or cerebrovascular disease or a family history of atherosclerosis. Management of patients with high Lp(a) concentrations should be directed at minimizing all other risk factors for atherosclerotic disease.     

High plasma levels of apo(a) fragments in Caucasians and African-Americans with end-stage renal disease: implications for plasma Lp(a) assay

Apolipoprotein(a) [apo(a)] is a plasma glycoprotein that is highly polymorphic in size due to differences in the number of a tandemly arrayed cysteine-rich repeat called kringle (K)4 at its N-terminus. Most plasma apo(a) is covalently attached to apolipoprotein B-100 and circulates as part of lipoprotein(a) [Lp(a)]. A fraction of apo(a) circulates free of lipoproteins. Almost all of the free apo(a) consists of fragments containing variable numbers of K4 repeats derived from the N-terminal region. Previously we provided evidence suggesting that the apo(a) fragments present in human plasma are the source of the apo(a) fragments in human urine. If this were the case, it would be expected that plasma levels of fragments would be higher in subjects with end-stage renal disease (ESRD). In this paper we quantified the levels of apo(a) fragments and plasma Lp(a) in 26 Caucasian and 26 African-American subjects with ESRD and 52 healthy subjects matched for race, sex and the size of the apo(a) isoforms. The plasma levels of apo(a) fragments and Lp(a) were both higher in the ESRD subjects. In addition, the ratio of apo (a) fragments to total immunodetectable apo(a) was increased in ESRD. To determine how much the increase in the apo(a) fragments contributed to the increase in plasma Lp(a) in ESRD, the plasma Lp(a) levels were measured employing two different anti-apo(a) enzyme-linked immunoabsorption assays (ELISA). One assay detected both free and bound apo(a), whereas the other assay detected only bound apo(a). Although the plasma levels of apo(a) in the ESRD subjects tended to be higher using the assay that detected both fragments and full-length apo(a), the increase was modest. Thus, although a greater proportion of the apo(a) in ESRD plasma circulates as fragments, most of the elevation in plasma levels of Lp(a) associated with renal insufficiency is due to an increase in intact Lp(a).     

Elevated endothelin levels in patients with hyperlipoproteinemia

We determined lipoproteins, apolipoproteins, and endothelin in 98 patients (58 female and 40 male, age 18–72 years) with hyperlipidemia (plasma cholesterol > 2.5 g/l and/or triglycerides > 2.0 g/1) and in 50 healthy subjects (20 female, 30 male, age 19–68 years). In patients with hyperlipidemia endothelin levels were elevated compared to healthy controls. Patients with plasma cholesterol above 2.5 g/l had higher Endothelin and lipoprotein(a) concentrations than patients with plasma cholesterol levels less than 2.5 g/l. A positive correlation was found between the concentrations of endothelin and apolipoprotein B (r = 0.2137; P < 0.013). Smoking patients with lipoprotein (a) above 300 mg/l had higher endothelin levels than both nonsmoking patients with lipoprotein (a) above 300 mg/l and smokers with normal lipoprotein(a). In smokers endothelin correlated positively with Lp(a) (r = 0.709; P < 0.01). No correlation was found between endothelin and triglycerides nor between endothelin and age or sex. The results suggest that the vasoconstrictor endothelin contributes to the increased vasal tone in hyperlipidemia. Because endothelin also has mitogenic properties, it may play a relevant role in the development of premature atherosclerosis in patients with hyperlipidemia.Abbreviations apo apolipoprotein - EDRF endothelium-derived relaxing factors - EDCF endothelium-derived contractile factors - LDL low density lipoproteins - HDL high-density lipoproteins - Lp(a) lipoprotein(a) Correspondence to: T. Haak     

Comparative long-term experience with immunoadsorption and dextran sulfate cellulose adsorption for extracorporeal elimination of low-density lipoproteins

Two low-density lipoprotein (LDL) apheresis methods allowing a specific extracorporeal removal of atherogenic lipoproteins from plasma were compared concerning their efficacy and safety in the long-term therapy of severe familial hypercholesterolemia. Five patients were treated with immunoadsorption (IMA) at weekly intervals over 3 years each, and three patients received weekly therapy with dextran sulfate cellulose adsorption (DSA) for up to 2 years. The mean plasma volume processed per session to decrease total cholesterol to a target level of 100–150 mg/dl at the end of LDL apheresis was significantly lower in DSA than in IMA: 143% vs. 180% of the individual plasma volume. Both LDL apheresis procedures achieved a mean acute reduction of plasma LDL cholesterol by more than 70%. The average interval concentrations of plasma LDL cholesterol obtained without concomitant lipid-lowering medication were 151 ± 26 mg/dl compared to 351 ± 65 mg/dl at baseline in the IMA-treated patients and 139 ± 18 mg/dl compared to 359 ± 48 mg/dl at baseline in the DSA-treated patients. Two patients from the DSA group died after 2 years of study participation due to a stroke and a sudden cardiac death several days after the last plasma therapy. Treatment-related side effects were infrequent. Long-term therapy with IMA and DSA was associated with symptomatic improvement of coronary artery disease and mobilization of tissue cholesterol deposits. Analysis of coronary angiograms after 3 years of weekly LDL apheresis with IMA revealed in five patients nearly identical atherosclerotic lesions without definite regression or progression.Abbreviations LDL low-density lipoprotein - IMA immunoadsorption - DSA dextran sulfate cellulose adsorption - apo apolipoprotein - Lp(a) lipoprotein(a) - HDL high-density lipoprotein - ACE angiotensin-converting enzyme     

Metabolism and clinical significance of lipoprotein Lp(a) (author's transl)

With sensitive methods, the lipoprotein Lp(a) can be demonstrated in the serum of all human subjects, except patients with abetalipoproteinaemia. A high serum level of Lp(a) is considered as a risk factor for atherosclerotic vascular disease (coronary heart disease). The chemical and physical properties of Lp(a) are very similar to those of low density lipoproteins (LDL, Lp-B). In contrast to LDL, Lp(a) has an additional apolipoprotein, the specific Lp(a) antigen. From in vivo studies with 125I-labeled lipoproteins, the following conclusions can be drawn: 1. Lp(a) is not a metabolic product of other apolipoprotein B-containing lipoproteins. Apparently, Lp(a) is synthesized as a separate lipoprotein. 2. Lp(a) is not catabolized to other lipoproteins. Lp(a) leaves the plasma as an intact particle. 3. The fractional catabolic rate and the distribution between the intra- and extravascular compartment are similar for Lp(a) and LDL. 4. The serum level of Lp(a) is primarily determined by the synthetic rate and not by the catabolic rate.     

Complement activation in patients with renal failure as detected through the quantitation of fragments of the complement proteins C3, C5, and factor B

Summary Using sensitive and highly specific enzyme-linked immunosorbent assays fragments of the complement proteins C3, C5, and factor B were quantitated in patients with renal failure. During hemodialysis on new cuprophan membranes raised levels not only of C3a, but in addition of activated C3, C5a, and Ba were demonstrated. In patients with chronic renal failure and end-stage renal disease plasma concentrations of Ba and activated C3 were markedly elevated independent of hemodialysis. This finding is taken as an indication of a continuous recruitment of the alternative pathway of complement in these patients. As the detected complement protein fragments are known to exert immune regulatory functions these findings may imply that these peptides are involved in the maintenance of the immune suppressed state in renal failure.Abbreviations ABTS 2.2 azino-di (3-ethyl-benzthiazoline sulfonate) - actC3 activated C3 - APC alternative pathway of the complement system - CPC classial pathway of the complement system - CRF chronic renal failure - EDTA ethylenediaminetetraacetic acid - ELISA enzyme-linked immunosorbent assay - ESRD end-stage renal disease - mAb monoclonal antibody     

Possible association between genetic variability at the apolipoprotein(a) locus and Alzheimer's disease in apolipoprotein E2 carriers

Apolipoprotein(a) (Apo(a)) is a glycoprotein that is linked by a disulfide bond to apolipoprotein B on low density lipoprotein particles to form lipoprotein(a) (Lp(a)). High plasma levels of Lp(a) are thought to contribute directly to the development of atherosclerosis. We tested a variant (T3888P) located in the Kringle-IV region of Apo(a) in a case-control series. Overall, there were no differences between case and controls. However, in the apoE2 positive subgroup, we noticed that the mutant allele is over-represented in the cases (P=0.005). We suggest that this polymorphism and others at the Apo(a) locus be further studied in relation to Alzheimer's disease.     

Plasma lipids, lipoproteins, and apolipoproteins in Nigerian diabetes mellitus, essential hypertension, and hypertensive-diabetic patients.

Plasma lipids, lipoproteins, and apolipoproteins were assessed in three groups of Nigerians at increased risk for atherosclerotic heart disease. The three patient groups, diabetes mellitus (n = 15), essential hypertension (n = 12), and hypertensive-diabetes mellitus (n = 11), were compared with age-matched, apparently healthy controls (n = 14). In subjects with diabetes mellitus, triglyceride and its related apolipoproteins CIII and CIII:NonB were significantly higher than controls. High-density lipoprotein cholesterol (HDL-C) was significantly lower; its related ratios, total/HDL-C and low-density lipoprotein cholesterol (LDL-C)/HDL-C were significantly higher than those for controls. Subjects with hypertension and hypertensive-diabetes mellitus had significantly higher values than controls for those lipids and lipid fractions considered atherogenic (total cholesterol, LDL-C, triglyceride, and the total/HDL-C and LDL-C/HDL-C ratios) as well as apolipoproteins B, CIII, and lipoprotein particles Lp(a) and CIII:NonB. Only hypertensive-diabetes mellitus subjects had lower HDL-C levels, while hypertension patients had significantly higher apolipoprotein AI and LpAI concentrations than controls. Subjects with hypertensive-diabetes mellitus had significantly worse lipid, lipoprotein, and apolipoprotein profiles both in terms of increased atherogenic and reduced anti-atherogenic parameters compared with subjects with diabetes mellitus or hypertension only. These studies suggest that Nigerians with diabetes, hypertension, and especially both hypertension and diabetes need to be fully evaluated from a lipid and lipoprotein standpoint, and any abnormalities detected need to be taken into consideration during therapy of this group of high-risk patients.     

Lipoprotein(a). A potential bridge between the fields of atherosclerosis and thrombosis

Lipoprotein(a) (Lp[a]) represents a class of plasma lipoprotein particles that have overall characteristics similar to low-density lipoproteins but distinct from them by having apolipoprotein B100 linked to apolipoprotein(a) by disulfide bridge(s). This protein has recently been shown to have a striking amino acid sequence homology with plasminogen, a serine protease zymogen that on activation to plasmin promotes the conversion of fibrinogen to fibrin. The high incidence of Lp(a) in the plasma of patients with cardiovascular disease has been noted by many investigators. The new knowledge being rapidly acquired on the structure of Lp(a) should facilitate the understanding of the mechanism of its atherogenicity and perhaps shed light on its possible physiologic role.