Inherited quantitative DNA variation in the LPA ("apolipoprotein (a)") gene

The Lp(a) antigen resides in a polypeptide chain that is attached to apolipoprotein B (apoB) by a disulfide bridge. Recently, cDNA for this polypeptide chain (frequently referred to as the Lp(a) polypeptide chain, Lp(a) apolipoprotein or apolipoprotein (a] was cloned and extensive homology to plasminogen was uncovered. This homology creates significant difficulties in studying DNA variation in the gene (the LPA gene) for this polypeptide and the plasminogen gene. We have studied a variant 2 kilobase (kb) DNA fragment detectable after digestion with the restriction enzyme MspI, which appears to originate from the LPA gene since it is detected by LPA probes but not with plasminogen probes. It is related to the "kringle IV" region of the LPA gene since it is detected with an LPA probe that only contains "kringle IV" repeats. A proportion of people appears to lack (or have an undetectable level of) the 2 kb fragment and there are significant quantitative differences between samples from people who have the fragment. Presence and amount of this fragment appear to segregate in families as a Mendelian trait. This quantitative DNA variation is likely to reflect differences between individuals in number of "kringle IV" repeats at the LPA locus.     

The lysine-binding function of Lp(a)

The atherogenicity of Lp(a) is attributable to the binding of its apolipoprotein(a) component to fibrin and other plasminogen substrates. It can attenuate the activation of plasminogen, diminishing plasmin-dependent fibrinolysis and transforming growth factor-β activation. Apolipoprotein(a) contains a major lysine-binding site in one of its kringle domains. Destroying this site by site-directed mutagenesis greatly reduces the binding of apolipoprotein(a) to lysine and fibrin. Transgenic mice expressing wild-type apolipoprotein(a) have a 5-fold increase in the development of lipid lesions, as well as a large increase in the focal deposition of apolipoprotein(a) in the aorta, compared to the lysine-binding site mutant strain and to non-transgenic litter mates. Although the adaptive function of apolipoprotein(a) remains obscure, a gene with similar structure has evolved by independent remodeling of the plasminogen twice during the course of mammalian evolution.     

Restriction site polymorphism at the LPA (Lp(a) apoliprotein; apoliprotein(a)) locus

A restriction site polymorphism in the Lp(a) apolipoprotein gene (the LPA gene) is reported. The basis for the polymorphism is presence or absence of an MspI restriction site that appears to be 3' to the last kringle IV structure of the gene. The "1" gene (presence of the restriction site) has a frequency of 0.316 and the "2" gene (absence of the restriction site) has a frequency of 0.684. Both members of each of 67 monozygotic (MZ) twin pairs had the same genotype and there was Mendelian segregation of the DNA variants in 40 families with a total of 75 children. There was a lower proportion of people with genotype 1-1 in the top quartile than in the 3 bottom quartiles of the population distribution of Lp(a) lipoprotein levels but the difference did not reach statistical significance.     

Changes in the ratio between apolipoprotein (a) and lipids in human plasma during interaction with polyclonal sheep antibodies against lipoprotein (a)

Plasma contents of apolipoprotein (a), apolipoprotein B 100, cholesterol, triglycerides, and vitamin E were measured in 2 patients with lipoprotein (a) concentration >100 mg/dl during the interaction with the anti-lipoprotein (a) immunosorbent. Intraindividual heterogeneity of apolipoprotein (a)-containing particles in the plasma was demonstrated. Polyclonal antibodies against lipoprotein (a) immobilized on Sepharose CL-4B more effectively removed free apolipoprotein (a) than complexes containing apolipoproteins B 100, apolipoprotein (a), lipids, and vitamin E.     

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.     

Lp(a) lipoprotein is a major risk factor for cardiovascular disease: pathogenic mechanisms and clinical significance

The results of two previous and two recent studies of middle-aged males and females are presented to exemplify the clinical importance of lipoprotein (a) (Lp(a)) as a risk factor for atherosclerosis and coronary heart disease. In these studies various conventional and recently suggested risk factors were included and different methods for Lp(a) quantification were used. Lp(a) was a significant risk factor in all four studies. In the recent prospective case-control study, Lp(a) and cholesterol were found to act synergistically and predict primary acute myocardial infarction in Swedish males. A cholesterol level above 6.5 mmol/1 increased the risk of acute myocardial infarction if the Lp(a) level was above 200 mg/1. The plasma apo A-I level was a protective factor. In the other recent case-control study, an Lp(a) level above 500 mg/1 was a highly significant risk factor in Black and White US women with myocardial infarction or advanced coronary artery disease in addition to low density lipoprotein cholesterol levels above 130 mg/dl. A high apo A-I level was a protective factor. In these studies no other factors tested reached significance in multivariate logistic regression analysis. A hypothetical association between high Lp(a) levels and intracellular infection with Chlamydia pneumoniae is discussed. The results suggest that the Lp(a) level is useful in identifying high-risk individuals. Lowering low density lipoprotein cholesterol below 100 mg/dl (7lt;2.6 mmol/1) seems to be most important in both males and females with high-risk Lp(a) levels.     

A recombination event in the closely linked plasminogen and apolipoprotein(a) gene loci

Genetic studies as well as in situ hybridisation data have strongly demonstrated that the genes coding for apoprotein(a) and plasminogen are linked and localised to chromosome 6 at band 6q26-27. We describe in this report the presence of a recombination event in a region of approximately 50 kb of DNA separating the two genes. The recombination was found in an Italian family, in which a mutation affecting both plasminogen plasma level and activity of plasminogen activity has been detected. Polymerase chain reaction and sequencing analysis showed the presence of a mutation different from those previouly reported in two Japanese families.     

Analysis of the mechanism of lipoprotein(a) assembly

We have assessed the ability of a battery of purified recombinant apolipoprotein(a) (r-apo(a)) derivatives to bind to immobilized low-density lipoprotein (LDL) by ELISA. Removal of the apo(a) kringle IV type 8 and type 9 sequences dramatically reduced apo(a) binding to LDL. The binding of apo(a) to LDL was effectively inhibited by arginine, lysine, the lysine analogue ε-aminocaproic acid and proline; comparable inhibition was observed using the 17K and KIV_5–8 r-apo(a) derivatives, suggesting a direct role for sequences contained in the latter species in mediating the initial non-covalent interactions which precede specific disulfide bond formation. We also determined that r-apo(a) binds directly to a synthetic apoB peptide spanning amino acid residues 3732–3745; this interaction appeared to be mediated by sequences present in apo(a) kringle IV types 8 and 9, and could be inhibited by arginine, lysine and proline. The results of this study indicate that the efficiency of Lp(a) assembly is a direct function of the initial non-covalent interactions between apo(a) and LDL; in addition, these studies suggest that Cys3734 in apoB mediates covalent linkage with apo(a) by virtue of the ability of the apoB sequences surrounding this residue to directly interact with apo(a) KIV type 9.     

Biogenesis of Lp(a) in transgenic mouse hepatocytes

Lipoprotein(a) [Lp(a)] biogenesis was examined in primary cultures of hepatocytes isolated from mice transgenic for both human apolipoprotein(a) [apo(a)] and human apoB. Steady-state and pulse-chase labeling experiments demonstrated that newly synthesized human apo(a) had a prolonged residence time (˜60 min) in the endoplasmic reticulum (ER) before maturation and secretion. Apo(a) was inefficiently secreted by the hepatocytes and a large portion of the protein was retained and degraded intracellularly. Apo(a) exhibited a prolonged and complex folding pathway in the ER, which included incorporation of apo(a) into high molecular weight, disulfide-linked aggregates. These folding characteristics could account for long ER residence time and inefficient secretion of apo(a). Mature apo(a) bound via its kringle domains to the hepatocyte cell surface before appearing in the culture medium. Apo(a) could be released from the cell surface by apoB-containing lipoproteins. These studies are consistent with a model in which the efficiency of posttranslational processing of apo(a) strongly influences human plasma Lp(a) levels, and suggest that cell surface assembly may be one pathway of human Lpfa) production in vivo. Transgenic mouse hepatocytes thus provide a valuable model system with which to study factors regulating human Lp(a) biogenesis.     

Lipoprotein(a): identification of subjects with a superbinding capacity for fibrinogen

We have previously shown that the binding of lipoprotein (a) [Lp(a)] to immobilized fibrinogen involves the domain located in kringles IV-5 to IV-8, but not kringle IV-10. In extending those studies to subjects living in Chicago and in the island of Sardinia, we found that about 6% of them had an Lp(a) with Bmax values of 27.7 + 6.0 fmol, which were about 5–8-fold higher than those of controls (3.4 + 2.8 fmol) and in the range of those observed for free apo(a) derived from the Lp(a) of controls (36.6 + 2.9 fmol). This superbinding phenotype was unaffected by age, sex, type of lipid disorder and hypolipidemic agents, and also had a familial incidence. We are currently exploring the hypothesis that this fibrinogen superbinding phenotype is due to conformational changes of apolipoprotein(a) [apo(a)] resulting from the lipid content and composition of the Lp(a) particle and/or sequence anomalies in the kringle domain IV-5 to IV-8.     

氧化修饰引起脂蛋白（a）结构和生化特性变化

本文观察了体外丙二醛（ＭＤＡ），铜离子（Ｃｕ２＋氧化修饰的脂蛋白（ａ）［Ｌｐ（ａ）］结构和生物学性质的变化。氧化修饰Ｌｐ（ａ）过氧化程度增高，负电荷增加，易被巨噬细胞—清道夫受体识别和摄取。ＭＤＡ修饰Ｌｐ（ａ）出现新的ＭＤＡ－ＬＤＬ位点；同纤维蛋白溶酶原（Ｐｇ）竞争抑制试验显示氧化、修饰Ｌｐ（ａ）同Ｐｇ同源性增加。提示载脂蛋白（ａ）状态同动脉粥样硬化的病理过程有关。     

The effect of percutaneous oestrogen replacement therapy on Lp(a) and other lipoproteins

Objectives: To determine the effect of percutaneous oestrogen replacement therapy on lipoprotein (a) and other plasma lipoproteins. Methods: Open longitudinal prospective study conducted at the hormone replacement clinic of the Prince of Wales Hospital, New Territories, Hong Kong. Thirty women who had undergone a total abdominal hysterectomy and bilateral salpingo-oophorectomy for benign gynaecological conditions were treated with 1.5 mg of percutaneous 17β-oestradiol gel applied daily for a period of 12 consecutive months. Measurements of plasma lipoproteins were made before the commencement of treatment and repeated at 6- and 12-month intervals. Results: There was a significant reduction in the concentrations of Lp(a) during the first 6 months of treatment, with median values falling from 7.87 mg dL⁻¹ to 6.16 mg dL⁻¹ (P = 0.004, 0–6 months). During the second 6 months, the median concentration increased to 9.38 mg dL⁻¹, (P = 0.072, 66-12 months), which did not significantly differ from the baseline level (P = 0.545, 0–12 months). Significant reductions in the concentrations of apoprotein A-I (apo A-I), apoprotein B (apo B), high density lipoprotein cholesterol (HDL-C), and HDL₃-C were also present after 6 months (P = 0.043, 0.049, 0.028, 0.013, respectively), but there were no differences between the baseline values of these lipoproteins and those at the completion of the study (P = 0.948, 0.244, 0.839, 0.117 respectively). Drug compliance was maintained throughout the study, with similar mean oestradiol concentrations at 6 and 12 months. Conclusions: The percutaneous administration of 17β-oestradiol has variable short term effects on plasma lipoproteins which are not maintained over a longer duration of treatment. By avoiding the ‘first pass’ effect on the liver, this method of delivery does not appear to produce the sustained changes in lipoproteins seen with oral treatment.     

How often has Lp(a) evolved?

The lipoprotein Lp(a) is associated with increased risk of atherosclerosis and myocardial infarction in humans. Lp(a) is mostly confined to primate species, due to the limited phylogenetic distribution of its distinguishing protein component, apolipoprotein(a) which is a close homolog of plasminogen. The known properties of Lp(a) are reviewed here. Many of these derive from the ability of Lp(a) to bind to the same substrates as plasminogen. A possible new animal model of Lp(a) is the hedgehog, which contains an Lp(a)-like particle that is the apparent product of independent evolution of a multi-kringle, apolipoprotein(a)-like protein by duplication and modification of portions of the hedgehog plasminogen gene.     

APO(a) variants and lipoprotein(a) in men with or without myocardial infarction

The lipoprotein Lp(a) with high plasma concentration is an independent genetic determinant for cardiovascular diseases. It was investigated as a quantitative factor of risk for myocardial infarction. A total of 345 Italian subjects, 127 Cases and 218 Controls, were studied. Lipids and lipoproteins were compared. Cases had atherogenic traits, such as lower HDL cholesterol and higher triglycerides than Controls. In particular, they had Lp(a) concentrations over the risk threshold, (median, 27 mg/dl in Cases vs 17 mg/dl in Controls; P = 0.0075, Mann-Whitney test) which confirmed the association of this parameter with the disease. Two main functional variants of the apo(a) gene, KringleIV and penta-nucleotide repeat, (PNR) were analyzed. Allele and genotype frequency distributions differed between Cases and Controls. Lp(a) concentrations differed according to PNR genotypes in Controls: subjects having alleles >8 showed lower Lp(a). This was not found in Cases. They had a higher prevalence of the smaller KringleIV alleles, the high Lp(a)-expressing ones. In Cases, genotypes consisting of two small KringleIV alleles were prevalently associated to PNR 8/9 and 8/10, thus preventing Lp(a) lowering. The putative apo(a) enhancer within LINE1 in the apo(a)-plasminogen intergenic region was investigated for functional polymorphisms. No variants that could be associated to the Lp(a) variability were found.     

The inheritance of sinking-pre-beta lipo-protein and its relation to the Lp(a) antigen*

We have investigated the genetics of plasma sinking-pre-beta lipoprotein (spβ) as determined by the method of Breckenridge and Maguire, using several approaches: (i) a population study, (ii) a twin study and (iii) the use of family data. In addition, by the use of split samples, the spβ level as determined by us was correlated with Lp(a) typing carried out in Oslo by Dr. Kåre Berg. Although the spβ level is a continuous character, the results clearly showed it to be to a considerable extent under the control of the major autosomal gene pair constituted by the alleles Lp^a and Lp, which mainly control the production of the Lp(a) antigen, Lp^a being dominant. In our data the boundary between the LpLp and Lp^a Lp genotypes appeared to fall between the spβ 2 and 3 mg% levels, while that between Lp^a Lp and Lp^a Lp^a was in the 15 mg% region. These boundaries, which were inferred from both typing and population statistics, received good confirmation from the family data. It appears that some 88% of the variation in spp level is directly ascribed to segregation of Lp^a and Lp. On the basis of the twin study and other data, we conclude that the residual observed variation in spβ is almost entirely ascribed to analytical error of determination and polygenic effects, the influence of environment being negligible. The heritability is close to 100%.     

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.     

Lp(a) lipoprotein enters cultured fibroblasts independently of the plasma membrane low density lipoprotein receptor

Lp(a) lipoprotein shares the apoB antigen with low density lipoprotein (LDL). The Lp(a) antigen is unique for Lp(a) lipoprotein. Fibroblast association (i.e. plasma membrane binding plus intracellular accumulation), plasma membrane binding, intracellular accumulation and degradation of 125I-Lp(a) lipoprotein were studied in strains from subjects with or without autosomal dominant hypercholesterolemia (HC). Subjects without HC (non-HCs) have cell surface receptors for low density lipoprotein (LDL receptors). On the average, HC heterozygotes have half-normal LDL receptor activity and "receptor-negative" HC homozygous cell strains lack functional receptors. Fibroblast processing of 125I-Lp(a) lipoprotein was compared to fibroblast processing of 125I-LDL. LDL receptor-dependent processing of 125I-LDL was saturated at about 50 microgram apo 125I-LDL.ml-1 in non-HC fibroblasts. 125I-Lp(a) lipoprotein was, however, largely processed independently of receptor mechanisms by non-HC cells (highest concentration examined 150 microgram apo 125I-Lp(a) lipoprotein . ml-1). Lp(a) lipoprotein did not interfere with 125I-LDL for fibroblast association, but inhibited 125I-LDL degradation. The interference with 125I-LDL degradation was time dependent. Only slightly higher 125I-Lp(a) lipoprotein processing values were found in non-HC and HC heterozygous strains than in "receptor-negative" HC homozygous strains. However, non-HC cells had more than tenfold higher 125I-LDL processing values than "receptor-negative" HC homozygous cells.     

In vitro studies of the interaction of calcium ions and other divalent cations with the Lp(a) lipoprotein and other isolated serum lipoproteins

The interaction of isolated Lp(a) lipoprotein with different divalent cations was studied and compared to that of other isolated lipoprotein classes.
Purified Lp(a) lipoprotein was found to be most sensitive to the metal ions tested, and the Lp(a) lipoprotein was the only lipoprotein which was precipitated by calcium ions alone. The precipitation apparently depends on the ionic radii of the cations used as well as on the lipoprotein class tested. The precipitation reaction between calcium ions and the Lp(a) lipoprotein, and the interaction between calcium ions and LDL (without precipitation) seem to follow the known rules for small ion - macromolecule interaction reasonably well. The calcium ion - Lp(a) lipoprotein interaction results in a small aggregate. The binding is of ionic type and the precipitation reaction is initially reversible. It was estimated that LDL particles have a mean of 290 equivalent and non-interacting binding sites for calcium ions.
The above observations concerning the Lp(a) lipoprotein may be of interest in view of the significantly higher frequency of early coronary heart disease in Lp(a+) than in Lp(a-) individuals, and in view of the previously reported biochemical differences between individuals of different Lp phenotype.