Genetic studies of human apolipoproteins. IX. Apolipoprotein D polymorphism and its relation to serum lipoprotein lipid levels.

Apolipoprotein D (APO D) is a constituent of plasma high-density lipoproteins. Its precise role in lipid metabolism is not well established, though it may be involved in cholesterol esterification and cholester ester transport to the liver for catabolism. No genetic polymorphism has been reported in the APO D gene product. To investigate the extent of genetic variation at the APO D structural locus, we have developed an isoelectric focusing-immunoblotting technique and have screened a large number of plasma samples from U.S. whites, U.S. blacks, Nigerian blacks, the Aleuts of the Pribilof Islands, Eskimo groups from Kodiak Island and St. Lawrence Island, and Amerindian populations from Mexico and Canada. Except for the U.S. blacks and Nigerian blacks, the APO D locus is monomorphic in all other population groups tested. In populations with black ancestry, the products of two alleles, APO D*1 and APO D*2, have been observed at respective allele frequencies .987 and .013 in U.S. blacks and .978 and .022 in Nigerian blacks. The detection of a unique protein polymorphism in blacks makes APO D a useful black marker of significance in anthropogenetics and racial admixture studies. In addition to the interindividual variation observed, APO D reveals extensive intraindividual molecular variation with a multiple banding pattern. The basis of this molecular variation is explained, in part, by variation in the number of terminal sialic acid residues. We have investigated the effect of the APO D polymorphism on triglycerides, total cholesterol, LDL-, VLDL-, HDL-, and HDL3 cholesterol in 352 Nigerian blacks (190 males and 162 females).(ABSTRACT TRUNCATED AT 250 WORDS)     

Genetic studies of low-abundance human plasma proteins. VI. Polymorphism of hemopexin.

An analytical isoelectric focusing method in 3 M urea followed by immunoblotting has been devised to detect genetic and biochemical variation in the glycoprotein hemopexin (HPX) in human plasma or serum. HPX reveals extensive microheterogeneity with multiple major and minor components that are susceptible to neuraminidase treatment, suggesting that the observed biochemical variation is due to differences in sialic acid content between HPX isoproteins. However, charge differences that persist in HPX isoproteins following neuraminidase treatment suggest the presence of genetically determined HPX variation, and this is confirmed by population and family studies. HPX was found to be monomorphic, with an invariant pattern, in U.S. whites; but it is polymorphic in U.S. blacks, with three alleles controlled by a single locus, a situation that demonstrates an autosomal codominant pattern of inheritance. The HPX 1, HPX 2, and HPX 3 allele frequencies in U.S. blacks are .941, .018, and .041, respectively.     

Population genetics of alpha-1-antitrypsin polymorphism in US whites, US blacks and African blacks.

An isoelectric focusing (IEF) procedure in an ultra-narrow pH range, 4.2-4.9, has been utilized to detect alpha 1-antitrypsin or alpha 1-protease inhibitor (PI) allele products in 2 US white and 3 US black populations as well as 1 native African black population. In addition to the 3 common alleles PI*M1, PI*M2 and PI*M3, products of the 4th allele PI*M4 have been identified in US whites at low-level frequency. The presence of the PI*S, PI*Z and PI*I alleles has also been verified in our population samples. While the PI*S allele is present at a polymorphic level in US whites, it is only present sporadically in US blacks and is completely absent in African blacks. The PI*Z allele was not detected in the black populations tested. The PI allele frequency data have been used to calculate white admixture in US blacks.     

Genetic studies of human apolipoproteins. XX. Genetic polymorphism of apolipoprotein J and its impact on quantitative lipid traits in normolipidemic subjects.

Apolipoprotein J (apo J) is a newly identified member of a growing family of proteins associated with various lipoprotein particles. Apo J is a glycoprotein which exists in the plasma associated with high-density lipoprotein subfractions which also contain apo A-I and cholesteryl ester transfer protein (CETP). We have investigated the possible existence of genetic polymorphism at the apo J structural locus and have evaluated its role in lipid metabolism. By employing isoelectric focusing and immunoblotting techniques, we have screened plasma or serum samples from six population groups: U.S. whites, Amerindians, Eskimos, New Guineans, U.S. blacks, and Nigerian blacks. Apo J revealed a common two-allele polymorphism only in populations with African ancestry and was found to be monomorphic in all other population groups tested. The genetic basis of the two alleles designated--APO J*1 and APO J*2, at a single structural locus, apo J-- was confirmed in a large number of segregating families. In the U.S. blacks, the frequencies of the APO J*1 and APO J*2 alleles were .76 and .24, respectively, and in the Nigerian blacks these values were .72 and .28, respectively. In addition, a single example of a rare allele designated APO J*3 was also encountered in the U.S. black sample. In Nigerian blacks, the apo J polymorphism's impact on seven quantitative lipid traits--total cholesterol, LDL-cholesterol, HDL-cholesterol, HDL3-cholesterol, HDL2-cholesterol, VLDL-cholesterol, and triglycerides--was investigated. No significant impact of the apo J polymorphism was observed for any of these lipid traits.     

Genetic studies of low-abundance human plasma proteins. V. Evidence for a second orosomucoid structural locus (ORM2) expressed in plasma.

Orosomucoid (ORM) or alpha-1-acid glycoprotein is an acute-phase protein of human plasma whose function is suggested to be the competitive inhibition of cellular recognition by infective agents. Genetically determined variation in ORM has been reported, with two major alleles segregating in all populations studied to date. Isoelectric focusing-immunoblotting studies of ORM revealed the presence of isoprotein species that did not segregate with the predominant alleles at the ORM locus and suggested the expression of a second structural gene locus for orosomucoid (ORM2). Genetically independent variation consistent with expression of the ORM2 locus was observed in plasma samples from American blacks but was not observed in U.S. whites or sampled populations of North- and South-American Indians, Eskimos, Aleuts, or New Guinea Highlanders. The population allele frequencies for this locus were .958, .025, .006, and .011 for alleles ORM*1, ORM2*2, ORM2*3, and ORM2*4, respectively. Family studies confirm the autosomal codominant inheritance of the observed phenotypes.     

Genetic studies of human apolipoproteins. III. Polymorphism of apolipoprotein C-II

Using a simple and rapid one-dimensional isoelectric focusing technique followed by immunoblotting, we have detected genetic polymorphism of human apolipoprotein C-II (APO C-II) in normal unfractionated plasma samples of individuals of black ancestry. Two common autosomal codominantly expressed alleles, designated APO C-II*1 and APO C-II*2, at the APO C-II structural locus have been observed with frequencies of 0.975 and 0.025 in US blacks and 0.943 and 0.049 in Nigerian blacks. In addition, the gene product of a rare allele designated APO C-II*3 was observed in a single Nigerian black. Apart from a single example of an APO C-II 2-1 phenotype in plasma samples from 187 whites, which was electrophoretically identical to the 2-1 phenotype observed in blacks, it appears that APO C-II*2 is a unique black marker of potential importance in anthropogenetic and atherosclerosis studies.     

Genetic studies of human apolipoproteins. I. Polymorphism of apolipoprotein A-IV.

Genetic polymorphism of human apolipoprotein A-IV has been detected by means of a simple and rapid one-dimensional isoelectric-focusing technique followed by immunoblotting. In plasma samples of normal U.S. whites and blacks, the specificity and sensitivity of the technique have been demonstrated to elucidate biochemical and genetic variation present in the APO A-IV molecule. Two common alleles, APO A-IV 1 and APO A-IV 2, have been observed with respective frequencies of .909 and .088 in whites and .961 and .035 in blacks. In addition, the products of two rare alleles designated APO A-IV 3 and APO A-IV 4 also have been observed. Family studies show autosomal codominant transmission of four alleles coded by a single structural locus.     

Genetic studies of low abundance human plasma proteins. II. Population genetics of coagulation factor XIIIB.

Plasma samples from a large number of different ethnic groups, consisting of U.S. whites, U.S. blacks, Eskimos from Kodiak and St. Lawrence Island, Aleuts of the Pribilof Islands, and three Amerindian groups from Canada and Mexico have been analyzed by isoelectric focusing followed by immunoblotting to determine the magnitude of genetic variation at the F XIIIB structural locus. The synthesis of published data and our new data demonstrate remarkable variation in the distribution of the three common alleles at this locus and establishes F XIIIB as an extremely informative marker for population differentiation and evolutionary studies. Genetic distance analysis based on this variation separates Caucasian, black, and Mongoloid populations into three distinct clusters.     

Molecular basis of the apolipoprotein H (β2-glycoprotein I) protein polymorphism

Apolipoprotein H (apoH, protein; APOH, gene) is considered to be an essential cofactor for the binding of certain antiphospholipid autoantibodies to anionic phospholipids. APOH exhibits a genetically determined structural polymorphism due to the presence of three common alleles (APOH*1, APOH*2 and APOH*3 ) detectable by isoelectric focusing (IEF) and immunoblotting. The APOH*3 allele can be further characterized into two subtypes, APOH*3^W and APOH*3^B, based upon its reactivity with monoclonal antibody 3D11. In this study we have determined the molecular basis of the APOH protein polymorphism and its distribution in three large U.S. population samples comprising 661 non-Hispanic whites, 444 Hispanics and 422 blacks. By direct DNA sequencing of PCR amplified fragments corresponding to the eight APOH exons, we identified two missense mutations that correspond to the APOH*1 and APOH*3^W alleles. A missense mutation (G→A) in exon 3, which alters amino acid Ser to Asn at codon 88 and creates a restriction site for TSP509 I, was present in all APOH*1 allele carriers. A second missense mutation (G→C) at codon 316 in exon 8, which replaces amino acid Trp with Ser and creates a restriction site for BSTBI, was present in all APOH*3^W carriers. The distribution of the Ser 88 Asn and Trp 316 Ser mutations was significantly different between the three racial groups. The frequency of the Asn-88 allele was 0.011, 0.043, and 0.056 in blacks, Hispanics and non-Hispanic whites, respectively. While the Ser-316 allele was observed sporadically in blacks (0.008), it was present at a polymorphic frequency in Hispanics (0.027) and non-Hispanic whites (0.059). The identification of the molecular basis of the APOH protein polymorphism will help to elucidate the structural – functional relationship of apoH in the production of antiphospholipid autoantibodies. Received: 20 November 1996 / Accepted: 13 February 1997     

Genetic studies of human apolipoproteins. IV. Structural heterogeneity of apolipoprotein H (beta 2-glycoprotein I).

Human beta 2-glycoprotein I has recently been identified as a component of several human plasma lipoprotein fractions and therefore termed as apolipoprotein H. Its metabolic function in lipid metabolism is not known with certainty, though it may be involved in very-low-density-lipoprotein metabolism. Previously, inherited quantitative variation in beta 2-glycoprotein I has been suggested in man. In this investigation, we document the evidence of genetically determined structural polymorphism of apolipoprotein H or beta 2-glycoprotein I by using thin-layer polyacrylamide isoelectric focusing gels followed by immunological identification by double antibody staining. The apolipoprotein H structural locus is characterized by the occurrence of three common alleles in U.S. whites and blacks. The frequency distributions of the three alleles designated APO H1, APO H2, and APO H3 are .059, .882, and .059 in whites and .017, .902, and .068 in blacks, respectively. In addition, the gene product of a fourth allele, APO H4, has been observed at polymorphic frequency in black individuals and may represent a black marker variant. Family data confirm the hypothesis of four alleles at a single APO H gene locus with an autosomal codominant pattern of inheritance.     

Genetic studies of low-abundance human plasma proteins

Summary Genetic variation in the C1R subcomponent of the first complement component C1 was investigated in U.S. whites by isoelectric focusing and immunoblotting. In addition to the previously described two alleles, the products of a new and rare third allele designated C1R ^*3 were detected. The expression of the new allele is consistent with autosomal codominant inheritance, which is confirmed by family data. The frequencies of the C1R ^*1, C1R ^*2 and C1R ^*3 alleles in 201 randomly selected U.S. whites are: 0.908, 0.090, and 0.002, respectively.     

Genetic studies of low abundance human plasma proteins. III. Polymorphism of the C1R subcomponent of the first complement component.

Genetic polymorphism of the C1R subcomponent of human complement component C1 has been detected in normal plasma samples using the high resolving power of isoelectric focusing in 6 M urea followed by immunoblotting. There are two common alleles at the C1R structural locus that show autosomal codominant inheritance. The C1R*1 and C1R*2 allele frequencies in U.S. white and U.S. black blood donors are: .934, .066, and .899, .101, respectively.     

Slow acetylator mutations in the human polymorphic N-acetyltransferase gene in 786 Asians, blacks, Hispanics, and whites: application to metabolic epidemiology.

Our aim was to determine the population frequencies of the major slow acetylator alleles of the polymorphic N-acetyltransferase (NAT2) gene, whose locus maps to chromosome 8. We used allele-specific PCR amplification on 786 dried blood spots obtained from Hong Kong Chinese, U.S. Koreans, U.S. blacks, U.S. Hispanics, Germans, and U.S. whites. Our results show that four slow acetylator alleles can be detected as mutations at positions 481, 590, and 857 in the NAT2 gene. Recognized base substitutions at positions 341 and 803 need not be determined, because they were almost always associated with the 481T mutation. The known mutation at position 282 was strongly associated with the 590A mutation. The 481T, 590A, and 857A mutations accounted for virtually all of the slow acetylator alleles in Asian and white populations. The 857A mutation proved to be an Asiatic allele. The results will be useful in large-scale epidemiologic studies of cancer and other conditions potentially associated with the acetylator polymorphism.     

HLA-DRB1*1101: a significant risk factor for sarcoidosis in blacks and whites

Sarcoidosis is a granulomatous disorder of unknown etiology, associated with an accumulation of CD4+ T cells and a TH1 immune response. Since previous studies of HLA associations with sarcoidosis were limited by serologic or low-resolution molecular identification, we performed high-resolution typing for the HLA-DPB1, HLA-DQB1, HLA-DRB1, and HLA-DRB3 loci and the presence of the DRB4 or DRB5 locus, to define HLA class II associations with sarcoidosis. A Case Control Etiologic Study of Sarcoidosis (ACCESS) enrolled biopsy-confirmed cases (736 total) from 10 centers in the United States. Seven hundred six (706) controls were case matched for age, race, sex, and geographic area. We studied the first 474 ACCESS patients and case-matched controls. The HLA-DRB1 alleles were differentially distributed between cases and controls (P<.0001). The HLA-DRB1*1101 allele was associated (P<.01) with sarcoidosis in blacks and whites and had a population attributable risk of 16% in blacks and 9% in whites. HLA-DRB1-F(47) was the amino acid residue most associated with sarcoidosis and independently associated with sarcoidosis in whites. The HLA-DPB1 locus also contributed to susceptibility for sarcoidosis and, in contrast to chronic beryllium disease, a non-E(69)-containing allele, HLA-DPB1*0101, conveyed most of the risk. Although significant differences were observed in the distribution of HLA class II alleles between blacks and whites, only HLA-DRB1*1501 was differentially associated with sarcoidosis (P<.003). In addition to being susceptibility markers, HLA class II alleles may be markers for different phenotypes of sarcoidosis (DRB1*0401 for eye in blacks and whites, DRB3 for bone marrow in blacks, and DPB1*0101 for hypercalcemia in whites). These studies confirm a genetic predisposition for sarcoidosis and present evidence for the allelic variation at the HLA-DRB1 locus as a major contributor.     

Dissection of a continuous distribution: red cell galactokinase activity in blacks.

A significant difference between blacks and whites in the distribution of red cell galactokinase (GALK) has been found by Tedesco et al. [2]. From the shapes of the distributions, it was inferred that whites are essentially all homozygous for one allele (GALKA), but blacks are polymorphic. A second allele (GALKP), for lower GALK activity, is presented at high frequency in blacks but rare or absent in whites. This paper presents a method which, assuming the genetic model presented, estimates the genotype composition of the black sample. We make some reasonable biochemical assumptions and fit a mixture of three normal distributions to the black data to obtain an estimate of p, the frequency of GALKA in blacks. The fit of the model to the data is excellent and the best estimate of p is .217 +/- .025. Since admixture of white genes in blacks from the United States is known to be about 20%, the value of p implies that virtually all GALKA alleles were introduced by admixture, and that the ancestral black population was monomorphic for GALKP. If whites are indeed monomorphic for GALKA, they differ from unmixed blacks by a full gene substitution at the locus for GALK.     

Genetic studies of human apolipoproteins. X. The effect of the apolipoprotein E polymorphism on quantitative levels of lipoproteins in Nigerian blacks.

Human apolipoprotein E exhibits genetic polymorphism in all populations examined to date. By isoelectric focusing and immunoblotting, three common alleles have been demonstrated in 365 unrelated Nigerian blacks. Furthermore, the APO E genetic polymorphism's effect on quantitative levels of lipids and lipoproteins has been determined. The respective frequencies of the APO E*2, APO E*3, and APO E*4 alleles are .027, .677, and .296. The effect of APO E polymorphism is significant only on total cholesterol and low-density lipoprotein cholesterol. The average excesses of the APO E*2 allele are to lower total cholesterol and low-density lipoprotein cholesterol by 9.19 mg/dl and 11.11 mg/dl, respectively. The average excesses of the APO E*4 allele are to increase total cholesterol and low-density lipoprotein cholesterol by 5.64 mg/dl and 6.18 mg/dl, respectively. On the basis of the differences in (a) the distribution of APO E allele frequencies between the Nigerians and other populations and (b) dietary lipids, we propose a model that shows that lipid metabolism is influenced by the combined effects of the APO E polymorphism and environmental factors.     

Genetic studies of human apolipoproteins. XI. The effect of the apolipoprotein C-II polymorphism on lipoprotein levels in Nigerian blacks

The human apolipoprotein C-II locus exhibits genetically determined structural polymorphism in United States and African blacks. In the present study, we have investigated the effect of the apoC-II polymorphism on quantitative serum levels of total cholesterol, total high density lipoprotein (HDL) cholesterol, cholesterol in high density lipoprotein subfractions, low density lipoprotein (LDL) cholesterol, and triglycerides (TG) in a sample of 368 unrelated Nigerian blacks. The frequencies of the APOC-II*1 and APOC-II*2 alleles in the samples were 0.947 and 0.053, respectively. In males, the effect of the APOC-II*2 allele was to lower the total serum cholesterol and LDL-cholesterol levels by 13.28 mg/dl and 10.55 mg/dl, respectively, relative to the common allele, APOC-II*1. In females, the effect was to lower total plasma cholesterol by 4.49 mg/dl and LDL-cholesterol by 3.21 mg/dl. The effect of apoC-II on quantitative lipoprotein levels is shown to be independent of variation at the linked apoE locus, but the products of the two loci interact in determining overall quantitative phenotypes.     

Genetic polymorphism of alpha 2HS-glycoprotein.

A genetic polymorphism of the human serum glycoprotein, alpha 2HS-glycoprotein, can be recognized using isoelectric focusing in polyacrylamide, followed by silver-stain immunofixation. In a North American Caucasian population, two common alleles and one rare allele have been recognized, with frequencies as follows: AHSG*1: .6419, AHSG*2: .3535, and AHSG*3: .0046; polymorphism information content (PIC): .36. A black population from various islands of the Caribbean has the two most common alleles, plus a variant (B) not found in the white population. Allele frequencies in the blacks were: AHSG*1: .6901, AHSG*2: .2606, AHSG*B: .0493; PIC: .396. Family studies confirmed the allele designations. Alleles in both populations were in Hardy-Weinberg equilibrium. This polymorphism will be useful as a marker on chromosome 3q and for forensic studies. The serum concentration associated with AHSG*1 may be somewhat greater than that associated with AHSG*2. Differences between the allele products remained after removal of sialic acid from the glycoprotein with neuraminidase. The silver-stain immunofixation technique used for this polymorphism has wide application for the study of polymorphisms where the protein is present in low concentration or where only low titer antiserum is available.     

Study of five haemogenetic markers (Gc, C3, Bf, Ag, and GALT) in six Indonesian populations and in 12 subgroups of Balinese

In various ethnic groups of the Indonesian archipelago and of Bali, the polymorphisms of the serum proteins Gc globulin (vitamin D-binding protein), C3 (complement component 3), Bf (complement factor B), Ag x,y (lipoprotein allotypes), and of the red cell enzyme system GALT (galactose-1P-uridyltransferase) were analysed. Among the studied proteins, the Gc system was the most informative one for the anthropologist. Besides considerable differences of frequencies of the common alleles Gc*1F, Gc*1S and Gc*2, a number of rare alleles (1A1, 1A3, 1A8, 1A9, 1A12, 1C2, 1C21, 1C24, and 2C8) and some new ones (1C28, 1C29, 1C30, 2C9) were observed. The presence of Gc*1A1 demonstrates the relationship to the Australo-Melanesian populations, but Mongolian variants (1A3, 1A8, 1A9, 1C2) were also encountered. Within the C3 system a very high frequency of the C3*S allele was observed in all populations. The rare alleles C3*F0.55, C3S1, and C3*S0.5 were observed in some groups. A new allele (C3*F0.35) was detected in a Chinese individual and in a nobleman from Bali. The frequency of the Bf*F allele was rather low in general, and the Bf*S0.7 allele was found in three Indonesian individuals only. The Ag*(x) frequencies were rather high, as it is known for Asiatic populations. Variability among subgroups was not very pronounced. The GALT*2 allele (Duarte variant of the enzyme) was observed very rarely; however, it was present in several populations. Enzyme activities could not be determined, and therefore we cannot tell whether the galactosaemia gene (GALT*0) was present or not.     

Caucasian genes in American blacks: new data.

Data on 15 polymorphic protein-coding loci are used to estimate the proportion of Caucasian genes in U.S. blacks from the greater-metropolitan area of Pittsburgh. Allele frequencies from U.S. whites of the same region and from a sample of Nigerians are used as representatives of the genetic contributions of the source populations between which admixture has occurred. These materials provide 18 unique variants that occur exclusively in the blacks and 5 variants that are restricted to the Caucasians only. As a result, when all segregating alleles (52) at these 15 loci are considered, the proportion (mean +/- SE) of Caucasian genes in U.S. blacks (25.2% +/- 2.7%) is estimated with a precision much better than that of all other previous estimates. The estimate based on the frequencies of these 18 unique variants of African origin (24.8% +/- 6.2%) is also consistent with the pooled estimate obtained from the 15 loci by the weighted least-square method. The homogeneity of locus-specific estimates of admixture indicates that these loci are appropriate for studying the proportion of black genes in any admixed population involving African admixture. The advantages of employing such loci for genetic-epidemiologic studies in U.S. blacks is discussed in the context of the availability of these large number of unique African variants at these protein loci.