Analysis of apolipoprotein E5 gene from a patient with hyperlipoproteinemia

We have isolated and analyzed apolipoprotein E5 gene from a patient with hyperlipoproteinemia. Apolipoprotein E5 is a variant of apolipoprotein E with two additional units of positive charge and smaller apparent molecular weight than apolipoprotein E3, which is the major isoform of apolipoprotein E. The heterozygous gene of apolipoprotein E5/3 from the patient was cloned into lambda phage. The cloned apolipoprotein E genes were subcloned into a murine retrovirus shuttle vector and were expressed. One out of four clones expressed apolipoprotein E5. The analysis of the nucleotide sequence of the exons and exon-intron boundary regions has shown a G to A substitution in the 18th nucleotide from the 5'-end of the third exon. This single base substitution changes the amino acid residue Glu to Lys at the third position from the amino-terminus of the mature protein, and gives two additional units of positive charge to the molecule.     

Structure and expression of mouse apolipoprotein E gene

The mouse apolipoprotein E gene was isolated from a genomic library by screening with a cDNA probe. DNA including apolipoprotein E gene plus segments 2.5 kilobases upstream and 0.3 kilobase downstream of the coding region was transfected into NIH3T3 cells. The cells expressed the same-size apolipoprotein E mRNA and protein as those produced by mouse endogenously. The nucleotide sequence of the gene plus 5' and 3' flanking regions (one kilobase each) was determined. The sequence of the mouse apoliprotein E gene was highly homologous to that of the rat gene, not only in the coding regions but also in the non-coding and intron regions. The mouse and the human apolipoprotein E genes were homologous in the 5' proximal flanking region up to about 200 nucleotides as well as in the four exons. This proximal region was highly conserved for the genes of mouse, rat and human; the relative positions of the "TATA box" and the two copies of "GC box" were identical.     

Identification of human apolipoprotein E variant gene: apolipoprotein E7 (Glu244,245----Lys244,245)

Apolipoprotein E (apoE) is one of the protein moieties of the human serum lipoproteins. Three major isoforms of apoE (apoE2, apoE3, and apoE4) and minor variant isoforms (apoE1, apoE5, and apoE7) have been detected by isoelectric focusing. In this study we have cloned the apoE7 gene from a patient with the apoE3/E7 phenotype associated with hypertriglyceridemia and diabetes mellitus. DNA sequencing revealed that the apoE7 gene has two base substitutions (G----A) changing Glu244,245----Lys244,245, compared with the apoE3 gene. The replacement of the two amino acids is consistent with the result of isoelectric focusing of the apoE7 isoprotein, which shifts to four positively charged units compared with the apoE3 isoprotein.     

Apolipoprotein E-4Philadelphia (Glu13----Lys,Arg145----Cys). Homozygosity for two rare point mutations in the apolipoprotein E gene combined with severe type III hyperlipoproteinemia.

The molecular defect in a 24-year-old white female with severe type III hyperlipoproteinemia has been elucidated. The patient's apolipoprotein (apo) E migrated in the apoE-4 position on isoelectric focusing gels. On sodium dodecyl sulfate-polyacrylamide gel electrophoresis the apoE-4 variant had a smaller apparent molecular weight than apoE-4(Cys112----Arg). Sequence analysis of DNA amplified with the polymerase chain reaction revealed two nucleotide substitutions in the proband's apoE gene. A C to T mutation converted arginine (CGT) at position 145 of the mature protein to cysteine (TGT) thus creating the apoE-2 variant. A second G to A substitution at amino acid 13 led to the exchange of lysine (AAG) for glutamic acid (GAG), thereby adding 2 positive charge units to the protein and producing the apoE-5 variant. Computer analysis of the apoE-4Philadelphia gene revealed that the G to A mutation in exon 3 resulted in the loss of an AvaI restriction enzyme site. The second mutation, a C to T substitution in the fourth exon of the apoE gene, eliminated a cleavage site for the enzyme BbvI. Using these restriction fragment length polymorphisms as well as DNA sequence analysis we have demonstrated that the patient is homozygous for both point mutations in the apoE gene.     

Two copies of the human apolipoprotein C-I gene are linked closely to the apolipoprotein E gene

The gene for human apolipoprotein (apo) C-I was selected from human genomic cosmid and lambda libraries. Restriction endonuclease analysis showed that the gene for apoC-I is located 5.5 kilobases downstream of the gene for apoE. A copy of the apoC-I gene, apoC-I', is located 7.5 kilobases downstream of the apoC-I gene. Both genes contain four exons and three introns; the apoC-I gene is 4653 base pairs long, the apoC-I' gene 4387 base pairs. In each gene, the first intron is located 20 nucleotides upstream from the translation start signal; the second intron, within the codon of Gly-7 of the signal peptide region; and the third intron, within the codon for Arg39 of the mature plasma protein coding region. The upstream apoC-I gene encodes the known apoC-I plasma protein and differs from the downstream apoC-I' gene in about 9% of the exon nucleotide positions. The most important difference between the exons results in a change in the codon for Gln-2 of the signal peptide region, which introduces a translation stop signal in the downstream gene. Major sequence differences are found in the second and third introns of the apoC-I and apoC-I' genes, which contain 9 and 7.5 copies, respectively, of Alu family sequences. The apoC-I gene is expressed primarily in the liver, and it is activated when monocytes differentiate into macrophages. In contrast, no mRNA product of the apoC-I' gene can be detected in any tissue, suggesting that it may be a pseudogene. The similar structures and the proximity of the apoE and apoC-I genes suggest that they are derived from a common ancestor. Furthermore, they may be considered to be constituents of a family of seven apolipoprotein genes (apoE, -C-I, -C-II, -C-III, -A-I, -A-II, and -A-IV) that have a common evolutionary origin.     

Genetic analysis of the polymorphism of the human apolipoprotein E using automated solid-phase sequencing

A direct sequencing approach has been used to analyze the polymorphism in the human apolipoprotein E gene. A method is described, in which the DNA is amplified by the polymerase chain reaction, immobilized, and sequenced by a semi-automatic procedure adaptable to clinical diagnosis. The three alleles of the apolipoprotein E gene, which differ from each other by two nucleotide substitutions and which influence serum cholesterol levels, were analyzed. The solid-phase method was able to resolve the correct nucleotide sequence in samples from both homozygous and heterozygous individuals. No cloning steps are needed and the immobilization and separation of the DNA is accomplished using magnetic beads.     

Clinical chemistry of common apolipoprotein E isoforms

Apolipoprotein E plays a central role in clearance of lipoprotein remnants by serving as a ligand for low-density lipoprotein and apolipoprotein E receptors. Three common alleles (apolipoprotein E₂, E₃ and E₄) give rise to six phenotypes. Apolipoprotein E₃ is the ancestral form. Common apolipoprotein E isoforms derive from nucleotide substitutions in codons 112 and 158. Resulting cysteine-arginine substitutions cause differences in: affinities for low-density lipoprotein and apolipoprotein E receptors, low-density lipoprotein receptor activities, distribution of apolipoprotein E among lipoproteins, low-density lipoprotein formation rate, and cholesterol absorption. Accompanying changes in triglycerides, cholesterol and low-density lipoprotein may promote atherosclerosis development. Over 90% of patients with familial dysbetalipoproteinaemia have apolipoprotein E₂/E₂. Apolipoprotein E₄ may promote atherosclerosis by its low-density lipoprotein raising effect. Establishment of apolipoprotein E isoforms may be important for patients with diabetes mellitus and several non-atherosclerotic diseases. Apolipoprotein E phenotyping exploits differences in isoelectric points. Isoelectric focusing uses gels that contain pH4–7 ampholytes and urea. Serum is directly applied, or prepurified by delipidation, lipoprotein precipitation or dialysation. Isoelectric focusing is followed by immunofixation/protein staining. Another approach is electro- or diffusion blotting, followed by protein staining or immunological detection with anti-apolipoprotein E antibodies and an enzyme-conjugated second antibody. Apolipoprotein E genotyping demonstrates underlying point mutations. Analyses of polymerase chain reaction products are done by allele-specific oligonucleotide probes, restriction fragment length polymorphism, single-stranded conformational polymorphism, the primer-guided nucleotide incorporation assay, or denaturating gradient gel electrophoresis. Detection with primers that either or not initiate amplification is performed with the amplification refractory mutation system. Disparities between phenotyping and genotyping may derive from isoelectric focusing methods that do not adequately separate apolipoprotein E posttranslational variants, storage artifacts or faint isoelectric focusing bands.     

Polymorphism of the apolipoprotein E gene and the risk of myocardial infarction

The apolipoprotein E (ApoE) gene polymorphism resulting from nucleotide substitutions in exon 4 was analyzed in Russian and Tatar patients with myocardial infarction (MI) from Bashkortostan. Alleles epsilon 2, epsilon 3, and epsilon 4 were identified by PCR. The genotype frequency distribution proved to be age-dependent in healthy Russians, genotype E2/3 increasing in frequency in subjects beyond 45. Russians who suffered MI under 45 had lower frequencies of genotype E3/3 (50.00% vs. 75.47% in controls of the same age, P = 0.013, OR = 0.33) and allele epsilon 3 (72.12% vs. 85.85%, P = 0.020, OR = 0.43) and a higher frequency of allele epsilon 4 (22.12% vs. 10.38%, P = 0.030, OR = 2.45). Russians who suffered MI complicated by cardiogenic shock (CS) had a significantly higher frequency of genotype E3/4 and lower frequencies of genotype E3/3 and allele epsilon 3 as compared with MI patients without CS. In Tatars, genotype E4/4 occurred at a frequency of 14.29% in patients who suffered MI under 45, and was not detected in healthy subjects of the same age (P = 0.024, OR = 17.85). Thus, the ApoE polymorphism was associated with higher risk of MI in Russians and Tatars under 45.     

Human apolipoprotein E mRNA. cDNA cloning and nucleotide sequencing of a new variant

The complete nucleotide sequences of three cloned cDNAs corresponding to human liver apolipoprotein E (apo-E) mRNA were determined. Analysis of the longest cDNA showed that it contained 1157 nucleotides of mRNA sequence with a 5'-terminal nontranslated region of 61 nucleotides, a signal peptide region corresponding to 18 amino acids, a mature protein region corresponding to 299 amino acids, and a 3'-terminal nontranslated region of 142 nucleotides. The inferred amino acid sequences from two cDNAs were identical and corresponded to the amino acid sequence for plasma apo-E3 that has been reported previously ( Rall , S. C., Jr., Weisgraber , K. H., and Mahley , R. W. (1982) J. Biol. Chem. 257, 4171-4178). The third cDNA differed from the other two cDNAs in five nucleotide positions. Three of these differences occurred in the third nucleotide position of amino acid codons, resulting in no change in the corresponding amino acids at residues Val-85, Ser-223, and Gln-248. The other two altered nucleotides occurred in the first nucleotide position of codons, leading to changes in the amino acids encoded. In the variant sequence, a threonine replaced the normal alanine at residue 99 and a proline replaced the normal alanine at residue 152. We have concluded that the human liver donor was heterozygous for the epsilon 3 genotype. The variant cDNA corresponds to a new, previously undescribed variant form of apo-E in which the amino acid substitutions of the protein are electrophoretically silent; it would probably be undetectable by standard apo-E phenotyping methods. The amino acid substitution at position 152 occurs in a region of apo-E that appears to be important for receptor binding, and it may have clinical significance.     

Alternative splicing attenuates transgenic expression directed by the apolipoprotein E promoter-enhancer based expression vector pLIV11

The plasmid vector pLIV11 is used commonly to achieve liver-specific expression of genes of interest in transgenic mice and rabbits. Expression is driven by the human apolipoprotein (apo)E 5′ proximal promoter, which includes 5 kb of upstream sequence, exon 1, intron 1, and 5 bp of exon 2. A 3.8 kb 3′ hepatic control region, derived from a region ∼18 kb downstream of the apoE gene, enhances liver-specific expression. Here, we report that cDNA sequences inserted into the multiple cloning site (MCS) of pLIV11, which is positioned just downstream of truncated exon 2, can cause exon 2 skipping. Hence, splicing is displaced to downstream cryptic 3′ splice acceptor sites causing deletion of cloned 5′ untranslated mRNA sequences and, in some cases, deletion of the 5′ end of an open reading frame. To prevent use of cryptic splice sites, the pLIV11 vector was modified with an engineered 3′ splice acceptor site inserted immediately downstream of truncated apoE exon 2. Presence of this sequence fully shifted splicing of exon 1 from the native intron 1–exon 2 splice acceptor site to the engineered site. This finding confirmed that sequences inserted into the MCS of the vector pLIV11 can affect exon 2 recognition and provides a strategy to protect cloned sequences from alternative splicing and possible attenuation of transgenic expression.     

Molecular cloning, nucleotide sequence and expression of the tufB gene encoding elongation factor Tu from Thermus thermophilus HB8

The tufB gene encoding elongation factor Tu (EF-Tu) of Thermus thermophilus HB8 was cloned and expressed. Compared with the known tufA gene of T. thermophilus, nucleotide differences were found at 10 positions out of 1221 nucleotides, and amino acid substitutions were found at 4 positions out of 406 amino acids. The tufB product was 70.9% homologous to the corresponding sequence of the tufB product of E. coli. The G+C content of the third base of the codon in the tufB gene was 84.8% and G was especially preferred in this position.     

Isolation and characterization of the human apolipoprotein A-II gene. Electron microscopic analysis of RNA:DNA hybrids, nucleotide sequence, identification of a polymorphic MspI site, and general structural organization of apolipoprotein genes

Three cloned apolipoprotein A-II genes were isolated from a human genomic cosmid library constructed in our laboratory. An approximately 3-kilobase HindIII insert containing the entire gene was analyzed by RNA:DNA hybridization and electron microscopy. The apo-A-II gene was found to consist of 4 exons and 3 intervening sequences (IVS), and the lengths of each exon and IVS were estimated by direct observation of the hybrids. The entire approximately 3-kilobase HindIII insert was sequenced. The 5' end of the gene was determined by primer extension. The DNA sequence confirms the presence of 4 exons and 3 IVS: exon 1, 34 nucleotides; exon 2, 76 nucleotides; exon 3, 133 nucleotides; exon 4, 230 nucleotides; IVS-I, 169 nucleotides; IVS-II, 299 nucleotides; and IVS-III, 396 nucleotides. A "TATA box" is located at position -29 from the CAP site. A "CAT box" is present at position -78. A "TG" element consisting of (TG)19 is identified at the 3' end of IVS-III. Furthermore, an enhancer core sequence, CTTTCCA, is identified at position -355 in the 5' flanking sequence. At positions -497 to -471 upstream from the CAP site is a stretch of 27 nucleotides that show high homology to stretches of 5' flanking sequences in the apo-C-II, apo-A-I, apo-E, and apo-C-III genes. An Alu dimer sequence is located approximately 300 nucleotides from the 3' end of the gene. Within this Alu sequence, we have identified a polymorphic MspI site. Restriction fragment length polymorphism involving this site has been previously shown to correlate with apo-A-II levels and high density lipoprotein structure. Analysis of conformation by Chou-Fasman analysis and by the helical hydrophobic moment of Eisenberg et al. (Eisenberg, D., Weiss, R. M., and Tergwillager, T. C. (1982). Nature (Lond.) 299, 371-374) indicates that in all of the 5 apolipoproteins characterized at the nucleotide level to date, i.e. apo-C-II, apo-A-II, apo-E, apo-A-I, and apo-C-III, the 2 IVS within the peptide coding regions of the gene tend to occur at regions corresponding to the surface of the polypeptide chain and divide the protein into distinct functional domains.     

Expression of a human alpha-globin/fibronectin gene hybrid generates two mRNAs by alternative splicing.

We have isolated genomic clones for human fibronectin (FN), by screening a human gene library with previously isolated FN cDNA clones. We have recently reported two different FN mRNAs, one of them containing an additional 270 nucleotide insert coding for a structural domain ED. Restriction mapping and DNA sequencing of the genomic clones show that the ED type III unit corresponds to exactly one exon in the gene, whilst the two flanking type III units are split in two exons at variable positions. When an alpha-globin/FN gene hybrid construct, containing the ED exon, flanking introns and neighbouring FN exons, is transfected into HeLa cells, two hybrid mRNAs differing by the ED exon are synthesized. These experiments confirmed that the two FN mRNAs observed in vivo arise from the same gene by alternative splicing.     

An in-silico study of alphaherpesviruses ICP0 genes: positive selection or strong mutational GC-pressure?

The purpose of our work was to analyze the case of the strong mutational GC-pressure influence on the ratio between nonsynonymous (DN) and synonymous (DS) distances (DN/DS ratio). We have used as the material the genes coding for ICP0 from five completely sequenced genomes of simplexviruses. DN/DS ratio, total GC-content (G + C), and GC-content in first, second, and third codon positions (1GC, 2GC, and 3GC, respectively) have been calculated separately for exon 2, nonconserved part of exon 3, and conserved part of exon 3 from ICP0 genes. Results showed that DN is more than DS only in the conserved part of exon 3 of ICP0 genes from cercopithecine herpesvirus 2 and cercopithecine herpesvirus 16. However, the cause of this result (DN/DS = 2.54) is the GC-pressure acting on the coding districts with 3GC = 99% rather than the biological process called positive selection. Only in these two viruses, because of the strong GC-pressure, 3GC has reached 99% in the conserved part of ICP0 exon 3, and so nucleotide substitutions that increase the GC-content practically cannot occur in third codon positions, where most substitutions are synonymous. In this case, GC-pressure has a substrate for nucleotide substitutions only in first and second codon positions, where most substitutions are nonsynonymous.     

Secretion by Saccharomyces cerevisiae of rat apolipoprotein E as a fusion to Mucor rennin

As the first step for production of rat apolipoprotein E (rApoE) in Saccharomyces cerevisiae, the rApoE cDNA was cloned and its nucleotide sequence was determined. When the intact rApoE gene including the presequence-encoding region was expressed under the control of the yeast GAL7 promoter, no protein immunoreactive with anti-rApoE antibody was detected either in the culture medium or inside the cells. For the purpose of the extracellular production of rApoE, three fusion genes were constructed in which the mature rApoE-encoding sequence was connected after the pre, prepro, and whole regions of the gene encoding a fungal aspartic proteinase, Mucor pusillus rennin (MPP), since MPP is efficiently secreted from recombinant S. cerevisiae containing the MPP gene. When these three fusion genes were expressed under the control of the GAL7 promoter, only one, encoding the mature rApoE connected to the whole MPP sequence, directed efficient secretion of the fused protein. The maximum yield of the fused protein secreted into the medium reached 11.8 mg/l and the calculated rApoE part was 5.3 mg in the fused protein. The excreted fusion protein was glycosylated at the original two sites in the MPP part. The fused protein was gradually degraded in the medium probably by proteases of the host cell, because no such degradation occured in a yeast pep4mutant strain.