Nucleotide sequence and organization of the human S-protein gene: repeating peptide motifs in the "pexin" family and a model for their evolution

The S-protein/vitronectin gene was isolated from a human genomic DNA library, and its sequence of about 5.3 kilobases including the adjacent 5' and 3' flanking regions was established. Alignment of the genomic DNA nucleotide sequence and the cDNA sequence indicated that the gene consisted of eight exons and seven introns. The intron positions in the S-protein gene and their phase type were compared to those in the hemopexin gene which shares amino acid sequence homologies with transin and the S-protein. Three introns have been found at equivalent positions; two other introns are very close to these positions and are interpreted as cases of intron sliding. Introns 3-7 occur at a conserved glycine residue within repeating peptide segments, whereas introns 1 and 2 are at the boundaries of the Somatomedin B domain of S-protein. The analysis of the exon structure in relation to repeating peptide motifs within the S-protein strongly suggests that it contains only seven repeats, one less than the hemopexin molecule. A very similar repeat pattern like that in hemopexin is shown to be present also in two other related proteins, transin and interstitial collagenase. An evolutionary model for the generation of the repeat pattern in the S-protein and the other members of this novel "pexin" gene family is proposed, and the sequence modifications for some of the repeats during divergent evolution are discussed in relation to known unique functional properties of hemopexin and S-protein.     

Guinea pigs possess a highly mutated gene for L-gulono-gamma-lactone oxidase, the key enzyme for L-ascorbic acid biosynthesis missing in this species.

Guinea pigs cannot synthesize L-ascorbic acid because of their deficiency in L-gulono-gamma-lactone oxidase, a key enzyme for the biosynthesis of this vitamin in higher animals. In this study we isolated the L-gulono-gamma-lactone oxidase gene of the rat and the homologue of this gene of the guinea pig by screening rat and guinea pig genomic DNA libraries in lambda phage vectors, respectively, using a rat L-gulono-gamma-lactone oxidase cDNA as a probe. Sequencing analysis showed that the amino acid sequence of the rat enzyme is encoded by 12 exons and that all the intron/exon boundaries follow the GT/AG rule. On the other hand, regions corresponding to exons I and V were not identified in the guinea pig L-gulono-gamma-lactone oxidase gene homologue. Other defects found in this gene homologue are a deletion of the nucleotide sequence corresponding to a 3' 84-base pair part of rat exon VI, a 2-base pair deletion in the remaining exon VI-related region, and nonconformance to the GT/AG rule at one of the putative intron/exon boundaries. Furthermore, a large number of mutations were found in the amino acid-coding regions of the guinea pig sequence; more than half of them lead to nonconservative amino acid changes, and there are three stop codons as well. Thus it is clear that the guinea pig homologue of the L-gulono-gamma-lactone oxidase gene exists as a pseudogene that randomly accumulated a large number of mutations without functional constraint since the gene ceased to be active during evolution. On the basis of the neutral theory of evolution, the date of the loss of L-gulono-gamma-lactone oxidase in the ancestors of the guinea pig was roughly calculated to be less than 20 million years ago.     

Splicing defects in the ataxia-telangiectasia gene, ATM: underlying mutations and consequences.

Mutations resulting in defective splicing constitute a significant proportion (30/62 [48%]) of a new series of mutations in the ATM gene in patients with ataxia-telangiectasia (AT) that were detected by the protein-truncation assay followed by sequence analysis of genomic DNA. Fewer than half of the splicing mutations involved the canonical AG splice-acceptor site or GT splice-donor site. A higher percentage of mutations occurred at less stringently conserved sites, including silent mutations of the last nucleotide of exons, mutations in nucleotides other than the conserved AG and GT in the consensus splice sites, and creation of splice-acceptor or splice-donor sites in either introns or exons. These splicing mutations led to a variety of consequences, including exon skipping and, to a lesser degree, intron retention, activation of cryptic splice sites, or creation of new splice sites. In addition, 5 of 12 nonsense mutations and 1 missense mutation were associated with deletion in the cDNA of the exons in which the mutations occurred. No ATM protein was detected by western blotting in any AT cell line in which splicing mutations were identified. Several cases of exon skipping in both normal controls and patients for whom no underlying defect could be found in genomic DNA were also observed, suggesting caution in the interpretation of exon deletions observed in ATM cDNA when there is no accompanying identification of genomic mutations.     

Structure of the murine complement factor H gene

Factor H is a regulatory protein of the alternative pathway of complement activation comprised of 20 tandem repeating units of 60 amino acids each. A factor H cDNA clone was used to identify 17 genomic clones from a cosmid library. Four clones were selected for analysis of intron/exon junctions and 5' and 3' regions of the gene and for mapping of the exons. The factor H gene was found to be comprised of 22 exons. Each repeating unit is encoded by one exon, except the second repeat, which is coded by two exons; the leader sequence is encoded by a separate exon. The exons range in size from 77 to 210 base pairs (bp) and average 178 bp. They span a region of approximately 100 kilobases (kb) on chromosome 1. The leader sequence exon is 26 kb upstream of the first repeat exon, representing the largest intron. The other introns range in size from 86 bp to 12.9 kb, and the average intron size is 4.7 kb. Analysis of the genomic organization of the factor H gene has provided insight into the protein structure and will enable the construction of deletion mutants for functional studies.     

Molecular analysis of hprt mutants induced by 2-cyanoethylene oxide in human lymphoblastoid cells

The mutagenic epoxide metabolite of acrylonitrile, 2-cyanoethylene oxide (ANO), was used to treat human TK6 lymphoblasts (150 microM x 2 h ANO). A collection of hypoxanthine-phosphoribosyltransferase (hprt) mutants was isolated and characterized by dideoxy sequencing of cloned hprt cDNA. Base-pair substitution mutations in the hprt coding region were observed in 19/39 of hprt mutants: 11 occurred at AT base pairs and 8 at GC base pairs. Two -1 frameshift mutations involving GC bases were also observed. Approximately half (17/39) of the hprt mutants displayed the complete loss of single and multiple exons from hprt cDNA, as well as small deletions, some extending from exon/exon junctions. Southern blot analysis of 5 mutants with single exon losses revealed no visible alterations. Analysis of 1 mutant missing exons 3-6 in its hprt mRNA revealed a visible deletion in the corresponding region in its genomic DNA. The missing exon regions of 4 mutants (one each with exons 6, 7 and 8 loss and one mutant with a 17-base deletion of the 5' region of exon 9) were PCR amplified from genomic DNA and analyzed by Southern blot using exon-specific probes. The exons missing from the hprt mRNA were present in the genomic hprt sequence. DNA sequencing of the appropriate intron/exon regions of hprt genomic DNA from a mutant with exon 8 loss and a mutant exhibiting aberrant splicing in exon 9 revealed point mutations in the splice acceptor site of exon 8 (T----A) and exon 9 (A----G), respectively.     

Nucleotide sequence of the gene for the b subunit of human factor XIII

Factor XIII (Mr 320,000) is a blood coagulation factor that stabilizes and strengthens the fibrin clot. It circulates in blood as a tetramer composed of two a subunits (Mr 75,000 each) and two b subunits (Mr 80,000 each). The b subunit consists of 641 amino acids and includes 10 tandem repeats of 60 amino acids known as GP-I structures, short consensus repeats (SCR), or sushi domains. In the present study, the human gene for the b subunit has been isolated from three different genomic libraries prepared in lambda phage. Fifteen independent phage with inserts coding for the entire gene were isolated and characterized by restriction mapping, Southern blotting, and DNA sequencing. The gene was found to be 28 kilobases in length and consisted of 12 exons (I-XII) separated by 11 intervening sequences. The leader sequence was encoded by exon I, while the carbonyl-terminal region of the protein was encoded by exon XII. Exons II-XI each coded for a single sushi domain, suggesting that the gene evolved through exon shuffling and duplication. The 12 exons in the gene ranged in size from 64 to 222 base pairs, while the introns ranged in size from 87 to 9970 nucleotides and made up 92% of the gene. The introns contained four Alu repetitive sequences, one each in introns A, E, I, and J. A fifth Alu repeat was present in the flanking 3' end of the gene. Two partial KpnI repeats were also found in the introns, including one in intron I and one in intron J. The KpnI repeat in intron J was 89% homologous to a sequence of approximately 2200 nucleotides flanking the gene coding for human beta globin and approximately 3800 nucleotides from the L1 insertion present in the gene for human factor VIII. Intron H also contained an "O" family repeat, while two potential regions for Z-DNA were identified within introns G and J. One nucleotide change was found in the coding region of the gene when its sequence was compared to that of the cDNA. This difference, however, did not result in a change in the amino acid sequence of the protein.     

Partial nucleotide sequence of a bovine major histocompatibility class II DR beta-like gene

A genomic clone containing a bovine DR beta-like gene, BoDR beta II, was isolated from a bovine genomic library and characterized by restriction enzyme mapping and nucleotide sequencing of exon regions. Alignment of this sequence with the human DR beta cDNA sequence allowed identification of exon/intron boundaries. The clone contains a 13.3-kilobase (kb) insert, and includes 1.3 kb 5' of the beta 1 exon and 6.7 kb 3' of the transmembrane (TM) exon. Open reading frames were present in the BoDR beta exons sequenced. Nucleotide identities of the bovine beta 1, beta 2 and TM exons with the corresponding human DR beta exons were 73, 91 and 83%, respectively. Nucleotide identities of these exons with those of a previously described bovine DR beta-like pseudogene, BoDR beta I, were 69, 95 and 81%, respectively. Although a limited amount of sequence data was obtained for the intron regions, a 71% identity was found within a 514-nucleotide region immediately 3' to the beta 2 exons in BoDR beta I and BoDR beta II. A series of GT residues followed by a longer series of GA residues began about 35 nucleotides 3' of the beta 1 exon in both BoDR beta I and BoDR beta II.     

Human urate oxidase gene: cloning and partial sequence analysis reveal a stop codon within the fifth exon

Using the cDNA and selected genomic probes of rat urate oxidase, we have screened the human genomic library and isolated seven clones; one clone (clone 13) contained exonic regions which correspond to the exons 5, 6, and 7 of rat urate oxidase gene. The nucleotide sequence was determined for these three exons and exon/intron junctions, and compared with the sequence from the rat gene. A mutation resulting in a stop codon TGA was found in the fifth exon of the human urate oxidase gene. Sequence analysis of the polymerase chain reaction amplified DNA, corresponding to the fifth exon of urate oxidase from DNA samples from four different individuals, confirmed the same TGA stop codon in all. This single stop codon mutation and/or other mutation(s) in this gene may be responsible for the lack of urate oxidase activity in the human.     

Structure and expression of the mouse prealbumin gene

We cloned a genomic DNA fragment which covers the entire sequence of the mouse prealbumin gene and then studied the structure. The coding regions are separated into four exons by three introns, and these numbers, the sizes of the exons and the relative sites of the exon-intron junctions are all in complete agreement with those determined for the human gene. The sequences of four exons can be aligned perfectly with that of the previously determined mouse prealbumin cDNA. In addition to the exon regions, we found two highly conserved DNA regions between the mouse and human prealbumin genes, one in the 5'-flanking region of the gene and the other in the 3' end region of the first intron. These DNA regions contain several consensus glucocorticoid receptor-binding site sequences, and the latter also contains an enhancer sequence present in the immunoglobulin kappa-chain joining-constant kappa intron. RNA hybridizing to the mouse prealbumin cDNA was detected in the extracts from liver, brain, and kidney, but was not detected in testes, spleen, or heart. Little change was caused in the level of prealbumin mRNA in the liver by administration of dexamethasone to mice.     

Gene structure of human and mouse methylenetetrahydrofolate reductase (MTHFR)

Methylenetetrahydrofolate reductase (MTHFR) catalyzes the conversion of 5,10-methylenetetrahydrofolate to 5-methyltetrahydrofolate, a co-substrate for homocysteine remethylation to methionine. A human cDNA for MTHFR, 2.2 kb in length, has been expressed and shown to result in a catalytically active enzyme of approximately 70 kDa. Fifteen mutations have been identified in the MTHFR gene: 14 rare mutations associated with severe enzymatic deficiency and 1 common variant associated with a milder deficiency. The common polymorphism has been implicated in three multifactorial diseases: occlusive vascular disease, neural tube defects, and colon cancer. The human gene has been mapped to chromosomal region 1p36.3 while the mouse gene has been localized to distal Chromosome (Chr) 4. Here we report the isolation and characterization of the human and mouse genes for MTHFR. A human genomic clone (17 kb) was found to contain the entire cDNA sequence of 2.2 kb; there were 11 exons ranging in size from 102 bp to 432 bp. Intron sizes ranged from 250 bp to 1.5 kb with one exception of 4.2 kb. The mouse genomic clones (19 kb) start 7 kb 5′ exon 1 and extend to the end of the coding sequence. The mouse amino acid sequence is approximately 90% identical to the corresponding human sequence. The exon sizes, locations of intronic boundaries, and intron sizes are also quite similar between the two species. The availability of human genomic clones has been useful in designing primers for exon amplification and mutation detection. The mouse genomic clones will be helpful in designing constructs for gene targeting and generation of mouse models for MTHFR deficiency. Received: 28 January 1998 / Accepted: 9 April 1998     

Determination of the exon structure of the distal portion of the dystrophin gene by vectorette PCR

The structure of the 3' one-third of the dystrophin gene has not previously been established. We have used vectorette PCR on a yeast artificial chromosome containing part of the human dystrophin gene to determine that there are 20 exons in this region and to characterize adjacent intron sequences of each one. Combined with previous information on the remainder of the gene, this study shows that the coding sequence is distributed between 79 exons. We have used PCR between exons to measure the distances that separate the more closely clustered exons. Vectorette PCR products were used as probes on Southern blots to assign all the 3' exons to genomic HindIII fragments that are commonly detected in the analysis of dystrophin gene deletions. The results will be useful for determining the effect of genomic deletions on the translational reading frame, for setting up genomic PCR assays to confirm point mutations, for analyzing splice site mutations, and for investigating potential cis-acting elements involved in tissue-specific alternative splicing. Vectorette PCR using primers derived from cDNA sequence represents an efficient and widely applicable method for establishing gene structure and obtaining intron sequence flanking exons, starting from a genomic clone and a cDNA sequence.     

Isolation of the osteonectin gene: evidence that a variable region of the osteonectin molecule is encoded within one exon

A complementary DNA clone for bovine osteonectin was used to isolate the osteonectin gene from two libraries of bovine genomic DNA fragments. Two overlapping clones were obtained whose relationship was determined by restriction mapping and sequence analysis. The two clones contain the entire osteonectin coding region spanning approximately 11 kilobases of genomic DNA. The coding region of the gene was determined, by electron microscopy and DNA sequencing, to reside in nine exons. In addition, there is at least one 5' exon interrupted by an intron in the 5'-nontranslated sequence of the gene. Excluding this 5' exon and the 3'-terminal exon, the exons are small and approximately uniform in size, averaging 130 +/- 17 base pairs. Three of the exons at the 5' end of the gene were sequenced and appear to encode discrete protein domains. For example, the putative exon 2 contains the coding region for the leader peptide of the molecule. The amino-terminal protein sequence was determined for osteonectin extracted from human, rabbit, and chicken bone and compared with those for bovine, mouse, and pig osteonectin. These data suggest that osteonectin is highly conserved between species, interspecies changes being seen primarily at the amino terminus of the protein and specifically in the region encoded by putative exon 3 in the bovine gene.     

Genomic organization and mutational analysis of HERG, a gene responsible for familial long QT syndrome

Familial long QT syndrome (LQTS) is characterized by prolonged ventricular repolarization. Clinical symptoms include recurrent syncopal attacks, and sudden death may occur as a result of ventricular tachyarrhythmias. Three genes responsible for this syndrome (KVLQT1, HERG, and SCN5A) have been identified so far, and mutations have been reported on the basis of partially characterized genomic organization. To optimize the search for HERG mutations, we have determined the genomic structure of HERG and investigated mutations in LQTS families. Human genomic clones containing the HERG gene were isolated from a human genomic library by using reverse-transcribed polymerase chain reaction (RT-PCR) products from this gene as probes. We determined exon/intron boundaries and flanking intronic sequences by using primers synthesized on the basis of the HERG cDNA sequence available in the DNA database. HERG was shown to consist of 15 exons spanning approximately 19 kb on chromosome 7q35. Subsequently, we synthesized oligonucleotide primers to cover the entire coding region and searched for mutations in 36 Japanese LQTS families. When genomic DNA from each proband was examined by the PCR/single-strand conformation polymorphism technique followed by direct DNA sequencing, five novel mutations were detected. Each mutation was present in affected relatives of the respective proband. This work should increase the efficiency of screening mutations associated with HERG. Received: 4 November 1997 / Accepted: 5 January 1998