Characterization of the human platelet glycoprotein IIIa gene. Comparison with the fibronectin receptor beta-subunit gene

This study was designed to determine the structure of the gene for glycoprotein (GP) GPIIIa, the beta-subunit of the platelet membrane GPIIb-IIIa complex. The complexity of the gene was determined after Southern analysis of human chromosomal DNA. Overlapping genomic clones were isolated from cosmid and phage lambda libraries that contained the entire coding unit of the human gene for the mature GPIIIa protein. The genomic clones spanned approximately 60 kilobase pairs of human DNA sequence. The exon containing segments of the clones was mapped and the exons, including the exonintron junctions, were sequenced. The GPIIIa protein is divided into 14 exons ranging in size from 87 to 430 nucleotides separated by introns, which were 0.3 to 9 kilobase pairs in size. The 3' exon was larger than 1700 nucleotides and contained the 3'-untranslated region. Several structural domains of the GPIIIa protein were contained within individual exons. These included (i) the transmembrane spanning segment, (ii) the cytoplasmic region containing the potential phosphorylation sites, and (iii) the six domains in the NH2-terminal half of GPIIIa that are highly conserved between two other integrin beta-subunits. In contrast, other domains such as the four cysteine-rich repeats were interrupted by introns. Genomic clones for the beta-subunit of the fibronectin receptor (beta 1) were also isolated, partially mapped, and sequenced. Of the eight splice sites identified in beta 1, six occurred at the same amino acid residue in GPIIIa. These results provide genetic evidence that GPIIIa and beta 1 have a common evolutionary origin within the integrin family.     

Evolution of the fibronectin gene. Exon structure of cell attachment domain

Genomic DNA coding for human fibronectin was identified from a human genomic library by screening with a cDNA clone that specifies the cell attachment domain in human fibronectin. Two clones which together provided more than 22 kilobase pairs of the fibronectin gene were isolated. The exons in this region correspond to approximately 40% of the coding region in the fibronectin gene. They code for the middle region of the polypeptide which consists of homologous repeating segments of about 90 amino acids called type III homologies. Nucleotide sequence of the portion of the gene corresponding to the cell attachment domain showed that the Arg-Gly-Asp-Ser cell attachment site is encoded within a 165-base pair exon. This exon, together with a 117-base pair exon codes for a homology unit. Analysis of the exon/intron organization in some of the neighboring homology units indicated a similar 2-exon structure. An exception to this pattern is that a single large exon codes for a type III homology unit that, due to alternative mRNA splicing, exists in some but not all fibronectin polypeptides. The introns separating the coding sequences for the type III homology units are located in conserved positions whereas the introns that interrupt the coding sequence within the units are in a variable position generating variations in the size of the homologous exons. This exon/intron organization suggests that the type III homology region of the fibronectin gene has evolved by a series of gene duplications of a primordial gene consisting of two exons. Specification of one of these homology units to the cell attachment domain has occurred within this exon/intron arrangement.     

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.     

Rapid changes in the exon/intron structure of a mammalian thrombin inhibitor gene

The genomic organization of the heparin cofactor II (HCII) gene from rat and mouse was investigated and compared with their human counterpart. The genes share a common core structure consisting of five exons interrupted by four introns, but the mouse and rat gene reveal individual additional features. A unique differentially spliced exon is present in the 5'-untranslated region of the rat gene, which most probably has arisen de novo by point mutations in intronic sequences of the ancestor gene. In the mouse HCII gene, a novel intron/exon boundary has been created due to the presence of an additional DNA segment, which simultaneously provides a 3'-splice site and a polypyrimidine stretch leading to an alternatively used exon of increased size. Our data suggest that, in contrast to most other mammalian genes, the exon/intron pattern of the gene coding for HCII is in dynamic evolution.     

Structure of a gene for rat calmodulin

The structural organization of the entire rat calmodulin gene was determined by cloning and sequencing overlapping genomic and cDNA clones from rat genomic and brain cDNA libraries. The intron/exon organization was determined by direct comparison of these sequences. Rat calmodulin gene is 9000 bases long and consisted of six exons interrupted by introns of variable sizes. The first intron separates the initiation codon (ATG) from the coding region of the protein. Three out of four intron/exon junctions in the coding region reside in the middle of calcium binding subdomains and do not correlate with the quarterly divided intramolecular homology of the protein. Their positions exactly coincide with those of the corrected version of chicken calmodulin gene. The rat calmodulin gene harbors a stretch of sequences homologous to a rat middle repetitive "identifier sequence" in the middle of the third intron. Analysis of the immediate 5' upstream region detected a TATA box (TATATATAT) and three C-G boxes (CCGCCC) but not a CAT box (CCAAT). A conserved sequence (GCGCCGCGYCYYGGGGGC) was found at -125 for rat and at -204 for chicken calmodulin genes.     

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.