Figure 1.
GP VI gene structure and targeted disruption. (A) The mouse GP VI gene is schematically presented as it spans a portion of GenBank Accession no. AC087129.1. Based on an alignment of the mouse GP VI cDNA sequence and genomic sequence, 8 exons (▦) and introns were identified. By sequence alignment with the human GP VI cDNA, a putative initiating Met codon (ATG) is shown in exon 1. (B) An expanded region of the wild-type mouse GP VI gene containing exons 1 to 3 is shown. (C) A 9-kb HindIII restriction fragment spanning exons 1 to 3 was subcloned into a pBS/KS-vector and altered via site-directed mutagenesis to place a stop codon (TGA) immediately 3′ to the initiating Met codon followed by an XhoI restriction site. Following successful mutagenesis a neocassette was cloned within the exon 1 sequence using the restriction site created during mutagenesis. (D) Successful homologous recombination in mouse ES cells results in the replacement of a 7-kb HincII restriction fragment with an 8.7-kb HincII fragment. (E) Germ line transmission of the ES cell genotype was obtained producing GP VIhet mice. The breeding of GP VIhet mice produced the expected 3 genotypes and shown is a representative Southern blot of each of the genotypes revealing the wild-type GP VI gene (7 kb) and the targeted allele (8.7 kb). (F) A mouse monoclonal antibody recognizing both human and mouse GP VI proteins was used to verify the lack of the GP VI polypeptide in platelet lysates from GP VInull mice. Shown is a Western blot of platelet lysates from each of the 3 genotypes. A gene dosage effect of GP VI levels is seen as a consequence of the altered GP VI allele. (G) The same filter was reprobed with an anti–14-3-3ζ polyclonal antibody to confirm the presence of platelet proteins in each lane.