Summary
The human hemopexin gene was isolated and its structure determined. The gene spans approximately 12 kb and is interrupted by nine introns. When the intron/exon pattern was examined with respect to the polypeptide segments they encode, a direct correspondence between exons and the 10 repeating units in the protein was observed. The introns are not randomly placed; they fall in the middle of the region of amino acid sequence homology in strikingly similar locations in 6 of the 10 units and in a symmetrical position in the two halves of the coding sequence. These features strongly support the hypothesis that the gene evolved through intron-mediated duplications of a primordial sequence to a five-exon cluster. A more recent gene duplication led to the present-day gene organization.
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Altruda, F., Poli, V., Restagno, G. et al. Structure of the human hemopexin gene and evidence for intron-mediated evolution. J Mol Evol 27, 102–108 (1988). https://doi.org/10.1007/BF02138368
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DOI: https://doi.org/10.1007/BF02138368