Isolation and characterization of human glycophorin A cDNA clones by a synthetic oligonucleotide approach: nucleotide sequence and mRNA structure

Abstract

In an effort to understand the relationships among and the regulation of human glycophorins, we have isolated and characterized several glycophorin A-specific cDNA clones obtained from a human erythroleukemic K562 cell cDNA library. This was accomplished by using mixed synthetic oligonucleotides, corresponding to various regions of the known amino acid sequence, to prime the synthesis of the cDNA as well as to screen the cDNA library. We also used synthetic oligonucleotides to sequence the largest of the glycophorin cDNAs. The nucleotide sequence obtained suggests the presence of a potential leader peptide, consistent with the membrane localization of this glycoprotein. Examination of the structure of glycophorin mRNA by blot hybridization revealed the existence of several electrophoretically distinct mRNAs numbering three or four, depending on the size of the glycophorin cDNA used as a hybridization probe. The smaller cDNA hybridized to three mRNAs of approximately 2.8, 1.7, and 1.0 kilobases. In contrast, the larger cDNA hybridized to an additional mRNA of approximately 0.6 kilobases. Further examination of the relationships between these multiple mRNAs by blot hybridization was conducted with the use of exact-sequence oligonucleotide probes constructed from various regions of the cDNA representing portions of the amino acid sequence of glycophorin A with or without known homology with glycophorin B. In total, the results obtained are consistent with our hypothesis that the three larger mRNAs represent glycophorin A gene transcripts and that the smallest (0.6 kilobase) mRNA may be specific for glycophorin B.