Site-specific base changes in the coding or promoter region of the human beta- and gamma-globin genes by single-stranded oligonucleotides.

SSOs (single-stranded oligonucleotides) can mediate site-specific alteration of base-pairs in episomal and chromosomal target genes in mammalian cells. The TNE (targeted nucleotide exchange) can result in either repair or mutation of a gene sequence and is mediated through endogenous DNA repair pathway(s). Thus the approach provides a technique for the treatment of monogenic disorders associated with specific point mutations such as SCD (sickle cell disease). We studied the potential application of SSOs for SCD by introducing either an A to T substitution at the sixth codon of the human beta-globin gene (sickle locus) or a C to G mutation at -202 of the Ggamma-globin gene promoter region. The latter TNE is an alternative strategy to ameliorate the clinical manifestations of sickle cell anaemia by re-activating fetal haemoglobin gene expression in adult erythrocytes. A sensitive and valid PCR assay system was developed, which allows detection of point mutations as low as 0.01% at these sites. Using this system, TNE between 0.01 and 0.1% at the sickle locus or gamma-globin gene promoter region was detected after transfection with SSOs in cultured human cell lines. TNE in the Ggamma-globin promoter region exhibited varying degrees of strand bias that was dependent on SSO design and the cell's DNA mismatch repair activity. The results suggest that the endogenous DNA repair machinery may permit SSO correction of the sickle defect by modification of the beta- and/or gamma-globin genes.