Experimental strategies have been developed to correct point mutations using chimeric oligonucleotides composed of RNA and DNA. We used these RNA-DNA oligonucleotides to correct a point mutation in mouse tyrosinase, a key enzyme for melanin synthesis and pigmentation. Melanocytes derived from albino mice contain a homozygous point mutation (TGT→ TCT) in the tyrosinase gene, resulting in an amino acid change from Cys→ Ser. Correction of this point mutation results in the restoration of tyrosinase activity and melanin synthesis, thus changing the pigmentation of the cells. Upon transfection of the RNA-DNA oligonucleotide to albino melanocytes, we detected black-pigmented cells and isolated multiple single clones. All black-pigmented clones exhibited a correction of the point mutation in a single allele of the tyrosinase gene. A full-length tyrosinase was detected by an antityrosinase antibody, and the enzymatic activity was restored in all converted black-pigmented clones. Only degraded fragments were detected in albino cells due to proteolytic cleavage of mutant tyrosinase. The phenotype and genotype of converted black-pigmented clones was stable. These results demonstrate a permanent and stable gene correction by the RNA-DNA oligonucleotide at the level of genomic sequence, protein, and phenotypic change by clonal analysis.