Purpose: Antigene radiotherapy (AR) is based on targeting localized radiodamage to specific sites in the genome by using sequence-specific triplex-forming oligonucleotides (TFO) to carry Auger-electron-emitters (A-Ettr) such as Iodine-125 ( 125I) to the target gene sequence. The radiodecay of an A-Ettr produces a cascade of low-energy electrons and creates a highly positively-charged daughter atom; delivered by a TFO, it should produce double-strand breaks (dsb) localized to the specific DNA target sequence. The result should be a “knock-out” of the targeted gene. Methods and Materials: As a model, we used the MDR1 gene amplified nearly 100 times in the human KB-V1 carcinoma cell line. Chemically modified TFO complementary to the polypurine/polypyrimidine region of the MDR1 gene were synthesized and radiolabeled with 125I-dCTP by the primer extension method. Purified plasmid and genomic DNA and extracted nuclei were treated with 125I-TFO and analyzed for sequence-specific cleavage by electrophoresis in agarose gel and Southern hybridization. Results: We created 125I-TFO that could effectively recognize, bind, and cleave the target sequence in plasmid and genomic DNA. We showed that these 125I-TFO in nanomolar concentrations were able to cleave the target MDR1 gene sequence in a natural environment, i.e., within the eucaryotic nucleus. Conclusion: 125I-TFO can effectively introduce sequence-specific dsb to a target within the MDR1 gene, both in purified DNA and inside intact nuclei. Chemically modified TFO conjugated with nuclear localization signal appear to be a promising delivery vehicle for future in vivo trials of AR.