Sequence-specific cleavage of double helical DNA by triple helix formation
HE Moser, PB Dervan - Science, 1987 - science.org
HE Moser, PB Dervan
Science, 1987•science.orgHomopyrimidine oligodeoxyribonucleotides with EDTA⋅ Fe attached at a single position
bind the corresponding homopyrimidine-homopurine tracts within large double-stranded
DNA by triple helix formation and cleave at that site. Oligonucleotides with EDTA⋅ Fe at the
5′ end cause a sequence specific double strand break. The location and asymmetry of the
cleavage pattern reveal that the homopyrimidine-EDTA probes bind in the major groove
parallel to the homopurine strand of Watson-Crick double helical DNA. The sequence …
bind the corresponding homopyrimidine-homopurine tracts within large double-stranded
DNA by triple helix formation and cleave at that site. Oligonucleotides with EDTA⋅ Fe at the
5′ end cause a sequence specific double strand break. The location and asymmetry of the
cleavage pattern reveal that the homopyrimidine-EDTA probes bind in the major groove
parallel to the homopurine strand of Watson-Crick double helical DNA. The sequence …
Homopyrimidine oligodeoxyribonucleotides with EDTA⋅Fe attached at a single position bind the corresponding homopyrimidine-homopurine tracts within large double-stranded DNA by triple helix formation and cleave at that site. Oligonucleotides with EDTA⋅Fe at the 5′ end cause a sequence specific double strand break. The location and asymmetry of the cleavage pattern reveal that the homopyrimidine-EDTA probes bind in the major groove parallel to the homopurine strand of Watson-Crick double helical DNA. The sequence-specific recognition of double helical DNA by homopyrimidine probes is sensitive to single base mismatches. Homopyrimidine probes equipped with DNA cleaving moieties could be useful tools for mapping chromosomes.
AAAS