Contrasting effects of mismatch locations on Z-DNA formation under bending force

Abstract

Z-DNA is a non-canonical, left-handed helical structure that plays crucial roles in various cellular processes. DNA mismatches, which involve the incorporation of incorrect Watson–Crick base pairs, are present in all living organisms and contribute to the mechanism of Z-DNA formation. However, the impact of mismatches on Z-DNA formation remains poorly understood. Moreover, the combined effect of DNA mismatches and bending, a common biological phenomenon observed in vivo, has not yet been explored due to technological limitations. Here, using single-molecule FRET, we show that a mismatch inside the Z-DNA region, i.e., the CG repeat region, hinders Z-DNA formation. In stark contrast, however, a mismatch in the B–Z junction facilitates Z-DNA formation. When the bending force is applied on double stranded DNA, a mismatch in the B–Z junction releases the bending stress more effectively than one in the CG repeat region. These findings provide mechanical insights into the role of DNA mismatches and bending forces in regulating Z-DNA formation, whether promoting or inhibiting it in biological environments.