posted on 2021-07-08, 15:22authored byRobert
J. Fick, Amy Y. Liu, Felix Nussbaumer, Christoph Kreutz, Atul Rangadurai, Yu Xu, Roger D. Sommer, Honglue Shi, Steve Scheiner, Allison L. Stelling
Measuring the strength
of the hydrogen bonds between DNA base pairs
is of vital importance for understanding how our genetic code is physically
accessed and recognized in cells, particularly during replication
and transcription. Therefore, it is important to develop probes for
these key hydrogen bonds (H-bonds) that dictate events critical to
cellular function, such as the localized melting of DNA. The vibrations
of carbonyl bonds are well-known probes of their H-bonding environment,
and their signals can be observed with infrared (IR) spectroscopy.
Yet, pinpointing a single bond of interest in the complex IR spectrum
of DNA is challenging due to the large number of carbonyl signals
that overlap with each other. Here, we develop a method using isotope
editing and infrared (IR) spectroscopy to isolate IR signals from
the thymine (T) C2O carbonyl. We use solvatochromatic studies
to show that the TC2O signal’s position in the IR spectrum
is sensitive to the H-bonding capacity of the solvent. Our results
indicate that C2O of a single T base within DNA duplexes experiences
weak H-bonding interactions. This finding is consistent with the existence
of a third, noncanonical CH···O H-bond between adenine
and thymine in both Watson–Crick and Hoogsteen base pairs in
DNA.