RESUMEN
Guanine quadruplexes (GQs), important for genome stability and biotechnology application, can form from both DNA and RNA. However, unlike the study of DNA GQs, little research has been conducted on excited states of GQs from RNA, which due to the ribose 2'-hydroxy group have structures distinct from their DNA counterparts. Combining ultrafast broadband time-resolved fluorescence and transient absorption measurements, we report the first direct probe of excitation dynamics for a bimolecular GQ from human telomeric repeat-containing RNA taking the typical highly compacted parallel folding with a propeller-like loop structure. The result revealed a multichannel decay containing an unusual high-energy excimer featuring charge transfer deactivated by rapid proton transfer in the tetrad core region. It also identified an unprecedented exciplex displaying massively red-shifted fluorescence produced from charge transfer in the loop region. The findings underscore the role of structural conformation and base content in determining the energy, electronic attribution, and decay dynamics of GQ excited states.
Asunto(s)
G-Cuádruplex , Protones , Humanos , ARN/química , Análisis Espectral , ADN/químicaRESUMEN
In contrast to the immense amount of research on electronically excited DNA, surprisingly little has been done about the excited states of RNA. Herein, we demonstrate an ultrafast broadband time-resolved fluorescence and fluorescence anisotropy study to probe directly the intrinsic fluorescence and overall dynamics of the fluorescence from a homopolymeric adenine·uracil RNA duplex adopting the A-form structure. The results unveiled complex deactivation through distinctive multichannels mediated by states of varied energy, a character of charge transfer, and a lifetime from sub-picosecond to nanoseconds. In particular, we observed an unprecedented kinetic isotopic effect and participation of unusual proton transfer from states in two discrete energies and time domains. We also identified a high-energy nanosecond emission that we attributed to its fluorescence anisotropy to long-lived weakly emissive excitons not reported in DNA. These distinguishing features originate from the stacking, pairing, and local hydration environment specific to the A-form conformation of the adenine·uracil double helix.