Abstract
We have observed the conformation-dependent electronic coupling between the monomeric subunits of a dinucleotide of 2-aminopurine (2-AP), a fluorescent analogue of the nucleic acid base adenine. This was accomplished by extending two-dimensional fluorescence spectroscopy (2D FS)—a fluorescence-detected variation of 2D electronic spectroscopy—to excite molecular transitions in the ultraviolet (UV) regime. A collinear sequence of four ultrafast laser pulses centered at 323 nm was used to resonantly excite the coupled transitions of 2-AP dinucleotide. The phases of the optical pulses were continuously swept at kilohertz frequencies, and the ensuing nonlinear fluorescence was phase-synchronously detected at 370 nm. Upon optimization of a point–dipole coupling model to our data, we found that in aqueous buffer the 2-AP dinucleotide adopts an average conformation in which the purine bases are non-helically stacked (center-to-center distance R12 = 3.5 ± 0.5 Å , twist angle θ12 = 5° ± 5° ), which differs from the conformation of such adjacent bases in duplex DNA. These experiments establish UV–2D FS as a method for examining the local conformations of an adjacent pair of fluorescent nucleotides substituted into specific DNA or RNA constructs, which will serve as a powerful probe to interpret, in structural terms, biologically significant local conformational changes within the nucleic acid framework of protein–nucleic acid complexes.
Highlights
The conformational manipulation of nucleic acid bases within functioning ‘macromolecular machines’ is a central feature of DNA replication and RNA transcription reactions
We introduce two-dimensional fluorescence spectroscopy (2D FS) in the ultraviolet (UV) regime to measure the electronic coupling between the subunits of a dinucleotide of the fluorescent nucleic acid base analog
It has been shown using circular dichroism (CD) spectroscopy that when two adjacent base residues in a DNA construct are substituted with 2-AP, interaction between the chromophores leads to exciton-coupling of the electronic states and splitting of the energy levels [2]
Summary
The conformational manipulation of nucleic acid bases within functioning ‘macromolecular machines’ is a central feature of DNA replication and RNA transcription reactions. In many cases, these manipulations involve the unwinding of DNA-DNA (or DNA-RNA, or RNARNA) duplexes at single-stranded-double-stranded (ss-ds) replication forks, or at PrimerTemplate (P/T) junctions. These manipulations involve the unwinding of DNA-DNA (or DNA-RNA, or RNARNA) duplexes at single-stranded-double-stranded (ss-ds) replication forks, or at PrimerTemplate (P/T) junctions Such unwinding processes provide access for the relevant DNA or RNA polymerases to the duplex ‘interior,’ and expose ss DNA or RNA sequences that serve as templates for replication and transcription.
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