Fluorescent Adenine Analogue Research Articles

Oxidation and reduction potentials of 8-vinyladenosine measured by cyclic voltammetry: Implications for photoinduced electron transfer quenching of a fluorescent adenine analog

Abstract 8-Vinyladenosine (8VA) is an adenine analog that effectively base pairs with thymine in duplex DNA. With a red-shifted absorption band centered around 290 nm excited 8VA emits Stokes-shifted fluorescence centered at 370 nm. The fluorescence quantum yield of 8VA* is sensitive to base stacking, making it an effective reporter of DNA structure and dynamics. We have performed cyclic voltammetry (CV) studies on 8VA in aprotic organic solvents to explore the mechanism of fluorescence quenching. Excited state oxidation and reduction potentials were calculated from the experimentally determined ground state one electron redox potentials. The Rehm–Weller equation was used to obtain the free energies of electron transfer for native nucleobase monophosphate oxidation and reduction paired with 8VA*. The magnitude and sign of the free energies have been used to assess whether electron transfer is thermodynamically plausible. The results suggest that electron transfer to or from 8VA* may not be the dominant mechanism of quenching for AMP, CMP, and perhaps GMP. In contrast, TMP may be an effective electron acceptor. Taken together, the results suggest that 8VA* quenching by nucleobase monophosphates in aqueous solution proceeds through a different mechanism than ET.

Quadracyclic Adenine: A Non-Perturbing Fluorescent Adenine Analogue

Fluorescent-base analogues (FBAs) comprise a group of increasingly important molecules for the investigation of nucleic acid structure and dynamics as well as of interactions between nucleic acids and other molecules. Here, we report on the synthesis, detailed spectroscopic characterisation and base-pairing properties of a new environment-sensitive fluorescent adenine analogue, quadracyclic adenine (qA). After developing an efficient route of synthesis for the phosphoramidite of qA it was incorporated into DNA in high yield by using standard solid-phase synthesis procedures. In DNA qA serves as an adenine analogue that preserves the B-form and, in contrast to most currently available FBAs, maintains or even increases the stability of the duplex. We demonstrate that, unlike fluorescent adenine analogues, such as the most commonly used one, 2-aminopurine, and the recently developed triazole adenine, qA shows highly specific base-pairing with thymine. Moreover, qA has an absorption band outside the absorption of the natural nucleobases (>300 nm) and can thus be selectively excited. Upon excitation the qA monomer displays a fluorescence quantum yield of 6.8 % with an emission maximum at 456 nm. More importantly, upon incorporation into DNA the fluorescence of qA is significantly less quenched than most FBAs. This results in quantum yields that in some sequences reach values that are up to fourfold higher than maximum values reported for 2-aminopurine. To facilitate future utilisation of qA in biochemical and biophysical studies we investigated its fluorescence properties in greater detail and resolved its absorption band outside the DNA absorption region into distinct transition dipole moments. In conclusion, the unique combination of properties of qA make it a promising alternative to current fluorescent adenine analogues for future detailed studies of nucleic acid-containing systems.

2-Aminopurine hairpin probes for the detection of ultraviolet-induced DNA damage

Nucleic acid exposure to radiation and chemical insults leads to damage and disease. Thus, detection and understanding DNA damage is important for elucidating molecular mechanisms of disease. However, current methods of DNA damage detection are either time-consuming, destroy the sample, or are too specific to be used for generic detection of damage. In this paper, we develop a fluorescence sensor of 2-aminopurine (2AP), a fluorescent analogue of adenine, incorporated in the loop of a hairpin probe for the quantification of ultraviolet (UV) C-induced nucleic acid damage. Our results show that the selectivity of the 2AP hairpin probe to UV-induced nucleic acid damage is comparable to molecular beacon (MB) probes of DNA damage. The calibration curve for the 2AP hairpin probe shows good linearity (R2=0.98) with a limit of detection of 17.2nM. This probe is a simple, fast and economic fluorescence sensor for the quantification of UV-induced damage in DNA.

Conformational Dynamics of Abasic DNA upon Interactions with AP Endonuclease 1 Revealed by Stopped-Flow Fluorescence Analysis

Apurinic/apyrimidinic (AP) sites are abundant DNA lesions arising from exposure to UV light, ionizing radiation, alkylating agents, and oxygen radicals. In human cells, AP endonuclease 1 (APE1) recognizes this mutagenic lesion and initiates its repair via a specific incision of the phosphodiester backbone 5' to the AP site. We have investigated a detailed mechanism of APE1 functioning using fluorescently labeled DNA substrates. A fluorescent adenine analogue, 2-aminopurine, was introduced into DNA substrates adjacent to the abasic site to serve as an on-site reporter of conformational transitions in DNA during the catalytic cycle. Application of a pre-steady-state stopped-flow technique allows us to observe changes in the fluorescence intensity corresponding to different stages of the process in real time. We also detected an intrinsic Trp fluorescence of the enzyme during interactions with 2-aPu-containing substrates. Our data have revealed a conformational flexibility of the abasic DNA being processed by APE1. Quantitative analysis of fluorescent traces has yielded a minimal kinetic scheme and appropriate rate constants consisting of four steps. The results obtained from stopped-flow data have shown a substantial influence of the 2-aPu base location on completion of certain reaction steps. Using detailed molecular dynamics simulations of the DNA substrates, we have attributed structural distortions of AP-DNA to realization of specific binding, effective locking, and incision of the damaged DNA. The findings allowed us to accurately discern the step that corresponds to insertion of specific APE1 amino acid residues into the abasic DNA void in the course of stabilization of the precatalytic complex.

Phasor Diagram Analysis of Telomeric G-Quadruplex Stability and Heterogeneity

Telomeres function to protect the end of linear chromosomes from damage and degradation. Human telomeres consists of several kilobases of the tandem repeat d(TTAGGG), which terminate in a 3′-single stranded overhang capable of forming G-Quadruplex structures. Telomeric G-Quadruplexes have potential roles in the maintenance of telomere integrity and the control of telomerase activity, an enzyme responsible for elongation of the telomeric overhang that is over expressed in a wide variety of cancers. Investigation of intramolecular G-Quadruplexes corresponding to the human telomere is complicated by the formation of multiple rapidly interconverting conformations. The multiple telomere G-Quadruplex conformations are identified by unique folding geometries containing distinct connecting loop regions.Time-resolved fluorescent measurements have been conducted to characterize the stability and heterogeneity of the telomeric G-Quadruplex forming sequence d(AGGG(TTAGGG)3). The fluorescent adenine analog, 2-aminopurine, served as an internal fluorescent probe of G-Quadruplex conformation and was used to specifically monitor loop regions. 2-aminopurine demonstrates a complex fluorescent decay upon incorporation into nucleic acid polymers that can be simplified by transformation of time-resolved data to an (S,G) phasor diagram. Phasor diagrams were used to monitor G-Quadruplex formation upon addition of NaCl or KCl and elucidated a unique KCl-dependent transition. The digestion of G-Quadruplex structure by a single-strand specific nuclease and acrylamide quenching are also evaluated through phasor diagrams. This work demonstrates the utility of phasor diagrams for the study of nucleic acid systems and the ability to sensitively monitor complex fluorescent decays that may complicate analysis through nonlinear regression techniques. Supported by awards RO1CA35635 and RO1GM077422 from the NCI and NIGMS.

Using the fluorescence decay of 2-aminopurine to investigate conformational change in the recognition sequence of the EcoRV DNA-(adenine-N6)-methyltransferase on enzyme binding

The EcoRV DNA methyltransferase methylates the first adenine in the GATATC recognition sequence. It is presumed that methylation proceeds by a nucleotide flipping mechanism but no crystal structure is available to confirm this. A popular solution-phase assay for nucleotide flipping employs the fluorescent adenine analogue, 2-aminopurine (2AP), substituted at the methylation target site; a substantial increase in fluorescence intensity on enzyme binding indicates flipping. However, this appeared to fail for M.EcoRV, since 2AP substituted for the non-target adenine in the recognition sequence showed a much greater intensity increase than 2AP at the target site. This anomaly is resolved by recording the fluorescence decay of 2AP which shows that the target 2AP is indeed flipped by the enzyme, but its fluorescence is quenched by interaction with aromatic residues in the catalytic site, whereas bending of the duplex at the non-target site alleviates inter-base quenching and exposes the 2AP to solvent.

Single-Step Charge Transport through DNA over Long Distances

Quantum yields for charge transport across adenine tracts of increasing length have been measured by monitoring hole transport in synthetic oligonucleotides between photoexcited 2-aminopurine, a fluorescent analogue of adenine, and N(2)-cyclopropyl guanine. Using fluorescence quenching, a measure of hole injection, and hole trapping by the cyclopropyl guanine derivative, we separate the individual contributions of single- and multistep channels to DNA charge transport and find that with 7 or 8 intervening adenines the charge transport is a coherent, single-step process. Moreover, a transition occurs from multistep to single-step charge transport with increasing donor/acceptor separation, opposite to that generally observed in molecular wires. These results establish that coherent transport through DNA occurs preferentially across 10 base pairs, favored by delocalization over a full turn of the helix.

Site-Pecific Fluorescnce Dynamics in an RNA ‘THERMOMETER’ Reveals the Mechanism of Temperature-Sensitive Translation

The ROSE (Repression Of heat Shock gene Expression) element of mRNA present in the 5’-UTR of small heat-shock genes in many Gram-negative bacteria is known to function as a ‘RNA thermometer’ by controlling protein translation in a temperature range of 30 - 42° C where the translation is blocked till 30°C and allowed at 42°C and beyond, perhaps due to an unfolding transition of the ROSE hair-pin motif.In this work, we have used site-specific fluorescence labeling and pico-second time-domain fluorescence spectroscopy to unravel the mechanism. The ‘ROSE RNA’ was site-specially labeled with 2-aminopurine (2-AP), a fluorescent analog of adenine. Observables such as fluorescence lifetime, fluorescence anisotropy decay kinetics and dynamic fluorescence quenching revealed properties such as the level of base stacking, rotational motion of the bases, segmental dynamics of the backbone and the level of exposure of base to solvent. As expected, all read-outs of 2-AP residue that were studied showed remarkable position-dependence/sensitivity in the RNA sequence at 25°C. The striking result was the persistence of the same position-dependence of the parameters even at 45°C albeit at a measurably reduced levels. However the same position-dependence was nearly ‘wiped out’ in the presence of urea where all intra-molecular interactions in RNA are undone. These observations have prompted us to revise the existing model of ROSE RNA action: we now suggest that unlike proposed earlier, the thermometer action of ROSE emanates not from its unfolding structural transition between 25 and 45°C, but rather from its propensity to enhance structural dynamics without “melting” the structure. We hypothesize that either the enhanced dynamics of the structure it self or its full melting due to an extrinsic factor (perhaps a protein interaction) might be the basis of its thermometer action.

Characterization of photophysical and base-mimicking properties of a novel fluorescent adenine analogue in DNA

To increase the diversity of fluorescent base analogues with improved properties, we here present the straightforward click-chemistry-based synthesis of a novel fluorescent adenine-analogue triazole adenine (AT) and its photophysical characterization inside DNA. AT shows promising properties compared to the widely used adenine analogue 2-aminopurine. Quantum yields reach >20% and >5% in single- and double-stranded DNA, respectively, and show dependence on neighbouring bases. Moreover, AT shows only a minor destabilization of DNA duplexes, comparable to 2-aminopurine, and circular dichroism investigations suggest that AT only causes minimal structural perturbations to normal B-DNA. Furthermore, we find that AT shows favourable base-pairing properties with thymine and more surprisingly also with normal adenine. In conclusion, AT shows strong potential as a new fluorescent adenine analogue for monitoring changes within its microenvironment in DNA.

Fluorescence-Based Assay to Measure the Real-time Kinetics of Nucleotide Incorporation during Transcription Elongation

Understanding the mechanism and fidelity of transcription by the RNA polymerase (RNAP) requires measurement of the dissociation constant (Kd) of correct and incorrect NTPs and their incorporation rate constants (kpol). Currently, such parameters are obtained from radiometric-based assays that are both tedious and discontinuous. Here, we report a fluorescence-based assay for measuring the real-time kinetics of single-nucleotide incorporation during transcription elongation. The fluorescent adenine analogue 2-aminopurine was incorporated at various single positions in the template or the nontemplate strand of the promoter-free elongation substrate. On addition of the correct NTP to the T7 RNAP-DNA, 2-aminopurine fluorescence increased rapidly and exponentially with a rate constant similar to the RNA extension rate obtained from the radiometric assay. The fluorescence stopped-flow assay, therefore, provides a high-throughput way to measure the kinetic parameters of RNA synthesis. Using this assay, we report the kpol and Kd of all four correct NTP additions by T7 RNAP, which showed a range of values of 145–190 s−1 and 28–124 μM, respectively. The fluorescent elongation substrates were used to determine the misincorporation kinetics as well, which showed that T7 RNAP discriminates against incorrect NTP both at the nucleotide binding and incorporation steps. The fluorescence-based assay should be generally applicable to all DNA-dependent RNAPs, as they use similar elongation substrates. It can be used to elucidate the mechanism, fidelity, and sequence dependency of transcription and is a rapid means to screen for inhibitors of RNAPs for therapeutic purposes.

Loop and stem dynamics during RNA hairpin folding and unfolding

2-Aminopurine (2AP) is a fluorescent adenine analog that probes mainly base stacking in nucleic acids. We labeled the loop or the stem of the RNA hairpin gacUACGguc with 2AP to study folding thermodynamics and kinetics at both loci. Thermal melts and fast laser temperature jumps detected by 2AP fluorescence monitored the stability and folding/unfolding kinetics. The observed thermodynamic and kinetic traces of the stem and loop mutants, though strikingly different at a first glance, can be fitted to the same free-energy landscape. The differences between the two probe locations arise because base stacking decreases upon unfolding in the stem, whereas it increases in the loop. We conclude that 2AP is a conservative adenine substitution for mapping out the contributions of different RNA structural elements to the overall folding process. Molecular dynamics (MD) totaling 0.6 μsec were performed to look at the conformations populated by the RNA at different temperatures. The combined experimental data, and MD simulations lead us to propose a minimal four-state free-energy landscape for the RNA hairpin. Analysis of this landscape shows that a sequential folding model is a good approximation for the full folding dynamics. The frayed state formed initially from the native state is a heterogeneous ensemble of structures whose stem is frayed either from the end or from the loop.

Photoinduced Electron Transfer Occurs between 2-Aminopurine and the DNA Nucleic Acid Monophosphates: Results from Cyclic Voltammetry and Fluorescence Quenching

2-Aminopurine (2AP) is a fluorescent adenine analogue that is useful in part because its substantial fluorescence quantum yield is sensitive to base stacking with native bases in ss- and ds-DNA. However, the degree of quenching is sequence dependent and the mechanism of quenching is still a matter of some debate. Here we show that the most likely quenching mechanism in aqueous solution involves photoinduced electron transfer (PET), as revealed by cyclic voltammetry (CV) performed in aprotic organic solvents. These potentials were used with spectroscopic data to obtain excited-state reduction and oxidation potentials. Stern-Volmer (S-V) experiments using the native base monophosphate nucleotides (NMPs) rGMP, rAMP, rCMP, and dTMP were performed in aqueous solution to obtain quenching rate constants kq. The results suggest that 2AP* can act as either an electron donor or an electron acceptor depending on the particular NMP but that PET proceeds for all NMPs tested.

Site-Specific Dynamics in TAT Triplex DNA As Revealed by Time-Domain Fluorescence of 2-Aminopurine

Triple helices of DNA are finding increasing level of applications in several areas, including antigene therapy and gene regulation. We have probed site-specific dynamic aspects of TAT triple helices of DNA by using steady-state and time-domain fluorescence of 2-aminopurine (2-AP), a fluorescent analog of adenine. TAT triplexes were formed from repeats of adenine and thymine with 2-AP incorporated at various locations in the polyadenine strand. We find an overall decrease in the level of near-neighbor base-stacking interaction in the TAT triplex when compared to AT duplex as reported by fluorescence decay kinetics of 2-AP. More strikingly, we have observed a stark asymmetry in both the level of base stacking and motional dynamics of the bases in the two ends of TAT triplexes, namely, the 5' end having a higher level of base stacking and segmental dynamics when compared to the 3' end. The possible implications of this asymmetry, which reflects the asymmetry in the strength of Hoogstein base-pairing with the 3' end having stronger Hoogstein pairing when compared to the 5' end, is discussed.

Site-Specific Characterization of HIV-1 Nucleocapsid Protein Binding to Oligonucleotides with Two Binding Sites

The nucleocapsid protein (NC) of HIV-1 is a highly conserved protein essential for the virus life cycle that constitutes an attractive target for new antiviral agents. Most NC functions rely on its binding to the HIV-1 genomic RNA and its DNA copies that contain multiple and possibly interdependent binding sites. Therefore, a detailed understanding of NC binding requires a site-specific experimental approach. We have recently shown that 2-aminopurine (2Ap), a fluorescent adenine analogue, can site-selectively probe the binding of NC. Here, we introduced 2Ap at various positions of model single-stranded dodecanucleotides containing two TG motifs which constitute putative specific binding sites. Steady-state and time-resolved fluorescence experiments indicated that NC binding strongly increased the fluorescence quantum yield of 2AP by reducing the dynamic quenching of 2Ap by its close neighbors and slowing the picosecond to nanosecond conformational fluctuations of the oligonucleotides. The dodecanucleotides were found to bind two NC molecules at physiological salt concentrations, confirming the preferential binding of NC to TG motifs and an occluded binding site size for NC of five to six bases. Using the NC-induced changes in 2Ap fluorescence, we determined the microscopic affinity constants of the individual binding sites and showed that affinities can significantly differ from one site to another within the same dodecanucleotide, depending on the position of the TG dinucleotide and the nature of its close neighbors. Moreover, our data suggest that binding of NC even to close binding sites shows no strong cooperativity.

Ultrafast charge transfer dynamics in 2-aminopurine modified double helical DNA

Ultrafast charge transfer dynamics in double helical DNAs and the corresponding single strands has been studied by femtosecond time-resolved fluorescence (TRF). The DNA molecules were modified by replacing one adenine with 2-aminopurine (2Ap), a fluorescent analogue of adenine. TRF signals of 2Ap in the DNAs require three time constants with the fastest in the range of 0.42–10 ps. The DNA duplex, where 2Ap and guanine are connected directly, shows the fastest 420 fs decay. The observed time scales are significantly different from the values reported previously. The time constant and amplitude of the fastest component vary with the nature and position of the bridges between the 2Ap and guanine in accordance with the oxidation potential of the bridge suggesting that the ultrafast component represents the charge transfer dynamics in DNA. The multi-exponential dispersive kinetics can be accounted for by invoking conformational heterogeneity.

Local RNA Conformational Dynamics Revealed by 2-Aminopurine Solvent Accessibility

Acrylamide quenching is widely used to monitor the solvent exposure of fluorescent probes in vitro. Here, we tested the utility of this technique to discriminate local RNA secondary structures using the fluorescent adenine analogue 2-aminopurine (2-AP). Under native conditions, the solvent accessibilities of most 2-AP-labeled RNA substrates were poorly resolved by classical single-population models; rather, a two-state quencher accessibility algorithm was required to model acrylamide-dependent changes in 2-AP fluorescence in structured RNA contexts. Comparing 2-AP quenching parameters between structured and unstructured RNA substrates permitted the effects of local RNA structure on 2-AP solvent exposure to be distinguished from nearest neighbor effects or environmental influences on intrinsic 2-AP photophysics. Using this strategy, the fractional accessibility of 2-AP for acrylamide ( f a) was found to be highly sensitive to local RNA structure. Base-paired 2-AP exhibited relatively poor accessibility, consistent with extensive shielding by adjacent bases. 2-AP in a single-base bulge was uniformly accessible to solvent, whereas the fractional accessibility of 2-AP in a hexanucleotide loop was indistinguishable from that of an unstructured RNA. However, these studies also provided evidence that the f a parameter reflects local conformational dynamics in base-paired RNA. Enhanced base pair dynamics at elevated temperatures were accompanied by increased f a values, while restricting local RNA breathing by adding a C-G base pair clamp or positioning 2-AP within extended RNA duplexes significantly decreased this parameter. Together, these studies show that 2-AP quenching studies can reveal local RNA structural and dynamic features beyond those that can be measured by conventional spectroscopic approaches.

Fluorescence intensity decays of 2-aminopurine solutions: Lifetime distribution approach

The fluorescent adenine analog 2-aminopurine (2AP) has been used extensively to monitor conformational changes and macromolecular binding events involving nucleic acids because its fluorescence properties are highly sensitive to changes in chemical environment. Furthermore, site-specific incorporation of 2AP permits local DNA and RNA conformational events to be discriminated from the global structural changes monitored by UV–Vis spectroscopy and circular dichroism. However, although the steady-state fluorescence properties of 2AP have been well defined in diverse settings, interpretation of 2AP fluorescence lifetime parameters has been hampered by the heterogeneous nature of multiexponential 2AP intensity decays observed across populations of microenvironments. To resolve this problem, we tested the utility of multiexponential versus continuous Lorentzian lifetime distribution models to describe fluorescence intensity decays from 2AP in diverse chemical backgrounds and within the context of RNA. Heterogeneity was introduced into 2AP intensity decays by mixing solvents of differing polarities or by adding quenchers under high viscosity to evaluate the transient effect. Heterogeneity of 2AP fluorescence within the context of a synthetic RNA hairpin was introduced by structural remodeling using a magnesium salt. In each case except folded RNA (which required a bimodal distribution), 2AP lifetime properties were well described by single Lorentzian distribution functions, abrogating the need to introduce additional discrete lifetime subpopulations. Rather, heterogeneity in fluorescence decay processes was accommodated by the breadth of each distribution. This approach also permitted solvent relaxation effects on 2AP emission to be assessed by comparing lifetime distributions at multiple wavelengths. Together, these studies provide a new perspective for the interpretation of 2AP fluorescence lifetime properties that will further the utility of this fluorophore in analyses of the complex and heterogeneous structural microenvironments associated with nucleic acids.

Probing dynamics of HIV-1 nucleocapsid protein/target hexanucleotide complexes by 2-aminopurine

The nucleocapsid protein (NC) plays an important role in HIV-1, mainly through interactions with the genomic RNA and its DNA copies. Though the structures of several complexes of NC with oligonucleotides (ODNs) are known, detailed information on the ODN dynamics in the complexes is missing. To address this, we investigated the steady state and time-resolved fluorescence properties of 2-aminopurine (2Ap), a fluorescent adenine analog introduced at positions 2 and 5 of AACGCC and AATGCC sequences. In the absence of NC, 2Ap fluorescence was strongly quenched in the flexible ODNs, mainly through picosecond to nanosecond dynamic quenching by its neighboring bases. NC strongly restricted the ODN flexibility and 2Ap local mobility, impeding the collisions of 2Ap with its neighbors and thus, reducing its dynamic quenching. Phe16→Ala and Trp37→Leu mutations largely decreased the ability of NC to affect the local dynamics of 2Ap at positions 2 and 5, respectively, while a fingerless NC was totally ineffective. The restriction of 2Ap local mobility was thus associated with the NC hydrophobic platform at the top of the folded fingers. Since this platform supports the NC chaperone properties, the restriction of the local mobility of the bases is likely a mechanistic component of these properties.

Altered Dynamics of DNA Bases Adjacent to a Mismatch: A Cue for Mismatch Recognition by MutS

The structural deviations as well as the alteration in the dynamics of DNA at mismatch sites are considered to have a crucial role in mismatch recognition followed by its repair utilizing mismatch repair family proteins. To compare the dynamics at a mismatch and a non-mismatch site, we incorporated 2-aminopurine, a fluorescent analogue of adenine next to a G.T mismatch, a C.C mismatch, or an unpaired T, and at several other non-mismatch positions. Rotational diffusion of 2-aminopurine at these locations, monitored by time-resolved fluorescence anisotropy, showed distinct differences in the dynamics. This alteration in the motional dynamics is largely confined to the normally matched base-pairs that are immediately adjacent to a mismatch/ unpaired base and could be used by MutS as a cue for mismatch-specific recognition. Interestingly, the enhanced dynamics associated with base-pairs adjacent to a mismatch are significantly restricted upon MutS binding, perhaps “resetting” the cues for downstream events that follow MutS binding. Recognition of such details of motional dynamics of DNA for the first time in the current study enabled us to propose a model that integrates the details of mismatch recognition by MutS as revealed by the high-resolution crystal structure with that of observed base dynamics, and unveils a minimal composite read-out involving the base mismatch and its adjacent normal base-pairs.

6MAP, a Fluorescent Adenine Analogue, Is a Probe of Base Flipping by DNA Photolyase

Cyclobutylpyrimidine dimers (CPDs) are formed between adjacent pyrimidines in DNA when it absorbs ultraviolet light. CPDs can be directly repaired by DNA photolyase (PL) in the presence of visible light. How PL recognizes and binds its substrate is still not well understood. Fluorescent nucleic acid base analogues are powerful probes of DNA structure. We have used the fluorescent adenine analogue 6MAP, a pteridone, to probe the local double helical structure of the CPD substrate when bound by photolyase. Duplex melting temperatures were obtained by both UV-vis absorption and fluorescence spectroscopies to ascertain the effect of the probe and the CPD on DNA stability. Steady-state fluorescence measurements of 6MAP-containing single-stranded and doubled-stranded oligos with and without protein show that the local region around the CPD is significantly disrupted. 6MAP shows a different quenching pattern compared to 2-aminopurine, another important adenine analogue, although both probes show that the structure of the complementary strand opposing the 5'-side of the CPD lesion is more destacked than that opposing the 3'-side in substrate/protein complexes. We also show that 6MAP/CPD duplexes are substrates for PL. Vertical excitation energies and transition dipole moment directions for 6MAP were calculated using time-dependent density functional theory. Using these results, the Förster resonance energy transfer efficiency between the individual adenine analogues and the oxidized flavin cofactor was calculated to account for the observed intensity pattern. These calculations suggest that energy transfer is highly efficient for the 6MAP probe and less so for the 2Ap probe. However, no experimental evidence for this process was observed in the steady-state emission spectra.