Change in Electronic Structure upon Optical Excitation of 8-Vinyladenosine: An Experimental and Theoretical Study

Kodali, Goutham; Kistler, Kurt A.; Narayanan, Madhavan; Matsika, Spiridoula; Stanley, Robert J.

doi:10.1021/jp908055h

Cited by 23 publications

(30 citation statements)

References 76 publications

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“…The ground-state geometries and molecular orbital energies of 9-CH 3 -εAde and 9-CH 3 -Ade radicals were optimized as before [44,45] using the Density Functional Theory (DFT) package in Gaussian 16 [46], with UB3LYP/6-311 + G(d,p) functional and basis set respectively, as well as lumiflavin anionic semiquinone as a control. B3YLP/6-311 + G(d,p) calculations for neutral lumiflavin, 9-CH 3 -ε-Ade, and 9-CH 3 -Ade were performed as additional checks on the radical calculations.…”

Section: Methodsmentioning

confidence: 99%

Comparing ultrafast excited state quenching of flavin 1,N6-ethenoadenine dinucleotide and flavin adenine dinucleotide by optical spectroscopy and DFT calculations

Morris

Barnard

Narayanan

et al. 2022

Photochem Photobiol Sci

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Flavins are photoenzymatic cofactors often exploiting the absorption of light to energize photoinduced redox chemistry in a variety of contexts. Both flavin adenine dinucleotide (FAD) and flavin mononucleotide (FMN) are used for this function. The study of these photoenzymes has been facilitated using flavin analogs. Most of these analogs involve modification of the flavin ring, and there is recent evidence that adenine (Ade)-modified FAD can affect enzyme turnover, but so far this has only been shown for enzymes where the adenine and flavin rings are close to each other in a stacked conformation. FAD is also stacked in aqueous solution, and its photodynamics are quite different from unstacked FAD or FMN. Oxidized photoexcited FAD decays rapidly, presumably through PET with Ade as donor and Fl* as acceptor. Definitive identification of the spectral signatures of Ade •+ and Fl •− radicals is elusive. Here we use the FAD analog Flavin 1,N 6 -Ethenoadenine Dinucleotide (εFAD) to study how different photochemical outcomes depend on the identity of the Ade moiety in stacked FAD and its analog εFAD. We have used UV-Vis transient absorption spectroscopy complemented by TD-DFT calculations to investigate the excited state evolution of the flavins. In FAD*, no radicals were observed, suggesting that FAD* does not undergo PET. εFAD* kinetics showed a broad absorption band that suggests a charge transfer state exists upon photoexcitation with evidence for radical pair formation. Surprisingly, significant triplet flavin was produced from εFAD* We hypothesize that the dipolar (ε)Ade moieties differentially modulate the singlet-triplet energy gap, resulting in different intersystem crossing rates. The additional electron density on the etheno group of εFAD supplies better orbital overlap with the flavin S 1 state, accelerating charge transfer in that molecule.

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Section: Methodsmentioning

confidence: 99%

Comparing ultrafast excited state quenching of flavin 1,N6-ethenoadenine dinucleotide and flavin adenine dinucleotide by optical spectroscopy and DFT calculations

Morris

Barnard

Narayanan

et al. 2022

Photochem Photobiol Sci

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“…1) results in a longer emission wavelength and higher quantum yield as compared to adenosine (l em 388 nm; f 0.66 vs. l em 319 nm; f 0.00026). [16][17][18] The purine p-system was also extended upon conjugation with aromatic moieties. Specifically, 8-(p-hydroxy-phenyl) nucleosides, 2-4 emit at ~390 nm with high quantum yields ranging from 0.25 to 0.56 in aqueous solution (pH 7).…”

Section: Introductionmentioning

confidence: 99%

8-(p-CF3-cinnamyl)-modified purine nucleosides as promising fluorescent probes

2011

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Natural nucleotides are not useful as fluorescent probes because of their low quantum yields. Therefore, a common methodology for the detection of RNA and DNA is the application of extrinsic fluorescent dyes coupled to bases in oligonucleotides. To overcome the many limitations from which fluorescent nucleotide-dye conjugates suffer, we have developed novel purine nucleosides with intrinsic fluorescence to be incorporated into oligonucleotide probes. For this purpose we synthesized adenosine and guanosine fluorescent analogues 7-25, conjugated at the C8 position with aryl/heteroaryl moieties either directly, or via alkenyl/alkynyl linkers. Directly conjugated analogues 7-14, exhibited high quantum yields, φ >0.1, and short λ(em) (<385 nm). Alkynyl conjugated analogues 22-25, exhibited low quantum yields, φ <0.075, and λ(em)<385 nm. The alkenyl conjugated analogues 15-21, exhibited λ(em) 408-459 nm. While analogues 15,16, and 20 bearing an EDG on the aryl moiety, exhibited φ <0.02, analogues 17, and 21 with EWG on the aryl moiety, exhibited extremely high quantum yields, φ ≈ 0.8, suggesting better intramolecular charge transfer. We determined the conformation of selected adenosine analogues. Directly conjugated analogue 8 and alkynyl conjugated analogue 22, adapted the syn conformation, whereas alkenyl conjugated analogue 15 adapted the anti conformation. Based on the long emission wavelengths, high quantum yields, anti conformation and base-paring compatibility, we suggest analogues 17 and 21 for further development as fluorescent probes for the sensitive detection of genetic material.

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“…For flavins though, higher levels of theory are sometimes useful. These approaches and results have been described in detail in previous papers (Kodali, Kistler, Matsika, & Stanley, 2008;Kodali, Kistler, Narayanan, Matsika, & Stanley, 2010;Kodali, Narayanan, & Stanley, 2012;Kodali et al, 2009; Pauszek III, Kodali, & Stanley, 2014;Pauszek, Kodali, Caldwell, et al, 2013;Pauszek et al, 2016;Rohwer et al, 2018). We believe that we are on the threshold of elucidating how the unique electrostatic cavity fields in proteins affect flavin energetics and catalysis.…”

Section: The ζ a Degeneracy Problemmentioning

confidence: 78%

Measuring electronic structure properties of flavins and flavoproteins by electronic Stark spectroscopy

Stanley

Galen

2019

Methods in Enzymology

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The optical spectrum of a flavoprotein is one of its signature properties. No two flavoprotein absorption spectra are exactly alike as each encodes the details of the interaction of the flavin cofactor electronic structure with the specific protein binding pocket. Electronic Stark spectroscopy has the potential to elucidate these interactions with high sensitivity, at low cost, and requiring minimal technical sophistication. In this chapter we will outline the theoretical basis for Stark spectroscopy and describe the construction of the Stark spectrometer.Step-by-step instructions are given for acquiring and interpreting Stark spectra to retrieve difference moments of the flavin ground versus excited state charge distributions.

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Change in Electronic Structure upon Optical Excitation of 8-Vinyladenosine: An Experimental and Theoretical Study

Cited by 23 publications

References 76 publications

Comparing ultrafast excited state quenching of flavin 1,N6-ethenoadenine dinucleotide and flavin adenine dinucleotide by optical spectroscopy and DFT calculations

Comparing ultrafast excited state quenching of flavin 1,N6-ethenoadenine dinucleotide and flavin adenine dinucleotide by optical spectroscopy and DFT calculations

8-(p-CF3-cinnamyl)-modified purine nucleosides as promising fluorescent probes

Measuring electronic structure properties of flavins and flavoproteins by electronic Stark spectroscopy

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