2‐(1‐Ethynylpyrene)‐Adenosine as a Folding Probe for RNA—Pyrene in or out

Förster, Ute; Lommel, Katharina; Sauter, Daniel; Grünewald, Christian; Engels, Joachim W.; Wachtveitl, Josef

doi:10.1002/cbic.200900778

Cited by 23 publications

(25 citation statements)

References 58 publications

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“…Substitution of pyrene at a single position is possible—for symmetry reasons, only the positions 1, 2 and 4 are distinct—and has frequently been utilized to generate various fluorescent nucleoside analogues for nucleic acids research . In general, both, the position of the substitution and their nature were found to affect the electronic and spectral properties of pyrene derivatives .…”

Section: Introductionmentioning

confidence: 99%

“…[7,8] Substitution of pyrene at as ingle position is possible-for symmetry reasons, only the positions 1, 2a nd 4a re distinctand has frequently been utilized to generate various fluorescent nucleoside analogues for nucleic acids research. [9][10][11][12][13][14][15] In general, both, the position of the substitution and their nature were found to affect the electronic and spectral properties of pyrene derivatives. [16][17][18][19][20] Linked to nucleosides,p yrene often forms pronouncedc harget ransfer( CT) states after excitation, acting as electron donor and acceptor when linked to pyrimidines andg uanosine, respectively.…”

Section: Introductionmentioning

confidence: 99%

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The Three Possible 2‐(Pyrenylethynyl) Adenosines: Rotameric Energy Barriers Govern the Photodynamics of These Structural Isomers

et al. 2016

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This article presents a comprehensive study of the photophysics of 2-(2-pyrenylethynyl) adenosine and 2-(4-pyrenylethynyl) adenosine, which are structural isomers of the well-established fluorescent RNA label 2-(1-pyrenylethynyl) adenosine. We performed steady-state and ultrafast transient absorption spectroscopy studies along with time-resolved fluorescence emission experiments in different solvents to work out the interplay of locally excited and charge-transfer states. We found the ultrafast photodynamics to be crucial for the fluorescence decay behavior, which extends up to tens of nanoseconds and is partially multi-exponential. These features in the ultrafast dynamics are indicative of the rotational energy barriers in the first excited state.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The Three Possible 2‐(Pyrenylethynyl) Adenosines: Rotameric Energy Barriers Govern the Photodynamics of These Structural Isomers

et al. 2016

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“…The pyrene fluorophore appended on adenine A PY , A P and G P has allowed these nucleobases to be excited at long ultraviolet to short blue ranges (380 to 420 nm) while emitting blue light (450 to 480 nm) (Fig. 3d) 32–34 . In some rarer cases, the 7 position can also be appended with fluorescence extensions, with replacement of the nitrogen at the 7 position with carbon to preserve aromaticity.…”

Section: Purine Architecture Modificationsmentioning

confidence: 99%

Fluorescent nucleobases as tools for studying DNA and RNA

2017

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Understanding the diversity of dynamic structures and functions of DNA and RNA in biology requires tools that can selectively and intimately probe these biomolecules. Synthetic fluorescent nucleobases that can be incorporated into nucleic acids alongside their natural counterparts have emerged as a powerful class of molecular reporters of location and environment. They are enabling new basic insights into DNA and RNA, and are facilitating a broad range of new technologies with chemical, biological and biomedical applications. In this Review, we will present a brief history of the development of fluorescent nucleobases and explore their utility as tools for addressing questions in biophysics, biochemistry and biology of nucleic acids. We provide chemical insights into the two main classes of these compounds: canonical and non-canonical nucleobases. A point-by-point discussion of the advantages and disadvantages of both types of fluorescent nucleobases is made, along with a perspective into the future challenges and outlook for this burgeoning field.

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“…Another favorable characteristic is the ability to form excimers upon close proximity of two PyAs of complementary strands in the minor groove [4]. Experiments revealed that PyA is also able to intercalate into RNA depending on the flanking bases in 5' direction of the modified base [5,6]. A G-C base pair leads to the intercalation of PyA, whereas A-U base pairs do not show this behavior.…”

Section: Introductionmentioning

confidence: 99%

Photophysical processes of the spectroscopic RNA probe 2-(1-ethynylpyrene)-adenosine (PyA)

Trojanowski

Plötner

Grünewald

et al. 2013

EPJ Web of Conferences

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Abstract. We examine the photoinduced excited state dynamics of pyrene modified adenosine, a versatile probe for folding and hybridization of ribonucleic acids. Measurements in different solvents revealed complex ultrafast dynamics, but high robustness since the overall fluorescence quantum yield ( f ) is hardly affected. The result is a strong fluorescent RNA-probe whose spectral properties change in a defined way upon environmental changes.

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2‐(1‐Ethynylpyrene)‐Adenosine as a Folding Probe for RNA—Pyrene in or out

Cited by 23 publications

References 58 publications

The Three Possible 2‐(Pyrenylethynyl) Adenosines: Rotameric Energy Barriers Govern the Photodynamics of These Structural Isomers

The Three Possible 2‐(Pyrenylethynyl) Adenosines: Rotameric Energy Barriers Govern the Photodynamics of These Structural Isomers

Fluorescent nucleobases as tools for studying DNA and RNA

Photophysical processes of the spectroscopic RNA probe 2-(1-ethynylpyrene)-adenosine (PyA)

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