Bioorthogonal Ligation‐Activated Fluorogenic FRET Dyads

Németh, Evelin; Kern, Dóra; Kormos, Attila; Bojtár, Márton; Török, György; Bíró, Adrienn; Szatmári, Ágnes; Németh, Krisztina; Kele, Péter

doi:10.1002/anie.202111855

Cited by 15 publications

(13 citation statements)

References 53 publications

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“…In 2022, Albitz et al demonstrated that bio-orthogonal ligation could be harnessed to activate FRET dyads via manipulating the quenching effect of tetrazine in the FRET pair . In the preactivated FRET pair, coumarin–tetrazine and Cy5 were conjugated into one molecule.…”

Section: In Vivo Imaging With Bio-orthogonal Ligationmentioning

confidence: 99%

The Application of Bio-orthogonality for In Vivo Animal Imaging

Yang

Zhu

Ran

2023

Chemical & Biomedical Imaging

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The application of bio-orthogonality has greatly facilitated numerous aspects of biological studies in recent years. In particular, bioorthogonal chemistry has transformed biological research, including in vitro conjugate chemistry, target identification, and biomedical imaging. In this review, we highlighted examples of bio-orthogonal in vivo imaging published in recent years. We grouped the references into two major categories: bio-orthogonal chemistry-related imaging and in vivo imaging with bio-orthogonal nonconjugated pairing. Lastly, we discussed the challenges and opportunities of bio-orthogonality for in vivo imaging.

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Section: In Vivo Imaging With Bio-orthogonal Ligationmentioning

confidence: 99%

The Application of Bio-orthogonality for In Vivo Animal Imaging

Yang

Zhu

Ran

2023

Chemical & Biomedical Imaging

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“…Besides the good biocompatibility of CPs modified with tetrazine groups, it can also be designed as turn-on fluorescence probe. 71 The tetrazine groups as energy acceptors can receive the energy given by the CPs so that the fluorescence of the CPs is quenched. However, when tetrazine groups react with TCO, the fluorescence signals of conjugated systems were recovered.…”

Section: Selective Responses Of Cpsmentioning

confidence: 99%

Conjugated polymers for biomedical applications

et al. 2022

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“…Arguably, the most important example of this concept is tetrazine (Tz) probes, which gained popularity due to their fast reactivity via inverseelectron-demand Diels-Alder cycloaddition reaction. [28][29][30][31][32][33][34][35][36][37][38] Tz has been shown to quench fluorescence via various photophysical mechanisms, including Forster resonance energy transfer (FRET), 39,40 through-bond energy transfer (TBET), 26,27 Dexter-type electron exchange, 41 and photoinduced electron transfer (PET). 42 Over the last few years, a range of design strategies has been investigated in collaboration with different fluorophore scaffolds to harness various Tz-mediated quenching mechanisms and achieve fluorogenic tetrazine probes extending up to the far-red/NIR range.…”

Section: Introductionmentioning

confidence: 99%

“…42 Over the last few years, a range of design strategies has been investigated in collaboration with different fluorophore scaffolds to harness various Tz-mediated quenching mechanisms and achieve fluorogenic tetrazine probes extending up to the far-red/NIR range. 26,27,30,[33][34][35][36][37][38][39][40][41][42] While such fluorogenic probes have been promising, the quenching strategies are not generalizable to diverse libraries of fluorophore families, requiring extensive design efforts to customize quenching mechanisms for each fluorophore scaffold. In addition, access to these fluorogenic probes often requires direct alteration of the core fluorophore skeleton, demanding re-optimization of the laborious fluorophore synthesis scheme and tackling critical synthetic challenges.…”

Section: Introductionmentioning

confidence: 99%

Supramolecular ‘catch-and-release’ strategy for bioorthogonal fluorogenic imaging across the visible spectrum

Sasmal

Som

Kumari

et al. 2023

Preprint

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Fluorogenic probes that unmask fluorescence signals in response to a bioorthogonal reaction are a powerful new addition to biological imaging. They can provide significantly reduced background fluorescence and minimize non-specific signals, potentially allowing real-time high-contrast imaging without washing out excess fluorophores. While diverse classes of highly refined synthetic fluorophores are readily available now, their integration into a bioorthogonal fluorogenic scheme still necessitates another level of extensive design efforts and customized structural alterations to optimize quenching mechanisms for each given fluorophore scaffold. Herein, we present an easy-to-implement and highly generalizable supramolecular catch-and-release strategy for generating an efficient bioorthogonal fluorogenic response from essentially any readily available fluorophores without further structural alterations. We designed this distinct strategy based on the macrocyclic cucurbit[7]uril (CB7) host, where a fluorogenic response is achieved by programming a guest displacement reaction from the macrocycle cavity. We used this strategy to rapidly generate fluorogenic probes across the visible spectrum from structurally diverse classes of fluorophore scaffolds, including coumarin, bodipy, rhodamine, and cyanine. These probes were applied to no-wash fluorogenic imaging of various target molecules in live cells and tissue with minimal background and no appreciable non-specific signal. Notably, the orthogonal reactivity profile of the system allowed us to pair this host-guest fluorogenic probe with the covalently clickable fluorogenic probe to achieve high-contrast super-resolution and multiplexed fluorogenic imaging in cells and tissue.

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Bioorthogonal Ligation‐Activated Fluorogenic FRET Dyads

Cited by 15 publications

References 53 publications

The Application of Bio-orthogonality for In Vivo Animal Imaging

The Application of Bio-orthogonality for In Vivo Animal Imaging

Conjugated polymers for biomedical applications

Supramolecular ‘catch-and-release’ strategy for bioorthogonal fluorogenic imaging across the visible spectrum

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