Lipidated cyclopropenes via a stable 3-N spirocyclopropene scaffold

Kumar, Pratik; Ji, Ting; Zainul, Omar; Preston, Alyssa N.; Li, Sining; Farr, Joshua D.; Suri, Pavit; Laughlin, Scott T.

doi:10.1016/j.tetlet.2018.08.010

Cited by 10 publications

(5 citation statements)

References 35 publications

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“…We obtained the acid from ester 12 , which, in turn, was obtained via n -BuLi-mediated iodo-orthoformate S6 (Scheme S5) substitution in 75% yield. To the best of our knowledge, this is the only method to directly install an ester functionality onto C1/C2 of a cyclopropene . Moreover, ketal-ester 12 upon saponification and acid workup directly afforded ketone cyclopropene 13 in 62% yield.…”

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confidence: 85%

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Caged Cyclopropenes with Improved Tetrazine Ligation Kinetics

et al. 2019

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Activatable cyclopropenes are unreactive toward their inverse electron demand Diels–Alder reaction partner (e.g., s-tetrazines) until they are activated. The activation strategy is highly modular due to the cyclopropene’s ability to be caged by various light- and enzyme-activatable groups. This work describes the next generation of activatable cyclopropenes with a new core scaffold that maintains the activation modularity of the first generation but improves upon the ligation kinetics with s-tetrazines by ≤270-fold.

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confidence: 85%

“…To the best of our knowledge, this is the only method to directly install an ester functionality onto C1/C2 of a cyclopropene. 40 Moreover, ketal-ester 12 upon saponification and acid workup directly afforded ketone cyclopropene 13 in 62% yield. Ketone 3-N cyclopropene acid 13 can be easily appended to amines.…”

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confidence: 99%

Caged Cyclopropenes with Improved Tetrazine Ligation Kinetics

et al. 2019

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“…[40] We were curious whether this oleic acid analogue could be used in live-cell compatible labelling chemistry, as it is known to be biologically stable and represents a minimal structural modification of one methylene compared to the parent oleic acid structure. Furthermore, all previously described bioorthogonal IED-DA applications have been explored for cyclopropenes with 1,3-, 3,3-or 1,2,3-substitution patterns, [31,32,41] whereas there has been no report of a 1,2-substituted cyclopropene as a bioorthogonal probe.…”

Section: Introductionmentioning

confidence: 99%

Live‐Cell Imaging of Sterculic Acid—a Naturally Occurring 1,2‐Cyclopropene Fatty Acid—by Bioorthogonal Reaction with Turn‐On Tetrazine‐Fluorophore Conjugates**

et al. 2022

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In the field of lipid research, bioorthogonal chemistry has made the study of lipid uptake and processing in living systems possible, whilst minimising biological properties arising from detectable pendant groups. To allow the study of unsaturated free fatty acids in live cells, we here report the use of sterculic acid, a 1,2‐cyclopropene‐containing oleic acid analogue, as a bioorthogonal probe. We show that this lipid can be readily taken up by dendritic cells without toxic side effects, and that it can subsequently be visualised using an inverse electron‐demand Diels–Alder reaction with quenched tetrazine‐fluorophore conjugates. In addition, the lipid can be used to identify changes in protein oleoylation after immune cell activation. Finally, this reaction can be integrated into a multiplexed bioorthogonal reaction workflow by combining it with two sequential copper‐catalysed Huisgen ligation reactions. This allows for the study of multiple biomolecules in the cell simultaneously by multimodal confocal imaging.

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“…[40] We were curious whether this oleic acid analogue could be used in livecell compatible labelling chemistry, as it is known to be biologically stable and represents a minimal structural modification of one methylene compared to the parent oleic acid structure. Furthermore, all previously described bioorthogonal IEDDA applications have been explored for cyclopropenes with 1,3-, 3,3-or 1,2,3-substitution patterns [31,32,41] , whereas there has been no report of a 1,2-substituted cyclopropene as a bioorthogonal probe. Here, we explore the use of 1 as a bioorthogonal reagent, assessing both its ligation kinetics, short-term toxicity and liveand fixed-cell imaging capacity.…”

Section: Introductionmentioning

confidence: 99%

Live‐Cell Imaging of Sterculic Acid—a Naturally Occurring 1,2‐Cyclopropene Fatty Acid—by Bioorthogonal Reaction with Turn‐On Tetrazine‐Fluorophore Conjugates**

et al. 2022

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In the field of lipid research, bioorthogonal chemistry has made the study of lipid uptake and processing in living systems possible, whilst minimising biological properties arising from detectable pendant groups. To allow the study of unsaturated free fatty acids in live cells, we here report the use of sterculic acid, a 1,2-cyclopropene-containing oleic acid analogue, as a bioorthogonal probe. We show that this lipid can be readily taken up by dendritic cells without toxic side effects, and that it can subsequently be visualised using an inverse electron-demand Diels-Alder reaction with quenched tetrazine-fluorophore conjugates. In addition, the lipid can be used to identify changes in protein oleoylation after immune cell activation. Finally, this reaction can be integrated into a multiplexed bioorthogonal reaction workflow by combining it with two sequential copper-catalysed Huisgen ligation reactions. This allows for the study of multiple biomolecules in the cell simultaneously by multimodal confocal imaging.

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Lipidated cyclopropenes via a stable 3-N spirocyclopropene scaffold

Cited by 10 publications

References 35 publications

Caged Cyclopropenes with Improved Tetrazine Ligation Kinetics

Caged Cyclopropenes with Improved Tetrazine Ligation Kinetics

Live‐Cell Imaging of Sterculic Acid—a Naturally Occurring 1,2‐Cyclopropene Fatty Acid—by Bioorthogonal Reaction with Turn‐On Tetrazine‐Fluorophore Conjugates**

Live‐Cell Imaging of Sterculic Acid—a Naturally Occurring 1,2‐Cyclopropene Fatty Acid—by Bioorthogonal Reaction with Turn‐On Tetrazine‐Fluorophore Conjugates**

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