Kaitlyn M. Mahoney scite author profile

Photocages are light-sensitive chemical protecting groups that provide external control over when, where, and how much of a biological substrate is activated in cells using targeted light irradiation. Regrettably, most popular photocages (e.g., o-nitrobenzyl groups) absorb cell-damaging ultraviolet wavelengths. A challenge with achieving longer wavelength bond-breaking photochemistry is that long-wavelength-absorbing chromophores have shorter excited-state lifetimes and diminished excited-state energies. However, here we report the synthesis of a family of BODIPY-derived photocages with tunable absorptions across the visible/near-infrared that release chemical cargo under irradiation. Derivatives with appended styryl groups feature absorptions above 700 nm, yielding photocages cleaved with the highest known wavelengths of light via a direct single-photon-release mechanism. Photorelease with red light is demonstrated in living HeLa cells, Drosophila S2 cells, and bovine GM07373 cells upon ∼5 min irradiation. No cytotoxicity is observed at 20 μM photocage concentration using the trypan blue exclusion assay. Improved B-alkylated derivatives feature improved quantum efficiencies of photorelease ∼20-fold larger, on par with the popular o-nitrobenzyl photocages (εΦ = 50-100 M cm), but absorbing red/near-IR light in the biological window instead of UV light.

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BODIPY-Derived Photoremovable Protecting Groups Unmasked with Green Light

Goswami

et al. 2015

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Photoremovable protecting groups derived from meso-substituted BODIPY dyes release acetic acid with green wavelengths >500 nm. Photorelease is demonstrated in cultured S2 cells. The photocaging structures were identified by our previously proposed strategy of computationally searching for carbocations with low-energy diradical states as a possible indicator of a nearby productive conical intersection. The superior optical properties of these photocages make them promising alternatives to the popular o-nitrobenzyl photocage systems.

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Self-Immolative Aryl Phthalate Esters

2012

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We report that aryl phthalate esters are robust self-immolative linkers. This linker is easy to conjugate and releases output phenols upon cleaving a fluoride-sensitive mask to yield a benign phthalic acid byproduct, making these linkers potentially useful as fluoride sensors and promising for use in biological and materials applications. ABSTRACT: We report that aryl phthalate esters are robust selfimmolative linkers. This linker is easy to conjugate and releases output phenols upon cleaving a fluoride-sensitive mask to yield a benign phthalic acid byproduct, making these linkers potentially useful as fluoride sensors and promising for use in biological and materials applications. Disciplines

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Self-Immolative Phthalate Esters Sensitive to Hydrogen Peroxide and Light

et al. 2014

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Light- and chemo-responsive organic molecules with biological application

Mahoney¹

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I would also like to thank Manibarsha Goswami who wasn't an official Winter group member, but a constant source of support. You all made grad school a better place and I wish only the best for you all. (I would specially like to thank Pratik and Mark for making the "Eastside Lab" the coolest place in Hach Hall ).ftb I would also like to thank new graduate students Julie Peterson and Yunfan (Frank) Qui for their support. I wish you the best and much grad school success. Last, but not least, I would like to thank my family for their endless love and support. Thank you to my dad for pushing me and encouraging me to achieve more and do my best work, to my mom for always being there and listening to all of my worries and problems and celebrating my successes, to my sister for keeping me grounded and to my brother for being my number one fan. Thanks again to everyone. I am so thankful to have all of you in my life.

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