Abstract:Bioorthogonal cleavage reactions are gaining popularity in chemically inducible prodrug activation and in the control of biomolecular functions. Despite similar applications, these reactions were developed and optimized on different substrates and under different experimental conditions. Reported herein is a side‐by‐side comparison of palladium‐, ruthenium‐ and tetrazine‐triggered release reactions, which aims at comparing the reaction kinetics, efficiency and overall advantages and limitations of the methods.… Show more
“…Toward this goal, we employed our recently developed TCO-caged resorufin dye conjugate (TCO-Reso). 53 Our initial experiments performed in a well plate format revealed that tetrazines bearing a single methyl substituent release almost 50% of the resorufin dye from TCO-Reso within the first hour. In contrast, tetrazines having an aryl substituent at this position displayed a rather slow gradual release of the dye over 12 h (Figure S21B).…”
Section: Mitochondria-specific Release Reaction In Live Cellssupporting
confidence: 74%
“…Because our cationic tetrazines comprise a structurally unprecedented motif, we first evaluated their releasing efficacy. Toward this goal, we employed our recently developed TCO-caged resorufin dye conjugate (TCO-Reso) . Our initial experiments performed in a well plate format revealed that tetrazines bearing a single methyl substituent release almost 50% of the resorufin dye from TCO-Reso within the first hour.…”
The development of
abiotic chemical reactions that can be performed
in an organelle-specific manner can provide new opportunities in drug
delivery and cell and chemical biology. However, due to the complexity
of the cellular environment, this remains a significant challenge.
Here, we introduce structurally redesigned bioorthogonal tetrazine
reagents that spontaneously accumulate in mitochondria of live mammalian
cells. The attributes leading to their efficient accumulation in the
organelle were optimized to include the right combination of lipophilicity
and positive delocalized charge. The best performing mitochondriotropic
tetrazines enable subcellular chemical release of TCO-caged compounds
as we show using fluorogenic substrates and mitochondrial uncoupler
niclosamide. Our work demonstrates that a shrewd redesign of common
bioorthogonal reagents can lead to their transformation into organelle-specific
probes, opening the possibility to activate prodrugs and manipulate
biological processes at the subcellular level by using purely chemical
tools.
“…Toward this goal, we employed our recently developed TCO-caged resorufin dye conjugate (TCO-Reso). 53 Our initial experiments performed in a well plate format revealed that tetrazines bearing a single methyl substituent release almost 50% of the resorufin dye from TCO-Reso within the first hour. In contrast, tetrazines having an aryl substituent at this position displayed a rather slow gradual release of the dye over 12 h (Figure S21B).…”
Section: Mitochondria-specific Release Reaction In Live Cellssupporting
confidence: 74%
“…Because our cationic tetrazines comprise a structurally unprecedented motif, we first evaluated their releasing efficacy. Toward this goal, we employed our recently developed TCO-caged resorufin dye conjugate (TCO-Reso) . Our initial experiments performed in a well plate format revealed that tetrazines bearing a single methyl substituent release almost 50% of the resorufin dye from TCO-Reso within the first hour.…”
The development of
abiotic chemical reactions that can be performed
in an organelle-specific manner can provide new opportunities in drug
delivery and cell and chemical biology. However, due to the complexity
of the cellular environment, this remains a significant challenge.
Here, we introduce structurally redesigned bioorthogonal tetrazine
reagents that spontaneously accumulate in mitochondria of live mammalian
cells. The attributes leading to their efficient accumulation in the
organelle were optimized to include the right combination of lipophilicity
and positive delocalized charge. The best performing mitochondriotropic
tetrazines enable subcellular chemical release of TCO-caged compounds
as we show using fluorogenic substrates and mitochondrial uncoupler
niclosamide. Our work demonstrates that a shrewd redesign of common
bioorthogonal reagents can lead to their transformation into organelle-specific
probes, opening the possibility to activate prodrugs and manipulate
biological processes at the subcellular level by using purely chemical
tools.
“…9,11,13,14 Despite proving the potential of catalysis-based approaches in medicine, the great majority of the schemes proposed so far display rather modest catalytic efficiencies, even in buffer solutions, as evidenced by low turnover numbers (TONs) and slow reaction kinetics. 15 The latter aspect is especially overlooked by the scientic community working in this eld, yet of key importance in the development of drug activation strategies. Apart from few exceptions, 2,12,16,17 catalysts currently reported in the literature typically achieve substrate conversion rates in solution that are in the order of 0.1-10 h À1 (10 À3 to 10 À1 min À1 ).…”
Section: Introductionmentioning
confidence: 99%
“…prodrug) to induce the desired therapeutic effects. In such a scenario, the catalyst intrinsic toxicity is critical 15 and the choice of drugs with high-potency (sub-μM) becomes often mandatory, overall limiting the therapeutic scope of several catalysis-based strategies for prodrug activation.…”
Loading of a flavin catalyst and Pt prodrug onto a hydrogel affords biomaterials for the catalytic generation and delivery of cisplatin upon light irradiation or addition of electron donors. Confinement boosts the turnover frequency of the flavin.
“…Intriguingly, pretreatment of cells with Pd reagents followed by the addition of the pro-fluorophore failed to generate any fluorescent signal, presumably because of the conversion of Pd complexes to inactive species. In another study, it was observed that even in simple systems such as phosphate-buffered saline, transition metal catalysts underwent partial deactivation [ 118 ]. Fig.…”
While bioorthogonal reactions are routinely employed in living cells and organisms, their application within individual organelles remains limited. In this review, we highlight diverse examples of bioorthogonal reactions used to investigate the roles of biomolecules and biological processes as well as advanced imaging techniques within cellular organelles. These innovations hold great promise for therapeutic interventions in personalized medicine and precision therapies. We also address existing challenges related to the selectivity and trafficking of subcellular dynamics. Organelle-targeted bioorthogonal reactions have the potential to significantly advance our understanding of cellular organization and function, provide new pathways for basic research and clinical applications, and shape the direction of cell biology and medical research.
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