Design of a Multiuse Photoreactor To Enable Visible‐Light Photocatalytic Chemical Transformations and Labeling in Live Cells

Bissonnette, Noah B.; Ryu, Keun Ah; Reyes‐Robles, Tamara; Wilhelm, Sharon; Tomlinson, Jake H.; Crotty, Kelly; Hett, Erik C.; Roberts, Lee R.; Hazuda, Daria J.; Willis, M. J.; Oslund, Rob C.; Fadeyi, Olugbeminiyi O.

doi:10.1002/cbic.202000392

Cited by 14 publications

(15 citation statements)

References 43 publications

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“…In anticipation of utilizing this photocatalyst system in a targeted fashion within biological environments, we designed an osmium photocatalyst containing an alkyne linker for easy attachment to targeting modalities (Figure S4). As a proof-of-concept experiment, we combined carbonic anhydrase (CA) with PFAA-biotin (15) and free osmium-alkyne photocatalyst followed by irradiation with red light (660 nm) using a recently developed biophotoreactor 33 (Figure 5A). Under these conditions, we observed biotinylation of CA in the presence of both the photocatalyst and red light whereas the absence of light or the use of red light without photocatalyst does not induce biotinylation (Figure 5B).…”

Section: Resultsmentioning

confidence: 99%

Targeted Activation in Localized Protein Environments via Deep Red Photoredox Catalysis

Tay

Ryu

Weber

et al. 2021

Preprint

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State-of-the art photoactivation strategies in chemical biology provide spatiotemporal control and visualization of biological processes. However, using high energy light (λ < 500 nm) for substrate or photocatalyst sensitization can lead to background activation of photoactive small molecule probes and reduce its efficacy in complex biological environments. Here we describe the development of targeted aryl azide activation via deep red light (λ = 660 nm) photoredox catalysis and its use in photocatalyzed proximity labeling. We demonstrate that aryl azides are converted to triplet nitrenes via a novel redox-centric mechanism and show that its spatially localized-formation requires both red light and a photocatalyst-targeting modality. This technology was applied in different colon cancer cell systems for targeted protein environment labeling of epithelial cell adhesion molecule (EpCAM). We identified a small subset of proteins with previously known and unknown association to EpCAM, including CDH3, a clinically relevant protein that shares high tumor selective expression with EpCAM.

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Section: Resultsmentioning

confidence: 99%

Targeted Activation in Localized Protein Environments via Deep Red Photoredox Catalysis

Tay

Ryu

Weber

et al. 2021

Preprint

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“…Further, biotinylation for labeling carbonic anhydrase and livecell labeling was performed using the same photoreactor. [67]…”

Section: Intramolecular Cyclizationmentioning

confidence: 99%

“…Proof of concept was demonstrated by performing C−N, C−C, and dehalogenation reactions in a single reactor array by changing the LED source. Further, biotinylation for labeling carbonic anhydrase and live‐cell labeling was performed using the same photoreactor [67] …”

Section: Photocatalytic Transformationsmentioning

confidence: 99%

Advancement in Organic Synthesis Through High Throughput Experimentation

2021

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and cyanoarenes has also been optimized using an HTE approach. [63] Other Photochemical TransformationsNon-activated alkyl bromides were coupled with Michael acceptors in a photoredox Giese-type reaction. [64] Reaction optimization was performed by studying the effect of photocatalyst, solvent, base, and varying amounts of radical initiator (Me 3 Si) 3 SiH on product and by-product profile. Another study of conjugate addition using photocatalytic methodology was shown for the synthesis of unnatural β-alkyl α-amino acid derivatives via decarboxylative photocatalysis. [65] Photocatalysis was performed with oxime and cyanopyridine precursors (Scheme 4g) to form primary amine products. [66] Four different solvents (acetone, DCE, ACN, DMSO), nine different photocatalysts, and two reductants were used to evaluate 45 unique reactions. DMSO with diisopropylamine and Ir[dF(Me) ppy] 2 dtbbpyPF 6 gave the highest yield by UPLC, although many Scheme 4. Photocatalytic transformations in HTE.

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“…In recent years, a range of different photoreactors (commercial and custom) were developed by different companies [32] and groups (Table S5) [33–41] . However, less cost‐intensive solutions often lack an efficient temperature controlling system or allow illumination of only a single sample.…”

Section: Introductionmentioning

confidence: 99%

Accelerated Reaction Engineering of Photo(bio)catalytic Reactions through Parallelization with an Open‐Source Photoreactor

et al. 2021

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Photobiocatalysis is an alternative approach in synthesis that has received much attention in the recent years. Due to the youth of the topic, only few reactor systems are commercially available. To allow a parallel parameter‐screening approach as often used in the optimization of biocatalytic processes, a photoreactor was developed that can illuminate up to 24 samples at well‐defined reaction conditions. The device‘s optical features and temperature regulation have been thoroughly characterized and its application was demonstrated in four examples, specifically three photobiocatalytic and one photocatalytic process: (i) Light‐dependent decarboxylation using a photodecarboxylase; (ii) Reduction of protochlorophyllide using a protochlorophyllide oxidoreductase; (iii) Photosynthetic oxygen production performed by cyanobacteria; and (iv) (−)‐Riboflavin‐catalyzed (E/Z)‐isomerization of cinnamic acid derivatives.

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Design of a Multiuse Photoreactor To Enable Visible‐Light Photocatalytic Chemical Transformations and Labeling in Live Cells

Cited by 14 publications

References 43 publications

Targeted Activation in Localized Protein Environments via Deep Red Photoredox Catalysis

Targeted Activation in Localized Protein Environments via Deep Red Photoredox Catalysis

Advancement in Organic Synthesis Through High Throughput Experimentation

Accelerated Reaction Engineering of Photo(bio)catalytic Reactions through Parallelization with an Open‐Source Photoreactor

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