Color‐Changing Paints Enabled by Photoresponsive Combinations of Bio‐Inspired Colorants and Semiconductors

Martin, Cassandra L.; Flynn, Kaitlyn R.; Kim, Taehwan; Nikolic, Skyler K.; Deravi, Leila F.; Wilson, Daniel J.

doi:10.1002/advs.202302652

Cited by 2 publications

References 53 publications

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Efficient Biomimetic Total Synthesis, Characterization, and Antioxidant Activity of Ommatins

Huang,

Kim,

Armendarez

et al. 2024

JACS Au

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Ommatins, natural colorants found in cephalopods and arthropods, are biosynthesized from tryptophan with uncyclized xanthommatin (Uc-Xa) as the key biosynthetic precursor. These pigments change color under oxidative or reductive conditions. Xanthommatin (Xa) and dihydro-xanthommatin (H 2 -Xa), as well as decarboxylated xanthommatin (Dc-Xa) and decarboxylated-dihydro-xanthommatin (Dc-H 2 -Xa), are some of the most common and well-studied ommatins. Herein, we describe the biomimetic total synthesis of Xa/H 2 -Xa on a gram scale by using the Mannich reaction and oxidative dimerization as the key steps. The 7-step linear synthetic sequence achieved an overall yield of 27%. Dc-Xa/Dc-H 2 -Xa and protected Uc-Xa/Uc-H 2 -Xa were also synthesized from the common intermediateprotected 3-hydroxykynurenine (3-OHK). The synthesized ommatins underwent thorough characterization using various spectroscopic techniques, including NMR, UV−vis, FTIR, HRMS, and LC−MS. Their optoelectronic properties were studied using spectrophotometry and electrochemical analysis. Furthermore, the antioxidant activity of the synthesized ommatins was evaluated using an oxygen radical antioxidant capacity activity assay. The results indicated that Dc-Xa exhibited the highest antioxidant activity, followed by Xa, while Uc-Xa showed the lowest activity.

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Efficient Biomimetic Total Synthesis, Characterization, and Antioxidant Activity of Ommatins

Huang,

Kim,

Armendarez

et al. 2024

JACS Au

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Growth-coupled microbial biosynthesis of the animal pigment xanthommatin

Bushin,

Alter,

Alván-Vargas

et al. 2024

Preprint

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The mining of genomes across life has unearthed a bounty of biosynthetic potential to diverse molecules key to a biobased future. While the heterologous expression of metabolic pathways has achieved broad success, most approaches suffer a similar fate in low initial production levels that require extensive, resource-heavy iterative strain engineering refinement. Herein we introduce a growth-coupled biosynthetic (GrowBio) strategy that irrevocably connects microbial growth with specialized compound production. We demonstrate the plug-and-play versatility of GrowBio in the production of the structurally complex animal biopigment xanthommatin, a color-changing ommochrome with material and cosmetic potential. Xanthommatin biosynthesis directly fuels growth of a newly designed Pseudomonas putida 5,10-methylenetetrahydrofolate auxotroph (PUMA). Aided by genome-scale metabolic modeling, PUMA was designed and built to be controlled by endogenous formate co-produced as a coupled biosynthetic byproduct in the multistep conversion of tryptophan to xanthommatin. Adaptive laboratory evolution was utilized to streamline xanthommatin's gram-scale bioproduction via growth rate selection, establishing GrowBio as a promising biotechnological approach for establishing and optimizing the microbial production of value-added molecules.

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Color‐Changing Paints Enabled by Photoresponsive Combinations of Bio‐Inspired Colorants and Semiconductors

Cited by 2 publications

References 53 publications

Efficient Biomimetic Total Synthesis, Characterization, and Antioxidant Activity of Ommatins

Efficient Biomimetic Total Synthesis, Characterization, and Antioxidant Activity of Ommatins

Growth-coupled microbial biosynthesis of the animal pigment xanthommatin

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