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"Faces" of the day:

Mia Schwerer

Maria Martinez Serrat

Rina Demjaha

Cansu Tafrali

Maria Anna Smolle

Bianca Perfler

Sandra Burgstaller

Katarina Vizar Cisarova

Marah Runtsch

Anna Damulina

Daniela Theresia Pinter

Sayantanee Dutta

Sonja Hochmeister

Helmut Bischof

Georg Hauer

Sebastian Vosberg

Stefan Kurath-Koller

Sebastian Tschauner

Michael Dengler

Armin Zebisch

Markus Absenger-Novak

Marko Bergovec

Stefan Pilz

Andreas Leithner

Michael Khalil

Philipp Jost

Christian Enzinger

Roland Malli

Stefan Ropele

Wolfgang Graier

Heinz Sill

Selected Publication:

SHR Neuro Cancer Cardio Lipid Metab Microb

Tseliou, V; Kqiku, L; Berger, M; Schiel, F; Zhou, H; Poelarends, GJ; Melchiorre, P.
Stereospecific radical coupling with a non-natural photodecarboxylase.
Nature. 2024; 634(8035):848-854 Doi: 10.1038/s41586-024-08004-9
PubMed FullText FullText_MUG

 

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Abstract:

Photoenzymes are light-powered biocatalysts that typically rely on the excitation of cofactors or unnatural amino acids for their catalytic activities^1,2. A notable natural example is the fatty acid photodecarboxylase, which uses light energy to convert aliphatic carboxylic acids to achiral hydrocarbons³. Here we report a method for the design of a non-natural photodecarboxylase based on the excitation of enzyme-bound catalytic intermediates, rather than reliance on cofactor excitation⁴. Iminium ions⁵, transiently generated from enals within the active site of an engineered class I aldolase⁶, can absorb violet light and function as single-electron oxidants. Activation of chiral carboxylic acids, followed by decarboxylation, generates two radicals that undergo stereospecific cross-coupling, yielding products with two stereocentres. Using the appropriate enantiopure chiral substrate, the desired diastereoisomeric product is selectively obtained with complete enantiocontrol. This finding underscores the ability of the active site to transfer stereochemical information from the chiral radical precursor into the product, effectively addressing the long-standing problem of rapid racemization of chiral radicals. The resulting 'memory of chirality' scenario⁷ is a rarity in enantioselective radical chemistry.

Find related publications in this database (using NLM MeSH Indexing)

Biocatalysis - radiation effects

Carboxy-Lyases - chemistry, metabolism

Carboxylic Acids - chemistry, metabolism

Catalytic Domain - administration & dosage

Coenzymes - chemistry, metabolism

Decarboxylation - administration & dosage

Electrons - administration & dosage

Free Radicals - chemistry, metabolism

Imines - chemistry, metabolism

Light - administration & dosage

Oxidants - chemistry, metabolism

Protein Engineering - administration & dosage

Stereoisomerism - administration & dosage

Substrate Specificity - administration & dosage

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