Issue 31, 2024

Hydrogen production by a fully de novo enzyme

Abstract

Molecular catalysts based on abundant elements that function in neutral water represent an essential component of sustainable hydrogen production. Artificial hydrogenases based on protein-inorganic hybrids have emerged as an intriguing class of catalysts for this purpose. We have prepared a novel artificial hydrogenase based on cobaloxime bound to a de novo three alpha-helical protein, α3C, via a pyridyl-based unnatural amino acid. The functionalized de novo protein was characterised by UV-visible, CD, and EPR spectroscopy, as well as MALDI spectrometry, which confirmed the presence and ligation of cobaloxime to the protein. The new de novo enzyme produced hydrogen under electrochemical, photochemical and reductive chemical conditions in neutral water solution. A change in hydrogen evolution capability of the de novo enzyme compared with native cobaloxime was observed, with turnover numbers around 80% of that of cobaloxime, and hydrogen evolution rates of 40% of that of cobaloxime. We discuss these findings in the context of existing literature, how our study contributes important information about the functionality of cobaloximes as hydrogen evolving catalysts in protein environments, and the feasibility of using de novo proteins for development into artificial metalloenzymes. Small de novo proteins as enzyme scaffolds have the potential to function as upscalable bioinspired catalysts thanks to their efficient atom economy, and the findings presented here show that these types of novel enzymes are a possible product.

Graphical abstract: Hydrogen production by a fully de novo enzyme

Supplementary files

Article information

Article type
Paper
Submitted
29 Mar 2024
Accepted
04 Jun 2024
First published
13 Jun 2024
This article is Open Access
Creative Commons BY license

Dalton Trans., 2024,53, 12905-12916

Hydrogen production by a fully de novo enzyme

S. Berglund, C. Bassy, I. Kaya, P. E. Andrén, V. Shtender, M. Lasagna, C. Tommos, A. Magnuson and S. D. Glover, Dalton Trans., 2024, 53, 12905 DOI: 10.1039/D4DT00936C

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