Engineering an efficient and enantioselective enzyme for the Morita–Baylis–Hillman reaction

Crawshaw, Rebecca; Crossley, Amy E.; Johannissen, Linus O.; Burke, Ashleigh J.; Hay, Sam; Levy, Colin; Baker, David; Lovelock, Sarah L.; Green, Anthony P.

doi:10.1038/s41557-021-00833-9

Cited by 56 publications

(101 citation statements)

References 67 publications

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“…Furthermore, most engineered de novo enzymes display very low activities and many rounds of laboratory directed evolution, a highly time-consuming procedure, are often required to bring their catalysis to levels similar to those of modern natural enzymes [37,45-47].…”

Section: Discussionmentioning

confidence: 99%

“…However, only about 30% of enzymes are metalloenzymes [43,44]and mechanisms for the emergence of new enzymes that do not rely on metal recruitment remain poorly understood. Furthermore, most engineered de novo enzymes display very low activities and many rounds of laboratory directed evolution, a highly time-consuming procedure, are often required to bring their catalysis to levels similar to those of modern natural enzymes [37,[45][46][47].…”

Section: Discussionmentioning

confidence: 99%

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Efficient base-catalysed Kemp elimination in an engineered ancestral enzyme

Gutierrez-Rus

Alcalde

Risso

et al. 2022

Preprint

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The routine generation of enzymes with completely new active sites is one of the major unsolved problems in protein engineering. Advances in this field have been so far modest, perhaps due, at least in part, to the widespread use of modern natural proteins as scaffolds for de novo engineering. Most modern proteins are highly evolved and specialized, and, consequently, difficult to repurpose for completely new functionalities. Conceivably, resurrected ancestral proteins with the biophysical properties that promote evolvability, such as high stability and conformational diversity, could provide better scaffolds for de novo enzyme generation. Kemp elimination, a non-natural reaction that provides a simple model of proton abstraction from carbon, has been extensively used as a benchmark in de novo enzyme engineering. Here, we present an engineered ancestral beta-lactamase with a new active site capable of efficiently catalysing the Kemp elimination. Our Kemp eliminase is the outcome of a minimalist design based on a single function-generating mutation followed by sharply-focused, low-throughput library screening. Yet, its catalytic parameters (kcat/KM=2x105 M-1s-1, kcat=635 s-1) compare favourably with the average modern natural enzyme and with the best proton-abstraction de novo Kemp eliminases reported in the literature. General implications of our results for de novo enzyme engineering are discussed.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Efficient base-catalysed Kemp elimination in an engineered ancestral enzyme

Gutierrez-Rus

Alcalde

Risso

et al. 2022

Preprint

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“…In a further recent development from the Arnold lab, they report the P450 catalyzed enantioselective ring expansion of aziridines to azetidines (Miller et al, 2022). Other methods to enable new to nature reactions (Leveson-Gower et al, 2019) include utilizing expanded genetic code via amber codon technology and tuning active site electronics (Ortmayer et al, 2020) as well as using Rosetta to design enzymes to carry out new to nature chemistry (Crawshaw et al, 2021).…”

Section: Future Challenges and Outlookmentioning

confidence: 99%

“…The logical progression of these strategies is in silico enzyme design facilitated by, for example, Rosetta. This tool has already been applied by several groups (Crawshaw et al, 2021) (Basanta et al, 2020) (Richter et al, 2011). Both approaches will also generate greater insight into the factors affecting substrate binding and catalytic mechanism which in turn will lead to more predictability.…”

Section: Future Challenges and Outlookmentioning

confidence: 99%

“…Computational methodology will enable a greater understanding of the role of flexible regions and protein dynamics in catalysis. Thus new computational tools and their democratization will, alongside the ongoing protein engineering revolution, lead to the second great revolution in enzyme engineering and is already proving exciting (Büchler et al, 2022) (Crawshaw et al, 2021). This combination will provide a much-needed pool of sustainable catalysts and hopefully a new era in chemical synthesis.…”

Section: Future Challenges and Outlookmentioning

confidence: 99%

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Redesigning Enzymes for Biocatalysis: Exploiting Structural Understanding for Improved Selectivity

Ding

Perez-Ortiz

Peate

et al. 2022

Front. Mol. Biosci.

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The discovery of new enzymes, alongside the push to make chemical processes more sustainable, has resulted in increased industrial interest in the use of biocatalytic processes to produce high-value and chiral precursor chemicals. Huge strides in protein engineering methodology and in silico tools have facilitated significant progress in the discovery and production of enzymes for biocatalytic processes. However, there are significant gaps in our knowledge of the relationship between enzyme structure and function. This has demonstrated the need for improved computational methods to model mechanisms and understand structure dynamics. Here, we explore efforts to rationally modify enzymes toward changing aspects of their catalyzed chemistry. We highlight examples of enzymes where links between enzyme function and structure have been made, thus enabling rational changes to the enzyme structure to give predictable chemical outcomes. We look at future directions the field could take and the technologies that will enable it.

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