From the University of Nottingham
December 1, 2020 -- Scientists have
broken the rules of enzyme engineering to unlock a new method for creating
chemical reactions that could unlock a wide range of new applications – from
creating new drugs to food production.
In their paper published today in Nature
Catalysis, Professor Francesca Paradisi and Dr.
Martina Contente of the University of Nottingham and the University of Bern
show a new method to produce chemical molecules more efficiently through a new
one step reaction in the enzyme.
We have demonstrated how a very simple
mutation in one of the key residues of a useful enzyme has dramatically
expanded its synthetic scope, enabling the use of the mutant variant in the
preparation of challenging chemical molecules, as well as natural metabolites
that are vital in many biological processes in the body. -- Professor Paradis, Professor of Biocatalysis
in the School of Chemistry in Nottingham
Any textbook on enzymes will report on
how the catalytic amino acids in any given enzyme family are highly conserved,
they are in fact a signature of the type of chemistry an enzyme can do.
Variations do occur and in some cases, if the replacing amino acid is similar,
both can be found in significant proportion in Nature, but others can be much
less common and are found only in a limited number of species.
“In this study we have explored an
untouched area of enzyme engineering and modified the a key catalytic residue
in the active site of an enzyme” adds Professor Paradisi, “Previously it was
thought that doing this would cause a loss of activity of the enzyme but we
have found this is not the case when this biocatalyst is used in a synthetic
direction and in fact challenging but very useful molecules can now be made
under mild conditions which could be easily scaled up and replicated
commercially for use in a wide range of products.”
To change the substrate scope of an
enzyme the approach has generally been to mutate the residues involved in
substrate recognition, whether through rational design or directed evolution,
leaving always untouched the catalytic ones.
The mutant variant of an acyl
transferase enzyme was rapidly created and while the native biocatalyst would
work with alcohols and linear amines, the mutant work with thiols and much more
complex amines too. The research demonstrated that indeed the new variant has
lost the ability to hydrolyse esters, but for synthetic applications, where an
ester or other functional groups need to be made (thioesters and amides) and
not cleaved, this is in fact a major advantage.
We have had fantastic feedback on this
study from the scientific community as it is providing a new tool for chemistry
that can be applied to a wide range of molecular reactions. The fact that it is
a very stable reaction created without the need for specific conditions mean it
has the potential for a low cost commercial application in the production of
new pharmaceuticals. We believe we have unlocked a new combination in the
catalytic triads which nature seem to have disfavoured, possibly to tighten the
control on reactivity, but that for a chemist could be a real goldmine. -- Dr Martina Contente
News
- Breaking the rules of chemistry unlocks new reaction - University of
Nottingham
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