Markus Piotrowski in front of a collage; an image of nitrilase helices taken with an electron microscope is shown at the bottom, a reconstruction of the spiral (calculated from the electron-microscope image) on the right, and the model of a single nitrilase enzyme on the left © RUB, Marquard

Biotechnology External structure can affect the function of enzymes

Enzymes that are identical on the inside may still perform different functions, depending on how tightly they are compressed.

As biocatalysts, enzymes are involved in many metabolic processes. They bind to a particular substance, i.e. the substrate, and convert it. Generally, the substrate-binding pocket inside the enzyme determines which type of substrate it processes. A research team from Ruhr-Universität Bochum (RUB) and from South Africa has analysed two enzymes with identical substrate binding pockets that nevertheless convert different substrates. In the process, it emerged that changes to the enzyme surface affect its substrate specificity by modifying how densely it is packed inside. These findings might pave the way for manipulating the enzyme function. The researchers published their report in the journal Communications Biology on 2 November 2018.

Swapping one single component

As the two analysed plant enzymes, so-called nitrilases, are very similar, the researchers were able to replace their components piece by piece. “We have thus found that merely by swapping one single component on the surface, we could make one enzyme convert the substrate of another enzyme,” explains Associate Professor Dr. Markus Piotrowski from the Department of Molecular Genetics and Physiology of Plants at RUB.

Breakthrough with electron microscopy

The researchers deployed electron microscopy to analyse why a modification of the surface can affect the substrate binding inside. The analysed nitrilases form larger helices that are big enough to be rendered visible under an electron microscope. “We could thus see that changes to the surface resulted in enzyme molecules in the helix to be more or less densely packed,” describes Piotrowski. “This, in turn, presumably causes the substrate binding site to be compressed more or less tightly.” In its more tightly compressed state, the binding pocket is no longer accessible to larger substrate molecules.

Biotechnological relevance

For researchers, nitrilases constitute a model of the evolution of enzymes, but they are also deployed in the chemical and pharmaceutical industry as biocatalysts. To date, experiments aiming at modifying these enzymes by altering their substrate binding site have mostly remained unsuccessful. “Our results have shown that the quaternary structure, namely the number and arrangement of individual enzyme molecules, has to be taken into consideration,” says Markus Piotrowski. Accordingly, targeted modifications of the enzyme function may be accomplished without performing any changes to the enzyme itself, but merely by compressing it into nitrilase helices with different densities.

Funding

The project was funded by the German Research Foundation (DFG), the National Research Foundation of South Africa, and the DFG Open Access Publishing Fund at Ruhr-Universität Bochum.

Original publication

Jeremy D. Woodward, Inga Trompetter, B. Trevor Sewell und Markus Piotrowski: Substrate specificity of plant nitrilase complexes is affected by their helical twist, in: Communications Biology, 2018, DOI: 10.1038/s42003-018-0186-4

Press contact

Priv.-Doz. Dr. Markus Piotrowski
Department of Molecular Genetics and Physiology of Plants
Faculty of Biology and Biotechnology
Ruhr-Universität Bochum
Germany
Phone: +49 234 32 24290
Email: markus.piotrowski@rub.de

Published

Tuesday
06 November 2018
9:17 am

By

Meike Drießen

Translated by

Donata Zuber

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