EnzymeML: seamless data flow and modeling of enzymatic data

Simone Lauterbach, Hannah Dienhart, Jan Range, Stephan Malzacher, Jan Dirk Spöring, Dörte Rother, Maria Filipa Pinto, Pedro Martins, Colton E. Lagerman, Andreas S. Bommarius, Amalie Vang Høst, John M. Woodley, Sandile Ngubane, Tukayi Kudanga, Frank T. Bergmann, Johann M. Rohwer, Dorothea Iglezakis, Andreas Weidemann, Ulrike Wittig, Carsten KettnerNeil Swainston, Santiago Schnell, Jürgen Pleiss*

*Corresponding author for this work

Research output: Contribution to journalJournal articleResearchpeer-review

Abstract

The design of biocatalytic reaction systems is highly complex owing to the dependency of the estimated kinetic parameters on the enzyme, the reaction conditions, and the modeling method. Consequently, reproducibility of enzymatic experiments and reusability of enzymatic data are challenging. We developed the XML-based markup language EnzymeML to enable storage and exchange of enzymatic data such as reaction conditions, the time course of the substrate and the product, kinetic parameters and the kinetic model, thus making enzymatic data findable, accessible, interoperable and reusable (FAIR). The feasibility and usefulness of the EnzymeML toolbox is demonstrated in six scenarios, for which data and metadata of different enzymatic reactions are collected and analyzed. EnzymeML serves as a seamless communication channel between experimental platforms, electronic lab notebooks, tools for modeling of enzyme kinetics, publication platforms and enzymatic reaction databases. EnzymeML is open and transparent, and invites the community to contribute. All documents and codes are freely available at https://enzymeml.org.

Original languageEnglish
JournalNature Methods
Volume20
Pages (from-to)400–402
ISSN1548-7091
DOIs
Publication statusPublished - 2023

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