INClusive: a Database Collecting Useful Information on Non-canonical Amino Acids and Their Incorporation into Proteins for Easier Genetic Code Expansion Implementation

Overview

Journal Nucleic Acids Res

Publisher Oxford University Press

Specialty Biochemistry

Date 2023 Nov 21

PMID 37986218

Authors

Leon-Samuel Icking

Andreas Martin Riedlberger

Fabian Krause

Jonas Widder

Anne Smedegaard Frederiksen

Fabian Stockert

Michael Spadt

Nikita Edel

Daniel Armbruster

Giada Forlani

Selene Franchini

Paulina Kaas

Busra Merve Kirpat Konak

Fabrice Krier

Maiwenn Lefebvre

Daniel Mazraeh

Jeremy Ranniger

Johanna Gerstenecker

Pia Gescher

Karsten Voigt

Pavel Salavei

Nicole Gensch

Barbara Di Ventura

Mehmet Ali Ozturk

Affiliations

Soon will be listed here.

Abstract

The incorporation of non-canonical amino acids (ncAAs) into proteins is a powerful technique used in various research fields. Genetic code expansion (GCE) is the most common way to achieve this: a specific codon is selected to be decoded by a dedicated tRNA orthogonal to the endogenous ones. In the past 30 years, great progress has been made to obtain novel tRNA synthetases (aaRSs) accepting a variety of ncAAs with distinct physicochemical properties, to develop robust in vitro assays or approaches for codon reassignment. This sparked the use of the technique, leading to the accumulation of publications, from which gathering all relevant information can appear daunting. Here we present iNClusive (https://non-canonical-aas.biologie.uni-freiburg.de/), a manually curated, extensive repository using standardized nomenclature that provides organized information on ncAAs successfully incorporated into target proteins as verified by mass spectrometry. Since we focused on tRNA synthetase-based tRNA loading, we provide the sequence of the tRNA and aaRS used for the incorporation. Derived from more than 687 peer-reviewed publications, it currently contains 2432 entries about 466 ncAAs, 569 protein targets, 500 aaRSs and 144 tRNAs. We foresee iNClusive will encourage more researchers to experiment with ncAA incorporation thus contributing to the further development of this exciting technique.

Citing Articles

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