Abstract
Most eukaryotic proteins are modified during and/or after translation, regulating their structure, function and localisation. The role of posttranslational modifications (PTMs) in both normal cellular processes and in diseases is already well recognised and methods for detection of PTMs and generation of specifically modified proteins have developed rapidly over the last decade. However, structural consequences of PTMs and their specific effects on protein dynamics and function are not well understood. Furthermore, while random coil NMR chemical shifts of the 20 standard amino acids are available and widely used for residue assignment, dihedral angle predictions and identification of structural elements or propensity, they are not available for most posttranslationally modified amino acids. Here, we synthesised a set of random coil peptides containing common naturally occurring PTMs and determined their random coil NMR chemical shifts under standardised conditions. We highlight unique NMR signatures of posttranslationally modified residues and their effects on neighbouring residues. This comprehensive dataset complements established random coil shift datasets of the 20 standard amino acids and will facilitate identification and assignment of posttranslationally modified residues. The random coil shifts will also aid in determination of secondary structure elements and prediction of structural parameters of proteins and peptides containing PTMs.
Highlights
Posttranslational modifications (PTMs) expand the complexity of the proteome and their role in altering protein function and regulation is well recognised (Walsh et al 2005; Aebersold et al 2018)
Samples of peptides containing γ-carboxyglutamic acid and carboxymethyl lysine as residue ‘X’ were prepared as above and the pH was adjusted to pH 2.0 with HCl
We have synthesised a set of random coil peptides containing common naturally-occurring protein PTMs and assigned the random coil NMR chemical shifts
Summary
Posttranslational modifications (PTMs) expand the complexity of the proteome and their role in altering protein function and regulation is well recognised (Walsh et al 2005; Aebersold et al 2018). NMR spectroscopy studies, are predominantly carried out using recombinant proteins that lack the relevant PTMs. Access to posttranslationally modified proteins is facilitated by recent developments in protein chemical synthesis (Conibear et al 2018), genetic code engineering (Liu and Schultz 2010; Lang and Chin 2014) and enzymatic protein modification (Zhang et al 2018), enabling studies of the role of PTMs in protein structure and function. Increased commercial availability of the requisite building blocks for solid phase peptide synthesis (SPPS) means that peptides and proteins bearing PTMs are finding application in the pharmaceutical industry, chemical biology and peptide-based materials (Barber and Rinehart 2018)
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