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Biotin proximity tagging favours unfolded proteins and enables the study of intrinsically disordered regions

David‐Paul Minde, Manasa Ramakrishna, Kathryn S. Lilley

2020Communications Biology44 citationsDOIOpen Access PDF

Abstract

Intrinsically Disordered Regions (IDRs) are enriched in disease-linked proteins known to have multiple post-translational modifications, but there is limited in vivo information about how locally unfolded protein regions contribute to biological functions. We reasoned that IDRs should be more accessible to targeted in vivo biotinylation than ordered protein regions, if they retain their flexibility in human cells. Indeed, we observed increased biotinylation density in predicted IDRs in several cellular compartments >20,000 biotin sites from four proximity proteomics studies. We show that in a biotin 'painting' time course experiment, biotinylation events in Escherichia coli ribosomes progress from unfolded and exposed regions at 10 s, to structured and less accessible regions after five minutes. We conclude that biotin proximity tagging favours sites of local disorder in proteins and suggest the possibility of using biotin painting as a method to gain unique insights into in vivo condition-dependent subcellular plasticity of proteins.

Topics & Concepts

BiotinylationBiotinIntrinsically disordered proteinsBiologyStreptavidinProteomicsIn vivoComputational biologyRibosomeCell biologyBiochemistryChemistryGeneticsRNAGeneBiotin and Related StudiesCellular transport and secretionClick Chemistry and Applications