Rapid Histone Post-Translational Modification Analysis Using Alternative Proteases and Tandem Mass Tags.

Authors

Natalie P Turner, Sabyasachi Baboo, Patrick Garrett, Jolene K Diedrich, Michal Bajo, Marisa Roberto, John R Yates Iii

Published in

Analytical chemistry. Jun 19, 2026. Epub Jun 19, 2026.

Abstract

Histone post-translational modifications (PTMs) alter chromatin dynamics and contribute to the regulation of gene expression in health and disease, yet mass spectrometry-based histone PTM analysis remains constrained by inefficient sample preparation workflows. Here, we develop RIPUP (Rapid Identification of histone PTMs in Underivatized Peptides), a streamlined multiprotease workflow that reduces sample preparation to hours while improving PTM coverage and quantitative accuracy. Systematic evaluation of Arg-C Ultra and a recombinant (r)-Chymotrypsin protease under varied conditions, including standard derivatization with propionic anhydride and tandem mass tag (TMT) labeling, demonstrated that Arg-C Ultra with TMT labeling achieves a detection of total PTM that exceeds Trypsin-based approaches. Using the HiP-Frag computational framework for unrestrictive PTM identification, we discovered that TMT's tertiary amine provides charge compensation that rescues the ionization of negatively charged acylations revealing 58 succinylation and 31 glutarylation sites─a "dark epigenome" largely undetected by propionylation-based methods. Complementary digestion with Arg-C Ultra and r-Chymotrypsin provides orthogonal sequence coverage, enabling the detection of PTMs in H2A variants, linker histones, and regions poorly represented by arginine-specific cleavage alone. In HEK293T cells treated with the pan-sirtuin inhibitor nicotinamide, RIPUP quantified 112 statistically significant peptidoforms (adj p < 0.05), predominantly increasing with the NAM dose (88 up, 24 down). Application of RIPUP to frozen-thawed rat hippocampal sections within a 3 h workflow identified >200 PTMs including H3 K27/K36/K37 methylation, H4 N-terminal acetylation patterns, and H2A K118/K119 ubiquitination. This rapid, high-efficiency platform enables timely discovery of epigenetic mechanisms and accelerates the path from PTM identification to therapeutic target validation.

PMID:
42319981
Bibliographic data and abstract were imported from PubMed on 20 Jun 2026.

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