Abstract
RationaleHistone post‐translational modifications (PTMs) play key roles in regulating eukaryotic gene expression. Mass spectrometry (MS) has emerged as a powerful method to characterize and quantify histone PTMs as it allows unbiased identification and quantification of multiple histone PTMs including combinations of the modifications present.MethodsIn this study we compared a range of data‐acquisition methods for the identification and quantification of the histone PTMs using a Q Exactive HF Orbitrap. We compared three different data‐dependent analysis (DDA) methods with MS2 resolutions of 120K, 60K, 30K. We also compared a range of data‐independent analysis (DIA) methods using MS2 isolation windows of 20 m/z and DIAvw to identify and quantify histone PTMs in Chinese hamster ovary (CHO) cells.ResultsThe increased number of MS2 scans afforded by the lower resolution methods resulted in a higher number of queries, peptide sequence matches (PSMs) and a higher number of peptide proteoforms identified with a Mascot Ion score greater than 46. No difference in the proportion of peptide proteoforms with Delta scores >17 was observed. Lower coefficients of variation (CVs) were obtained in the DIA MS1 60 K MS2 30 K 20 m/z isolation windows compared with the other data‐acquisition methods.ConclusionsWe observed that DIA which offers advantages in flexibility and identification of isobaric peptide proteoforms performs as well as DDA in the analysis of histone PTMs. We were able to identify 71 modified histone peptides for histone H3 and H4 and quantified 64 across each of the different acquisition methods.
Highlights
Regulation of eukaryotic gene transcription is a complex, carefully orchestrated series of molecular interactions where epigenetic mechanisms of control are becoming increasingly recognized[1]
We successfully applied a number of data dependent and data independent methods to analyse changes in relative abundance of histone post translational modifications (PTMs) in Chinese Hamster Ovary (CHO) cells
This study illustrates the versatility of mass spectrometry for the study of changes in relative abundance in histone PTMs
Summary
Regulation of eukaryotic gene transcription is a complex, carefully orchestrated series of molecular interactions where epigenetic mechanisms of control are becoming increasingly recognized[1]. The chemical modifications of the N-terminal tail of histones, termed post translational modifications (PTMs) alter the conformation of the chromatin thereby affecting the availability of the DNA3to transcription factors[1]. These histone PTMs play key roles in regulating eukaryotic gene expression. The PTM of histones provides binding sites for a number of effector molecules that can establish and orchestrate downstream events such as gene transcription These histone marks dictate chromatin structure but they control access to the underlying DNA and are involved in all DNA-based processes including gene expression
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