The Impact of Commonly Used Alkylating Agents on Artifactual Peptide Modification.

Iodoacetamide is by far the most commonly used agent for alkylation of cysteine during sample preparation for proteomics. An alternative, 2-chloroacetamide, has recently been suggested to reduce the alkylation of residues other than cysteine, such as the N-terminus, Asp, Glu, Lys, Ser, Thr, and Tyr. Here we show that although 2-chloroacetamide reduces the level of off-target alkylation, it exhibits a range of adverse effects. The most significant of these is methionine oxidation, which increases to a maximum of 40% of all Met-containing peptides, compared with 2-5% with iodoacetamide. Increases were also observed for mono- and dioxidized tryptophan. No additional differences between the alkylating reagents were observed for a range of other post-translational modifications and digestion parameters. The deleterious effects were observed for 2-chloroacetamide from three separate suppliers. The adverse impact of 2-chloroacetamide on methionine oxidation suggests that it is not the ideal alkylating reagent for proteomics.

[1]  F. Gurd [34a] carboxymethylation. , 1972, Methods in enzymology.

[2]  J. Blankenship,et al.  I. Aplysia californica neurons R3–R14: Primary structure of the myoactive histidine-rich basic peptide and peptide I , 1989, Peptides.

[3]  P. Selvin,et al.  A comparison between the sulfhydryl reductants tris(2-carboxyethyl)phosphine and dithiothreitol for use in protein biochemistry. , 1999, Analytical biochemistry.

[4]  N. Sherman,et al.  Protein Sequencing and Identification Using Tandem Mass Spectrometry: Kinter/Tandem Mass Spectrometry , 2000 .

[5]  V. N. Lapko,et al.  Identification of an artifact in the mass spectrometry of proteins derivatized with iodoacetamide. , 2000, Journal of mass spectrometry : JMS.

[6]  E. Boja,et al.  Overalkylation of a protein digest with iodoacetamide. , 2001, Analytical chemistry.

[7]  W. Lehmann,et al.  Iodoacetamide-alkylated methionine can mimic neutral loss of phosphoric acid from phosphopeptides as exemplified by nano-electrospray ionization quadrupole time-of-flight parent ion scanning. , 2005, Rapid communications in mass spectrometry : RCM.

[8]  R. Aebersold,et al.  Dynamic Spectrum Quality Assessment and Iterative Computational Analysis of Shotgun Proteomic Data , 2006, Molecular & Cellular Proteomics.

[9]  Sean L Seymour,et al.  The Paragon Algorithm, a Next Generation Search Engine That Uses Sequence Temperature Values and Feature Probabilities to Identify Peptides from Tandem Mass Spectra*S , 2007, Molecular & Cellular Proteomics.

[10]  M. Mann,et al.  Iodoacetamide-induced artifact mimics ubiquitination in mass spectrometry , 2008, Nature Methods.

[11]  Gennifer E. Merrihew,et al.  Expediting the development of targeted SRM assays: using data from shotgun proteomics to automate method development. , 2009, Journal of proteome research.

[12]  E. Go,et al.  A general protease digestion procedure for optimal protein sequence coverage and post-translational modifications analysis of recombinant glycoproteins: application to the characterization of human lysyl oxidase-like 2 glycosylation. , 2011, Analytical chemistry.

[13]  Eunok Paek,et al.  Fast Multi-blind Modification Search through Tandem Mass Spectrometry* , 2011, Molecular & Cellular Proteomics.

[14]  R. Zahedi,et al.  Protein carbamylation: In vivo modification or in vitro artefact? , 2013, Proteomics.

[15]  Xin Huang,et al.  ISPTM: an iterative search algorithm for systematic identification of post-translational modifications from complex proteome mixtures. , 2013, Journal of proteome research.

[16]  Andrew R. Jones,et al.  ProteomeXchange provides globally co-ordinated proteomics data submission and dissemination , 2014, Nature Biotechnology.

[17]  Hui Zhang,et al.  Inhibition of protein carbamylation in urea solution using ammonium-containing buffers. , 2014, Analytical biochemistry.

[18]  M. Mann,et al.  Minimal, encapsulated proteomic-sample processing applied to copy-number estimation in eukaryotic cells , 2014, Nature Methods.

[19]  R. Aebersold,et al.  Minimal sample requirement for highly multiplexed protein quantification in cell lines and tissues by PCT‐SWATH mass spectrometry , 2015, Proteomics.

[20]  Brian L. Frey,et al.  Global Identification of Protein Post-translational Modifications in a Single-Pass Database Search , 2015, Journal of proteome research.

[21]  R. Aebersold,et al.  Reproducible Tissue Homogenization and Protein Extraction for Quantitative Proteomics Using MicroPestle-Assisted Pressure-Cycling Technology. , 2016, Journal of proteome research.

[22]  Jun Zhong,et al.  Common errors in mass spectrometry‐based analysis of post‐translational modifications , 2016, Proteomics.

[23]  A. Stensballe,et al.  Proteome stability analysis of snap frozen, RNAlater preserved, and formalin-fixed paraffin-embedded human colon mucosal biopsies , 2016, Data in brief.

[24]  T. Müller,et al.  Systematic Evaluation of Protein Reduction and Alkylation Reveals Massive Unspecific Side Effects by Iodine-containing Reagents* , 2017, Molecular & Cellular Proteomics.