Reactive oxygen species (ROS) are both physiological intermediates in cellular signaling and mediators of oxidative stress. The cysteine-specific redox-sensitivity of proteins can shed light on how ROS are regulated and function, but low sensitivity has limited quantification of the redox state of many fundamental cellular regulators in a cellular context. Here we describe a highly sensitive and reproducible oxidation analysis approach (OxMRM) that combines protein purification, differential alkylation with stable isotopes, and multiple reaction monitoring mass spectrometry that can be applied in a targeted manner to virtually any cysteine or protein. Using this approach, we quantified the site-specific cysteine oxidation status of endogenous p53 for the first time and found that Cys182 at the dimerization interface of the DNA binding domain is particularly susceptible to diamide oxidation intracellularly. OxMRM enables analysis of sulfinic and sulfonic acid oxidation levels, which we validate by assessing the oxidation of the catalytic Cys215 of protein tyrosine phosphatase-1B under numerous oxidant conditions. OxMRM also complements unbiased redox proteomics discovery studies as a verification tool through its high sensitivity, accuracy, precision, and throughput. Molecular & Cellular Proteomics 9:1400 -1410, 2010.Oxidation of cysteine residues plays a critical role in modifying the structure and function of many proteins. Although cysteine oxidation is a tightly regulated biological process, nonenzymatic processes can contribute substantially to its levels, such as during oxidative stress. Regulatory oxidation states such as disulfide bonding and S-nitrosylation are readily modulated (1) and play an essential role in many physiological processes, including cell cycle, growth, death, and differentiation (2). In contrast, prolonged accumulation of reactive oxygen species is associated with many pathological conditions and leads to stable overoxidized states (sulfinic and sulfonic acid) that may disrupt redox regulation and protein function (3) and, in most cases, are thought to be nonregenerative.Assays capable of comprehensively assessing the dynamic changes in site-specific oxidation states are especially critical to understanding the contribution of redox status to many diseases. Numerous redox-sensitive proteins, including essential cellular regulators such as p53, have been described previously (for review, see ref. 4). However, technical factors have hampered the identification of specific site(s) of modification and characterization of their redox status in cells. Sitedirected mutagenesis is often employed to determine whether specific cysteines have redox-regulated functional roles (1), but this approach provides no information on the oxidation status of the endogenous protein. In addition, cysteine oxidation is dynamically dependent on the concentration, location, and specificity of small-molecule oxidants (5) and regulators of various antioxidant enzymes (6). Thiol pKa (7), solvent accessibility, and ...
A systematic study of posttranslational modifications of the estrogen receptor isolated from the MCF-7 human breast cancer cell line is reported. Proteolysis with multiple enzymes, mass spectrometry, and tandem mass spectrometry achieved very high sequence coverage for the full-length 66-kDa endogenous protein from estradiol-treated cell cultures. Nine phosphorylated serine residues were identified, three of which were previously unreported and none of which were previously observed by mass spectrometry by any other laboratory. Two additional modified serine residues were identified in recombinant protein, one previously reported but not observed here in endogenous protein and the other previously unknown. Although major emphasis was placed on identifying new phosphorylation sites, N-terminal loss of methionine accompanied by amino acetylation and a lysine side chain acetylation (or possibly trimethylation) were also detected. The use of both HPLC-ESI and MALDI interfaced to different mass analyzers gave higher sequence coverage and identified more sites than could be achieved by either method alone. The estrogen receptor is critical in the development and progression of breast cancer. One previously unreported phosphorylation site identified here was shown to be strongly dependent on estradiol, confirming its potential significance to breast cancer. Greater knowledge of this array of posttranslational modifications of estrogen receptor, particularly phosphorylation, will increase our understanding of the processes that lead to estradiol-induced activation of this protein and may aid the development of therapeutic strategies for management of hormonedependent breast cancer. Molecular & Cellular Proteomics 8:467-480, 2009.The ␣-isoform of the estrogen receptor (ER␣) 1 is a 66-kDa nuclear transcription factor that mediates transcriptional regulation of genes involved in cell proliferation and differentiation and plays a pivotal role in the development and progression of breast cancer (1-3). Consequently the development of therapies for management of hormone-dependent breast cancer has targeted signaling pathways based on modulation of ER␣ activity (4 -6). Current knowledge and understanding of ER␣ activity is derived from over 30 years of accumulated scientific evidence that has sought to delineate ER-mediated mechanisms and signaling pathways under pathological conditions modeled in cultured breast cancer cell lines. Because the function or activity of a protein may depend strongly on the presence of posttranslational modifications (PTMs), significant research has focused on detection and quantitation of such modifications in ER␣. The constellation of PTMs on a protein constitutes a molecular code that may dictate protein conformation, localization, and function. Thus biological inference based on ER␣ structure requires a comprehensive study of all possible PTMs on the constituent amino acids.Modifications to ER␣ reported to date are listed in Table I. Two of the most common and important PTMs that modulate the...
An intramolecular transacylation reaction was observed in the mass spectrometry of molecules containing both benzoyl and carboxymethyl groups on an aromatic heterocyclic core. The reaction is triggered by a dissociative protonation on the heterocyclic ring at the atom (carbon or nitrogen) that bonds to the benzoyl group, leading to an intermediate ion-neutral complex. The incipient benzoyl cation in the complex migrates to attack the carboxyl group of the neutral partner at the carbonyl or hydroxyl oxygen under thermodynamic or kinetic control, respectively. Elimination of benzoic acid followed by loss of carbon monoxide takes place as a result of the transacylation.
Activated estrogen receptor (ER␣) plays a critical role in breast cancer development and is a major target for drug treatment. Serine phosphorylation within the N-terminal domain (NTD) contributes to ER␣ activation and may also cause drug resistance. Previous biochemical identification of phosphorylated ER␣ residues was limited to protein artificially overexpressed in transfected cell lines. We report mass spectrometric methods that have allowed the identification of a new site within the NTD of ER␣ isolated from cultured human breast cancer cells. Immunoprecipitation, trypsin digestion, and analysis by nano-LC-ESI-MS/MS (Q-STAR, MDS Sciex) and vMALDI-MS n (Finnigan™ LTQ™, Thermo-Electron) identified peptides containing 8 of 14 serine residues within the NTD, one being partially phosphorylated Ser-167, known but not previously reported by MS. Chymotrypsin digestion revealed other known sites at Ser-102/104/106 and 118. Tandem methods developed for the peptide containing Ser-118 and the use of hypothesis-driven experiments-i.e., the assumption that an intact phosphopeptide showing no molecular ion might yield fragment ions including loss of phosphoric acid in vMALDI-MS/MS-allowed the identification of a novel site at Ser-154. Quantitation by selected reaction monitoring demonstrated 6-fold and 2.5-fold increases in Ser-154 phosphorylation in estradiol-and EGF-treated cells, respectively, compared to controls, confirmed by immunoblotting with a novel rabbit polyclonal antibody. Thus, the protein isolation and MS strategies described here can facilitate discovery of novel phosphorylation sites within low abundance, clinically important cancer targets like ER␣, and may thereby contribute to our understanding of the role of phosphorylation in the development of breast cancer. (J Am
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