In Situ Click Reaction Coupled with Quantitative Proteomics for Identifying Protein Targets of Catechol Estrogens.

Catechol estrogens (CEs) are metabolic electrophiles that actively undergo covalent interaction with cellular proteins, influencing molecular function. There is no feasible method to identify their binders in a living system. Herein, we developed a click chemistry-based approach using ethinylestradiol (EE2) as the precursor probe coupled with quantitative proteomics to identify protein targets of CEs and classify their binding strengths. Using in situ metabolic conversion and click reaction in liver microsomes, CEs-protein complex was captured by the probe, digested by trypsin, stable isotope labeled via reductive amination, and analyzed by liquid chromatography-mass spectrometry (LC-MS). A total of 334 liver proteins were repeatedly identified ( n ≥ 2); 274 identified proteins were classified as strong binders based on precursor mass mapping. The binding strength was further scaled by D/H ratio (activity probe/solvent): 259 strong binders had D/H > 5.25; 46 weak binders had 5.25 > D/H > 1; 5 nonspecific binders (keratins) had D/H < 1. These results were confirmed using spiked covalent control (strong binder) and noncovalent control (weak binder), as well as in vitro testing of cytochrome c (D/H = 5.9), which showed covalent conjugation with CEs. Many identified strong binders, such as glutathione transferase, catechol-O-methyl transferase, superoxide dismutase, catalase, glutathione peroxidase, and cytochrome c, are involved in cellular redox processes or detoxification activities. CE conjugation was shown to suppress the superoxide oxidase activity of cytochrome c, suggesting that CEs modification may alter the redox action of cellular proteins. Due to structural similarity and inert alkyne group, EE2 probe is very likely to capture protein targets of CEs in general. Thus, this strategy can be adopted to explore the biological impact of CEs modification in living systems.

Site-specific covalent modifications of human insulin by catechol estrogens: Reactivity and induced structural and functional changes.

Proteins, covalently modified by catechol estrogens (CEs), were identified recently from the blood serum of diabetic patients and referred to as estrogenized proteins. Estrogenization of circulating insulin may occur and affect its molecular functioning. Here, the chemical reactivity of CEs towards specific amino acid residues of proteins and the structural and functional changes induced by the estrogenization of insulin were studied using cyclic voltammetry, liquid chromatography-mass spectrometry, circular dichroism spectroscopy, molecular modeling, and bioassays. Our results indicate that CEs, namely, 2- and 4-hydroxyl estrogens, were thermodynamically and kinetically more reactive than the catechol moiety. Upon co-incubation, intact insulin formed a substantial number of adducts with one or multiple CEs via covalent conjugation at its Cys 7 in the A or B chain, as well as at His10 or Lys29 in the B chain. Such conjugation was coupled with the cleavage of inter-chain disulfide linkages. Estrogenization on these sites may block the receptor-binding pockets of insulin. Insulin signaling and glucose uptake levels were lower in MCF-7 cells treated with modified insulin than in cells treated with native insulin. Taken together, our findings demonstrate that insulin molecules are susceptible to active estrogenization, and that such modification may alter the action of insulin.

Identification of Endogenous Site-specific Covalent Binding of Catechol Estrogens to Serum Proteins in Human Blood.

Protein adducts covalently modified by catechol estrogens (CEs), referred to as estrogenized proteins, are potential biomarkers for estrogen homeostasis or exposure to environmental toxicants. However, serum proteins endogenously modified by CEs and the modification sites remain elusive. In this study, liquid chromatography-mass spectrometry (LC-MS)-based shotgun proteomics is applied to identify site-specific protein estrogenization in human blood via a systematic approach and stringent validation. We showed CEs, namely 2- and 4-hydroxyl estrogens which are regarded as biomarkers for estrogen homeostasis, form covalent bonds with proteins, mainly via side chain Cys, Lys, or His residue. Estrogenization of purified human serum albumin (HSA) and immunoglobulin G (IgG) at specific sites was achieved by co-incubation and used as the standards to confirm the identified estrogenization in serum proteins. Based on a database search, estrogenized peptides derived from serum proteins in patient blood were identified; endogenous estrogenization of HSA and IgG-1 at multiple sites were confirmed as compared to the standards. Based on a test using Ellman's reagent, estrogenization produced stable products and irreversibly abolished the reactivity of Cys34-HSA, which is the most important antioxidant and nitric oxide carrier in blood. Given the importance of estrogen metabolism in environmental toxicology, further exploration of estrogenized proteins is warranted for biomarker discovery and/or new mechanisms in disease process.