Natural polyphenols convert proteins into histone-binding ligands

[en] Antioxidants are sensitive to oxidation and are immediately converted into their oxidized forms that can react with proteins. We have recently found that proteins incubated with oxidized vitamin C (dehydroascorbate) gain a new function as a histone-binding ligand. This finding led us to predict that antioxidants, through conversion to their oxidized forms, may generally have similar functions. In the present study, we identified several natural polyphenols as a source of histone ligands and characterized the mechanism for the interaction of protein-bound polyphenols with histone. Through screening of 25 plant-derived polyphenols by assessing their ability to convert bovine serum albumin into histone ligands, we identified seven polyphenols, including (-)-epigallocatechin-3-O-gallate (EGCG). Additionally, we found that the histone tail domain, which is a highly charged and conformationally flexible region, is involved in the interaction with the polyphenol-modified proteins. Further mechanistic studies showed the involvement of a complex heterogeneous group of the polyphenol-derived compounds bound to proteins as histone-binding elements. We also determined that the interaction of polyphenol-modified proteins with histones formed aggregates and exerted a protective effect against histone-mediated cytotoxicity toward endothelial cells. These findings demonstrated that histones are one of the major targets of polyphenol-modified proteins and provide important insights into the chemoprotective functions of dietary polyphenols.

Disciplines :

Biochemistry, biophysics & molecular biology

Author, co-author :

Yamaguchi, Kosuke

ITAKURA, Masanori ; University of Luxembourg > Luxembourg Centre for Systems Biomedicine (LCSB) > Neuroinflammation Group

Tsukamoto, Mona

Lim, Sei-Young

Uchida, Koji

External co-authors :

yes

Language :

English

Title :

Natural polyphenols convert proteins into histone-binding ligands

Publication date :

2022

Journal title :

Journal of Biological Chemistry

ISSN :

0021-9258

eISSN :

1083-351X

Publisher :

American Society for Biochemistry and Molecular Biology, Us md

Volume :

298

Issue :

Pages :

102529

Peer reviewed :

Peer Reviewed verified by ORBi

Additional URL :

https://app.readcube.com/library/a9ec3f18-47dd-4e50-bc89-1e8528daa3d7/item/7b1920e2-7095-46c3-a653-90e594d7ff18

Available on ORBilu :

since 29 November 2023

Statistics

Number of views

86 (1 by Unilu)

Number of downloads

40 (1 by Unilu)

More statistics

Scopus citations^®

Scopus citations^®
without self-citations

OpenCitations

OpenAlex citations

Bibliography

Hatasa, Y., Chikazawa, M., Furuhashi, M., Nakashima, F., Shibata, T., Kondo, T., et al. Oxidative deamination of serum albumins by (-)-epigallocatechin-3-o-gallate: a potential mechanism for the formation of innate antigens by antioxidants. PLoS One, 11, 2016, e0153002.
Yamaguchi, K., Itakura, M., Kitazawa, R., Lim, S.-Y., Nagata, K., Shibata, T., et al. Oxidative deamination of lysine residues by polyphenols generates an equilibrium of aldehyde and 2-piperidinol products. J. Biol. Chem., 297, 2021, 101035.
Furuhashi, M., Hatasa, Y., Kawamura, S., Shibata, T., Akagawa, M., Uchida, K., Identification of polyphenol-specific innate epitopes that originated from a resveratrol analogue. Biochemistry 56 (2017), 4701–4712.
Ishii, T., Mori, T., Tanaka, T., Mizuno, D., Yamaji, R., Kumazawa, S., et al. Covalent modification of proteins by green tea polyphenol (–)-epigallocatechin-3-gallate through autoxidation. Free Radic. Biol. Med. 45 (2008), 1384–1394.
Gerszon, J., Serafin, E., Buczkowski, A., Michlewska, S., Bielnicki, J.A., Rodacka, A., Functional consequences of piceatannol binding to glyceraldehyde-3-phosphate dehydrogenase. PLoS One, 13, 2018, e0190656.
Ku, M.C., Fang, C.M., Cheng, J.T., Liang, H.C., Wang, T.F., Wu, C.H., et al. Site-specific covalent modifications of human insulin by catechol estrogens: reactivity and induced structural and functional changes. Sci. Rep., 6, 2016, 28804.
Herren, T., Burke, T.A., Das, R., Plow, E.F., Identification of histone H2B as a regulated plasminogen receptor. Biochemistry 45 (2006), 9463–9474.
Das, R., Burke, T., Plow, E.F., Histone H2B as a functionally important plasminogen receptor on macrophages. Blood 110 (2007), 3763–3772.
Brinkmann, V., Reichard, U., Goosmann, C., Fauler, B., Uhlemann, Y., Weiss, D.S., et al. Neutrophil extracellular traps kill bacteria. Science 303 (2004), 1532–1535.
Xu, J., Zhang, X., Pelayo, R., Monestier, M., Ammollo, C.T., Semeraro, F., et al. Extracellular histones are major mediators of death in sepsis. Nat. Med. 15 (2009), 1318–1321.
Okubo, K., Kurosawa, M., Kamiya, M., Urano, Y., Suzuki, A., Yamamoto, K., et al. Macrophage extracellular trap formation promoted by platelet activation is a key mediator of rhabdomyolysis-induced acute kidney injury. Nat. Med. 24 (2018), 232–238.
Silvestre-Roig, C., Braster, Q., Wichapong, K., Lee, E.Y., Teulon, J.M., Berrebeh, N., et al. Externalized histone H4 orchestrates chronic inflammation by inducing lytic cell death. Nature 569 (2019), 236–240.
Itakura, M., Yamaguchi, K., Kitazawa, R., Lim, S.-Y., Anan, Y., Yoshitake, J., et al. Histone functions as a cell-surface receptor for AGEs. Nat. Commun., 13, 2022, 2974.
Wei, Y., Chen, P., Ling, T., Wang, Y., Dong, R., Zhang, C., et al. Certain (−)-epigallocatechin-3-gallate (EGCG) auto-oxidation products (EAOPs) retain the cytotoxic activities of EGCG. Food Chem. 204 (2016), 218–226.
Sang, S., Lambert, J.D., Ho, C.-T., Yang, C.S., The chemistry and biotransformation of tea constituents. Pharmacol. Res. 64 (2011), 87–99.
Pemberton, A.D., Brown, J.K., Inglis, N.F., Proteomic identification of interactions between histones and plasma proteins: implications for cytoprotection. Proteomics 10 (2010), 1484–1493.
Gonias, S.L., Pasqua, J.J., Greenberg, C., Pizzo, S.V., Precipitation of fibrinogen, fibrinogen degradation products and fibrin monomer by histone H3. Thromb. Res. 39 (1985), 97–116.
Daigo, K., Nakakido, M., Ohashi, R., Fukuda, R., Matsubara, K., Minami, T., et al. Protective effect of the long pentraxin PTX3 against histone-mediated endothelial cell cytotoxicity in sepsis. Sci. Signal., 7, 2014, ra88.
Kurinomaru, T., Shiraki, K., Aggregative protein–polyelectrolyte complex for high-concentration formulation of protein drugs. Int. J. Biol. Macromol. 100 (2017), 11–17.
Chikazawa, M., Otaki, N., Shibata, T., Miyashita, H., Kawai, Y., Maruyama, S., et al. Multispecificity of immunoglobulin M antibodies raised against advanced glycation end products: involvement of electronegative potential of antigrns. J. Biol. Chem. 288 (2013), 13204–13214.
Roginsky, V., Alegria, A.E., Oxidation of tea extracts and tea catechins by molecular oxygen. J. Agric. Food Chem. 53 (2005), 4529–4535.
Tompa, P., The interplay between structure and function in intrinsically unstructured proteins. FEBS Lett. 579 (2005), 3346–3354.
Jöbstl, E., O'Connell, J., Fairclough, J.P.A., Williamson, M.P., Molecular model for astringency produced by polyphenol/protein interactions. Biomacromolecules 5 (2004), 942–949.
Hong, S., Wang, Y., Park, S.Y., Lee, H., Progressive fuzzy cation-π assembly of biological catecholamines. Sci. Adv., 4, 2018, eaat7457.
Qamar, S., Wang, G., Randle, S.J., Ruggeri, F.S., Varela, J.A., Lin, J.Q., et al. FUS phase separation is modulated by a molecular chaperone and methylation of arginine cation-π interactions. Cell 173 (2018), 720–734.e15.
Ullmann, U., Haller, J., Decourt, J., Girault, N., Girault, J., Richard-Caudron, A., et al. A single ascending dose study of epigallocatechin gallate in healthy volunteers. J. Int. Med. Res. 31 (2003), 88–101.
Silk, E., Zhao, H., Weng, H., Ma, D., The role of extracellular histone in organ injury. Cell Death Dis., 8, 2017, e2812.
Rhee, S.G., Cho, C.S., Blot-based detection of dehydroalanine-containing glutathione peroxidase with the use of biotin-conjugated cysteamine. Met. Enzymol. 474 (2010), 23–34.
Tanaka, Y., Tawaramoto-Sasanuma, M., Kawaguchi, S., Ohta, T., Yoda, K., Kurumizaka, H., et al. Expression and purification of recombinant human histones. Methods 33 (2004), 3–11.
Machida, S., Takaku, M., Ikura, M., Sun, J., Suzuki, H., Kobayashi, W., et al. Nap1 stimulates homologous recombination by RAD51 and RAD54 in higher-ordered chromatin containing histone H1. Sci. Rep., 4, 2014, 4863.
Kujirai, T., Horikoshi, N., Sato, K., Maehara, K., Machida, S., Osakabe, A., et al. Structure and function of human histone H3.Y nucleosome. Nucl. Acids Res. 44 (2016), 6127–6141.
Basu, S.K., Goldstein, J.L., Anderson, R.G.W., Degradation of cationized low density lipoprotein and regulation of cholesterol metabolism in homozygous familial hypercholesterolemia fibroblasts. Proc. Natl. Acad. Sci. U. S. A. 73 (1976), 3178–3182.
LaVoie, M.J., Ostaszewski, B.L., Weihofen, A., Schlossmacher, M.G., Selkoe, D.J., Dopamine covalently modifies and functionally inactivates parkin. Nat. Med. 11 (2005), 1214–1221.