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803 results on '"Gabius, HJ"'

1. Targeting the CRD F-face of Human Galectin-3 and Allosterically Modulating Glycan Binding by Angiostatic PTX008 and a Structurally Optimized Derivative

Author

Miller MC, Zheng Y, Suylen D, Ippel H, Berbis MA, Cañada FJ, Jimenez-Barbero J, Tai G, Gabius HJ, and Mayo KH

Subjects
galectin-3, calixarene, NMR
Abstract

Calix[4]arenePTX008isanangiostaticagentthatinhibitstumorgrowthinmicebybindingtogalectin-1,ab-galactoside-bindinglectin.ToassesstheaffinityprofileofPTX008forgalectins,weused15N–1HHSQCNMRspectroscopytoshowthatPTX008alsobindstogalectin-3(Gal-3),albeitmoreweakly.WeidentifiedthecontactsiteforPTX008ontheF-faceoftheGal-3carbohydraterecognitiondomain.STDNMRrevealedthatthehydrophobicphenylringcrownofthecalixareneisthebindingepitope.

Published
2020

2. Galektin-1, -3 und -8 induzieren arthrose-relevante Mechanismen in Knorpelzellen via NF-kB

Author

Toegel, S, Kinslechner, K, Kenn, M, Weinmann, D, Walzer, SM, Schreiner, W, Gabius, HJ, and Windhager, R

Subjects
qPCR, ddc: 610, MMP, Galektin, Immunhistochemie, NF-kB, 610 Medical sciences, Medicine, In Cell Western, Osteoarthrose
Abstract

Fragestellung: Die Pathophysiologie der Osteoarthrose (OA) ist durch Entzündungsprozesse sowie den Abbau extrazellulärer Matrix gekennzeichnet. Wir beschäftigen uns mit der Frage, ob glykobiologische Mechanismen (wie die Interaktion von zellulären Glykanen mit glykan-bindenden Proteinen)[zum vollständigen Text gelangen Sie über die oben angegebene URL], Deutscher Kongress für Orthopädie und Unfallchirurgie (DKOU 2019)

Published
2019
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3. Program and abstracts for the 2011 Meeting of the Society for Glycobiology

Author

Hollingsworth, MT, Hart, GW, Paulson, JC, Stansell, E, Canis, K, Huang, IC, Panico, M, Morris, H, Haslam, S, Farzan, M, Dell, A, Desrosiers, R, von Itzstein, M, Matroscovich, M, Luther, KB, Hülsmeier, AJ, Schegg, B, Hennet, T, Nycholat, C, McBride, R, Ekiert, D, Xu, R, Peng, W, Razi, N, Gilbert, M, Wakarchuk, W, Wilson, IA, Gahlay, G, Geisler, C, Aumiller, JJ, Moremen, K, Steel, J, Labaer, J, Jarvis, DL, Drickamer, K, Taylor, M, Nizet, V, Rabinovich, G, Lewis, C, Cobb, B, Kawasaki, N, Rademacher, C, Chen, W, Vela, J, Maricic, I, Crocker, P, Kumar, V, Kronenberg, M, Paulson, J, Glenn, K, Mallinger, A, Wen, H, Srivastava, L, Tundup, S, Harn, D, Menon, AK, Yamaguchi, Y, Mkhikian, H, Grigorian, A, Li, C, Chen, HL, Newton, B, Zhou, RW, Beeton, C, Torossian, S, Tatarian, GG, Lee, SU, Lau, K, Walker, E, Siminovitch, KA, Chandy, KG, Yu, Z, Dennis, JW, Demetriou, M, Pandey, MS, Baggenstoss, BA, Washburn, JL, Weigel, PH, Chen, CI, Keusch, JJ, Klein, D, Hofsteenge, J, Gut, H, Szymanski, C, Feldman, M, Schaffer, C, Gao, Y, Strum, S, Liu, B, Schutzbach, JS, Druzhinina, TN, Utkina, NS, Torgov, VI, Szarek, WA, Wang, L, Brockhausen, I, Hitchen, P, Peyfoon, E, Meyer, B, Albers, SV, Chen, C, Newburg, DS, Jin, C, Dinglasan, RD, Beverley, SM, Guo, H, Novozhilova, N, Hickerson, S, Elnaiem, DE, Sacks, D, Turco, SJ, McKay, D, Castro, E, Takahashi, H, Straus, AH, Stalnaker, SH, Live, D, Boons, GJ, Wells, L, Stuart, R, Aoki, K, Boccuto, L, Zhang, Q, Wang, H, Bartel, F, Fan, X, Saul, R, Chaubey, A, Yang, X, Steet, R, Schwartz, C, Tiemeyer, M, Pierce, M, Kraushaar, DC, Condac, E, Nakato, H, Nishihara, S, Sasaki, N, Hirano, K, Nasirikenari, M, Collins, CC, Lau, JT, Devarapu, SK, Jeyaweerasinkam, S, Albiez, RS, Kiessling, L, Gu, J, Clark, GF, Gagneux, P, Ulm, C, Mahavadi, P, Müller, S, Rinné, S, Geyer, H, Gerardy-Schahn, R, Mühlenhoff, M, Günther, A, Geyer, R, Galuska, SP, Shibata, T, Sugihara, K, Nakayama, J, Fukuda, M, Fukuda, MN, Ishikawa, A, Terao, M, Kimura, A, Kato, A, Katayama, I, Taniguchi, N, Miyoshi, E, Aderem, A, Yoneyama, T, Angata, K, Bao, X, Chanda, S, Lowe, J, Sonon, R, Ishihara, M, Talabnin, K, Wang, Z, Black, I, Naran, R, Heiss, C, Azadi, P, Hurum, D, Rohrer, J, Balland, A, Valliere-Douglass, J, Kodama, P, Mujacic, M, Eakin, C, Brady, L, Wang, WC, Wallace, A, Treuheit, M, Reddy, P, Schuman, B, Fisher, S, Borisova, S, Coates, L, Langan, P, Evans, S, Yang, SJ, Zhang, H, Hizal, DB, Tian, Y, Sarkaria, V, Betenbaugh, M, Lütteke, T, Agravat, S, Cholleti, S, Morris, T, Saltz, J, Song, X, Cummings, R, Smith, D, Hofhine, T, Nishida, C, Mialy, R, Sophie, D, Sebastien, F, Patricia, C, Eric, S, Stephane, H, Mokros, D, Joosten, RP, Dominik, A, Vriend, G, Nguyen, LD, Martinez, J, Hinderlich, S, Reissig, HU, Reutter, W, Fan, H, Saenger, W, Moniot, S, Asada, H, Nakahara, T, Miura, Y, Stevenson, T, Yamazaki, T, De Castro, C, Burr, T, Lanzetta, R, Molinaro, A, Parrilli, M, Sule, S, Gerken, TA, Revpredo, L, Thome, J, Cardenas, G, Almeida, I, Leung, MY, Yan, S, Paschinger, K, Bleuler-Martinez, S, Jantsch, V, Wilson, I, Yoshimura, Y, Adlercreutz, D, Mannerstedt, K, Wakarchuk, WW, Dovichi, NJ, Hindsgaul, O, Palcic, MM, Chandrasekaran, A, Bharadwaj, R, Deng, K, Adams, P, Singh, A, Datta, A, Konasani, V, Imamura, A, Lowry, T, Scaman, C, Zhao, Y, Zhou, YD, Yang, K, Zhang, XL, Leymarie, N, Hartshorn, K, White, M, Cafarella, T, Seaton, B, Rynkiewicz, M, Zaia, J, Acosta-Blanco, I, Ortega-Francisco, S, Dionisio-Vicuña, M, Hernandez-Flores, M, Fuentes-Romero, L, Newburg, D, Soto-Ramirez, LE, Ruiz-Palacios, G, Viveros-Rogel, M, Tong, C, Li, W, Kong, L, Qu, M, Jin, Q, Lukyanov, P, Zhang, W, Chicalovets, I, Molchanova, V, Wu, AM, Liu, JH, Yang, WH, Nussbaum, C, Grewal, PK, Sperandio, M, Marth, JD, Yu, R, Usuki, S, Wu, HC, O'Brien, D, Piskarev, V, Ramadugu, SK, Kashyap, HK, Ghirlanda, G, Margulis, C, Brewer, C, Gomery, K, Müller-Loennies, S, Brooks, CL, Brade, L, Kosma, P, Di Padova, F, Brade, H, Evans, SV, Asakawa, K, Kawakami, K, Kushi, Y, Suzuki, Y, Nozaki, H, Itonori, S, Malik, S, Lebeer, S, Petrova, M, Balzarini, J, Vanderleyden, J, Naito-Matsui, Y, Takematsu, H, Murata, K, Kozutsumi, Y, Subedi, GP, Satoh, T, Hanashima, S, Ikeda, A, Nakada, H, Sato, R, Mizuno, M, Yuasa, N, Fujita-Yamaguchi, Y, Vlahakis, J, Nair, DG, Wang, Y, Allingham, J, Anastassiades, T, Strachan, H, Johnson, D, Orlando, R, Harenberg, J, Haji-Ghassemi, O, Mackenzie, R, Lacerda, T, Toledo, M, Straus, A, Takahashi, HK, Woodrum, B, Ruben, M, O'Keefe, B, Samli, KN, Yang, L, Woods, RJ, Jones, MB, Maxwell, J, Song, EH, Manganiello, M, Chow, YH, Convertine, AJ, Schnapp, LM, Stayton, PS, Ratner, DM, Yegorova, S, Rodriguez, MC, Minond, D, Jiménez-Barbero, J, Calle, L, Ardá, A, Gabius, HJ, André, S, Martinez-Mayorga, K, Yongye, AB, Cudic, M, Ali, MF, Chachadi, VB, Cheng, PW, Kiwamoto, T, Na, HJ, Brummet, M, Finn, MG, Hong, V, Polonskaya, Z, Bovin, NV, Hudson, S, Bochner, B, Gallogly, S, Krüger, A, Hanley, S, Gerlach, J, Hogan, M, Ward, C, Joshi, L, Griffin, M, Demarco, C, Deveny, R, Aggeler, R, Hart, C, Nyberg, T, Agnew, B, Akçay, G, Ramphal, J, Calabretta, P, Nguyen, AD, Kumar, K, Eggers, D, Terrill, R, d'Alarcao, M, Ito, Y, Vela, JL, Matsumura, F, Hoshino, H, Lee, H, Kobayashi, M, Borén, T, Jin, R, Seeberger, PH, Pitteloud, JP, Cudic, P, Von Muhlinen, N, Thurston, T, von Muhlinen, N, Wandel, M, Akutsu, M, Foeglein, AÁ, Komander, D, Randow, F, Maupin, K, Liden, D, Haab, B, Dam, TK, Brown, RK, Wiltzius, M, Jokinen, M, Andre, S, Kaltner, H, Bullen, J, Balsbaugh, J, Neumann, D, Hardie, G, Shabanowitz, J, Hunt, D, Hart, G, Mi, R, Ding, X, Van Die, I, Chapman, AB, Cummings, RD, Ju, T, Aryal, R, Ashley, J, Feng, X, Hanover, JA, Wang, P, Keembiyehetty, C, Ghosh, S, Bond, M, Krause, M, Love, D, Radhakrishnan, P, Grandgenet, PM, Mohr, AM, Bunt, SK, Yu, F, Hollingsworth, MA, Ethen, C, Machacek, M, Prather, B, Wu, Z, Kotu, V, Zhao, P, Zhang, D, van der Wel, H, Johnson, JM, West, CM, Abdulkhalek, S, Amith, SR, Jayanth, P, Guo, M, Szewczuk, M, Ohtsubo, K, Chen, M, Olefsky, J, Marth, J, Zapater, J, Foley, D, Colley, K, Kawashima, N, Fujitani, N, Tsuji, D, Itoh, K, Shinohara, Y, Nakayama, K, Zhang, L, Ten Hagen, K, Koren, S, Yehezkel, G, Cohen, L, Kliger, A, Khalaila, I, Finkelstein, E, Parker, R, Kohler, J, Sacoman, J, Badish, L, Hollingsworth, R, Tian, E, Hoffman, M, Hou, X, Tashima, Y, Stanley, P, Kizuka, Y, Kitazume, S, Yoshida, M, Kunze, A, Nasir, W, Bally, M, Hook, F, Larson, G, Mahan, A, Alter, G, Zeidan, Q, Copeland, R, Pokrovskaya, I, Willett, R, Smith, R, Morelle, W, Kudlyk, T, Lupashin, V, Vasudevan, D, Takeuchi, H, Majerus, E, Haltiwanger, RS, Boufala, S, Lee, YA, Min, D, Kim, SH, Shin, MH, Gesteira, T, Pol-Fachin, L, Coulson-Thomas, VJ, Verli, H, Nader, H, Liu, X, Yang, P, Thoden, J, Holden, H, Tytgat, H, Sánchez-Rodríguez, A, Schoofs, G, Verhoeven, T, De Keersmaecker, S, Marchal, K, Ventura, V, Sarah, N, Joann, P, Ding, Y, Jarrell, K, Cook, MC, Gibeault, S, Filippenko, V, Ye, Q, Wang, J, Kunkel, JP, Arteaga-Cabello, FJ, Arciniega-Fuentes, MT, McCoy, J, Ruiz-Palacios, GM, Francoleon, D, Loo, RO, Loo, J, Ytterberg, AJ, Kim, U, Gunsalus, R, Costello, C, Soares, R, Assis, R, Ibraim, I, Noronha, F, De Godoy, AP, Bale, MS, Xu, Y, Brown, K, Blader, I, West, C, Chen, S, Ye, X, Xue, C, Li, G, Yu, G, Yin, L, Chai, W, Gutierrez-Magdaleno, G, Tan, C, Wu, D, Li, Q, Hu, H, Ye, M, Liu, D, Mink, W, Kaese, P, Fujiwara, M, Uchimura, K, Sakai, Y, Nakada, T, Mabashi-Asazuma, H, Toth, AM, Scott, DW, Chacko, BK, Patel, RP, Batista, F, Mercer, N, Ramakrishnan, B, Pasek, M, Boeggeman, E, Verdi, L, Qasba, PK, Tran, D, Lim, JM, Liu, M, Mo, KF, Kirby, P, Yu, X, Lin, C, Costello, CE, Akama, TO, Nakamura, T, Huang, Y, Shi, X, Han, L, Yu, SH, Zhang, Z, Knappe, S, Till, S, Nadia, I, Catarello, J, Quinn, C, Julia, N, Ray, J, Tran, T, Scheiflinger, F, Szabo, C, Dockal, M, Niimi, S, Hosono, T, Michikawa, M, Kannagi, R, Takashima, S, Amano, J, Nakamura, N, Kaneda, E, Nakayama, Y, Kurosaka, A, Takada, W, Matsushita, T, Hinou, H, Nishimura, S, Igarashi, K, Abe, H, Mothere, M, Leonhard-Melief, C, Johnson, H, Nagy, T, Nairn, A, Rosa, MD, Porterfield, M, Kulik, M, Dalton, S, Pierce, JM, Hansen, SF, McAndrew, R, Degiovanni, A, McInerney, P, Pereira, JH, Hadi, M, Scheller, HV, Barb, A, Prestegard, J, Zhang, S, Jiang, J, Tharmalingam, T, Pluta, K, McGettigan, P, Gough, R, Struwe, W, Fitzpatrick, E, Gallagher, ME, Rudd, PM, Karlsson, NG, Carrington, SD, Katoh, T, Panin, V, Gelfenbeyn, K, Freire-de-Lima, L, Handa, K, Hakomori, SI, Bielik, AM, McLeod, E, Landry, D, Mendoza, V, Guthrie, EP, Mao, Y, Wang, X, Moremen, KW, Meng, L, Ramiah, AP, Gao, Z, Johnson, R, Xiang, Y, Rosa, MDEL, Wu, SC, Gilbert, HJ, Karaveg, K, Chen, L, Wang, BC, Mast, S, Sun, B, Fulton, S, Kimzey, M, Pourkaveh, S, Minalla, A, Haxo, T, Wegstein, J, Murray, AK, Nichols, RL, Giannini, S, Grozovsky, R, Begonja, AJ, Hoffmeister, KM, Suzuki-Anekoji, M, Suzuki, A, Yu, SY, Khoo, KH, van Alphen, L, Fodor, C, Wenzel, C, Ashmus, R, Miller, W, Stahl, M, Stintzi, A, Lowary, T, Wiederschain, G, Saba, J, Zumwalt, A, Meitei, NS, Apte, A, Viner, R, Gandy, M, Debowski, A, Stubbs, K, Witzenman, H, Pandey, D, Repnikova, E, Nakamura, M, Islam, R, Kc, N, Caster, C, Chaubard, JL, Krishnamurthy, C, Hsieh-Wilson, L, Pranskevich, J, Rangarajan, J, Guttman, A, Szabo, Z, Karger, B, Chapman, J, Chavaroche, A, Bionda, N, Fields, G, Jacob, F, Tse, BW, Guertler, R, Nixdorf, S, Hacker, NF, Heinzelmann-Schwarz, V, Yang, F, Kohler, JJ, Losfeld, ME, Ng, B, Freeze, HH, He, P, Wondimu, A, Liu, Y, Zhang, Y, Su, Y, Ladisch, S, Grewal, P, Mann, C, Ditto, D, Lardone, R, Le, D, Varki, N, Kulinich, A, Kostjuk, O, Maslak, G, Pismenetskaya, I, Shevtsova, A, Takeishi, S, Okudo, K, Moriwaki, K, Terao, N, Kamada, Y, Kuroda, S, Li, Y, Peiris, D, Markiv, A, Dwek, M, Adamczyk, B, Thanabalasingham, G, Huffman, J, Kattla, J, Novokmet, M, Rudan, I, Gloyn, A, Hayward, C, Reynolds, R, Hansen, T, Klimes, I, Njolstad, P, Wilson, J, Hastie, N, Campbell, H, McCarthy, M, Rudd, P, Owen, K, Lauc, G, Wright, A, Goletz, S, Stahn, R, Danielczyk, A, Baumeister, H, Hillemann, A, Löffler, A, Stöckl, L, Jahn, D, Bahrke, S, Flechner, A, Schlangstedt, M, Karsten, U, Goletz, C, Mikolajczyk, S, Ulsemer, P, Gao, N, Cline, A, Flanagan-Steet, H, Sadler, KC, Lehrman, MA, Coulson-Thomas, YM, Gesteira, TF, Mader, AM, Waisberg, J, Pinhal, MA, Friedl, A, Toma, L, Nader, HB, Mbua, EN, Johnson, S, Wolfert, M, Dimitrievska, S, Huizing, M, Niklason, L, Perdivara, I, Petrovich, R, Tokar, EJ, Waalkes, M, Fraser, P, Tomer, K, Chu, J, Rosa, S, Mir, A, Lehrman, M, Sadler, K, Lauer, M, Hascall, V, Calabro, A, Cheng, G, Swaidani, S, Abaddi, A, Aronica, M, Yuzwa, S, Shan, X, Macauley, M, Clark, T, Skorobogatko, Y, Vosseller, K, Vocadlo, D, Banerjee, A, Baksi, K, Banerjee, D, Melcher, R, Kraus, I, Moeller, D, Demmig, S, Rogoll, D, Kudlich, T, Scheppach, W, Scheurlen, M, Hasilik, A, Steirer, L, Lee, J, Moe, G, Troy, FA, Wang, F, Xia, B, Wang, B, Yi, S, Yu, H, Suzuki, M, Kobayashi, T, Sato, Y, Zhou, H, Briscoe, A, Lee, R, Wolfert, MA, Matsumoto, Y, Hamamura, K, Yoshida, T, Akita, K, Okajima, T, Furukawa, K, Urano, T, Ruhaak, LR, Miyamoto, S, and Lebrilla, CB

Subjects
Embryogenesis, Cancer screening, Cancer research, medicine, Cell migration, Neural cell adhesion molecule, Biology, medicine.disease, Biochemistry, Metastasis
Abstract

Cell surface mucins configure the cell surface by presenting extended protein backbones that are heavily O-glycosylated. The glycopeptide structures establish physicochemical properties at the cell surface that enable and block the formation of biologically important molecular complexes. Some mucins, such as MUC1, associate with receptor tyrosine kinases and other cell surface receptors, and engage in signal transduction in order to communicate information regarding conditions at the cell surface to the nucleus. In that context, the MUC1 cytoplasmic tail (MUC1CT) receives phosphorylation signals from receptor tyrosine kinases and serine/threonine kinases, which enables its association with different signaling complexes that conduct these signals to the nucleus and perhaps other subcellular organelles. We have detected the MUC1CT at promoters of over 500 genes, in association with several different transcription factors, and have shown that promoter occupancy can vary under different growth factor conditions. However, the full biochemical nature of the nuclear forms of MUC1 and its function at these promoter regions remain undefined. I will present evidence that nuclear forms of the MUC1CT include extracellular and cytoplasmic tail domains. In addition, I will discuss evidence for a hypothesis that the MUC1CT possesses a novel catalytic function that enables remodeling of the transcription factor occupancy of promoters, and thereby engages in regulation of gene expression.

Published
2016

4. Die Rolle der Mikrovaskularisation und der Wachstum/Adhesionregulationslektine in der Prognose des nicht-kleinzelligen Bronchialkarzinoms im Stadium II

Author

Szöke, T, Kayser, K, Trojan, I, Kayser, G, Furak, J, Tiszlavicz, L, Baumhäkel, JD, and Gabius, HJ

Subjects
ddc: 610, 610 Medical sciences, Medicine
Abstract

Problemstellung: Zweck unserer Studie war die bessere Prognosebestimmung des operierten nicht-kleinzelligen Bronchialkarzinoms (NSCLC) im Stadium II durch quantitative Lektinimmunohistochemie und die Messung der Mikrovaskularisation. Methoden: Das histologische Material von 94 radikal operierten [for full text, please go to the a.m. URL], 16. Jahrestagung der Deutschen Gesellschaft für Thoraxchirurgie

Published
2010
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7. Carbohydrate-protein interaction studies by laser photo CIDNP NMR methods

Author

Siebert, HC, Kaptein, R, Beintema, JJ, Soedjanaatmadja, UM, Wright, CS, Rice, A, Kleineidam, RG, Kruse, S, Schauer, R, Pouwels, PJW, Kamerling, JP, Gabius, HJ, Vliegenthart, JFG, and Groningen Biomolecular Sciences and Biotechnology

Subjects
ISOLECTINS, carbohydrate-protein interaction, RESOLUTION, WHEAT, CRYSTAL-STRUCTURE, NMR, chemically induced dynamic nuclear polarization (CIDNP)
Abstract

The side chains of tyrosine, tryptophan and histidine are able to produce CIDNP (Chemically Induced Dynamic Nuclear Polarization) signals after laser irradiation in the presence of a suitable radical pair-generating dye. Elicitation of such a response in proteins implies surface accessibility of the respective groups to the light-absorbing dye, In principle, this technique allows the monitoring of the effect of ligand binding to a receptor and of site-directed mutagenesis on conformational aspects of any protein if CIDNP-reactive amino acids are involved. The application of this method in glycosciences can provide insights into the protein-carbohydrate interaction process, as illustrated in this initial model study for several N-acetyl-glucosamine-binding lectins of increasing structural complexity as well as for a wild type bacterial sialidase and its mutants. Experimentally, the shape and intensity of CIDNP signals are determined in the absence and in the presence of specific glycoligands. When the carbohydrate is bound, CIDNP signals of side chain protons of tyrosine, tryptophan or histidine residues can be broadened and of reduced intensity. This is the case for hevein, pseudo-hevein, the four hevein domains-containing lectin wheat germ agglutinin (WGA) and the cloned B-domain of WGA 1 (domB) representing one hevein domain. This response indicates either a spatial protection by the ligand or a ligand-induced positioning of formerly surface-exposed side chains into the protein's interior part, thereby precluding interaction with the photo-activated dye. Some signals of protons from the reactive side chains can even disappear when the lectin-ligand complexes are monitored. The ligand binding, however, can apparently also induce a conformational change in a related lectin that causes the appearance of a new signal, as seen for Urtica dioica agglutinin (UDA) which consists of two hevein domains. Additionally, the three CIDNP-reactive amino acids are used as sensors for the detection of conformational changes caused by pH variations or by deliberate amino acid exchanges, as determined for the isolectins hevein and pseudo-hevein as well as for the cloned small sialidase of Clostridium perfringens and two of its mutants. Therefore, CIDNP has proven to be an excellent tool for protein-carbohydrate binding studies and can be established in glycosciences as a third biophysical method beside X-ray-crystallography and high-resolution multidimensional NMR studies which provides reliable information of certain structural aspects of carbohydrate-binding proteins in solution.

Published
1997

8. Role of aromatic amino acids in carbohydrate binding of plant lectins: Laser photo chemically induced dynamic nuclear polarization study of hevein domain-containing lectins

Author

Siebert, HC, vonderLieth, CW, Kaptein, R, Beintema, JJ, Dijkstra, K, vanNuland, N, Soedjanaatmadja, UMS, Rice, A, Vliegenthart, JFG, Wright, CS, Gabius, HJ, and Groningen Biomolecular Sciences and Biotechnology

Subjects
REFINEMENT, nuclear magnetic resonance (NMR), molecular modeling, PROTEIN, ISOLECTIN, WHEAT-GERM-AGGLUTININ, lectins, agglutinins, chemically induced dynamic nuclear polarization (CIDNP), OLIGOSACCHARIDES, URTICA-DIOICA AGGLUTININ, RESOLUTION, CIDNP, CRYSTAL-STRUCTURE, SIALOGLYCOPEPTIDE
Abstract

Carbohydrate recognition by lectins often involves the side chains of tyrosine, tryptophan, and histidine residues. These moieties are able to produce chemically induced dynamic nuclear polarization (CIDNP) signals after laser irradiation in the presence of a suitable radical pair-generating dye. Elicitation of such a response in proteins implies accessibility of the respective groups to the light-absorbing dye. In principle, this technique is suitable to monitor surface properties of a receptor and the effect of ligand binding if CIDNP-reactive amino acids are affected. The application of this method in glycosciences can provide insights into the protein carbohydrate interaction process, as illustrated in this initial study. It focuses on a series of N-acetylglucosamine-binding plant lectins of increasing structural complexity (hevein, pseudohevein, Urtica dioica agglutinin and wheat germ agglutinin and its domain B), for which structural NMR- or X-ray crystallographic data permit a decision of the validity of the CIDNP method derived conclusions. On the other hand, the CIDNP data presented in this study can be used for a rating of our molecular models of hevein, pseudohevein, and domain B obtained by various modeling techniques. Experimentally, the shape and intensity of CIDNP signals are determined in the absence and in the presence of specific glycoligands. When the carbohydrate ligand is bound, CIDNP signals of side chain protons of tyrosine, tryptophan, or histidine residues are altered, for example, they are broadened and of reduced intensity or disappear completely. In the case of UDA, the appearance of a new tryptophan signal upon ligand binding was interpreted as an indication for a conformational change of the corresponding indole ring. Therefore, CIDNP represents a suitable tool to study protein-carbohydrate interactions in solution, complementing methods such as X-ray crystallography, high-resolution multidimensional nuclear magnetic resonance, transferred nuclear Overhauser effect experiments, and molecular modeling. (C) 1997 Wiley-Liss, Inc.

Published
1997

10. Knowledge-based homology modeling and experimental determination of amino acid side chain accessibility by the laser photo CIDNP (chemically induced dynamic nuclear polarization) approach in solution: Lessons from the small sialidase of Clostridium perfringens

Author

Siebert, HC, Tajkhorshid, E, vonderLieth, CW, Kleineidam, RG, Kruse, S, Schauer, R, Kaptein, R, Gabius, HJ, and Vliegenthart, JFG

Subjects
protein modelling, DOMAINS, PROTEINS, sialidase, BACTERIAL SIALIDASE, CRYSTAL-STRUCTURE, NEURAMINIDASE, NMR, molecular dynamics
Abstract

The success of knowledge-based homology modelling is critically dependent on the predictive potency of the program structure-based calculations, which attempt to translate homologous sequences into three-dimensional structures, and on the actual relevance of the crystal structure for the protein topology. As quality control, experimental data for selected parameters of the protein's conformation are required. Using the crystal structure of the sialidase of Salmonella typhimurium as framework for model building of the homologous enzyme from Clostridium perfringens, a set of energy-minimised conformers is derived. These proteins present e.g. Tyr, Trp and His residues with an assessable area on the surface, since the side chains of these amino acid residues are responsive to chemically induced dynamic nuclear polarization (CIDNP), monitored by NMR. Hence, as first lesson, a comparative analysis for model-derived and experimentally determined values can be performed. The second lesson of this study concerns the notable impact of single amino acid substitutions (Tyr/Phe, Cys/Ser) on the surface accessibility of the CIDNP-reactive amino acid side chains in mutant forms of the sialidase. Corroborating the predictions from the theoretical calculations, the spectra of the engineered mutants reveal marked and non-uniform alterations. Thus, the effect of apparently rather conservative amino acid substitutions on a distinct conformational aspect of this protein, even at distant sites, should not be underestimated.

Published
1996

12. Glycohistochemical characterization of vascular muscle cell destruction in CADASIL subjects by lectins, neoglycoconjugates and galectin-specific antibodies

Author

UCL, Brulin-Fardoux, P, Godfrain, C, Maurage, CA, De Reuck, J, Hauw, JJ., Kaltner, H, Bovin, NV, Gabius, HJ, Ruchoux, MM, Kiss, R, Camby, Isabelle, UCL, Brulin-Fardoux, P, Godfrain, C, Maurage, CA, De Reuck, J, Hauw, JJ., Kaltner, H, Bovin, NV, Gabius, HJ, Ruchoux, MM, Kiss, R, and Camby, Isabelle

Abstract

CADASIL (Cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy) is a type of small-artery stroke and vascular dementia-inducing pathology of the brain. In order to explain the molecular mechanisms behind the alterations to the blood vessels in CADASIL subjects, we scrutinized the expression of glycan and glycan-binding sites in the wall of vessels taken from five such subjects (vs. five control subjects matched for age and sex). Specimens were taken from the brain, heart, kidney, liver and lung. Although the main vessel lesions were observed in the tissues depending on the blood-brain barrier, alterations to systemic vessels were also observed despite the absence of any symptoms. The histochemical expression of a panel of 10 biotinylated neoglycoconjugates [Gal-beta(1-4)-d-Glc, Galbeta(1-3)GalNAc, alpha-d-GalNAc, beta-d-GalNAc, GalNAcalpha(1-3)-d-GalNAcalpha, GalNAcalpha(1-3)-d-GalNAcbeta, beta-d-Glc, alpha-d-Man, l-Fucose and d-Glcalpha(1-4)-d-Glc], eight plant lectins (PNA, MAA, SNA, DBA, WGA, ConA, GNA and UEA-1) and two antigalectin antibodies was monitored by means of semiquantitative and quantitative computer-assisted microscopy. The data show the altered histochemical binding of plant lectins, such as UEA-1 and ConA, in the vessel walls of CADASIL subjects. The present work, based upon staining by a panel of neoglycoconjugates, provides a biochemical characterization of the alteration of vessel walls in the brain compared to other organs including the heart, kidney, lung and liver in CADASIL as opposed to control subjects. These glycohistochemical results suggest a functional relevance of protein-carbohydrate interactions in this disease.

Published
2003

13. Autoantibodies against galectin-8: their specificity, association with lymphopenia in systemic lupus erythematosus and detection in rheumatoid arthritis and acute inflammation

Author

Massardo, L, primary, Metz, C, additional, Pardo, E, additional, Mezzano, V, additional, Babul, M, additional, Jarpa, E, additional, Guzmán, AM, additional, André, S, additional, Kaltner, H, additional, Gabius, HJ, additional, Jacobelli, S, additional, González, A, additional, and Soza, A, additional

Published
2009
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25. Evolutionary aspects of accuracy of phenylalanyl-tRNA synthetase. A comparative study with enzymes from Escherichia coli, Saccharomyces cerevisiae, Neurospora crassa, and turkey liver using phenylalanine analogs

Author

Gabius Hj, Friedrich Cramer, and von der Haar F

Subjects
Turkeys, Phenylalanine, Saccharomyces cerevisiae, Aminoacylation, Biochemistry, Neurospora crassa, Amino Acyl-tRNA Synthetases, Structure-Activity Relationship, Species Specificity, Escherichia coli, Animals, chemistry.chemical_classification, biology, biology.organism_classification, Biological Evolution, Amino acid, Neurospora, enzymes and coenzymes (carbohydrates), Enzyme, Liver, chemistry, Transfer RNA, Proofreading, Phenylalanine-tRNA Ligase, Leucine
Abstract

The phenylalanyl-tRNA synthetases from Escherichia coli, Saccharomyces cerevisiae, Neurospora crassa, and turkey liver activate a number of phenylalanine analogues (tyrosine, leucine, methionine, p-fluorophenylalanine, beta-phenylserine, beta-thien-2-ylalanine, 2-amino-4-methylhex-4-enoic acid, mimosine, N-benzyl-L- or N-benzyl-D-phenylalanine, and ochratoxin A), as demonstrated by Km and kcat of the ATP/PPi pyrophosphate exchange. Upon complexation with tRNA, the enzyme-tRNAPhe complexes show a significantly increased initial discrimination of these amino acid analogues expressed in higher Km and lower kcat values, as determined by amino-acylation of tRNAPhe-C-C-A(3'NH2). The overall accuracy is further enhanced by a second discrimination, a proofreading step. The strategies employed by the enzymes with respect to accuracy differ. Better initial discrimination in the aminoacylation and less elaborated proofreading for the E. coli enzyme can be compared to a more efficient proofreading by other synthetases. In this way the comparatively poor initial amino acid recognition in the case of the S. cerevisiae and N. crassa enzymes is balanced. The extent of initial discrimination is therefore inversely coupled to the hydrolytic capacity of the proofreading. A striking difference can be noted for the proofreading mechanisms. Whereas the enzymes from E. coli, S. cerevisiae, and N. crassa follow the pathway of posttransfer proofreading, namely, enzymatic hydrolysis of the misaminoacylated tRNA, the turkey liver enzyme uses tRNA-dependent pretransfer proofreading in the case of natural amino acids. In spite of the same subunit structure and similar molecular weight, the phenylalanyl-tRNA synthetases from a prokaryotic and lower and higher eukaryotic organisms show obvious mechanistic differences in their strategy to achieve the necessary fidelity.

Published
1983

26. Viscum albumagglutinin-induced aggregation of blood cells and the lectin effects on neutrophil function

Author

Timoshenko, AV, Cherenkevich, SN, and Gabius, HJ

Abstract

Extracts from mistletoe enjoy a large popularity in central Europe as an unconventional treatment modality for cancer, warranting scientific efforts with defined components to delineate any potential benefit. The galactose-specific lectin from Viscum album(VAA), known to exhibit immunomodulatory and ensuing antitumoral capacities in animal model systems, was shown to aggregate human blood cells in the following order: neutrophils, mononuclear cells — thrombocytes and erythrocytes. To contribute to the analysis of lectin effects on individual aspects of the host defence system, two parameters of neutrophils were quantitatively assessed, namely the aggregating activity of VAA as a measure of strength of interaction with cell surface ligands and the effect of lectin on oxidative metabolism (H2O2release) of these cells. It was found that whole lectin and its carbohydrate-binding B-subunit possessed the capacity to induce cell aggregation and H2O2release, which were blocked by D-galactose and lactose. Both effects displayed similar dependence on the lectin concentration in the range 0.1–25 μg/ml. The toxic A-subunit displayed detectable activity only in high doses (50 (μg/ml) while the bovine heart galaptin (14kDa; galeclin-1) failed to affect neutrophils. The role of oxidative metabolism in regulation of neutrophil aggregation induced by VAA was studied using metabolic inhibitors and controlled heating at 46°C leading to inhibition of plasma membrane NADPH-oxidase system. Trifluoperazine and menadione inhibited the neutrophil aggregation in a dose-dependent manner in comparison with such inhibitors as amiloride and theophylline. The treatment of cells by heating at 46°C elicited a complete inhibition of H2O2release in 5 minutes, whereas the aggregation was observed ad least after 30 minute incubation at the elevated temperature. These findings indicated that VAA-induced aggregation of neutrophils is necessary, but not sufficient for H2O2release from cells. Finally, both VAA capacities were found to be inhibited by blood plasma that may play an important role in impairing of the lectin biological activity upon injection to cancer patients.

Published
1995
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30. Autoantibodies against galectins are associated with antiphospholipid syndrome in patients with systemic lupus erythematosus

Author

Sabine André, Georg Schett, Herbert Kaltner, Hans-Joachim Gabius, Kerstin Sarter, Martin Schiller, Luis E. Muñoz, David A. Isenberg, Jürgen Rech, Martin Herrmann, Hanns Martin Lorenz, Angelo A. Manfredi, Christine Schorn, Laura Andreoli, Christina Janko, Silke Winkler, Sarter, K, Janko, C, André, S, Muñoz, Le, Schorn, C, Winkler, S, Rech, J, Kaltner, H, Lorenz, Hm, Schiller, M, Andreoli, L, Manfredi, ANGELO ANDREA M. A., Isenberg, Da, Schett, G, Herrmann, M, and Gabius, Hj

Subjects
Male, Galectins, Enzyme-Linked Immunosorbent Assay, medicine.disease_cause, Biochemistry, Cohort Studies, 03 medical and health sciences, 0302 clinical medicine, Rheumatoid Factor, Antiphospholipid syndrome, medicine, Humans, Lupus Erythematosus, Systemic, Rheumatoid factor, skin and connective tissue diseases, Autoantibodies, 030304 developmental biology, Galectin, 030203 arthritis & rheumatology, 0303 health sciences, business.industry, Autoantibody, Immune dysregulation, Antiphospholipid Syndrome, medicine.disease, 3. Good health, Rheumatoid arthritis, Immunology, Biomarker (medicine), Female, business, Biomarkers, Anti-SSA/Ro autoantibodies
Abstract

The presence of autoantibodies against immunoregulatory effectors can be relevant for onset and/or the progression of autoimmune disease. Emerging insights into an immunological activity profile including a role as opsonins give reason to systematically monitor sera of patients for immunoglobulin G (IgG) autoantibodies, preferably for several galectins at the same time. Here, we report on a study of chronic inflammatory rheumatic diseases, i.e. systemic lupus erythematosus (SLE; pilot cohort p, n = 40; confirmation cohort c, n = 109), rheumatoid arthritis (RA; p, n = 32; c, n = 25) and primary antiphospholipid syndrome (APS; c, n = 64). Enzyme-linked immunosorbent assay-based series using galectin-1, -2, -3, -4, -7, -8 and -9 and natural processing products, i.e. the truncated version of galectin-3 and the N-terminal domains of galectin-4, -8 and -9, were performed. Normal healthy donors (p, n = 20; c, n = 21) and patients with paraproteins (c, n = 19) served as controls. Highly significant optical density-value readings for IgG autoantibodies were consistently detected for the proto-type galectin-7 (SLE) and the tandem repeat-type galectin-8 and -9 (SLE and RA). Their presence was independent from the autoantibody status against double-stranded DNA (for patients with SLE) or a rheumatoid factor (for patients with RA), respectively. Importantly, anti-galectin-2 autoantibodies highly significantly correlated with the appearance of a secondary APS in patients with SLE so that this parameter may serve as an additional biomarker for APS. Equally of note, the presence of IgG autoantibodies against galectins capable to act as an opsonin may contribute to a sustained immune dysregulation in patients with chronic inflammatory rheumatic diseases.

Published
2013

31. Cysteine Oxidation in Human Galectin-1 Occurs Sequentially via a Folded Intermediate to a Fully Oxidized Unfolded Form.

Author

Ippel H, Miller MC, Dings RPM, Ludwig AK, Gabius HJ, and Mayo KH

Subjects
Humans, Disulfides metabolism, Disulfides chemistry, Protein Folding, Protein Unfolding, Models, Molecular, Lactose metabolism, Lactose chemistry, Mutagenesis, Site-Directed, Galectin 1 metabolism, Galectin 1 chemistry, Galectin 1 genetics, Oxidation-Reduction, Cysteine metabolism, Cysteine chemistry
Abstract

Galectins are multifunctional effectors in cellular homeostasis and dysregulation. Oxidation of human galectin-1 (Gal-1) with its six sulfhydryls produces a disulfide-bridged oxidized form that lacks normal lectin activity yet gains new glycan-independent functionality. Nevertheless, the mechanistic details as to how Gal-1 oxidation occurs remain unclear. Here, we used 15 N and 13 C HSQC NMR spectroscopy to gain structural insight into the CuSO 4 -mediated path of Gal-1 oxidation and identified a minimum two-stage conversion process. During the first phase, disulfide bridges form slowly between C16-C88 and/or C42-C66 to produce a partially oxidized, conformationally flexible intermediate that retains the ability to bind lactose. Site-directed mutagenesis of C16 to S16 impedes the onset of this overall slow process. During the second phase, increased motional dynamics of the intermediate enable the relatively distant C2 and C130 residues to form the third and final disulfide bond, leading to an unfolded state and consequent dimer dissociation. This fully oxidized end state loses the ability to bind lactose, as shown by the hemagglutination assay. Consistent with this model, we observed that the Gal-1 C2S mutant maintains intermediate-state structural features with a free sulfhydryl group at C130. Incubation with dithiothreitol reduces all disulfide bonds and allows the lectin to revert to its native state. Thus, the sequential, non-random formation of three disulfide bridges in Gal-1 in an oxidative environment acts as a molecular switch for fundamental changes to its functionality. These data inspire detailed bioactivity analysis of the structurally defined oxidized intermediate in, e.g., acute and chronic inflammation.

Published
2024
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32. Galectin-9 as a Potential Modulator of Lymphocyte Adhesion to Endothelium via Binding to Blood Group H Glycan.

Author

Rapoport EM, Ryzhov IM, Slivka EV, Korchagina EY, Popova IS, Khaidukov SV, André S, Kaltner H, Gabius HJ, Henry S, and Bovin NV

Subjects
Humans, Galectins, Glycolipids, Jurkat Cells, Endothelium, Endothelial Cells, ABO Blood-Group System
Abstract

The recruitment of leukocytes from blood is one of the most important cellular processes in response to tissue damage and inflammation. This multi-step process includes rolling leukocytes and their adhesion to endothelial cells (EC), culminating in crossing the EC barrier to reach the inflamed tissue. Galectin-8 and galectin-9 expressed on the immune system cells are part of this process and can induce cell adhesion via binding to oligolactosamine glycans. Similarly, these galectins have an order of magnitude higher affinity towards glycans of the ABH blood group system, widely represented on ECs. However, the roles of gal-8 and gal-9 as mediators of adhesion to endothelial ABH antigens are practically unknown. In this work, we investigated whether H antigen-gal-9-mediated adhesion occurred between Jurkat cells (of lymphocytic origin and known to have gal-9) and EA.hy 926 cells (immortalized endothelial cells and known to have blood group H antigen). Baseline experiments showed that Jurkat cells adhered to EA.hy 926 cells; however when these EA.hy 926 cells were defucosylated (despite the unmasking of lactosamine chains), adherence was abolished. Restoration of fucosylation by insertion of synthetic glycolipids in the form of H (type 2) trisaccharide Fucα1-2Galβ1-4GlcNAc restored adhesion. The degree of lymphocyte adhesion to native and the "H-restored" (glycolipid-loaded) EA.hy 926 cells was comparable. If this gal-9/H (type 2) interaction is similar to processes that occur in vivo, this suggests that only the short (trisaccharide) H glycan on ECs is required.

Published
2023
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33. Altering the Modular Architecture of Galectins Affects its Binding with Synthetic α-Dystroglycan O-Mannosylated Core M1 Glycoconjugates In situ.

Author

Villones LL Jr, Ludwig AK, Kikuchi S, Ochi R, Nishimura SI, Gabius HJ, Kaltner H, and Hinou H

Subjects
Glycoconjugates metabolism, Glycopeptides, Dystroglycans, Galectins metabolism
Abstract

The multifunctionality of galectins helps regulate a broad range of fundamental cellular processes via cis-binding and trans-bridging activities and has gained widespread attention with respect to the importance of the natural specificity/selectivity of this lectin family to its glycoconjugate receptors. Combining galectin (Gal)-1, -3, -4, and -9 variant test panels, achieved via rational protein engineering, and a synthetic α-dystroglycan (DG) O-Mannosylated core M1 glycopeptide library, a detailed comparative analysis was performed, utilizing microarray experiments to delineate the design-functionality relationships within this lectin family. Enhancement of prototype Gal-1 and chimera-type Gal-3 cis-binding toward the prepared ligands is possible by transforming these lectins into tandem-repeat type and prototypes, respectively. Furthermore, Gal-1 variants demonstrated improved trans-bridging capabilities between core M1 α-DG glycopeptides and laminins in microarray, suggesting the possible translational applications of these galectin variants in the treatment of some forms of α-dystroglycanopathy., (© 2023 Wiley-VCH GmbH.)

Published
2023
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34. Structure of Galectin-3 bound to a model membrane containing ganglioside GM1.

Author

Vander Zanden CM, Majewski J, Weissbarth Y, Browne DF, Watkins EB, and Gabius HJ

Subjects
Gangliosides, Cell Membrane metabolism, Molecular Dynamics Simulation, G(M1) Ganglioside chemistry, Galectin 3 metabolism
Abstract

Galectin-3 (Gal-3) is a β-galactosidase-binding protein involved in various biological processes, including neuronal growth and adhesion. The pairing of Gal-3 with ganglioside GM1's pentasaccharide chain at the outer leaflet of the plasma membrane, which triggers downstream cell-signaling cascades, seems to be involved in these processes. A crucial feature of Gal-3 is its ability to form oligomers and supramolecular assemblies that connect various carbohydrate-decorated molecules. Although we know the atomistic structure of Gal-3 bound to small carbohydrate ligands, it remains unclear how Gal-3 binds GM1 in a membrane. Furthermore, the influence of this interaction on Gal-3's structure and oligomeric assembly has to be elucidated. In this study, we used X-ray reflectivity (XR) from a model membrane to determine the structure and surface coverage of Gal-3 bound to a membrane containing GM1. We observed that the carbohydrate recognition domain interacts with GM1's pentasaccharide, while the N-terminal domain is pointed away from the membrane, likely to facilitate protein-protein interactions. In a membrane containing 20 mol % GM1, Gal-3 covered ∼50% of the membrane surface with one Gal-3 molecule bound per 2130 Å 2 . We used molecular dynamics simulations and Voronoi tessellation algorithms to build an atomistic model of membrane-bound Gal-3, which is supported by the XR results. Overall, this work provides structural information describing how Gal-3 can bind GM1's pentasaccharide chain, a prerequisite for triggering regulatory processes in neuronal growth and adhesion., Competing Interests: Declaration of interests The authors declare no conflict of interest., (Copyright © 2022 Biophysical Society. All rights reserved.)

Published
2023
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35. Targeting osteoarthritis-associated galectins and an induced effector class by a ditopic bifunctional reagent: Impact of its glycan part on binding measured in the tissue context.

Author

Manning JC, Baldoneschi V, Romero-Hernández LL, Pichler KM, GarcÍa Caballero G, André S, Kutzner TJ, Ludwig AK, Zullo V, Richichi B, Windhager R, Kaltner H, Toegel S, Gabius HJ, Murphy PV, and Nativi C

Subjects
Humans, Ligands, Cross-Linking Reagents, Galectin 3 metabolism, Polysaccharides chemistry, Matrix Metalloproteinases, Galectins chemistry, Galectins metabolism, Osteoarthritis drug therapy, Osteoarthritis metabolism
Abstract

Pairing glycans with tissue lectins controls multiple effector pathways in (patho)physiology. A clinically relevant example is the prodegradative activity of galectins-1 and -3 (Gal-1 and -3) in the progression of osteoarthritis (OA) via matrix metalloproteinases (MMPs), especially MMP-13. The design of heterobifunctional inhibitors that can block galectin binding and MMPs both directly and by preventing their galectin-dependent induction selectively offers a perspective to dissect the roles of lectins and proteolytic enzymes. We describe the synthesis of such a reagent with a bivalent galectin ligand connected to an MMP inhibitor and of two tetravalent glycoclusters with a subtle change in headgroup presentation for further elucidation of influence on ligand binding. Testing was performed on clinical material with mixtures of galectins as occurring in vivo, using sections of fixed tissue. Two-colour fluorescence microscopy monitored binding to the cellular glycome after optimization of experimental parameters. In the presence of the inhibitor, galectin binding to OA specimens was significantly reduced. These results open the perspective to examine the inhibitory capacity of custom-made ditopic compounds on binding of lectins in mixtures using sections of clinical material with known impact of galectins and MMPs on disease progression., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2022 Elsevier Ltd. All rights reserved.)

Published
2022
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36. Exploring the In situ pairing of human galectins toward synthetic O-mannosylated core M1 glycopeptides of α-dystroglycan.

Author

Villones LL Jr, Ludwig AK, Kumeta H, Kikuchi S, Ochi R, Aizawa T, Nishimura SI, Gabius HJ, and Hinou H

Subjects
Humans, Galectins metabolism, Laminin metabolism, Ligands, Dystrophin, Polysaccharides metabolism, Carbohydrates, Dystroglycans metabolism, Glycopeptides chemistry
Abstract

Dystroglycan (DG), which constitutes a part of the dystrophin-glycoprotein complex, connects the extracellular matrix to the cytoskeleton. The matriglycans presented by the extracellular α-DG serve as a contact point with extracellular matrix proteins (ECM) containing laminin G-like domains, providing cellular stability. However, it remains unknown whether core M1 (GlcNAcβ1-2Man) structures can serve as ligands among the various O-Mannosylated glycans. Therefore, based on the presence of N-acetylLactosamine (LacNAc) in this glycan following the core extension, the binding interactions with adhesion/growth-regulatory galectins were explored. To elucidate this process, the interaction between galectin (Gal)-1, -3, -4 and -9 with α-DG fragment 372 TRGAIIQTPTLGPIQPTRV 390 core M1-based glycopeptide library were profiled, using glycan microarray and nuclear magnetic resonance studies. The binding of galectins was revealed irrespective of its modular architecture, adding galectins to the list of possible binding partners of α-DG core M1 glycoconjugates by cis-binding (via peptide- and carbohydrate-protein interactions), which can be abrogated by α2,3-sialylation of the LacNAc units. The LacNAc-terminated α-DG glycopeptide interact simultaneously with both the S- and F-faces of Gal-1, thereby inducing oligomerization. Furthermore, Gal-1 can trans-bridge α-DG core M1 structures and laminins, which proposed a possible mechanism by which Gal-1 ameliorates muscular dystrophies; however, this proposal warrants further investigation., (© 2022. The Author(s).)

Published
2022
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37. What is the Sugar Code?

Author

Gabius HJ, Cudic M, Diercks T, Kaltner H, Kopitz J, Mayo KH, Murphy PV, Oscarson S, Roy R, Schedlbauer A, Toegel S, and Romero A

Subjects
Carbohydrates chemistry, Lectins metabolism, Polysaccharides chemistry, Nucleic Acids, Sugars
Abstract

A code is defined by the nature of the symbols, which are used to generate information-storing combinations (e. g. oligo- and polymers). Like nucleic acids and proteins, oligo- and polysaccharides are ubiquitous, and they are a biochemical platform for establishing molecular messages. Of note, the letters of the sugar code system (third alphabet of life) excel in coding capacity by making an unsurpassed versatility for isomer (code word) formation possible by variability in anomery and linkage position of the glycosidic bond, ring size and branching. The enzymatic machinery for glycan biosynthesis (writers) realizes this enormous potential for building a large vocabulary. It includes possibilities for dynamic editing/erasing as known from nucleic acids and proteins. Matching the glycome diversity, a large panel of sugar receptors (lectins) has developed based on more than a dozen folds. Lectins 'read' the glycan-encoded information. Hydrogen/coordination bonding and ionic pairing together with stacking and C-H/π-interactions as well as modes of spatial glycan presentation underlie the selectivity and specificity of glycan-lectin recognition. Modular design of lectins together with glycan display and the nature of the cognate glycoconjugate account for the large number of post-binding events. They give an entry to the glycan vocabulary its functional, often context-dependent meaning(s), hereby building the dictionary of the sugar code., (© 2021 The Authors. ChemBioChem published by Wiley-VCH GmbH.)

Published
2022
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38. Galectin network in osteoarthritis: galectin-4 programs a pathogenic signature of gene and effector expression in human chondrocytes in vitro.

Author

Pichler KM, Fischer A, Alphonsus J, Chiari C, Schmidt S, Kenn M, Schreiner W, Weinmann D, Rothbauer M, Windhager R, Gabius HJ, and Toegel S

Subjects
Cells, Cultured, Chondrocytes metabolism, Chondrocytes pathology, Galectin 4 metabolism, Humans, Osteoarthritis metabolism, Osteoarthritis pathology, RNA, Messenger genetics, RNA, Messenger metabolism, Chondrocytes chemistry, Galectin 4 genetics, Osteoarthritis genetics
Abstract

Galectin-4 (Gal-4) is a member of the galectin family, which have been identified as galactose-binding proteins. Gal-4 possesses two tandem repeat carbohydrate recognition domains and acts as a cross-linking bridge in sulfatide-dependent glycoprotein routing. We herein document its upregulation in osteoarthritis (OA) in correlation with the extent of cartilage degradation in vivo. Primary human OA chondrocytes in vitro respond to carbohydrate-inhibitable Gal-4 binding with the upregulation of pro-degradative/-inflammatory proteins such as interleukin-1β (IL-1β) and matrix metalloproteinase-13 (MMP-13), as documented by RT-qPCR-based mRNA profiling and transcriptome data processing. Activation of p65 by phosphorylation of Ser536 within the NF-κB pathway and the effect of three p65 inhibitors on Gal-4 activity support downstream involvement of such signaling. In 3D (pellet) cultures, Gal-4 presence causes morphological and biochemical signs of degradation. Taken together, our findings strongly support the concept of galectins acting as a network in OA pathogenesis and suggest that blocking their activity in disease progression may become clinically relevant in the future., (© 2021. The Author(s).)

Published
2022
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39. Brain macrophages acquire distinct transcriptomes in multiple sclerosis lesions and normal appearing white matter.

Author

Miedema A, Gerrits E, Brouwer N, Jiang Q, Kracht L, Meijer M, Nutma E, Peferoen-Baert R, Pijnacker ATE, Wesseling EM, Wijering MHC, Gabius HJ, Amor S, Eggen BJL, and Kooistra SM

Subjects
Animals, Brain pathology, Demyelinating Diseases chemically induced, Demyelinating Diseases genetics, Demyelinating Diseases pathology, Female, Humans, Macrophages pathology, Male, Mice, Multiple Sclerosis genetics, Multiple Sclerosis pathology, White Matter pathology, Brain metabolism, Demyelinating Diseases metabolism, Macrophages metabolism, Multiple Sclerosis metabolism, Transcriptome, White Matter metabolism
Abstract

Multiple sclerosis (MS) is a disease of the central nervous system that is characterized by inflammation and focal areas of demyelination, ultimately resulting in axonal degradation and neuronal loss. Several lines of evidence point towards a role for microglia and other brain macrophages in disease initiation and progression, but exactly how lesion formation is triggered is currently unknown. Here, we characterized early changes in MS brain tissue through transcriptomic analysis of normal appearing white matter (NAWM). We found that NAWM was characterized by enriched expression of genes associated with inflammation and cellular stress derived from brain macrophages. Single cell RNA sequencing confirmed a stress response in brain macrophages in NAWM and identified specific microglia and macrophage subsets at different stages of demyelinating lesions. We identified both phagocytic/activated microglia and CAM clusters that were associated with various MS lesion types. These overall changes in microglia and macrophages associated with lesion development in MS brain tissue may provide therapeutic targets to limit lesion progression and demyelination., (© 2022. The Author(s).)

Published
2022
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40. Introducing 77 Se NMR Spectroscopy to Analyzing Galectin -Ligand Interaction.

Author

Raics M, Timári I, Szilágyi L, Gabius HJ, and Kövér KE

Subjects
Glycosides, Ligands, Magnetic Resonance Spectroscopy methods, Carbohydrates chemistry, Galectins metabolism
Abstract

Their emerging nature as multifunctional effectors explains the large interest to monitor glycan binding to galectins and to define bound-state conformer(s) of their ligands in solution. Basically, NMR spectroscopy facilitates respective experiments. Towards developing new and even better approaches for these purposes, extending the range of exploitable isotopes beyond 1 H, 13 C, and 15 N offers promising perspectives. Having therefore prepared selenodigalactoside and revealed its bioactivity as galectin ligand, monitoring of its binding by 77 Se NMR spectroscopy at a practical level becomes possible by setting up a 2D 1 H, 77 Se CPMG-HSQBMC experiment including CPMG-INEPT long-range transfer. This first step into applying 77 Se as sensor for galectin binding substantiates its potential for screening relative to inhibitory potencies in compound mixtures and for achieving sophisticated epitope mapping. The documented strategic combination of synthetic carbohydrate chemistry and NMR spectroscopy prompts to envision to work with isotopically pure 77 Se-containing β-galactosides and to build on the gained experience with 77 Se by adding 19 F as second sensor in doubly labeled glycosides., (© 2022. Springer Science+Business Media, LLC, part of Springer Nature.)

Published
2022
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41. Exploring the Galectin Network by Light and Fluorescence Microscopy.

Author

García Caballero G, Manning JC, Gabba A, Beckwith D, FitzGerald FG, Kutzner TJ, Ludwig AK, Kaltner H, Murphy PV, Cudic M, and Gabius HJ

Subjects
Animals, Chickens, Humans, Microscopy, Fluorescence, Galectins metabolism, Polysaccharides metabolism
Abstract

Dynamic changes of a cell's glycophenotype are increasingly interpreted as shifts in the capacity to interact with tissue (endogenous) lectins. The status of glycan branching or chain length (e.g., core 1 vs core 2 mucin-type O-glycans and polyLacNAc additions) as well as of sialylation/sulfation has been delineated to convey signals. They are "read" by galectins, for example regulating lattice formation on the membrane and cell growth. Owing to the discovery of the possibility that these effectors act in networks physiologically resulting in functional antagonism or cooperation, their detection and distribution profiling need to be expanded from an individual (single) protein to the-at best-entire family. How to work with non-cross-reactive antibodies and with the labeled tissue-derived proteins (used as probes) is exemplarily documented for chicken and human galectins including typical activity and specificity controls. This description intends to inspire the systematic (network) study of members of a lectin family and also the application of tissue proteins beyond a single lectin category in lectin histochemistry., (© 2022. Springer Science+Business Media, LLC, part of Springer Nature.)

Published
2022
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42. What Happens If a Human Galectin Enters the Endoplasmic Reticulum?

Author

Kutzner TJ, Higuero AM, Süßmair M, Hingar M, Kaltner H, Lindner I, Kopitz J, Abad-Rodríguez J, Reusch D, and Gabius HJ

Subjects
Animals, Glycosylation, Golgi Apparatus metabolism, Humans, Mammals metabolism, Protein Sorting Signals, Endoplasmic Reticulum metabolism, Galectins metabolism
Abstract

Mammalian galectins have no signal peptide, and it is not known what would happen if a galectin is directed to take the classical export route. The corresponding engineering of galectin-specific cDNA will answer questions on the fate of a signal peptide-bearing protein variant after its entry into the endoplasmic reticulum (ER). Affinity chromatography and mass-spectrometric analysis of occupancy of potential N-glycosylation sites for the galectin, binding and functional assays with cells as well as subcellular fractionation by density gradient ultracentrifugation and immunocytochemical colocalization with ER/Golgi markers report on aspects of the consequences of letting a galectin enter new territory. Applying these methods will help to clarify why galectins are leaderless and thus produced by free ribosomes., (© 2022. Springer Science+Business Media, LLC, part of Springer Nature.)

Published
2022
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43. Examining Galectin Gene Regulation by Reporter Assays.

Author

Schmidt S, Kaltner H, and Gabius HJ

Subjects
Luciferases genetics, Promoter Regions, Genetic, Galectins genetics, Gene Expression Regulation
Abstract

Matching their role as potent and versatile effectors in cellular homeostasis and disease processes, galectins are subject to a fine-tuned transcriptional regulation of gene expression. It can apparently even involve coregulation with certain elements of the enzymatic machinery for glycan biosynthesis/remodeling and/or functional carriers of galectin-binding glycans such as the α 5 β 1 -integrin. All this suggests not yet fully known combinatorial processes to reach the desired outcome. Identification of transcription start point(s), cloning of upstream promoter region, and the design of plasmids for luciferase-based reporter assays establish the platform to initiate a systematic search of regulatory sequences. Their elucidation is also a step toward rationally manipulating expression of galectin genes in pathogenesis., (© 2022. Springer Science+Business Media, LLC, part of Springer Nature.)

Published
2022
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44. Structural Characterization of Rat Galectin-5, an N-Tailed Monomeric Proto-Type-like Galectin.

Author

Ruiz FM, Medrano FJ, Ludwig AK, Kaltner H, Shilova NV, Bovin NV, Gabius HJ, and Romero A

Subjects
Amino Acid Motifs, Animals, Carbohydrate Sequence, Crystallography, X-Ray, Galectins genetics, Models, Molecular, Protein Binding, Protein Domains, Protein Multimerization, Protein Structure, Secondary, Rats, Scattering, Small Angle, Galectins chemistry, Galectins metabolism, Polysaccharides chemistry, Polysaccharides metabolism
Abstract

Galectins are multi-purpose effectors acting via interactions with distinct counterreceptors based on protein-glycan/protein recognition. These processes are emerging to involve several regions on the protein so that the availability of a detailed structural characterization of a full-length galectin is essential. We report here the first crystallographic information on the N-terminal extension of the carbohydrate recognition domain of rat galectin-5, which is precisely described as an N-tailed proto-type-like galectin. In the ligand-free protein, the three amino-acid stretch from Ser2 to Ser5 is revealed to form an extra β-strand (F0), and the residues from Thr6 to Asn12 are part of a loop protruding from strands S1 and F0. In the ligand-bound structure, amino acids Ser2-Tyr10 switch position and are aligned to the edge of the β-sandwich. Interestingly, the signal profile in our glycan array screening shows the sugar-binding site to preferentially accommodate the histo-blood-group B (type 2) tetrasaccharide and N-acetyllactosamine-based di- and oligomers. The crystal structures revealed the characteristically preformed structural organization around the central Trp77 of the CRD with involvement of the sequence signature's amino acids in binding. Ligand binding was also characterized calorimetrically. The presented data shows that the N-terminal extension can adopt an ordered structure and shapes the hypothesis that a ligand-induced shift in the equilibrium between flexible and ordered conformers potentially acts as a molecular switch, enabling new contacts in this region.

Published
2021
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45. The marriage of chemokines and galectins as functional heterodimers.

Author

von Hundelshausen P, Wichapong K, Gabius HJ, and Mayo KH

Subjects
Animals, Humans, Chemokines metabolism, Galectins metabolism, Inflammation physiopathology
Abstract

Trafficking of leukocytes and their local activity profile are of pivotal importance for many (patho)physiological processes. Fittingly, microenvironments are complex by nature, with multiple mediators originating from diverse cell types and playing roles in an intimately regulated manner. To dissect aspects of this complexity, effectors are initially identified and structurally characterized, thus prompting familial classification and establishing foci of research activity. In this regard, chemokines present themselves as role models to illustrate the diversification and fine-tuning of inflammatory processes. This in turn discloses the interplay among chemokines, their cell receptors and cognate glycosaminoglycans, as well as their capacity to engage in new molecular interactions that form hetero-oligomers between themselves and other classes of effector molecules. The growing realization of versatility of adhesion/growth-regulatory galectins that bind to glycans and proteins and their presence at sites of inflammation led to testing the hypothesis that chemokines and galectins can interact with each other by protein-protein interactions. In this review, we present some background on chemokines and galectins, as well as experimental validation of this chemokine-galectin heterodimer concept exemplified with CXCL12 and galectin-3 as proof-of-principle, as well as sketch out some emerging perspectives in this arena., (© 2021. The Author(s).)

Published
2021
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46. Glycans in autophagy, endocytosis and lysosomal functions.

Author

Reggiori F, Gabius HJ, Aureli M, Römer W, Sonnino S, and Eskelinen EL

Subjects
Gene Expression Regulation, Proteins genetics, Proteins metabolism, Autophagy physiology, Endocytosis physiology, Lysosomes physiology, Polysaccharides metabolism
Abstract

Glycans have been shown to function as versatile molecular signals in cells. This prompted us to look at their roles in endocytosis, endolysosomal system and autophagy. We start by introducing the cell biological aspects of these pathways, the concept of the sugar code, and provide an overview on the role of glycans in the targeting of lysosomal proteins and in lysosomal functions. Moreover, we review evidence on the regulation of endocytosis and autophagy by glycans. Finally, we discuss the emerging concept that cytosolic exposure of luminal glycans, and their detection by endogenous lectins, provides a mechanism for the surveillance of the integrity of the endolysosomal compartments, and serves their eventual repair or disposal., (© 2021. The Author(s).)

Published
2021
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47. Imitating evolution's tinkering by protein engineering reveals extension of human galectin-7 activity.

Author

Ludwig AK, Michalak M, Gabba A, Kutzner TJ, Beckwith DM, FitzGerald FG, García Caballero G, Manning JC, Kriegsmann M, Kaltner H, Murphy PV, Cudic M, Kopitz J, and Gabius HJ

Subjects
Cell Line, Tumor, Galectins analysis, Galectins isolation & purification, Humans, Mass Spectrometry, Galectins metabolism, Protein Engineering
Abstract

Wild-type lectins have distinct types of modular design. As a step to explain the physiological importance of their special status, hypothesis-driven protein engineering is used to generate variants. Concerning adhesion/growth-regulatory galectins, non-covalently associated homodimers are commonly encountered in vertebrates. The homodimeric galectin-7 (Gal-7) is a multifunctional context-dependent modulator. Since the possibility of conversion from the homodimer to hybrids with other galectin domains, i.e. from Gal-1 and Gal-3, has recently been discovered, we designed Gal-7-based constructs, i.e. stable (covalently linked) homo- and heterodimers. They were produced and purified by affinity chromatography, and the sugar-binding activity of each lectin unit proven by calorimetry. Inspection of profiles of binding of labeled galectins to an array-like platform with various cell types, i.e. sections of murine epididymis and jejunum, and impact on neuroblastoma cell proliferation revealed no major difference between natural and artificial (stable) homodimers. When analyzing heterodimers, acquisition of altered properties was seen. Remarkably, binding properties and activity as effector can depend on the order of arrangement of lectin domains (from N- to C-termini) and on the linker length. After dissociation of the homodimer, the Gal-7 domain can build new functionally active hybrids with other partners. This study provides a clear direction for research on defining the full range of Gal-7 functionality and offers the perspective of testing applications for engineered heterodimers., (© 2021. The Author(s).)

Published
2021
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48. Simulating cellular galectin networks by mixing galectins in vitro reveals synergistic activity.

Author

Dings RPM, Kumar N, Mikkelson S, Gabius HJ, and Mayo KH

Abstract

Background: Even though members of the family of adhesion/growth-regulatory galectins are increasingly detected to be co-expressed, they are still being routinely tested separately. The recent discovery of heterodimer formation among galectins-1, -3, and -7 in mixtures prompts further study of their functional activities in mixtures., Methods: Cell agglutination, galectin binding to cells, as well as effects on cell proliferation, onset of apoptosis and migration were determined in assays using various cell types and mixtures of galectins-1, -3, and -7., Results: Evidence for a more than additive increases of experimental parameters was consistently obtained., Conclusion: Testing galectins in mixtures simulates the situation of co-expression in situ and reveals unsuspected over-additive activities. This new insight is relevant for analyzing galectin functionality in (patho)physiological conditions., Competing Interests: The authors declare that they have no conflict of interests., (© 2021 The Authors.)

Published
2021
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49. Glycobiology of developing chicken kidney: Profiling the galectin family and selected β-galactosides.

Author

Manning JC, García Caballero G, Ludwig AK, Kaltner H, Sinowatz F, and Gabius HJ

Subjects
Animals, Chickens, Glycomics, Glycosylation, Kidney embryology, Galactosides metabolism, Galectins metabolism, Kidney metabolism
Abstract

The concept of the sugar code interprets the cellular glycophenotype as a rich source of information read by glycan-lectin recognition in situ. This study's aim is the comprehensive characterization of galectin expression by immunohistochemistry during chicken nephrogenesis along with mapping binding sites by (ga)lectin histochemistry. Light and two-color fluorescence microscopy were used. First, six plant/fungal lectins that are specific for galectin-binding parts of N- and O-glycans were applied. The spatiotemporally regulated distributions of these glycans in meso- and metanephros equip cells with potential binding partners for the galectins. Complete galectin profiling from HH Stage 20 (about 70-72 hr) onward revealed cell-, galectin-, and stage-dependent expression patterns. Representatives of all three types of modular architecture of the galectin family are detectable, and overlaps of signal distribution in light and two-color fluorescence microscopy illustrate a possibility for functional cooperation among them. Performing systematic galectin histochemistry facilitated comparisons between staining profiles of plant lectins and galectins. They revealed several cases for differences so that tissue lectins appear to be selective among the β-galactosides. Notably, selectivity is also disclosed in intrafamily comparison. Thus, combining experimental series with plant and tissue lectins is a means to characterize target populations of glycans presented by cellular glycoconjugates for individual galectins. Our results document the presence and sophisticated level of elaboration among β-galactosides and among the members of the family of galectins during organogenesis, using chicken galectins and kidney as model. Thus, they provide a clear guideline for functional assays using supramolecular tools, cells, and organ cultures., (© 2020 The Authors. The Anatomical Record published by Wiley Periodicals LLC on behalf of American Association for Anatomy.)

Published
2021
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50. Characterizing ligand-induced conformational changes in clinically relevant galectin-1 by H N /H 2 O (D 2 O) exchange.

Author

Schedlbauer A, Gilles U, Ludwig AK, Adler A, Kaltner H, Lindner I, Mayo KH, Diercks T, Reusch D, and Gabius HJ

Subjects
Deuterium Exchange Measurement, Humans, Nuclear Magnetic Resonance, Biomolecular, Galectin 1 chemistry
Abstract

Glycans of cellular glycoconjugates serve as biochemical signals for a multitude of (patho)physiological processes via binding to their receptors (e.g. lectins). In the case of human adhesion/growth-regulatory galectin-1 (Gal-1), small angle neutron scattering and fluorescence correlation spectroscopy have revealed a significant decrease of its gyration radius and increase of its diffusion coefficient upon binding lactose, posing the pertinent question on the nature and region(s) involved in the underlying structural alterations. Requiring neither a neutron source nor labeling, diffusion measurements by 1 H NMR spectroscopy are shown here to be sufficiently sensitive to detect this ligand-induced change. In order to figure out which region(s) of Gal-1 is (are) affected at the level of peptides, we first explored the use of H/D exchange mass spectrometry (HDX MS). Hereby, we found a reduction in proton exchange kinetics beyond the lactose-binding site. The measurement of fast H N /H 2 O exchange by phase-modulated NMR clean chemical exchange (CLEANEX) NMR on 15 N-labeled Gal-1 then increased the spatial resolution to the level of individual amino acids. The mapped regions with increased protection from H N /H 2 O (D 2 O) exchange that include the reduction of solvent exposure around the interface can underlie the protein's compaction. These structural changes have potential to modulate this galectin's role in lattice formation on the cell surface and its interaction(s) with protein(s) at the F-face., Competing Interests: Declaration of competing interest The authors declared no conflicts of interest., (Copyright © 2021 Elsevier B.V. and Société Française de Biochimie et Biologie Moléculaire (SFBBM). All rights reserved.)

Published
2021
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