A practical guide to the MaxQuant computational platform for SILAC-based quantitative proteomics J Cox, I Matic, M Hilger, N Nagaraj, M Selbach, JV Olsen, M Mann Nature protocols 4 (5), 698-705, 2009 | 873 | 2009 |
System-wide changes to SUMO modifications in response to heat shock F Golebiowski, I Matic, MH Tatham, C Cole, Y Yin, A Nakamura, J Cox, ... Science signaling 2 (72), ra24-ra24, 2009 | 557 | 2009 |
Family-wide analysis of poly (ADP-ribose) polymerase activity S Vyas, I Matic, L Uchima, J Rood, R Zaja, RT Hay, I Ahel, P Chang Nature communications 5 (1), 4426, 2014 | 479 | 2014 |
Defining the transcriptome and proteome in three functionally different human cell lines E Lundberg, L Fagerberg, D Klevebring, I Matic, T Geiger, J Cox, ... Molecular systems biology 6 (1), 450, 2010 | 442 | 2010 |
In vivo identification of human small ubiquitin-like modifier polymerization sites by high accuracy mass spectrometry and an in vitro to in vivo strategy I Matic, M van Hagen, J Schimmel, B Macek, SC Ogg, MH Tatham, ... Molecular & cellular proteomics 7 (1), 132-144, 2008 | 366 | 2008 |
Site-specific identification of SUMO-2 targets in cells reveals an inverted SUMOylation motif and a hydrophobic cluster SUMOylation motif I Matic, J Schimmel, IA Hendriks, MA van Santen, F van de Rijke, ... Molecular cell 39 (4), 641-652, 2010 | 351 | 2010 |
Deficiency of terminal ADP‐ribose protein glycohydrolase TARG1/C6orf130 in neurodegenerative disease R Sharifi, R Morra, C Denise Appel, M Tallis, B Chioza, G Jankevicius, ... The EMBO journal 32 (9), 1225-1237, 2013 | 313 | 2013 |
Serine ADP-ribosylation depends on HPF1 JJ Bonfiglio, P Fontana, Q Zhang, T Colby, I Gibbs-Seymour, I Atanassov, ... Molecular cell 65 (5), 932-940. e6, 2017 | 289 | 2017 |
Phosphoribosylation of ubiquitin promotes serine ubiquitination and impairs conventional ubiquitination S Bhogaraju, S Kalayil, Y Liu, F Bonn, T Colby, I Matic, I Dikic Cell 167 (6), 1636-1649. e13, 2016 | 287 | 2016 |
Serine is a new target residue for endogenous ADP-ribosylation on histones O Leidecker, JJ Bonfiglio, T Colby, Q Zhang, I Atanassov, R Zaja, ... Nature chemical biology 12 (12), 998-1000, 2016 | 220 | 2016 |
Proteome-wide identification of SUMO2 modification sites T Tammsalu, I Matic, EG Jaffray, AFM Ibrahim, MH Tatham, RT Hay Science signaling 7 (323), rs2-rs2, 2014 | 215 | 2014 |
Regulation of translesion synthesis DNA polymerase η by monoubiquitination M Bienko, CM Green, S Sabbioneda, N Crosetto, I Matic, RG Hibbert, ... Molecular cell 37 (3), 396-407, 2010 | 208 | 2010 |
Serine is the major residue for ADP-ribosylation upon DNA damage L Palazzo, O Leidecker, E Prokhorova, H Dauben, I Matic, I Ahel Elife 7, e34334, 2018 | 207 | 2018 |
Purification and identification of endogenous polySUMO conjugates R Bruderer, MH Tatham, A Plechanovova, I Matic, AK Garg, RT Hay EMBO reports 12 (2), 142-148, 2011 | 207 | 2011 |
Serine ADP-ribosylation reversal by the hydrolase ARH3 P Fontana, JJ Bonfiglio, L Palazzo, E Bartlett, I Matic, I Ahel Elife 6, e28533, 2017 | 204 | 2017 |
Comparative proteomic analysis identifies a role for SUMO in protein quality control MH Tatham, I Matic, M Mann, RT Hay Science signaling 4 (178), rs4-rs4, 2011 | 193 | 2011 |
The ubiquitin-proteasome system is a key component of the SUMO-2/3 cycle J Schimmel, KM Larsen, I Matic, M van Hagen, J Cox, M Mann, ... Molecular & Cellular Proteomics 7 (11), 2107-2122, 2008 | 186 | 2008 |
ADP‐ribosyltransferases, an update on function and nomenclature B Lüscher, I Ahel, M Altmeyer, A Ashworth, P Bai, P Chang, M Cohen, ... The FEBS journal 289 (23), 7399-7410, 2022 | 184 | 2022 |
The ubiquitin E1 enzyme Ube1 mediates NEDD8 activation under diverse stress conditions O Leidecker, I Matic, B Mahata, E Pion, DP Xirodimas Cell cycle 11 (6), 1142-1150, 2012 | 156 | 2012 |
Processing of protein ADP-ribosylation by Nudix hydrolases L Palazzo, B Thomas, AS Jemth, T Colby, O Leidecker, KLH Feijs, R Zaja, ... Biochemical Journal 468 (2), 293-301, 2015 | 143 | 2015 |