| IUPred: web server for the prediction of intrinsically unstructured regions of proteins based on estimated energy content Z Dosztányi, V Csizmok, P Tompa, I Simon Bioinformatics 21 (16), 3433-3434, 2005 | 2327 | 2005 |
| InterPro in 2017—beyond protein family and domain annotations RD Finn, TK Attwood, PC Babbitt, A Bateman, P Bork, AJ Bridge, ... Nucleic acids research 45 (D1), D190-D199, 2017 | 1610 | 2017 |
| IUPred2A: context-dependent prediction of protein disorder as a function of redox state and protein binding B Mészáros, G Erdős, Z Dosztányi Nucleic acids research 46 (W1), W329-W337, 2018 | 1377 | 2018 |
| The pairwise energy content estimated from amino acid composition discriminates between folded and intrinsically unstructured proteins Z Dosztanyi, V Csizmok, P Tompa, I Simon Journal of molecular biology 347 (4), 827-839, 2005 | 1154 | 2005 |
| D2P2: database of disordered protein predictions ME Oates, P Romero, T Ishida, M Ghalwash, MJ Mizianty, B Xue, ... Nucleic acids research 41 (D1), D508-D516, 2012 | 747 | 2012 |
| ANCHOR: web server for predicting protein binding regions in disordered proteins Z Dosztányi, B Mészáros, I Simon Bioinformatics 25 (20), 2745-2746, 2009 | 684 | 2009 |
| Prediction of protein binding regions in disordered proteins B Mészáros, I Simon, Z Dosztányi PLoS computational biology 5 (5), e1000376, 2009 | 662 | 2009 |
| IUPred3: prediction of protein disorder enhanced with unambiguous experimental annotation and visualization of evolutionary conservation G Erdős, M Pajkos, Z Dosztányi Nucleic acids research 49 (W1), W297-W303, 2021 | 420 | 2021 |
| Disorder and sequence repeats in hub proteins and their implications for network evolution Z Dosztanyi, J Chen, AK Dunker, I Simon, P Tompa Journal of proteome research 5 (11), 2985-2995, 2006 | 393 | 2006 |
| PDB_TM: selection and membrane localization of transmembrane proteins in the protein data bank GE Tusnády, Z Dosztányi, I Simon Nucleic acids research 33 (suppl_1), D275-D278, 2005 | 351 | 2005 |
| DisProt 7.0: a major update of the database of disordered proteins D Piovesan, F Tabaro, I Mičetić, M Necci, F Quaglia, CJ Oldfield, ... Nucleic acids research 45 (D1), D219-D227, 2017 | 339 | 2017 |
| Analyzing protein disorder with IUPred2A G Erdős, Z Dosztányi Current protocols in bioinformatics 70 (1), e99, 2020 | 327 | 2020 |
| Molecular principles of the interactions of disordered proteins B Mészáros, P Tompa, I Simon, Z Dosztányi Journal of molecular biology 372 (2), 549-561, 2007 | 323 | 2007 |
| What’s in a name? Why these proteins are intrinsically disordered: Why these proteins are intrinsically disordered AK Dunker, MM Babu, E Barbar, M Blackledge, SE Bondos, Z Dosztányi, ... Intrinsically disordered proteins 1 (1), e24157, 2013 | 306 | 2013 |
| Transmembrane proteins in the Protein Data Bank: identification and classification GE Tusnády, Z Dosztányi, I Simon Bioinformatics 20 (17), 2964-2972, 2004 | 302 | 2004 |
| Critical assessment of protein intrinsic disorder prediction M Necci, D Piovesan, SCE Tosatto Nature methods 18 (5), 472-481, 2021 | 273 | 2021 |
| DisProt: intrinsic protein disorder annotation in 2020 A Hatos, B Hajdu-Soltész, AM Monzon, N Palopoli, L Álvarez, ... Nucleic acids research 48 (D1), D269-D276, 2020 | 260 | 2020 |
| MobiDB 3.0: more annotations for intrinsic disorder, conformational diversity and interactions in proteins D Piovesan, F Tabaro, L Paladin, M Necci, I Mičetić, C Camilloni, N Davey, ... Nucleic acids research 46 (D1), D471-D476, 2018 | 226 | 2018 |
| Prediction of protein disorder based on IUPred Z Dosztányi Protein Science 27 (1), 331-340, 2018 | 226 | 2018 |
| MobiDB: intrinsically disordered proteins in 2021 D Piovesan, M Necci, N Escobedo, AM Monzon, A Hatos, I Mičetić, ... Nucleic acids research 49 (D1), D361-D367, 2021 | 219 | 2021 |
Peter TompaPofessor of biochemistry, VIB SBRC, Brussels確認したメール アドレス: vub.ac.be
