Thermotolerance requires refolding of aggregated proteins by substrate translocation through the central pore of ClpB J Weibezahn, P Tessarz, C Schlieker, R Zahn, Z Maglica, S Lee, ... Cell 119 (5), 653-665, 2004 | 536 | 2004 |
Global unfolding of a substrate protein by the Hsp100 chaperone ClpA EU Weber-Ban, BG Reid, AD Miranker, AL Horwich Nature 401 (6748), 90-93, 1999 | 520 | 1999 |
Structural basis of enzyme encapsulation into a bacterial nanocompartment M Sutter, D Boehringer, S Gutmann, S Günther, D Prangishvili, ... Nature structural & molecular biology 15 (9), 939-947, 2008 | 444 | 2008 |
Protein post-translational modifications in bacteria B Macek, K Forchhammer, J Hardouin, E Weber-Ban, C Grangeasse, ... Nature Reviews Microbiology 17 (11), 651-664, 2019 | 290 | 2019 |
Chaperone rings in protein folding and degradation AL Horwich, EU Weber-Ban, D Finley Proceedings of the National Academy of Sciences 96 (20), 11033-11040, 1999 | 260 | 1999 |
Bacterial ubiquitin-like modifier Pup is deamidated and conjugated to substrates by distinct but homologous enzymes F Striebel, F Imkamp, M Sutter, M Steiner, A Mamedov, E Weber-Ban Nature structural & molecular biology 16 (6), 647-651, 2009 | 219 | 2009 |
ClpA mediates directional translocation of substrate proteins into the ClpP protease BG Reid, WA Fenton, AL Horwich, EU Weber-Ban Proceedings of the National Academy of Sciences 98 (7), 3768-3772, 2001 | 189 | 2001 |
Clp chaperone–proteases: structure and function W Kress, Ž Maglica, E Weber-Ban Research in microbiology 160 (9), 618-628, 2009 | 154 | 2009 |
Targeted delivery of an ssrA-tagged substrate by the adaptor protein SspB to its cognate AAA+ protein ClpX DA Dougan, E Weber-Ban, B Bukau Molecular cell 12 (2), 373-380, 2003 | 150 | 2003 |
Pilus chaperones represent a new type of protein-folding catalyst M Vetsch, C Puorger, T Spirig, U Grauschopf, EU Weber-Ban, ... Nature 431 (7006), 329-333, 2004 | 149 | 2004 |
Controlled destruction: AAA+ ATPases in protein degradation from bacteria to eukaryotes F Striebel, W Kress, E Weber-Ban Current opinion in structural biology 19 (2), 209-217, 2009 | 145 | 2009 |
The mycobacterial Mpa–proteasome unfolds and degrades pupylated substrates by engaging Pup's N‐terminus F Striebel, M Hunkeler, H Summer, E Weber‐Ban The EMBO journal 29 (7), 1262-1271, 2010 | 135 | 2010 |
Protein architecture, dynamics and allostery in tryptophan synthase channeling P Pan, E Woehl, MF Dunn Trends in biochemical sciences 22 (1), 22-27, 1997 | 134 | 1997 |
Role of the proximal ligand in peroxidase catalysis. Crystallographic, kinetic, and spectral studies of cytochrome c peroxidase proximal ligand mutants. K Choudhury, M Sundaramoorthy, A Hickman, T Yonetani, E Woehl, ... Journal of Biological Chemistry 269 (32), 20239-20249, 1994 | 123 | 1994 |
Dop functions as a depupylase in the prokaryotic ubiquitin‐like modification pathway F Imkamp, F Striebel, M Sutter, D Özcelik, N Zimmermann, P Sander, ... EMBO reports 11 (10), 791-797, 2010 | 102 | 2010 |
A distinct structural region of the prokaryotic ubiquitin-like protein (Pup) is recognized by the N-terminal domain of the proteasomal ATPase Mpa M Sutter, F Striebel, FF Damberger, FHT Allain, E Weber-Ban FEBS letters 583 (19), 3151-3157, 2009 | 102 | 2009 |
Mycobacterial ubiquitin-like protein ligase PafA follows a two-step reaction pathway with a phosphorylated pup intermediate E Guth, M Thommen, E Weber-Ban Journal of Biological Chemistry 286 (6), 4412-4419, 2011 | 96 | 2011 |
Monovalent metal ions play an essential role in catalysis and intersubunit communication in the tryptophan synthase bienzyme complex EU Woehl, MF Dunn Biochemistry 34 (29), 9466-9476, 1995 | 84 | 1995 |
Pupylation as a signal for proteasomal degradation in bacteria F Striebel, F Imkamp, D Özcelik, E Weber-Ban Biochimica et Biophysica Acta (BBA)-Molecular Cell Research 1843 (1), 103-113, 2014 | 82 | 2014 |
Deletion of dop in Mycobacterium smegmatis abolishes pupylation of protein substrates in vivo F Imkamp, T Rosenberger, F Striebel, PM Keller, B Amstutz, P Sander, ... Molecular microbiology 75 (3), 744-754, 2010 | 79 | 2010 |