  Information literacy in the context of Evidence-Based Medicine: teaching and learning assessment of a course intended for 4th year students in medicine at the University of Liège (Belgium)Durieux, Nancy  ; De Lemos Esteves, Frédéric ; Pasleau, Françoise Conference (2012, July 06) Detailed reference viewed: 22 (7 ULg) Analysis of Root Secreted Proteases in Arabidopsis thaliana and Nicotiana tabacumDésiron, Carole ; De Lemos Esteves, Frédéric ; et alPoster (2011, June 09) Plants are promising tools to produce complex recombinant proteins like antibodies. When host plants are grown on hydroponics, the production of recombinant proteins that are secreted by the roots ... [more ▼] Plants are promising tools to produce complex recombinant proteins like antibodies. When host plants are grown on hydroponics, the production of recombinant proteins that are secreted by the roots ('rhizosecretion') greatly simplifies harvest and purification of the product, during whole plant life. However, proteases represent up to 10% of the naturally secreted proteins and are known to significantly decrease the yield of production by rhizosecretion. In this study, we analyzed the rhizosecreted proteases of Arabidopsis thaliana and Nicotiana tabacum. Total rhizosecreted proteins were recovered by salt extraction and the protease activity was assayed in vitro or by zymography. The relative contribution of major protease families to total activity was evaluated with specific inhibitors and revealed significant differences between the two species. The degradation capacity of the root-secreted proteases was further characterized against selected target proteins: BSA and human IgGs. [less ▲] Detailed reference viewed: 57 (24 ULg)Improving the alkalophilic performances of the Xyl1 xylanase from Streptomyces sp S38: Structural comparison and mutational analysisDe Lemos Esteves, Frédéric ; ; et alin Protein Science : A Publication of the Protein Society (2005), 14(2), 292-302 Endo-beta-1,4-xylanases of the family 11 glycosyl-hydrolases are catalytically active over a wide range of pH. Xyl1 from Streptomyces sp. S38 belongs to this family, and its optimum pH for enzymatic ... [more ▼] Endo-beta-1,4-xylanases of the family 11 glycosyl-hydrolases are catalytically active over a wide range of pH. Xyl1 from Streptomyces sp. S38 belongs to this family, and its optimum pH for enzymatic activity is 6. Xyn11 from Bacillus agaradhaerens and XylJ from Bacillus sp. 41M-1 share 85% sequence identity and have been described as highly alkalophilic enzymes. In an attempt to better understand the alkalophilic adaptation of xylanases, the three-dimensional structures of Xyn11 and Xyl1 were compared. This comparison highlighted an increased number of salt-bridges and the presence of more charged residues in the catalytic cleft as well as an eight-residue-longer loop in the alkalophilic xylanase Xyn11. Some of these charges were introduced in the structure of Xyl1 by site-directed mutagenesis with substitutions Y16D, S18E, G50R, N92D, A135Q, E139K, and Y186E. Furthermore, the eight additional loop residues of Xyn11 were introduced in the homologous loop of Xyl1. In addition, the coding sequence of the XylJ catalytic domain was synthesized by recursive PCR, expressed in a Streptomyces host, purified, and characterized together with the Xyl1 mutants. The Y186E substitution inactivated Xyl1, but the activity was restored when this mutation was combined with the G50R or S18E substitutions. Interestingly, the E139K mutation raised the optimum pH of Xyl1 from 6 to 7.5 but had no effect when combined with the N92D substitution. Modeling studies identified the possible formation of an interaction between the introduced lysine and the substrate, which could be eliminated by the formation of a putative salt-bridge in the N92D/E139K mutant. [less ▲] Detailed reference viewed: 35 (10 ULg)Acidophilic adaptation of family 11 endo--1,4-xylanases: Modeling and mutational analysisDe Lemos Esteves, Frédéric ; ; Lamotte-Brasseur, Josette et alin Protein Science : A Publication of the Protein Society (2004), 13(5), 12091218 Xyl1 from Streptomyces sp. S38 belongs to the low molecular mass family 11 of endo--1,4-xylanases. Its three-dimensional structure has been solved at 2.0 Å and its optimum temperature and pH for enzymatic ... [more ▼] Xyl1 from Streptomyces sp. S38 belongs to the low molecular mass family 11 of endo--1,4-xylanases. Its three-dimensional structure has been solved at 2.0 Å and its optimum temperature and pH for enzymatic activity are 60°C and 6.0, respectively. Aspergillus kawachii xylanase XynC belongs to the same family but is an acidophilic enzyme with an optimum pH of 2.0. Structural comparison of Xyl1 and XynC showed differences in residues surrounding the two glutamic acid side chains involved in the catalysis that could be responsible for the acidophilic adaptation of XynC. Mutations W20Y, N48D, A134E, and Y193W were introduced by site-directed mutagenesis and combined in multiple mutants. Trp 20 and Tyr 193 are involved in substrate binding. The Y193W mutation inactivated Xyl1 whereas W20Y decreased the optimum pH of Xyl1 to 5.0 and slightly increased its specific activity. The N48D mutation also decreased the optimum pH of Xyl1 by one unit. The A134E substitution did not induce any change, but when combined with N48D, a synergistic effect was observed with a 1.4 unit decrease in the optimum pH. Modeling showed that the orientations of residue 193 and of the fully conserved Arg 131 are different in acidophilic and alkaline xylanases whereas the introduced Tyr 20 probably modifies the pKa of the acid-base catalyst via residue Asn 48. Docking of a substrate analog in the catalytic site highlighted striking differences between Xyl1 and XynC in substrate binding. Hydrophobicity calculations showed a correlation between acidophilic adaptation and a decreased hydrophobicity around the two glutamic acid side chains involved in catalysis. [less ▲] Detailed reference viewed: 13 (1 ULg)An Additional Aromatic Interaction Improves the Thermostability and Thermophilicity of a Mesophilic Family 11 Xylanase: Structural Basis and Molecular Study; De Lemos Esteves, Frédéric ; et alin Protein Science : A Publication of the Protein Society (2000), 9(3), 466-75 In a general approach to the understanding of protein adaptation to high temperature, molecular models of the closely related mesophilic Streptomyces sp. S38 Xyl1 and thermophilic Thermomonospora fusca ... [more ▼] In a general approach to the understanding of protein adaptation to high temperature, molecular models of the closely related mesophilic Streptomyces sp. S38 Xyl1 and thermophilic Thermomonospora fusca TfxA family 11 xylanases were built and compared with the three-dimensional (3D) structures of homologous enzymes. Some of the structural features identified as potential contributors to the higher thermostability of TfxA were introduced in Xyl1 by site-directed mutagenesis in an attempt to improve its thermostability and thermophilicity. A new Y11-Y16 aromatic interaction, similar to that present in TfxA and created in Xyl1 by the T11Y mutation, improved both the thermophilicity and thermostability. Indeed, the optimum activity temperature (70 vs. 60 degrees C) and the apparent Tm were increased by about 9 degrees C, and the mutant was sixfold more stable at 57 degrees C. The combined mutations A82R/F168H/N169D/delta170 potentially creating a R82-D169 salt bridge homologous to that present in TfxA improved the thermostability but not the thermophilicity. Mutations R82/D170 and S33P seemed to be slightly destabilizing and devoid of influence on the optimal activity temperature of Xyl1. Structural analysis revealed that residues Y11 and Y16 were located on beta-strands B1 and B2, respectively. This interaction should increase the stability of the N-terminal part of Xyl1. Moreover, Y11 and Y16 seem to form an aromatic continuum with five other residues forming putative subsites involved in the binding of xylan (+3, +2, +1, -1, -2). Y11 and Y16 might represent two additional binding subsites (-3, -4) and the T11Y mutation could thus improve substrate binding to the enzyme at higher temperature and thus the thermophilicity of Xyl1. [less ▲] Detailed reference viewed: 8 (3 ULg) |
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