Your search keyword '"Arnaud Baslé"' showing total 3 results

1. Visualizing Biological Copper Storage: The Importance of Thiolate-Coordinated Tetranuclear Clusters

Author

Semeli Platsaki, Christopher Dennison, and Arnaud Baslé

Subjects

0301 basic medicine, chemistry.chemical_classification, Metal ions in aqueous solution, chemistry.chemical_element, General Medicine, Crystal structure, 010402 general chemistry, 01 natural sciences, Copper, 0104 chemical sciences, 03 medical and health sciences, Cytosol, Crystallography, 030104 developmental biology, chemistry, Storage protein, Reactivity (chemistry)

Abstract

Bacteria possess cytosolic proteins (Csp3s) capable of binding large quantities of copper and preventing toxicity. Crystal structures of a Csp3 plus increasing amounts of Cu(I) provide atomic-level information about how a storage protein loads with metal ions. Many more sites are occupied than Cu(I) equivalents added, with binding by twelve central sites dominating. These initially form three [Cu4(S-Cys)4] intermediates leading to [Cu4(S-Cys)5]-, [Cu4(S-Cys)6]2-, and [Cu4(S-Cys)5(O-Asn)]- clusters. Construction of the five Cu(I) sites at the opening of the bundle lags behind the main core, and the two least accessible sites are occupied last. Facile Cu(I)-cluster formation, reminiscent of that for inorganic complexes with organothiolate ligands, is largely avoided in biology but is used by proteins that store copper in the cytosol of prokaryotes and eukaryotes, where this reactivity is also key to toxicity.

Published

2017

2. Disulfide bond tethering of extracellular loops does not affect the closure of OmpF porin at acidic pH

Author

Arnaud Baslé, Anne H. Delcour, and Beau Wager

Subjects

Models, Molecular, Conformational change, Protein Conformation, Escherichia coli Proteins, Mutant, Porins, Hydrogen-Ion Concentration, Microscopy, Atomic Force, Biochemistry, chemistry.chemical_compound, Crystallography, Protein structure, Monomer, chemistry, Structural Biology, Mutation, Porin, Escherichia coli, Extracellular, Biophysics, Disulfides, Bacterial outer membrane, Acids, Molecular Biology, Cysteine

Abstract

The permeability of the outer membrane of gram-negative bacteria is essentially controlled by pore-forming proteins of the porin family. The trimeric E. coli porin OmpF is assembled as a triple β-barrel, where each monomer contains a central pore and extracellular loops. Electrophysiological analysis of the behavior of OmpF at acidic pH reveals that the protein undergoes a conformational change leading to the sequential step-wise closure of the three monomers. A previous atomic force microscopy study suggested that the conformational change might be due to a bending of extracellular loops over the pore opening, and loop deletion experiments suggested that loops L1, L7, and L8 are involved. In order to test the hypothesis for loop movement, we engineered a series of double cysteine mutants in loops L1, L6, L7 and L8 in order to create disulfide bonds linking two loops to each other, or the two branches of a loop, or a loop to the β-barrel. Five out of the six mutants showed the formation of the disulfide bond. However, none of these had an altered response to acidic pH relative to the wildtype channel. Although we cannot dismiss the possibility that the mobility restriction introduced by each disulfide bond was too localized to impact a more global conformational change of the three loops, the fact that all of the different types of disulfide bond tethering were similarly ineffective suggests that the extracellular loops L1, L7, and L8 may not undergo a major acidic-pH induced conformational change leading to channel closure.

Published

2010

3. A new mechanism of antibiotic resistance in Enterobacteriaceae induced by a structural modification of the major porin

Author

Monique Malléa, Emmanuelle Dé, Michel Jaquinod, Nathalie Saint, Jean-Marie Pagès, Gérard Molle, and Arnaud Baslé

Subjects

Strain (chemistry), biology, Wild type, biochemical phenomena, metabolism, and nutrition, Enterobacter aerogenes, biology.organism_classification, Microbiology, Enterobacteriaceae, Multiple drug resistance, Biochemistry, Porin, bacteria, Lipid bilayer, Bacterial outer membrane, Molecular Biology

Abstract

In Enterobacter aerogenes, multidrug resistance involves a decrease in outer membrane permeability associated with changes in an as yet uncharacterized porin. We purified the major porin from the wild-type strain and a resistant strain. We characterized this porin, which was found to be an OmpC/OmpF-like protein and analysed its pore-forming properties in lipid bilayers. The porin from the resistant strain was compared with the wild-type protein and we observed (i) that its single-channel conductance was 70% lower than that of the wild type; (ii) that it was three times more selective for cations; (iii) a lack of voltage sensitivity. These results indicate that the clinical strain is able to synthesize a modified porin that decreases the permeability of the outer membrane. Mass spectrometry experiments identified a G to D mutation in the putative loop 3 of the porin. Given the known importance of this loop in determining the pore properties of porins, we suggest that this mutation is responsible for the novel resistance mechanism developed by this clinical strain, with changes in porin channel function acting as a new bacterial strategy for controlling β-lactam diffusion via porins.

Published

2001