T. Ballet scite author profile

T. Ballet

3Publications

72Citation Statements Received

193Citation Statements Given

How they've been cited

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211

187

Affiliations

Grenoble Institute of Technology, Grenoble Alpes University

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Protein conformational changes induced by adsorption onto material surfaces: an important issue for biomedical applications of material science

Ballet¹,

Boulangé²,

Bréchet³

et al. 2010

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Abstract. Protein adsorption on solid surfaces is a widespread phenomenon of large biological and biotechnological significance. Conformational changes are likely to accompany protein adsorption, but are difficult to evidence directly. Nevertheless they have important consequences, since the partial unfolding of protein domains can expose hitherto hidden amino acids. This remodeling of the protein surface can trigger the activation of molecular complexes such as the blood coagulation cascade or the innate immune complement system. In the case of extracellular matrix, it can also change the way cells interact with the material surfaces and result in modified cell behavior. In this review, we present direct and indirect evidences that support the view that some proteins change their conformation upon adsorption. We also show that both physical and chemical methods are needed to study the extent and kinetics of protein conformational changes. In particular, AFM techniques and cryo-electron microscopy provide useful and complementary information. We then review the chemical and topological features of both proteins and material surfaces in relation with protein adsorption. Mutating key amino acids in proteins changes their stability and this is related to material-induced conformational changes, as shown for instance with insulin. In addition, combinatorial methods should provide valuable information about peptide or antibody adsorption on well-defined material surfaces. These techniques could be combined with molecular modeling methods to decipher the rules governing conformational changes associated with protein adsorption.

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DnaK Prevents Human Insulin Amyloid Fiber Formation on Hydrophobic Surfaces

et al. 2012

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We have developed a multiwell-based protein aggregation assay to study the kinetics of insulin adsorption and aggregation on hydrophobic surfaces and to investigate the molecular mechanisms involved. Protein-surface interaction progresses in two phases: (1) a lag phase during which proteins adsorb and prefibrillar aggregates form on the material surface and (2) a growth phase during which amyloid fibers form and then are progressively released into solution. We studied the effect of three bacterial chaperones, DnaK, DnaJ, and ClpB, on insulin aggregation kinetics. In the presence of ATP, the simultaneous presence of DnaK, DnaJ, and ClpB allows good protection of insulin against aggregation. In the absence of ATP, DnaK alone is able to prevent insulin aggregation. Furthermore, DnaK binds to insulin adsorbed on hydrophobic surfaces. This process is slowed in the presence of ATP and can be enhanced by the cochaperone DnaJ. The peptide LVEALYL, derived from the insulin B chain, is known to promote fast aggregation in a concentration- and pH-dependent manner in solution. We show that it also shortens the lag phase for insulin aggregation on hydrophobic surfaces. As this peptide is also a known DnaK substrate, our data indicate that the peptide and the chaperone might compete for a common site during the process of insulin aggregation on hydrophobic surfaces.

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Photocatalytic generation of silver nanoparticles and application to the antibacterial functionalization of textile fabrics

Messaoud

Chadeau

Brunon³

et al. 2010

Journal of Photochemistry and Photobiology A: Chemistry

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T. Ballet

Protein conformational changes induced by adsorption onto material surfaces: an important issue for biomedical applications of material science

DnaK Prevents Human Insulin Amyloid Fiber Formation on Hydrophobic Surfaces

Photocatalytic generation of silver nanoparticles and application to the antibacterial functionalization of textile fabrics

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