Novel methodologies in native mass spectrometry and ion mobility for structural characterization of macrobiomolecules and their related complexes

Ce travail de thèse porte sur le développement de méthodes en spectrométrie de masse (MS) et mobilité ionique (IM-MS) supramoléculaires pour la caractérisation fine de complexes protéine-ligand et d’assemblages protéiques hétérogènes de hauts poids moléculaires. L’optimisation instrumentale apportée à l’étude de ces systèmes, permet d’étendre le potentiel de ces deux approches en biologie structurale. Le criblage de complexes protéine-ligand permet ici une détermination de leurs propriétés d’interaction et la mise en évidence de subtils changements de conformation induits, pouvant être suivis au cours du temps. L’application de ce couplage à l’analyse de complexes multi-protéiques, réfractaires aux techniques conventionnelles, donne accès à la topologie de ces assemblages, facilitant la proposition de modèles structuraux. Enfin, l’apport récent de la haute résolution en MS native est ici illustré à travers l’étude de protéines complexes et hétérogènes : les anticorps thérapeutiques et leurs conjugués. Ces développements permettent de repousser certaines limites en MS native et IM-MS native, élargissant leurs perspectives d’application dans la recherche et l’industrie pharmaceutique.This PhD thesis aims at developing methods in native mass spectrometry (MS) combined with ion mobility (IM-MS) to characterize protein-ligand complexes and large protein assemblies. Fine-tuning of instrumental settings allowed expanding the scope of these approaches in structural biology. Real-time monitoring of protein-ligand complexes by native MS and IM-MS enabled to screen their binding properties while depicting subtle conformational changes induced upon binding. Applying these methods to refractory multi-protein complexes provided insights about their topology, making structural modeling easier. Finally, benefits from high-resolution native MS were highlighted through the characterization of heterogeneous systems, including monoclonal antibodies and their drug conjugates. Here, these developments enable to push some technical limits one step forward, increasing the potential of native MS and IM-MS both in academic research and pharmaceutical industry

Novel methodologies in native mass spectrometry and ion mobility for structural characterization of macrobiomolecules and their related complexes

Ce travail de thèse porte sur le développement de méthodes en spectrométrie de masse (MS) et mobilité ionique (IM-MS) supramoléculaires pour la caractérisation fine de complexes protéine-ligand et d’assemblages protéiques hétérogènes de hauts poids moléculaires. L’optimisation instrumentale apportée à l’étude de ces systèmes, permet d’étendre le potentiel de ces deux approches en biologie structurale. Le criblage de complexes protéine-ligand permet ici une détermination de leurs propriétés d’interaction et la mise en évidence de subtils changements de conformation induits, pouvant être suivis au cours du temps. L’application de ce couplage à l’analyse de complexes multi-protéiques, réfractaires aux techniques conventionnelles, donne accès à la topologie de ces assemblages, facilitant la proposition de modèles structuraux. Enfin, l’apport récent de la haute résolution en MS native est ici illustré à travers l’étude de protéines complexes et hétérogènes : les anticorps thérapeutiques et leurs conjugués. Ces développements permettent de repousser certaines limites en MS native et IM-MS native, élargissant leurs perspectives d’application dans la recherche et l’industrie pharmaceutique.This PhD thesis aims at developing methods in native mass spectrometry (MS) combined with ion mobility (IM-MS) to characterize protein-ligand complexes and large protein assemblies. Fine-tuning of instrumental settings allowed expanding the scope of these approaches in structural biology. Real-time monitoring of protein-ligand complexes by native MS and IM-MS enabled to screen their binding properties while depicting subtle conformational changes induced upon binding. Applying these methods to refractory multi-protein complexes provided insights about their topology, making structural modeling easier. Finally, benefits from high-resolution native MS were highlighted through the characterization of heterogeneous systems, including monoclonal antibodies and their drug conjugates. Here, these developments enable to push some technical limits one step forward, increasing the potential of native MS and IM-MS both in academic research and pharmaceutical industry

Nouvelles méthodologies en spectrométrie de masse native et mobilité ionique pour la caractérisation structurale de macrobiomolécules et de leurs complexes associés

This PhD thesis aims at developing methods in native mass spectrometry (MS) combined with ion mobility (IM-MS) to characterize protein-ligand complexes and large protein assemblies. Fine-tuning of instrumental settings allowed expanding the scope of these approaches in structural biology. Real-time monitoring of protein-ligand complexes by native MS and IM-MS enabled to screen their binding properties while depicting subtle conformational changes induced upon binding. Applying these methods to refractory multi-protein complexes provided insights about their topology, making structural modeling easier. Finally, benefits from high-resolution native MS were highlighted through the characterization of heterogeneous systems, including monoclonal antibodies and their drug conjugates. Here, these developments enable to push some technical limits one step forward, increasing the potential of native MS and IM-MS both in academic research and pharmaceutical industry.Ce travail de thèse porte sur le développement de méthodes en spectrométrie de masse (MS) et mobilité ionique (IM-MS) supramoléculaires pour la caractérisation fine de complexes protéine-ligand et d’assemblages protéiques hétérogènes de hauts poids moléculaires. L’optimisation instrumentale apportée à l’étude de ces systèmes, permet d’étendre le potentiel de ces deux approches en biologie structurale. Le criblage de complexes protéine-ligand permet ici une détermination de leurs propriétés d’interaction et la mise en évidence de subtils changements de conformation induits, pouvant être suivis au cours du temps. L’application de ce couplage à l’analyse de complexes multi-protéiques, réfractaires aux techniques conventionnelles, donne accès à la topologie de ces assemblages, facilitant la proposition de modèles structuraux. Enfin, l’apport récent de la haute résolution en MS native est ici illustré à travers l’étude de protéines complexes et hétérogènes : les anticorps thérapeutiques et leurs conjugués. Ces développements permettent de repousser certaines limites en MS native et IM-MS native, élargissant leurs perspectives d’application dans la recherche et l’industrie pharmaceutique

Measuring the NQO2: Melatonin Complex by Native Nano-Electrospray Ionization Mass Spectrometry

International audienceMelatonin exerts its effects through a series of target proteins/receptors and enzymes. Its antioxidant capacity might be due to its capacity to inhibit a quinone reductase (NQO2) at high concentration (50 µM). Demonstrating the existence of a complex between a compound and a protein is often not easy. It requires either that the compound is an inhibitor-and the complex translates by an inhibition of the catalytic activity-or the compound is radiolabeled-and the complex translates in standard binding approaches, such as in receptology. Outside these two cases, the detection of the protein:small molecule complexes by mass spectrometry has recently been made possible, thanks to the development of so called native mass spectrometry. Using this approach one can measure masses corresponding to a intact noncovalent complex between a compound and its target, usually after titration or competition experiments. In the present chapter, we detail the characterization of NQO2:melatonin interaction using native mass spectrometry

Redox regulation : insights into the interaction mechanism of sulfiredoxin with peroxiredoxin and ATP

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Ion mobility coupled to native mass spectrometry as a relevant tool to investigate extremely small ligand-induced conformational changes

International audienceWe evaluate the potential of native mass spectrometry (MS) and ion mobility (IM-MS) for the screening of protein : ligand complexes when very subtle conformational changes are involved. As a proof of concept, we investigate the interactions between a peptide deformylase (PDF1B), a promising target for the development of new antibiotics, and three of its specific inhibitors that bind in different modes. First, real-time native MS reveals two types of ligands, both interacting in a 1 : 1 stoichiometry with PDF1B but with different affinities and gas phase stabilities. Conformational IM-MS screening then highlights two very close but significantly distinct ligand-induced conformations with collision cross sections that differ by less than 1%. Real-time IM-MS is used to monitor not only the dynamics of ligand binding to apoPDF1B but also the switching between holo conformations. This study provides additional evidence that the most potent ligands inhibit peptide deformylases through a slow-tight binding mechanism, in agreement with previous structural and enzymology studies. Furthermore, this approach, wherein the characteristics obtained by native MS are combined with IM-MS conformational screening, prove valuable in characterizing extremely subtle dynamic conformational changes induced when ligands bind to protein assemblies. We discuss the promise and limitations of IM-MS in the context of detection of very small conformational changes induced upon ligand binding

VHH characterization.Recombinant VHHs: Production, characterization and affinity

International audienceAmong the biological approaches to therapeutics, are the cells, such as CAR-T cells engineered or not, the antibodies armed or not, and the smaller protein scaffolds that can be modified to render them specific of other proteins, à la façon of antibodies. For several years, we explored ways to substitute antibodies by nanobodies (also known as VHHs), the smallest recognizing part of camelids’ heavy-chain antibodies: production of those small proteins in host microorganisms, minute analyses, characterization, and qualification of their affinity towards designed targets. Here, we present three standard VHHs described in the literature: anti-albumin, anti-EGF receptor and anti-HER2, a typical cancer cell surface -associated protein. Because they differ slightly in global structure, they are good models to assess our body of analytical methodologies. The VHHs were expressed in several bacteria strains in order to identify and overcome the bottlenecks to obtain homogeneous preparations of this protein. A large panel of biophysical tools, ranging from spectroscopy to mass spectrometry, was here combined to assess VHH structural features and the impact of the disulfide bond. The routes are now ready to move to more complex VHHs raised against specific targets in numerous areas including oncology

Interdomain electron transfer in cellobiose dehydrogenase is governed by surface electrostatics

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Soaking suggests "alternative facts": Only cocrystallization discloses major ligand-induced interface rearrangements of a homodimeric tRNA-binding protein indicating a novel mode-of-inhibition

For the efficient pathogenesis of Shigella, the causative agent of bacillary dysentery, full functionality of tRNA-guanine transglycosylase (TGT) is mandatory. TGT performs post-transcriptional modifications of tRNAs in the anticodon loop taking impact on virulence development. This suggests TGT as a putative target for selective anti-shigellosis drug therapy. Since bacterial TGT is only functional as homodimer, its activity can be inhibited either by blocking its active site or by preventing dimerization. Recently, we discovered that in some crystal structures obtained by soaking the full conformational adaptation most likely induced in solution upon ligand binding is not displayed. Thus, soaked structures may be misleading and suggest irrelevant binding modes. Accordingly, we re-investigated these complexes by co-crystallization. The obtained structures revealed large conformational rearrangements not visible in the soaked complexes. They result from spatial perturbations in the ribose-34/phosphate-35 recognition pocket and, consequently, an extended loop-helix motif required to prevent access of water molecules into the dimer interface loses its geometric integrity. Thermodynamic profiles of ligand binding in solution indicate favorable entropic contributions to complex formation when large conformational adaptations in the dimer interface are involved. Native MS titration experiments reveal the extent to which the homodimer is destabilized in the presence of each inhibitor. Unexpectedly, one ligand causes a complete rearrangement of subunit packing within the homodimer, never observed in any other TGT crystal structure before. Likely, this novel twisted dimer is catalytically inactive and, therefore, suggests that stabilizing this non-productive subunit arrangement may be used as a further strategy for TGT inhibition.ISSN:1932-620

Biochemistry, structure, and cellular internalization of a four nanobody-bearing Fc dimer

International audienceVHH stands for the variable regions of heavy chain only of camelid IgGs. The VHH family forms a set of interesting proteins derived from antibodies that maintain their capacity to recognize the antigen, despite their relatively small molecular weight (in the 12,000 Da range). Continuing our exploration of the possibilities of those molecules, we chose to design alternative molecules with maintained antigen recognition, but enhanced capacity, by fusing four VHH with one Fc, the fragment crystallizable region of antibodies. In doing so, we aimed at having a molecule with superior quantitative antigen recognition (×4) while maintaining its size below the 110 kDa. In the present paper, we described the building of those molecules that we coined VHH2-Fc-VHH2. The structure of VHH2-Fc-VHH2 in complex with HER2 antigen was determined using electronic microscopy and modeling. The molecule is shown to bind four HER2 proteins at the end of its flexible arms. VHH2-Fc-VHH2 also shows an internalization capacity via HER2 receptor superior to the reference anti-HER2 monoclonal antibody, Herceptin®, and to a simple fusion of two VHH with one Fc (VHH2-Fc). This new type of molecules, VHH2-Fc-VHH2, could be an interesting addition to the therapeutic arsenal with multiple applications, from diagnostic to therapy