Nanoparticules dérivées de virus de plante pour le traitement et l'imagerie du cancer / Plant virus-derived nanoparticles for the imaging and treatment of cancer

Gamper, Coralie

23 September 2019

Les possibilités de combinaison thérapeutiques offertes par les nanoparticules ont ouvert un nouveau champ d’investigation pour la recherche sur le cancer. Dans ce projet de recherche, des nanoparticules dérivées de la protéine de capside du virus de la mosaïque du tabac (TMV) ont été utilisées afin de transporter différents peptides thérapeutiques ciblant le récepteur neuropiline-1. Cette stratégie a permis de solubiliser un peptide fortement hydrophobe ayant préalablement démontré son efficacité anticancéreuse sur des lignées de cancer du sein humain et de glioblastome. Les résultats obtenus ont également permis de démontrer la possibilité de combiner différents peptides thérapeutiques via l’auto-assemblage de la protéine de capside du TMV. / Nanoparticles play an ever increase role in carrying therapeutic compounds in the cancer field. In this research project, the coat protein of Tobacco mosaic virus (TMV) was used as nanocarrier to solubilize a hydrophobic peptide interfering with the transmembrane domain of neuropilin-1. The nanoparticles created have conserved the antiangiogenic and antimigratory effect of the therapeutic peptide. This strategy was also used to create nanoparticles carrying a peptide targeting the ectodomain of neuropilin-1. The two types of nanoparticles were then assembled through auto-assembling ability of the coat protein. These nanoparticles also exhibit antiangiogenic ability thus, confirming the validity of this approach to combine therapeutic peptides.

Nanoparticule

Neuropiline-1

Cancer du sein

Peptide

TMV

Therapeutic peptides

Nanoparticles

Targeted therapy

Neuropilin-1

Breast cancer

TMV

Theranostic

572.8

579.2

616.99

FIBRILLATION OF THERAPEUTIC PEPTIDES

Harshil K Renawala (12456981)

25 April 2022

<p>Therapeutic peptides have become a clinically and commercially important drug class providing novel treatment options in variety of disease areas. Today, more than 80 peptide drugs are marketed worldwide and hundreds more are in development. However, the development of peptide drugs can be hindered by their tendency to self-associate to form fibrils, an impurity that can affect potency and increase the potential for adverse immune responses in patients. Fibrillation of therapeutic peptides can present significant quality concerns and poses challenges for manufacturing and storage. From a pharmaceutical development perspective, early detection of instabilities can inform the development of mitigation strategies to minimize the risk of product failure and avoid costly delays in clinical development. A fundamental understanding of the mechanisms of fibrillation is critical for the rational design of fibrillation-resistant peptide drugs and formulations.</p> <p>The objective of this dissertation was to develop structurally modified fibrillation-resistant peptides based on a mechanistic understanding of the fibrillation process. The therapeutic peptides studied were human calcitonin (hCT), a glucagon/GLP-1 analog, and human insulin B-chain (INSB). Pulsed hydrogen-deuterium exchange mass spectrometry (HDX-MS) and other biophysical methods were used to provide mechanistic understanding of the intermolecular interactions and structural transitions during peptide fibrillation. Coupled with proteolytic digestion, pulsed HDX-MS of fibrillating peptides enabled identification of the residues involved in the early interactions leading to fibrillation based on their differential deuterium exchange rates. The high-resolution residue level information was used to make site-specific modifications to hCT, with phosphorylation in the central region resulting in complete inhibition of fibrillation for the phospho-Thr-13 hCT analog under the stress conditions employed. Reversible ‘prodrug’ modifications such as phosphorylation can aid the rational design of fibrillation-resistant therapeutic peptides. Furthermore, the effects of structural modifications on peptide fibrillation were evaluated by reducing the Cys1-Cys7 disulfide bond in hCT, and by C-terminal amidation or substitution with a helix-stabilizing residue (α-aminoisobutyric acid, Aib) in the glucagon/GLP-1 analog peptide. Finally, studies of insulin B-chain probed fibrillation mechanisms of this therapeutically important peptide, contributing to our understanding of the mechanisms of insulin fibrillation with the broad goal of developing fibrillation-resistant, rapid-acting, monomeric insulin analogs. Overall, the results demonstrate that small structural changes can have significant effects on peptide fibrillation, that pulsed HDX-MS can be used to probe these effects, and that an understanding of these effects can inform the rational development of fibrillation-resistant peptide drugs. </p>

Pharmaceutical Sciences

fibrillation

Therapeutic Peptides

insulin

calcitonin

Glucagon-like peptide-1 analogues

thioflavin T fluorescence

Peptide Prodrugs

Etude de la réponse des lymphocytes T spécifiques de l’hormone humaine H2-relaxine et de modifications non-naturelles : perspectives pour la réduction de l’immunogénicité des protéines et peptides thérapeutiques / Study of the response of human hormone H2-relaxin-specific T-cells and non-natural modifications : perspectives for the reduction of the immunogenicity of therapeutic proteins and peptides

Azam, Aurélien

14 June 2018

Ce projet a accompagné le développement pré-clinique de l'hormone humaine Relaxine-2 (Rln2) ayant induit des anticorps durant des essais cliniques, il est axée autour de 2 problématiques : (1) comprendre son immunogénicité, (2) étudier l’impact de modifications chimiques sur l’immunogénicité afin d'augmenter sa stabilité.Compte tenu du rôle des lymphocytes T CD4 dans les réponses immunitaires, la fréquence de cellules T spécifiques de la Rln2 dans un large panel de donneurs sains a été estimée et a permis d’expliquer le développement d’anticorps anti-Rln2. La cartographie des épitopes T a ensuite identifié les zones portant son immunogénicité. Puis, 6 modifications chimiques (acide aminé D, acide aminé isobutyrique, peptoïde, N-méthylation, C-méthylation et réduction de la liaison peptidique) utilisées pour augmenter la demi-vie ont été introduites à la plupart des positions d’un peptide hautement immunogène. La reconnaissance par des cellules T, la liaison aux molécules de présentation et la capacité à induire des lymphocytes T CD4 ont été étudiées pour les peptides analogues modifiés. La plupart des modifications se sont révélées être très efficaces pour minimiser les propriétés immunogéniques.Ce projet de thèse se situe donc à la croisée des chemins entre l’acquisition de connaissances nouvelles en immunologie et leur application dans des processus de conception et de gestion des risques de peptides thérapeutiques. / This project has accompanied the pre-clinical development of the human hormone Relaxin-2 (Rln2) that induced antibodies during clinical trials, it focuses on two issues: (1) to understand its immunogenicity, (2) to study the impact of unnatural modifications on immunogenicity to increase its stability.Given the role of CD4 T-cells in immune responses, the frequency of Rln2-specific T-cells in a large panel of healthy donors was estimated, and explained the development of anti-Rln2 antibodies. The T epitope mapping then identified the areas responsible for its immunogenicity. Then, 6 unnatural modifications (D amino acid, amino isobutyric acid, peptoid, N-methylation, C-methylation & reduced peptide bond) used to increase the half-life were introduced at most positions of a highly immunogenic peptide. T-cell recognition, binding to HLA molecules and the ability to induce CD4 T-cells were studied for modified analog peptides. Most of the modifications were very effective in minimizing immunogenic properties.This thesis project is at the crossroads between the acquisition of new knowledge in immunology and its application in the process of design & risk management of therapeutic peptides.

Immunogénicité

Peptides thérapeutiques

Modifications non-Naturelles

Molécules HLA de classe II

Lymphocytes T CD4

Epitope T

Immunogenicity

Therapeutic peptides

Non-Natural modifications

HLA class II molecules

CD4 T-Cells

T epitope