Live single cell fluorescence microscopy; from antibiotic resistance detection to mitochondrial dysfunction

Ray, Lucille Alexandria

26 August 2020

No description available.

Biochemistry

Chemistry

Microbiology

microscopy

single-cell

antibiotic resistance

fluorescence

mitochondria

cuprizone

antibacterial susceptibility testing

antimicrobial polymer

Functionalization of poly(epsilon-caprolactone) and its macromolecular engineering

Riva, Raphael

20 April 2007

Macromolecular engineering is one of the most powerful tools to control the molecular parameters, including architecture of polymers, and to improve their performances or to impart them new properties. This contribution aims at reporting on a novel strategy for the macromolecular engineering of poly-ε-caprolactone (PCL) which is based on the use of functional ε-caprolactone, the α-chloro-ε-caprolactone (αClεCL). Indeed, αClεCL is a precursor of polymers and copolymers with εCL that bear pendant activated chlorides well suited to grafting from reaction. These (co)polyesters have been used as macroinitiators for the Atom Transfer Radical Polymerization (ATRP) of methyl methacrylate leading to the corresponding graft copolymer. They have also been involved in an Atom Transfer Radical Addition (ATRA) reaction with a series of olefins bearing different functional groups (hydroxyl, carboxylic acid and epoxy group) in order to functionalize the polyester backbone without deleterious degradation. ATRA of PEO chains with an unsaturation end groups has also been carried out in order to prepare PCL-g-PEO of different compositions to be used as stabilizers of polyester nanoparticles. Combination of ring-opening polymerization of ε-caprolactone and the copper-catalyzed Huisgens [3+2] cycloaddition is a novel strategy for going a step further in the macromolecular engineering of poly-ε-caprolactone (PCL). This click reaction is very well-suited to the chemical modification of aliphatic polyesters because, its implementation under very mild conditions prevents chain degradation from occurring. Indeed, alkynes were cycloadded onto azide containing PCL at low temperature (35°C) in an organic solvent (DMF or THF). Originally, α-chloro-ε-caprolactone and ε-caprolactone were randomly copolymerized in toluene at room temperature followed by reaction of the activated chlorides with sodium azide. In order to make a wide range of functional aliphatic polyesters available, poly(α-azide-ε-caprolactone-co-ε-caprolactone) copolyesters were reacted with a series of alkynes substituted by a functional group, e.g., hydroxyl, acrylate and quaternary ammonium salts, This strategy turned out to be efficient to synthesize for instance hydrophilic, photo-cross-linkable and hydrosoluble PCL. Moreover, a variety of graft copolymers were prepared by both the grafting from and the grafting onto techniques. Indeed, an ATRP initiator was attached onto PCL followed by polymerization of vinyl monomers, whereas alkyne endcapped PEO was cycloadded onto azide-containing PCL with formation of amphiphilic PCL-g-PEO copolymers. Last but not least, the click chemistry was very instrumental in imparting an antimicrobial activity to PCL or for the preparation of new functionalized caprolactones.

PCL

functionalization/fonctionalisation

graft copolymers/polymeres greffes

lactones

ATRA

Click chemistry

Les peptides antimicrobiens dérivés de la chromogranine A et Staphylococcus aureus : de l'analyse de l'interaction hôte-pathogène au développement de revêtement de polymère antimicrobien / Antimicrobial chromogranin A derived peptides and Staphylococcus aureus : from host pathogen interaction analysis to development of antimicrobial polymer coating

Aslam, Rizwan

15 April 2013

Les chromogranines (Cgs) sont une famille de protéines acides exprimées dans les granules des cellules neuroendocrines et immunitaires. Plusieurs peptides dérivés des Cgs présentent des activités antimicrobiennes. L’objectif de ma thèse est d’évaluer l’interaction hôte-pathogène et ensuite de développer un polymère antimicrobien avec insertion du peptide antimicrobien cateslytin (CTL).Dans une première partie, nous avons évalué l’aptitude de la leukotoxine LukE/D à induire la sécrétion des neutrophiles et rôle des protéases bactériennes à dégrader les peptides dérivés de la CgA. Les neutrophiles activés sécrètent de nombreux composés que nous avons identifiés. De plus, la dégradation des PAMs dérivés de la CgA par les protéases de S.aureus a été déterminée. Sur tous les PAMs testés, CTL est le seul qui tue S.aureus et résister à dégradation. Par ailleurs, CgA et CgB sont dégradés par la protéase Glu-C pour produire de nouveaux fragments sans activité antibactérienne, mais d’activité antifongique.Dans une deuxième partie, nous avons décidé de préparer un revêtement conjugué à CTL. CTL-C est utilisé pour préparer des films avec le dépôt alterné de CHI et HA-CTL-C. Par la suite nous avons synthétisé HAFITC-CTL-C and HAFITC pour analyser leur interaction. HAFITC-CTL-C est rapidement détectable dans le cytoplasme sans provoquer la lyse cellulaire. De plus, les films contenant CTL-C ne sont pas toxiques pour les fibroblastes gingivaux humains.En conclusion, CTL est le seul peptide antimicrobien dérivé de la CgA qui peut tuer S.aureus et résiste à la dégradation protéolytique, ce qui est de bon augure pour de nouvelles études visant à développer des biomatériaux antimcrobiens. / Chromogranins (Cgs) are a family of acidic proteins, expressed in secretory granules of neuro-endocrine and immune cells. Several Cgs derived peptides express antimicrobial activity. Current study was aimed to evaluate host-pathogen interaction and ultimately to develop antimicrobial polymer with insertion of cateslytine (CTL).In first part, stimulatory ability of leukotoxin LukE/D to induce neutrophils secretions and role of bacterial proteases to degrade CgA-derived AMPs was evaluated. Activated neutrophils secrete various components which were identified. Later by using antimicrobial assays, several fractions were found active and later discussed with respect to proteomic analysis. Additionally, degradation of CgA derived AMPs by S. aureus proteases was demonstrated. Out of various AMPs tested, CTL was only that can kill S. aureus and resist protease degradation. Furthermore, CgA and CgB are processed by Glu-C protease to produce new fragments lacking antibacterial activity but presenting antifungal activity.Secondly, we aimed to prepare CTL conjugated biomaterial coating. CTL-C was used to prepare PEM films with alternative deposition of CHI and HA-CTL-C and evaluated for antimicrobial activities. Later on, we synthesized HAFITC-CTL-C and HAFITC to analyze their interaction. HAFITC-CTL-C was readily detectable in cytoplasm without provoking cell lysis. Moreover CTL-C inserted PEM films are non-toxic to human gingival fibroblast cells.In conclusion, CTL is the only CgA-derived AMP that can kill S. aureus and resistant to proteolytic degradation, which is a promising feature for further studies in order to develop antimicrobial biomaterials.

Staphylococcus aureus

Leucotoxine

LukE/D

L'immunité innée

Les peptides antimicrobiens

Chromogranines

Cateslytin

Revêtement de polymère antimicrobien

Biomatériaux antimcrobiens

Staphylococcus aureus

Leukotoxin

LukE/D

Innate immunity

Antimicrobial peptides

Chromogranins

Cateslytin

Antimicrobial polymer coating

Antimicrobial biomaterial

572.6

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