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Mechanisms of Bacterial Copper Detoxification and Oxygen Reduction in CueO and Chemotactic Signal Amplification by Receptor ClusteringSingh, Satish Kumar January 2009 (has links)
CueO is a multicopper oxidase and catalyses the four-electron reduction of dioxygen to water and functions to protect Escherichia coli against copper-induced toxicity. The mechanism of oxygen reduction in multicopper oxidases has been well studied, but the key structures of the reaction intermediates are not known. A combination of kinetic measurements, mutagenesis and X-ray crystallographic studies were conducted to entrap and structurally characterize the reaction states in CueO. CueO has a methionine-rich insert and a labile copper binding site, two features found only in multicopper oxidases involved in copper detoxification. The role of these features in CueO activity has been investigated. In a separate study, a simple mathematical model based on infectivity amongst clustered receptors was developed to explain the chemotactic sensitivity, response range and other key features of chemotaxis.This study describes the successful entrapment of three out of four functional states in CueO. The crystal structures of these reaction states are presented. Using single-turnover oxygen reduction kinetics that were measured using a stopped-flow device, the optical absorption features of three different fully oxidized forms of CueO were captured: the native intermediate, the resting oxidized state and another intermediate lying between them. Stopped-flow studies combined with electron transfer kinetic measurements revealed a role of the conserved residue, E506, in either the protonation of the native intermediate or the release of water molecules formed as a product of the reaction.Cu(I) and Ag(I) bound crystal structures of CueO were determined revealing three binding sites along the methionine-rich helix used by both metal ions. The labile, regulatory copper site in CueO was shown to be a Cu(I) susbtrate oxidation site. Ag(I) was shown to be a potent inhibitor of all CueO activities in vitro and copper detoxification by the cue system in vivo. The cus system was discovered to be necessary for removing Ag(I) inhibition of copper detoxification by the cue system. These results provide further insights into the role of CueO in copper detoxification and the effect of silver on the detoxification mechanism.
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Etude de thérapies génique et pharmacologique visant à restaurer les capacités cognitives d’un modèle murin de la Dystrophie musculaire de Duchenne / Gene and pharmacological therapies to restore cognitive abilities of a mouse model of Duchenne muscular DystrophyPerronnet, Caroline 21 January 2011 (has links)
L’objectif était d’évaluer l’efficacité de thérapies développées pour traiter la dystrophie musculaire de Duchenne (DMD, due à des mutations du gène de la dystrophine) dans la restauration de déficits cognitifs associés à ce syndrome. Deux pistes thérapeutiques visant à compenser les altérations cérébrales liées à la perte de dystrophine ont été explorées chez les souris mdx, modèle de DMD. Une approche pharmacologique basée sur la surexpression de l’utrophine, homologue de la dystrophine, n’améliore pas les déficits comportementaux des souris mdx. Par contre, une intervention génique basée sur l’épissage de l’exon muté conduit à la restauration d’une dystrophine endogène et une récupération d’altérations cérébrales comme l’agrégation des récepteurs GABAA et la plasticité synaptique hippocampique. Ceci suggère un rôle de la dystrophine dans la plasticité du cerveau adulte et l’applicabilité de cette approche de thérapie génique au traitement des altérations cognitives de la DMD. / Therapies have been developed to treat Duchenne muscular dystrophy (DMD, due to mutation in the dystrophin gene), but their ability to restore the cognitive deficits associated with this syndrome has not been yet studied. We explored two therapeutic approaches to compensate for the brain alterations resulting from the loss of dystrophin in the mdx mouse, a model of DMD. A pharmacological approach based on the overexpression of utrophin, a dystrophin homologue, does not alleviate the behavioural deficits in these mice. In contrast, a genetic intervention based on the splicing of the mutated exon leads to the restoration of endogenous dystrophin and a recovery of brain alterations such as the clustering of GABAA receptors and hippocampal synaptic plasticity in mdx mice. These results suggest a role for dystrophin in adult brain plasticity and indicate that this gene therapy approach is applicable to the treatment of cognitive impairments in DMD.
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Elucidating the Functional Role of Human Nucleoporin Nup88 in Health and DiseaseBonnin, Edith 27 February 2018 (has links)
Movement is a prerequisite for normal fetal development and growth. Intrauterine movement restrictions cause a broad spectrum of disorders in which the unifying feature is a reduction or lack of fetal movement, giving rise to the term fetal akinesia deformations sequence (FADS [OMIM 208150]). FADS corresponds to a clinically and genetically heterogeneous constellation of properties and is characterized by multiple joint contractures, facial abnormalities, and lung hypoplasia as a result of the decreased in utero movement of the fetuses. Affected babies are often prematurely and stillborn, and those born alive typically die within minutes or hours after birth. The genetic causes for this fatal disorder are ill-defined as a genetic diagnosis is rarely executed, but mutations in three genes, namely RAPSN, DOK7, and MUSK, as well as in the subunits of the muscular nicotinic acetylcholine receptor (AChR) have been described. These mutations are thought to affect neuromuscular junctions, although this has not been proven experimentally.The nucleoporin NUP88 is a constituent of the nuclear pore complex (NPC), the gate for all trafficking between the nucleus and the cytoplasm. NUP88 resides on both the cytoplasmic and the nuclear side of NPCs, and it is found in two distinct subcomplexes. It associates with NUP214 and NUP62 on the cytoplasmic face, while on the nuclear side NUP88 binds NUP98 and the intermediate filament protein lamin A. The NUP88-NUP214-NUP62 complex plays an essential role in the nuclear export of a subset of proteins and pre-ribosomes, which is mediated by the nuclear export receptor CRM1. NUP88 in particular somewhat participates in the nuclear export of NF-κB proteins in a CRM1-dependent manner. Moreover, NUP88 is frequently overexpressed in a variety of human cancers, and its role in cancer appears linked to the deregulation of the anaphase-promoting complex. Here, we report the first Mendelian disorders caused by mutations in NUP88 and with that the first lethal developmental human disease due to mutations in a nuclear pore component. We demonstrate that biallelic mutations in NUP88 are likely to cause fetal akinesia of the Pena-Shokeir subtype. We confirm in zebrafish that loss of NUP88 impairs movement and the mutations identified in the affected individuals resemble a loss-of-function phenotype. We show that loss of NUP88 affects expression and localization of rapsyn, the protein encoded by RAPSN, in human and mouse cell lines, and patient samples. Consistent with altered rapsyn, AChR clustering and neuromuscular junction formation in zebrafish are abnormal. We therefore propose that defective NUP88 function cause FADS by affecting neuromuscular junction formation.Keywords: Nuclear pore complex, NUP88, Fetal Akinesia Deformation Sequence, rapsyn, acetylcholine receptor clustering, synaptic transmission, fetal development, inherited developmental disorder. / Doctorat en Sciences / info:eu-repo/semantics/nonPublished
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