Etude moléculaire et structurale d'une intégrase rétrovirale pour le développement de nouveaux antirétroviraux et étude cristallographique d' -galactosidases thermostables issues du microorganisme Geobacillus stearothermophilus

摘要

Integrase (IN) is a key protein in the retrovirus life cycle and constitutes an important therapeutic target for the development of antiretroviral compounds. This enzyme is involved in the early phase of theretroviral replication cycle and catalyses the retrotranscribed viral DNA integration into the host cell genome.The teams of BioCrystallography and Retrovirology of Lyon Gerland demonstrated by X ray crystallography, the existence of a new dimeric assembly of the central catalytic domain (CCD) of Rous Associated Virus type 1integrase or RAV 1 IN. As part of my thesis work, a protocol of overproduction and purification of the H103Cisolated catalytic domain mutant was developed to demonstrate the existence of this dimeric assembly insolution stabilized by an inter molecular disulfide bond. Biochemical and biophysical methods were developed to test the ability of small molecules of interest to bind and stabilize this "new" assembly. A protocol ofoverproduction and purification of full length RAV1 integrase was developed. Crystallization trials and SAXSstudies were undertaken. The H103C mutant of the entire protein was produced to verify the formation of the"new" interface on the full length protein.The microorganism Geobacillus stearothermophilus produces two thermostable ɑ-galactosidases named AgaA and AgaB, which belong to theGH36 glycoside hydrolase family. These two isoenzymes share97% sequence identity, but have different catalytic properties. A collaborative study was initiated with theInstitute of Industrial Genetics, University of Stuttgart (Germany),to better understand the catalytic specificity of these two isoenzymes. The crystal structures of AgaA and AgaB were solved in two different crystal systems.The crystal structure of the mutant AgaA A355E, which has catalytic properties similar of those of AgaB, wasalso determined. These three structures show that the A355E substitution results in a signifiant displacement of the W336 tryptophan residue from the catalytic subsite -1. This could explain the catalytic specificities of the two isoenzymes