A Structural and Enzymatic Characterization of Purified Human Diacylglycerol Kinase Epsilon / Purification and Characterization of Diacylglycerol Kinase Epsilon

Jennings, William

January 2016

Diacylglycerol kinases (DGK’s) tightly regulate the intracellular levels of diacylglycerol (DAG) and phosphatidic acid (PA). DAG is an important intermediate in lipid biosynthetic pathways and acts as a lipid second messenger in a number of signaling pathways. Similarly, since PA serves as a potent signaling lipid and is a precursor for lipid biosynthesis, intracellular PA levels must be tightly regulated. There are ten isoforms of DGK in mammals, but we have decided to focus solely on the epsilon form (DGKε) in this work. DGKε is the only isoform that shows specificity for the acyl chains of its DAG substrate; as a consequence, it contributes to the dramatic enrichment of cellular lipids with sn-1 stearoyl and sn-2 arachidonoyl. The most notable example is the highly enriched bioactive lipid 1-stearoyl-2-arachidonoyl phosphatidylinositol. We have purified active human DGKε to near homogeneity and thoroughly characterized its stability as well as examined its secondary structure with CD. We also purified a truncated form (DGKε Δ40) that shows increased stability compared to the full-length protein. Our purified fractions are well suited for a wide range of exciting applications and studies. We have begun incorporating DGKε into liposomes in order to develop a liposome-based assay, which would be a dramatic improvement over the presently used micelle-based assay. This purification also allows for high throughput screens of chemical compounds to test for a specific inhibitor. These studies will reveal valuable information about the structural and functional properties of DGKε and will aid in the development of therapies for DGKε-related diseases. / Thesis / Master of Science (MSc)

Membrane Protein Biochemistry

Development of a wheat germ cell-free expression system for the production, the purification and the structural and functional characterization of eukaryotic membrane proteins : application to the preparation of hepatitis C viral proteins / Développement d'un système d'expression acellulaire à base d'extrait de germe de blé pour la production, la purification et la caractérisation structurale et fonctionnelle de protéines membranaires eucaryotes : application à la préparation des protéines du virus de l'hépatite C

Fogeron, Marie-Laure

30 June 2015

Alors que 30% du génome code pour des protéines membranaires, moins de 3% des structures protéiques dans la Protein Data Bank correspondent à ces protéines. En raison de leur nature hydrophobe, les protéines membranaires sont en effet très difficiles à produire dans des systèmes d'expression classique en cellules, notamment en bactéries. L'étude structurale des protéines membranaires du virus de l'hépatite C (VHC) sous forme entière et native a donc été pendant longtemps entravée. Le VHC est un virus à ARN positif dont le complexe de réplication est basé sur un réarrangement spécifique des membranes induit par l'action concertée de plusieurs protéines non structurales du virus dont NS2, NS4B et NS5A. La structure tridimensionnelle et le rôle de ces protéines dans la réplication virale sont encore mal connus. Pour surmonter les limitations qui empêchent leurs études structurales et fonctionnelles, un système d'expression acellulaire à base d'extrait de germe de blé a été développé avec succès, permettant la production des protéines NS2, NS4B et NS5A entières directement sous une forme solubilisée en présence de détergent. Ces protéines membranaires sont produites et purifiées par chromatographie d'affinité dans des quantités de l'ordre du milligramme. Des analyses par filtration sur gel indiquent que les échantillons obtenus sont homogènes. De plus, des analyses structurales par dichroïsme circulaire montrent que les protéines produites dans ce système sont bien repliées. Leur reconstitution dans des lipides est en cours d'optimisation. Le but ultime est en effet de déterminer leur structure par RMN du solide dans un environnement lipidique mimant l'environnement natif / While 30% of the genome encodes for membrane proteins, less than 3% of protein structures in the Protein Data Bank correspond to such proteins. Due to their hydrophobic nature, membrane proteins are indeed notoriously difficult to express in classical cell-based protein expression systems. The structural study of the membrane proteins of hepatitis C virus (HCV) in their full-length and native form has therefore been for long time hampered. HCV is a positive-strand RNA virus building its replication complex on a specific membrane rearrangement (membranous web), which serves as a scaffold for the HCV replicase, and is induced by the concerted action of several HCV non-structural proteins including NS2, NS4B and NSSA. The knowledge of the three- dimensional structure of these proteins and their role in virus replication is still limited. To overcome the limitations that prevent the structural and functional studies of these proteins, a wheat germ cell-free protein expression system has been developed. A production protocol was designed which allows us to directly obtain membrane proteins in a soluble form by adding detergent during the in vitro protein synthesis. A large number of mainly viral proteins were successfully expressed, and full protocols were developed for the full-length NS2, NS4B and NSSA proteins. These membrane proteins were produced and purified by affinity chromatography using a Strep-tag II in the milligram range. These protein samples are homogenous, as shown by gel filtration analysis. Moreover, structural analyses by circular dichroism showed that the proteins produced in the wheat germ cell-free system are well folded. Reconstitution of these proteins in lipids is currently under optimization. The ultimate goal is to determine their structure by solid-state NMR in a native-like membrane lipids environment

Biochimie des protéines membranaires

Biologie moléculaire

Virus de l'hépatite C

Expression acellulaire de protéines

Détergents

Purification des protéines

Reconstitution en lipides

Résonance magnétique nucléaire (RMN)

Membrane protein biochemistry

Molecular Biology

Hepatitis C virus

Cell-free protein expression

Detergents

Protein purification

Lipid reconstitution

Nuclear magnetic resonance (NMR)

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