Investigating Host-Viral Interactions in Liver Lipid Homeostasis and HCV Pathology

Delcorde, Julie

January 2014

Hepatitis C virus (HCV) infects an estimated 170 million people worldwide and is a major cause of chronic hepatitis and hepatocellular carcinoma. As there are limited treatment options, the elucidation of novel host-viral interactions during HCV pathogenesis will be critical for the development of new therapeutics. My thesis work has identified cell death-inducing DFF45-like effector B (CIDEB) as a host factor that is disregulated during HCV infection, and has delineated the relevance of CIDEB’s dual roles in apoptosis and lipid metabolism in the context of the HCV lifecycle. Moreover, additional host factors necessary for the HCV lifecycle were investigated using unnatural amino acid (UAA) technology. With this technique, the photo-cross-linking UAA p-azido-phenlyalanine (AZF) and 3’-azibutyl-N-carbamoyl-lysine (Abk) were incorporated into viral proteins by expanding the genetic code of the host organism. This conferred diverse physicochemical and biological properties to these proteins that were exploited to investigate protein structure and function in vitro and in vivo. In summary, gaining insight into the numerous host-viral interactions that take place during HCV infection will both advance our understanding of HCV pathogenesis and uncover potential therapeutic targets.

Hepatitis C Virus

CIDEB

Lipids

Host-factor

Unnatural amino acid

Identification Of Proteins Regulating Vldl Sorting Into The Vldl Transport Vesicle (vtv) And Involved In The Biogenesis Of The Vtv

Tiwari, Samata

01 January 2013

Increased secretion of very low-density lipoprotein (VLDL), a triglyceride-rich lipoprotein, by the liver causes hypertriglyceridemia, which is a major risk factor for the development of atherosclerosis. The rate of VLDL-secretion from the liver is determined by its controlled transport from the endoplasmic reticulum (ER) to the Golgi. The ER-to-Golgi transport of newly synthesized VLDL is a complex multi-step process and is mediated by the VLDL transport vesicle (VTV). Once a nascent VLDL particle is synthesized in the lumen of the ER, it triggers the process of VTV-biogenesis and this process requires coat complex II (COPII) proteins that mediate the formation of classical protein transport vesicles (PTV). Even though, both VTV and PTV bud off the same ER at the same time and require the same COPII proteins, their cargos and sizes are different. The VTV specifically exports VLDL to the Golgi and excludes hepatic secretory proteins such as albumin and the size of the VTV is larger (~ 100 -120 nm) than PTV to accommodate VLDL-sized particles. These observations indicate (i) the existence of a sorting mechanism at the level of the ER; and (ii) the involvement of proteins in addition to COPII components. This doctoral thesis is focused on identification of proteins regulating VLDL sorting into the VTV and involved in the biogenesis of the VTV. In order to identify proteins present exclusively in VTV, we have characterized the proteome of VTV, which suggest CideB (cell death-inducing DFF45-like effector b) and SVIP (small VCP/P97 interacting protein) as candidates, present in VTV but excluded from PTV. We further confirmed the finding by performing co-immunoprecipitation studies and confocal microscopy studies. CideB, a 26-kDa protein was found to interact with apolipoprotein iv B100 (apoB 100), the structural protein of VLDL. Moreover, CideB interacts with two of the COPII components, Sar1 and Sec24. VTV generation was examined after blocking CideB by specific antibodies and by silencing CideB in rat primary hepatocytes. Knockdown of CideB in primary hepatocytes showed significant reduction in VTV generation, however, CideB was concentrated in VTV as compared with the ER suggesting its functional role in the sorting of VLDL into the VTV. SVIP, a small (~ 9-kDa) protein was found to interact with Sar1, a COPII component that initiates the budding of vesicles from ER membrane. SVIP has sites for myristoylation and we found increased recruitment of SVIP on ER membrane upon myristic acid (MA) treatment. Sar1 that lacks sites for myristoylation also is recruited more on ER upon myristoylation indicating that SVIP promotes Sar1 recruitment on ER. Additionally, our data suggest that Sar1 interacts with SVIP and forms a multimer that facilitates the biogenesis of VTV. Interestingly, silencing of SVIP reduced the VTV generation significantly. Conversely, incubation with MA increased the VTV budding, suggesting recruitment of SVIP on ER surface facilitates the VTV budding. We conclude that SVIP recruits Sar1 on ER membrane and makes an intricate COPII coat leading to the formation of a large vesicle, the VTV. Overall, the data presented in this thesis, determines the role of CideB and SVIP in regulating VLDL sorting and VTV biogenesis.

Vldl

endoplasmic reticulum

cideb

svip

coat complex ii

aopolipoprotein b 100

vldl transport vesicle

Molecular Biology

Interactions entre le métabolisme hépatique des sels biliaires et des lipoprotéines et les infections par les virus des hépatites B et C / Interactions between hepatic metabolism of bile acids and lipoproteins and Hepatitis B and C infections

Ramière, Christophe

23 February 2012

Les virus des hépatites B et C (VHB et VHC) entretiennent des liens étroits avec le métabolisme lipidique des hépatocytes. Ainsi, la réplication du VHB est dépendante de certains récepteurs nucléaires hépatiques, tels que HNF4α et PPARα, impliqués dans ce métabolisme. L’assemblage des particules virales du VHC dépend lui de la voie de synthèse des lipoprotéines de très faible densité (VLDL) et le virus circule dans le sang sous forme de lipo-viro-particules associé notamment à l’apolipoprotéine B, un composant essentiel des VLDL. Dans ce travail, nous avons d’abord étudié le rôle de FXRα, le récepteur nucléaire des sels biliaires, sur la réplication du VHB. Nous avons montré, in vitro, que les sels biliaires, via FXRα, activaient le promoteur de Core du VHB qui contrôle le niveau de réplication virale. Puis dans l’étude des liens entre les lipoprotéines et le VHC, nous avons montré que l’apoB présente sur certaines particules virales jouaient un rôle important dans l’infectiosité du virus in vitro, et que la protéine Cideb, présente en surface des gouttelettes lipidiques et impliquée dans l’assemblage des VLDL, était impliquée dans l’association du VHC avec l’apoB et influençait l’infectiosité des virions sécrétés. De plus nous avons mis en évidence l’existence de particules sub-virales chez les patients infectés, de nature lipoprotéique mais ne portant que les protéines d’enveloppes du VHC. Tous ces résultats renforcent l’idée d’une adaptation du VHB et du VHC au métabolisme lipidique hépatique. Les bénéfices éventuels qu’en retirent ces deux virus, ainsi que l’existence de possibles thérapeutiques anti-virales ciblant le métabolisme lipidique, restent à explorer / Hepatitis B and C viruses (HBV and HCV) infections are tightly linked with hepatic lipid metabolism. HBV replication depends on specific nuclear receptors, such as HNF4α and PPARα, both implicated in this metabolism. HCV assembly depends on the synthesis of Very-Low-Density Lipoproteins (VLDL), and the virus circulates in the blood as lipo-viral-particles associated in particular with apoB, an essential component of VLDL. In this study, we first studied the influence of FXRα, the nuclear receptor for bile acids, on HBV replication. We showed that, in vitro, bile acids, via FXRα, were able to activate the HBV Core promoter which controls the level of viral replication. Then, in the study of the interactions between HCV and lipoproteins, we demonstrated that apoB, which is associated with a proportion of viral particles, played an important role in HCV infectivity in vitro, and that Cideb, a protein involved in VLDL assembly, was implicated in the association between HCV and apoB and influenced the infectivity of secreted viral particles. Finally, we showed that, besides HCV infectious particles, sub-particles bearing only viral envelope glycoproteins circulated in the blood of infected patients. Interactions of HBV with the metabolism of bile acids, and of HCV with the metabolism of lipoproteins, are two examples of adaptation of a parasite to its host. The potential benefits from these interactions are still to be determined, as well as the possibility to develop anti-viral strategies targeting lipid metabolism

Acides biliaires

FXRalpha

Virus de l’hépatite B

Virus de l’hépatite C

Lipoprotéines

Apolipoprotéine B

Cideb

Réplication virale

Bile acids

FXRalpha

Hepatitis B virus

Hepatitis C virus

Lipoproteins

Apolipoprotein B

Cideb

Viral replication

616.3623