Chronic viral hepatitis and human lipid and carbohydrate metabolism / Hépatites virales chroniques et métabolisme glucido-lipidique humain

Enache, Liviu

26 September 2014

L'infection au virus de l'hépatite B (VHB) est étroitement liée au métabolisme énergétique hépatique. La réplication du virus est contrôlée en principal par des facteurs de transcription et récepteurs nucléaires tels que PPARa, HNF4a et Foxül, impliqués dans ce métabolisme. Ainsi, la réplication du virus est augmentée par la privation de nutriments et le stress énergétique en modèles cellulaires, et par le jeûne, en modèles murins. PGC-la, un régulateur majeur de la réponse métabolique adaptative au jeûne, est impliqué dans l'augmentation de la transcription du VHB par son interaction avec plusieurs facteurs de transcription. Il est connu que le récepteur des acides biliaires, FXRa, qui est capable d'activer le promoteur de Core du VHB, est co-activaté par PGC-la. Un autre acteur important dans l'adaptation métabolique à la privation d'énergie est la protéine déacétylase SIRTl. Lorsqu'il est activé, SIRTl hépatique est capable de désacétyler et activer autant PGC-la que FXRa. Ces données nous ont amenés à émettre l'hypothèse que SIRTl pourrait coopérer avec FXRa et PGC-la pour augmenter la transcription du VHB. Dans un premier travail, nous avons donc étudié le rôle de la coopération de ces trois facteurs métaboliques dans la réplication du virus. Ça nous a permis de décrire un nouveau réseau métabolique, composé de FXRa, PGC-la et SIRTl, qui régule l'activité transcriptionnelle du VHB. Nous avons montré que SIRTl augmente l'activité du promoteur de Core par l'intermède d'autre facteurs, parmi lesquels, FXRa. Nous avons en outre observé que la fonction de déacétylase de SIRTl était nécessaire pour l'amplification de l'effet de FXRa sur VHB promoteur de Core. Une autre cible de SIRTl, connue pour son activité co-activatrice sur FXRa, est PGC-la. Grâce à une série d'expériences de surexpression et suppression, nous avons montré que non seulement la co-activation de FXRa par PGC-la est potentialisée par SIRTl, mais la présence de PGC-la est nécessaire pour l'effet de SIRTl sur l'activation du promoteur de Core VHB induite par FXRa. Ces données suggèrent que FXRa, PGC-la et SIRTl coopèrent dans la modulation de l'activité transcriptionnelle du promoteur de Core. Nous avons ensuite confirmé nos observations initiales et avons montré que l'activation de l'axe SIRTl/PGC-la/FXRa induit la transcription de l'ARN de VHB dans des lignées cellulaires d'origine hépatique et non-hépatique. Ces résultats renforcent l'idée que la réplication du VHB peut être modulée en fonction de l'état nutritionnel. Les rapports des études précédentes menées in vitro et sur des modèles animaux suggèrent que la transcription du VHB est contrôlée de la même manière que les gènes de la néoglucogenèse. Notre hypothèse a été que chez l'homme, la réplication du VHB montrerait des fluctuations diurnes, selon les périodes de la journée de jeûne et de réalimentation. Le but de la deuxième étude a été donc de déterminer si la charge viral du VHB plasmatique montre des variations importantes tout au long du nichthemeron chez les patients chroniquement infectés par VHB, avec une réplication virale active [etc...] / Hepatitis B virus (HBV) infection is tightly linked with hepatic fuel metabolism. HBV replication depends on the activity of several liver-enriched nuclear receptors and transcription factors, such as PPARa, HNF4a, and Fox01, involved in the metabolic adaptive response to fasting. In the first part of our work, we identified a metabolic subnetwork that enhances the activity of HBV core promoter. FXRa (NR1H4), PPAR gamma coactivator 1a and SIRT1, the members of this regulatory axis, cooperate to increase HBV transcription. The three molecules are themselves key factors of liver metabolism, linking HBV replication to complex metabolic cues, such as energy status and nutrient availability during the fasting-refeeding cycles. We then observed the existence of a circadian cycle of HBV replication in humans, underlining the role of nutrient availability in the modulation of HBV replication, previously predicted by experimental models. The second part of the work focused on the plasma cell-free nucleic acids as potential biomarkers in chronic viral hepatitis. Due to the multiple links between HBV replication and cellular factors involved in fuel metabolism, we hypothesized that plasma mRNAs corresponding to these factors may constitute potential biomarkers for chronic hepatitis B. We successfully detected more than 30 plasma mRNA sequences corresponding to enzymes, transporters, nuclear receptors and transcription factors involved in fatty acids synthesis and oxidation, cholesterol synthesis, transport and excretion, and energy sensing and expenditure. The circadian variation and the multiple correlations in the expression patterns of these plasma transcripts are similar to those previously described in cells both in vitro and in vivo. This suggests that cell- free mRNAs may provide a "virtual biopsy" of the transcriptional status of the organism. Moreover, we found significant differences in the plasma mRNA profiles of HBV carriers compared with healthy controls, similar to those found in experimental models of infection, suggesting that these transcripts may also serve as biomarkers of liver disease. Further research is warranted to shed new light on the complex relationship between HBV life cycle and host lipid-carbohydrate-fuel metabolism and may lead to the identification of both actionable targets in antiviral therapy, and putative biomarkers in chronic hepatitis B

Virus de l'hépatite B

Récepteurs nucléaires

Farnesoid X receptor

PPAR gamma coactivator 1a

Sirtuin l

Cycle circadien

Acides nucléiques circulants

Réplication virale

Hepatitis B virus

Nuclear receptors

Farnesoid X receptor

PPAR gamma coactivator 1a

Sirtuin l

Circadian cycle

Circulating nucleic acids

Viral replication

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Role of the Yeast Ste20 Protein Kinase Ortholog Map4k4 in Adipose Tissue Function: A Dissertation

Guntur, Kalyani V. P.

10 February 2011

Obesity has increased globally in epidemic proportions and as have the associated disorders. Insulin resistance that could further lead to type 2 diabetes is a major obesity associated dysfunction. Studies using insulin resistant mouse models and observations from human subjects exhibiting insulin resistance provide evidence for ectopic lipid deposition in organs like liver, muscle and heart as one of the major risk factors for developing insulin resistance. These observations suggest that deregulated adipose function to sequester and store excess energy as fat, could lead to insulin resistance. Furthermore, several studies have demonstrated adipose tissue dysfunction leading to inflammation and related syndromes. Interestingly, a mouse model with transgenic expression of glucose transporter in the adipose tissue exhibited improved glucose tolerance and increased insulin sensitivity despite development of obesity, upon high fat feeding. Thus mechanisms that improve adipose function could alleviate insulin resistance and associated diseases. Mitogen activated protein kinase kinase kinase kinase 4 (MAP4K4) was identified in our laboratory as a negative regulator of adipocyte function. Interestingly, siRNA mediated knockdown of MAP4K4 promoted PPARγ protein expression. Additionally, silencing of MAP4K4 increased adipocyte triglyceride content. Because MAP4K4 is a negative regulator of PPARγ expression and adipocyte function, understanding the mechanism by which MAP4K4 regulates PPARγ expression is of interest. Thus, for the first part of this thesis, I characterized the signaling pathways utilized by MAP4K4 to regulate PPARγ expression in cultured adipocytes. Here I show that MAP4K4 regulates PPARγ expression through regulation of its protein translation. siRNA mediated MAP4K4 gene silencing stimulated PPARγ protein synthesis without changing its mRNA transcription or its protein degradation. This increase in PPARγ protein translation was due to an increase in the activity of mammalian target of rapamycin (mTOR). The increase in PPARγ protein expression mediated by mTOR activation was a specific effect of the 4E-BP1 phosphorylation that leads to its inactivation and was not a general increase in mTOR activity towards all of its substrates. Finally, adenovirus mediated over expression of MAP4K4 inhibited mTOR activation, and suppressed PPARγ protein translation. For the second part of this thesis, I assessed the role of MAP4K4 in adipocytes in vivo. To accomplish this, a lentivirus mediated shRNA construct was generated to attenuate MAP4K4 expression selectively in the mouse adipose tissue. First we demonstrate that the MAP4K4 shRNA construct is able to efficiently silence the expression of MAP4K4 in vitro when co-expressed with Cre recombinase. Furthermore, we show that following modification of the lentiviral conditional vector that was introduced into a mouse embryo at one cell stage, and crossing the resulting founders with aP2-Cre mice, adipose tissue specific MAP4K4 gene silencing was achieved. Moreover, shRNA mediated gene silencing is a faster and an inexpensive means of achieving tissue specific gene knockdown relative to the available traditional gene knockout approaches. Utilizing these adipose specific MAP4K4 gene knockdown mice, I reveal that MAP4K4 silencing enhanced fat mass as well as PPARγ expression significantly. This is accompanied by improved whole body insulin sensitivity. Furthermore, when challenged with high fat diet, adipose-specific MAP4K4 silenced mice exhibit enhanced adiposity with decreased lean mass. Moreover, adipocyte cell size and triglyceride content are significantly increased. Interestingly, despite increased adiposity, hepatic insulin sensitivity is significantly improved leading to decreased glucose output. Thus MAP4K4 is an important regulator of adipocyte function that mediates whole body glucose homeostasis, through a mechanism that is yet to be identified.

Adipose Tissue

Protein-Serine-Threonine Kinases

PPAR gamma

Amino Acids, Peptides, and Proteins

Enzymes and Coenzymes

Fungi

Genetic Phenomena

Nutritional and Metabolic Diseases

Tissues

The Co-chaperones FKBP51 and PP5 Control Nuclear Receptor Phosphorylation and Adipogenesis

Stechschulte, Lance A.

21 August 2013

No description available.

Biomedical Research

Endocrinology

Molecular Biology

Pharmacology

Physiology

FK506-binding protein 51

FKBP51

Protein Phosphatase 5

PP5

Tetratricopeptide Repeat

TPR

glucocorticoid receptor -GR

PPAR gamma

Akt

p38 MAPK

Tibia Morphology & Bone Marrow Adipose Tissue Phenotype is Controlled by Sex Steroids in C57BL/6 Mice

Sherman, Shermel B.

January 2016

No description available.

Endocrinology

Biomedical Research