The Role of ApoE and Liver X Receptors in Alzheimer's Disease

Jiang, Qingguang

23 June 2008

No description available.

Biomedical Research

ApoE

LXR

ABCA1

A&946

APP

Alzheimer's disease

NF&954

B

inflammation

microglia

astrocyte

IDE

neprilysin

HDL

GW3965

p65

acetylation

HDAC3

SMRT

p300

pCAF

lipidation

Mapování regulačních elementů v 5' oblasti lokusu Disp3 / Mapping of regulatory elements within 5' region of the Disp3 locus

Oltová, Jana

January 2012

Dispatched 3 (Disp3), a thyroid hormone-regulated gene, is studied extensively in our laboratory. Phenotype of cells with overexpressed Disp3 and its expression pattern make it a perfect candidate for a molecular link between thyroid hormone action and cholesterol homeostasis in the brain. Moreover, we hypothesize that it might play a role in certain neurodegenerative disorders and brain tumours. This thesis is aimed at the process of regulation of this gene via thyroid hormone receptor (TR), specifically identification of responsive elements of the thyroid hormone receptor that are necessary for the regulation. Also, we searched for elements recognized by liver X receptor (LXR), as LXR binds to the same arrangement of repeats as TR and there are a number of genes regulated by both of them. We combined in silico analysis of the Disp3 locus with reporter luciferase assays. A cluster of six elements identified around the first exon with two of them being conserved among human and mice draw our attention. In order to analyze this sequence in more detail, reporter vectors of various truncations of 3 kb region around exon 1 were constructed and tested in reporter assays. Reporter assays did not reveal any substantial element activated by TR or LXR; on the other hand, region containing repressor element(s)...

Impacts des oxystérols par le biais des LXRs et du AhR dans la myélinisation / Impact of oxysterols on myelination processes through LXRs and AhR

Shackleford, Ghjuvan'Ghjacumu

17 June 2014

La formation de la gaine de myéline est un processus complexe et finement régulé. Une altération de l’expression des gènes codant pour les protéines structurales de cette gaine entraine de graves neuropathies démyélinisantes. Notre objectif est d’identifier de nouvelles voies de signalisation capables de moduler l’expression de ces gènes. Les cellules de Schwann et les oligodendrocytes contiennent et synthétisent de grande quantité de dérivés oxydés du cholestérol : les oxystérols. Ces molécules sont connues pour leurs rôles dans le maintien de l’homéostasie du cholestérol et dans la progression des maladies neurodégénératives. Les oxystérols peuvent être classés en deux groupes : ceux dont l’oxydation a lieu sur la chaine carbonée latérale (25OH) et ceux qui portent une oxydation sur l’un des cycles du cholestérol (7KC). Nous nous sommes tout d’abord intéressés à la première catégorie d’oxystérols. Nous avons montré que le 25OH, réprimait l’expression des gènes de la myéline périphérique P0 et PMP22. Cette activité répressive était le fruit d’un mécanisme direct conduisant à une augmentation de la quantité des LXRs liés à leurs éléments de réponse sur les promoteurs des gènes de la myéline, et d’un mécanisme indirect provoquant une diminution de l’activité de la voie Wnt/β-caténine. En revanche, dans le SNC, nos résultats indiquent que le 25OH active l’expression des gènes de la myéline PLP et MBP. Le traitement, par ces oxystérols, de cultures organotypiques de cervelet démyélinisées par la lysolécithine permet une remyélinisation des axones des cellules de Purkinje. Nous nous sommes ensuite penchés sur le rôle du corégulateur transcriptionnel RIP140. Ce dernier peut soit agir comme un corépresseur soit comme un coactivateur. Il peut interagir avec le LXR. L’invalidation de RIP140 dans le poisson zèbre altère les gaines de myéline. Nous avons montré que RIP140 possédait des rôles bivalents dans la régulation de la myélinisation. En effet, il est capable d’activer mais aussi de réprimer l’activité transcriptionnelle de P0 et de PMP22. Enfin, nous nous sommes intéressés à la seconde catégorie d’oxystérols. Le 7KC est l’oxystérol majoritairement présent dans le SNP et la CS. Il est connu pour moduler l’action du récepteur aux dioxines : le AhR. Ce récepteur a été très largement étudié dans un cadre toxicologique. Cependant ses rôles et ses ligands endogènes restent à ce jour encore assez méconnus. Nos résultats indiquent que le AhR est impliqué dans le contrôle de l’expression des gènes de la myéline périphérique. L’invalidation du AhR, chez la souris, provoque des anomalies structurales de la gaine de myéline conduisant à des déficits moteurs. Cette étude a permis de mieux comprendre les dialogues entre les voies de signalisation gouvernant le processus de myélinisation. Ce travail apporte également de nouvelles perspectives thérapeutiques des maladies neurodégénératives comme la CMT1A ou la sclérose en plaques. / The myelination of axons is a complex process performed by Schwann cells (SC) and by oligodendrocytes (OL) respectively in the peripheral nervous system (PNS) and in the central nervous system (CNS). A slight change in expression of myelin structural proteins has a deep impact on the development and preservation of nerve fibers and their myelin sheaths, as observed for example in Charcot-Marie-Tooth disease or in Pelizaeus-Merzbacher disease. Our aim is to identify new signaling pathways able to control the expression of these structural proteins. SC and OL contain and synthesize high amount of reactive molecules generated from the oxidation of cholesterol: the oxysterols. Their implication in cholesterol homeostasis and in the progression of neurodegenerative disorders is well known but few data are available for their functions in myelination of PNS and CNS. Firstly, we demonstrate that oxysterols inhibit peripheral myelin gene expression: MPZ and PMP22. This downregulation is mediated by two mechanisms: by increasing the binding of LXRs to myelin genes promoters and by inhibiting the Wnt/β-catenin pathway leading to a decrease of b-catenin recruitment at the levels of the MPZ and PMP22 promoters. However, in the CNS, our data demonstrate that activation of LXRS by oxysterols stimulate myelin genes expression (PLP and MBP). Interestingly, by using demyelinated organotipc culture of cerebellum, we show that oxysterols enhance OL differentiation and promote remyelination, via LXRs. Then, we studied the role of the transcriptional coregulatory, RIP140, in myelination. RIP140 is able to act as a corepressor or as a coactivator and can interact with LXRs. In Zebrafish, the knocked down of the orthologue of RIP140 led to a decrease of peripheral and central myelin gene expression and to a defect in myelin sheath ultrastructure. Finally, we focused on impact of AhR in myelination process. AhR is a ligand activated transcription factor mostly known to interact with environmental pollutant like dioxins to mediate their toxic and carcinogenic effect. However, its detoxifying activity is posterior to the apparition of the gene and its physiological roles and endogenous ligands remain elusive. We show that the main oxysterol in the nervous system is 7-ketocholesterol which is an endogenous modulator of AhR. We report that the constitutive absence of AhR in mice leads to defects in locomotion behaviors. We studied the impact of this invalidation on the myelin of sciatic nerve. We observed a severe demyelinating phenotype and deregulation of myelin genes expression. Moreover, we demonstrated a cross-talk between AhR and Wnt/β-catenin pathways. Our data reveal a new endogenous role of AhR in myelination process.

Myéline

Myélinisation

Système nerveux

Cervelet

Nerfs

Cellule de Schwann

Oligodendrocytes

Gène de la myéline

Oxystérol

LXR

AhR

Dioxine

TCDD

PCB

Wnt/beta-caténine

RIP140

NRIP1a

Maladie de Charcot-Marie-Tooth

Sclérose en plaques

Schwannome

Myelin

Myelination

Nervous system

Nerve

Cerebellum

Schwann cell

Oligodendrocyte

Myelin genes

Oxysterols

LXR

AhR

Dioxin

TCDD

PCB

Wnt/beta-catenin pathway

RIP140

NRIP1a

Charcot-Marie-Tooth disease

Multiple sclerosis

Schwannoma

612.8

Analysis of the Role of Astrocyte Elevated Gene-1 in Normal Liver Physiology and in the Onset and Progression of Hepatocellular Carcinoma

Robertson, Chadia L

01 January 2014

First identified over a decade ago, Astrocyte Elevated Gene-1 (AEG-1) has been studied extensively due to early reports of its overexpression in various cancer cell lines. Research groups all over the globe including our own have since identified AEG-1 overexpression in cancers of diverse lineages including cancers of the liver, colon, skin, prostate, breast, lung, esophagus, neurons and neuronal glia as compared to matched normal tissue. A comprehensive and convincing body of data currently points to AEG-1 as an essential component, critical to the progression and perhaps onset of cancer. AEG-1 is a potent activator of multiple pro-tumorigenic signal transduction pathways such as mitogen-activated protein extracellular kinase (MEK)/ extracellular signal-regulated kinase (ERK), phosphotidyl-inositol-3-kinase (PI3K)/Akt/mTOR, NF-κB and Wnt/β-catenin pathway. In addition, studies show that AEG-1 not only alters global gene and protein expression profiles, it also modulates fundamental intracellular processes, such as transcription, translation and RNA interference in cancer cells most likely by functioning as a scaffold protein. The mechanisms by which AEG-1 is overexpressed in cancer have been studied extensively and it is clear that multiple layers of regulation including genomic amplification, transcriptional, posttranscriptional, and posttranslational controls are involved however; the mechanism by which AEG 1 itself induces its oncogenic effects is still poorly understood. Just as questions remain about the exact role of AEG-1 in carcinogenesis, very little is known about the role of AEG-1 in regulating normal physiological functions in the liver. With the help of the Massey Cancer Center Transgenic/Knockout Mouse Core, our lab has successfully created a germline-AEG-1 knockout mouse (AEG-1-/-) as a model to interrogate AEG-1 function in vivo. Here I present the insights gained from efforts to analyze this novel AEG-1-/- mouse model. Aspects of the physiological functions of AEG-1 will be covered in chapter two wherein details of the characterization of the AEG-1-/- mouse are described including the role of AEG-1 in lipid metabolism. Chapter three discusses novel discoveries about the specific role of AEG-1 in mediating hepatocarcinogenesis by modulating NF-κB, a critical inflammatory pathway. First identified over a decade ago, Astrocyte Elevated Gene-1 (AEG-1) has been studied extensively due to early reports of its overexpression in various cancer cell lines. Research groups all over the globe including our own have since identified AEG-1 overexpression in cancers of diverse lineages including cancers of the liver, colon, skin, prostate, breast, lung, esophagus, neurons and neuronal glia as compared to matched normal tissue. A comprehensive and convincing body of data currently points to AEG-1 as an essential component, critical to the progression and perhaps onset of cancer. AEG-1 is a potent activator of multiple pro-tumorigenic signal transduction pathways such as mitogen-activated protein extracellular kinase (MEK)/ extracellular signal-regulated kinase (ERK), phosphotidyl-inositol-3-kinase (PI3K)/Akt/mTOR, NF-κB and Wnt/β-catenin pathway. In addition, studies show that AEG-1 not only alters global gene and protein expression profiles, it also modulates fundamental intracellular processes, such as transcription, translation and RNA interference in cancer cells most likely by functioning as a scaffold protein. The mechanisms by which AEG-1 is overexpressed in cancer have been studied extensively and it is clear that multiple layers of regulation including genomic amplification, transcriptional, posttranscriptional, and posttranslational controls are involved however; the mechanism by which AEG 1 itself induces its oncogenic effects is still poorly understood. Just as questions remain about the exact role of AEG-1 in carcinogenesis, very little is known about the role of AEG-1 in regulating normal physiological functions in the liver. With the help of the Massey Cancer Center Transgenic/Knockout Mouse Core, our lab has successfully created a germline-AEG-1 knockout mouse (AEG-1-/-) as a model to interrogate AEG-1 function in vivo. Here I present the insights gained from efforts to analyze this novel AEG-1-/- mouse model. Aspects of the physiological functions of AEG-1 will be covered in chapter two wherein details of the characterization of the AEG-1-/- mouse are described including the role of AEG-1 in lipid metabolism. Chapter three discusses novel discoveries about the specific role of AEG-1 in mediating hepatocarcinogenesis by modulating NF-κB, a critical inflammatory pathway.

AEG-1

HCC

NF-κB

LXR

PPARα

Lipid Metabolism

Disease Modeling

Gastroenterology

Genetic Phenomena

Genetic Processes

Hepatology

Immune System Diseases

Medical Immunology

Medical Molecular Biology

Oncology

Etude du rôle des récepteurs nucléaires des oxystérols LXR alpha et LXR bêta dans la physiologie de la reproduction chez la souris femelle

Mouzat, Kevin

11 December 2007

Le cholestérol, élément nutritif indispensable mais toxique en excès, est naturellement converti en oxystérols. Les LXRs (Liver X Receptor) α et β sont les récepteurs nucléaires des oxystérols ayant un rôle hypocholestérolémiant et contrôlant plusieurs fonctions physiologiques. Notre but a été d'étudier leur rôle dans la reproduction chez la femelle. Dans l'ovaire, l'induction de l'ovulation chez des souris lxrα;β-/- provoque une hyperstimulation ovarienne (OHSS), caractérisée par une augmentation de la masse, des troubles vasculaires et de la sensibilité hormonale. Les LXRs contrôlent de plus l'oestradiolémie. Au niveau utérin, nous montrons un rôle spécifique de LXRβ. Les souris lxrβ-/- présentent une séquestration anormale d'esters de cholestérol dans les myocytes associée à un défaut de contractilité utérine. Cette étude montre l'importance des LXRs dans la reproduction chez la femelle et permettra de comprendre le lien entre déséquilibre alimentaire et troubles de la fertilité.

cholestérol

oxystérol

LXR (Liver X Receptor) α et β