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1	Cannabinoid (CB2) Receptor Deficiency Reduces the Susceptibility of Macrophages to Oxidized LDL/Oxysterol-Induced Apoptosis Freeman-Anderson, Natalie, Pickle, Theresa G., Netherland, Courtney D., Bales, Alicia, Buckley, Nancy E., Thewke, Douglas P. 01 December 2008 (has links) Macrophage apoptosis is an important process in the pathophysiology of atherosclerosis. Oxidized low-density lipoproteins (OxLDL) are a major component of lesions and potently induce macrophage apoptosis. Cannabinoid receptor 2 (CB2), the predominant macrophage cannabinoid receptor, modulates several macrophage processes associated with ongoing atherosclerosis; however, the role of CB2 in macrophage apoptosis is unknown. To determine if CB2 influences a macrophage apoptotic pathway relevant to atherosclerosis, we examined the effect of CB2 deficiency on OxLDL-induced macrophage apoptosis. In situ terminal transferase-mediated dUTP nick end labeling (TUNEL) analysis of resident peritoneal macrophages detected significantly fewer apoptotic CB2-/- macrophages than CB2+/+ macrophages after incubation with OxLDL (27.9 ± 4.7% vs. 61.9 ± 8.5%, P < 0.001) or 7-ketocholesterol (7KC) (18.9 ± 10.5% vs. 54.1 ± 6.9%, P < 0.001), an oxysterol component of OxLDL. Caspase-3 activity; proteolytic conversion of procaspase-3; and cleavage of a caspase-3 substrate, PARP, were also diminished in 7KC-treated CB2-/-macrophages. Furthermore, the deactivation of the prosurvival kinase, Akt, in response to 7KC was impaired in CB2-/-macrophages. These results suggest that CB2 expression increases the susceptibility of macrophages to OxLDL-induced apoptosis, in part, by modulating the effect of oxysterols on the Akt survival pathway and that CB2 may influence atherosclerosis by modulating lesional macrophage apoptosis. 7-ketocholesterol Akt atherosclerosis caspase-3 Biomedical Sciences
2	AM-251 and SR144528 are Acyl CoA:Cholesterol Acyltransferase Inhibitors Thewke, Douglas, Freeman-Anderson, Natalie, Pickle, Theresa, Netherland, Courtney, Chilton, Courtney 03 April 2009 (has links) Oxysterol-induced macrophage apoptosis may have a role in atherosclerosis. Macrophages lacking the type 2 cannabinoid receptor (CB2) are partially resistant to apoptosis induced by 7-ketocholesterol (7KC). AM-251 and SR144528 are selective antagonists of CB1 and CB2 receptors, respectively. We observed that both compounds reduce 7KC-induced apoptosis in Raw 264.7 macrophages. As oxysterol-induced macrophage apoptosis requires acyl-coenzymeA:cholesterol acyltransferase (ACAT) activity, we tested their affects on ACAT activity. AM-251 and SR144528 both reduced cholesteryl ester synthesis in unstimulated and acetylated LDL-stimulated Raw 264.7 macrophages, CB2+/+ and CB2-/- peritoneal macrophages, as well as in vitro, in mouse liver microsomes. Consistent with inhibition of ACAT, the development of foam cell characteristics in macrophages by treatment with acetylated LDL was reduced by both compounds. This work is the first evidence that AM-251 and SR144528 are inhibitors of ACAT and as a result, might have anti-atherosclerotic activities independent of their affect on cannabinoid signaling. 7-ketocholesterol ACAT AM-251 apoptosis SR144528 Biomedical Sciences
3	Acyl-coenzyme a:Cholesterol Acyltransferase Promotes Oxidized LDL/Oxysterol-Induced Apoptosis in Macrophages Freeman, Natalie E., Rusinol, Antonio E., Linton, MacRae, Hachey, David L., Fazio, Sergio, Sinensky, Michael S., Thewke, Douglas 01 September 2005 (has links) 7-Ketocholesterol (7KC) is a cytotoxic component of oxidized low density lipoproteins (OxLDLs) and induces apoptosis in macrophages by a mechanism involving the activation of cytosolic phospholipase A2 (cPLA 2). In the current study, we examined the role of ACAT in 7KC-induced and OxLDL-induced apoptosis in murine macrophages. An ACAT inhibitor, Sandoz 58-035, suppressed 7KC-induced apoptosis in P388D1 cells and both 7KC-induced and OxLDL-induced apoptosis in mouse peritoneal macrophages (MPMs). Furthermore, compared with wild-type MPMs, ACAT-1-deficient MPMs demonstrated significant resistance to both 7KC-induced and OxLDL-induced apoptosis. Macrophages treated with 7KC accumulated ACAT-derived [14C]cholesteryl and [ 3H]7-ketocholesteryl esters. Tandem LC-MS revealed that the 7KC esters contained primarily saturated and monounsaturated fatty acids. An inhibitor of CPLA2, arachidonyl trifluoromethyl ketone, prevented the accumulation of 7KC esters and inhibited 7KC-induced apoptosis in P388B1 cells. The decrease in 7KC ester accumulation produced by the inhibition of cPLA 2 was reversed by supplementing with either oleic or arachidonic acid (AA); however, only AA supplementation restored the induction of apoptosis by 7KC. These results suggest that 7KC not only initiates the apoptosis pathway by activating cPLA2, as we have reported previously, but also participates in the downstream signaling pathway when esterified by ACAT to form 7KC-arachidonate. 7-ketocholesterol low density lipoproteins oxysterol esterification Biomedical Sciences
4	Préparation et caractérisation d'extraits d'Argania spinosa et d'huile d'argan et évaluation de leurs effets neuroprotecteurs in vivo et in vitro / Preparation and characterization of extracts argania spinosa and argan oil and evaluation of their neuroprotective effects in vivo and in vitro Badreddine, Asmaa 13 December 2016 (has links) Parmi les huiles naturelles, l'huile d'argan suscite beaucoup d’intérêt. Elle a été utilisée en médecine traditionnelle, en usage externe par les femmes berbères pour les soins corporels et capillaires, et en usage interne pour prévenir certaines maladies cardiovasculaires. L’huile d’argan se caractérise par ses fonctions hypocholestérolémiantes, anti-diabètique et antiproliférative sur des lignées cancéreuses humaines de prostate. Riche en acides gras insaturés, l’huile d’argan est caractérisée également par ses composés mineurs : polyphénols, tocophérols et stérols qui lui confèrent des propriétés antioxydantes. Le rôle des antioxydants alimentaires dans la fonction neurologique et dans certaines maladies liès à l’âge est centrée sur la vitamine E qui est une molécule majoritaire de l’huile d’argan dotée. L’objectif de ce travail a consisté dans un premier temps en une étude phytochimique et en une évalutation du pouvoir antioxydant des extraits d’arganier de deux régions marocaines. Une caractérisation biochimique de la composition de l’huile d’argan a aussi été réalisée. Dans un second temps, une évaluation des effets protecteurs de l’huile d’argan ou certains de ces composés majoritaires a été réalisée in vitro sur des oligodendrocytes murins 158N et in vivo sur des rats. ces effets ont été spécifiés dans un environnement pro-oxydant et cytotoxique mimé par le 7-cétocholestérol (7KC) et l’AlCl3. La cytotoxicité du 7KC induit divers effets au niveau de la mitochondrie (modification fonctionnelle), ce qui conduit à une rupture de l’équilibre RedOx (surproduction d’espèces radicalaires de l’oxygène), à une induction d’apoptose et d’autophagie, à une perte d’adhésion, à une diminution de la prolifération et à des dysfonctions du lysosome. Le 7KC affecte aussi l’expression des marqueurs peroxysomaux (ABCD1, ABCD2, ACOX1) ainsi que l’expression de facteur de transcription PPARα au niveau cellulaire. L’étude in vivo réalisée sur des rats Wistar traités à 100 mg/kg d’AlCl3, a montré qu’AlCl3 induit une rupture de l’équilibre RedOx en diminuant les activités des enzymes anti-oxydantes (catalase, superoxyde dismutase, les glutathions) au niveau du cortex, une altération des fonctions cognitives qui ont été étroitement liées aux maladies neurodégénératives, et des modifications des paramètres plasmatiques. AlCl3 induit une légère perte du poids corporel des rats tout au long de la période de traitement. Dans son ensemble, le travail réalisé montre que l’huile d’argan est capable de s’opposer au stress oxydatif induit par 7KC et AlCl3. L’huile d’argan pourrait être potentiellement être intéressante pour traiter les maladies neurodégénératives. Elle pourrait exercer des effets cytoprotecteurs et antioxydants ce qui permet d’envisager de nouveaux domaines d’applications pour cette huile. / Argan oil has lot of interest for human health. It has been used in traditional medicine for several centuries. The rich composition of argan oil in term of tocopherols and unsaturated fatty acid makes it a very interesting oil regarding its potential actions on risk factors for cardiovascular diseases, hyperlipidemia, hypercholesterolemia and hypertension. Argan oil is also used for skin infections. Previous studies have shown the antiproliferative and pro-apoptotic effects on prostate cancer cell lines. The role of dietary antioxidants in neurological function and in some aged related diseases is centered on vitamin E which is a major molecule of argan oil. The objective of this work was 1) to do a phytochemical study and to evalutate the argan extracts antioxidant properties of argan oils from two Moroccan regions, and 2) to characterize the biochemical composition of argan oils used in this study. Third, we evaluated the protective effects of argan oil and of some of its major compounds in vitro on 158N murine oligodendrocytes, and in vivo in the rat. The effects have been specified in a pro-oxidant environment and cytotoxic mimicked by the 7-ketocholesterol (7KC) and AlCl3. Different methodologies were used: phase contrast microscopy, fluorescence microscopy, histochemistry, flow cytometry, western blotting, and several biochemical methods. Furthermore, 7KC affect the expression of peroxisomal markers (ABCD1, ABCD3, ACOX1) as well as expression of PPARα at the cellular level. The results show that argan oil has cytoprotective and antioxidant effects on 158N murine oligodendrocytes. Argan oil is able to attenuate the overproduction of reactive oxygen species, mitochondrial and lysosomal dysfunctions, loss of cell adhesion and decreased proliferation, cell death by apoptosis and autophagy. We investigate also the effect of aluminum chloride (AlCl3) on brain function and neuronal oxidative stress. Male Wistar rats received daily AlCl3 100 mg/kg for 42 days. AlCl3 exposed group showed a significant reduction in spatial memory performance. Moreover, AlCl3 – treated rats exhibited a marked deterioration of oxidative markers; SOD, CAT, GSH, and changes in the plasma parameters. AlCl3 slightly affects the body weight of rat. Argan oils (or some of their compounds) have cytoprotective and antioxidant effects on 158N murine oligodendrocytes. These different molecules attenuate oxidative stress and could be potentially useful for treating neurodegenerative diseases. Argan oil could exert cytoprotective and antioxidant effects which allows to consider new fields of application for this oil. It is possible to envisage that a controlled diet or functional foods with argan oil could help to prevent some forms of neurodegeneration. / من بين الزيوت الطبيعية أثار زيت أركان الكثير من الاهتمام. فقد استخدم زيت الأركان في الطب التقليدي، من قبل نساء البربرللعناية بالجسم و الشعر، و لمنع بعض الأمراض القلب و الأوعية الدموية . يتميز زيت الأركان بوظائفه التي تخص خفض الكوليسترول، مكافحة داء السكري ومكافحة التكاثر في خطوط الخلايا السرطانية البشرية للبروستات. يعتبر زيت اركان غنيا بالأحماض الدهنية غير المشبعة، البوليفينول، التوكوفيرول و الستيرول .هذه المواد تجعله مادة مضادة للأكسدة.يتركز دور مضادات الأكسدة الغذائية في وظيفة الجهاز العصبي وبعض الأمراض المرتبطة بالعمر على فيتامين E الذي يعتبر المكون الرئيسي لزيت أركان . الهدف من هذا العمل هو أولا دراسة كيميائية لنبتة اركان وتقييم القوة المضادة للأكسدة لمقتطفات هذه النبتة مع توصيف شامل لتركيبة زيت أركان المستخدم في دراستنا.وثانيا تقييم للآثار الوقائية لهذا الزيت ولبعض مركباته الرئيسية في المختبر على الخلايا العصبيةN158 وعلى فئران من فئة وينستار. وقد تم تحديد فوائد زيت اركان في بيئة سامة بواسطة KC7 و AlCl3 النتائج المحصل عليها تكمن في تأثيرات مختلفة على الميتوكوندريا، الأمر الذي يؤدي إلى تمزق في توازن الأكسدة , استحثاث موت الخلايا المبرمج والالتهام الذاتي وفقدان الإلتصاق. يؤثر KC7 أيضا على الناقلات البيروكسيزومية (ABCD1,ABCD3,ACOX1) على المستوى الخلوي PARaP. الدراسة المجراة على الفئران بجرعة 100 ملغم/كغم من AlCl3 أظهرت أن AlCl3 يؤدي الى تمزق التوازن الأكسدة عن طريق الحد من أنشطة الإنزيمات المضادة للأكسدة (الكاتلاز,الجلوتاثيون،سيبيروكسيد) على مستوى المادة الرمادية بالمخ وضعف الادراك الذي ارتبط ارتباطا وثيقا بالأمراض العصبية والتغيرات في معالم البلازما. وبشكل عام، تشير الدراسة ان زيت أركان أو البعض من مكوناته قادرون على مكافحة الأكسدة الناجمة عن KC7 و AlCl3 . Huile d’argan 7-cétocholestérol Aluminium Neurodégénérescence Argan oil 7-ketocholesterol Aluminium Neurodegeneration 572 571.6
5	Stimulation of Akt Poly-Ubiquitination and Proteasomal Degradation in P388D1 Cells by 7-Ketocholesterol and 25-Hydroxycholesterol Liu, June, Netherland, Courtney, Pickle, Theresa, Sinensky, Michael S., Thewke, Douglas P. 01 July 2009 (has links) Akt plays a role in protecting macrophages from apoptosis induced by some oxysterols. Previously we observed enhanced degradation of Akt in P388D1 moncocyte/macrophages following treatment with 25-hydroxycholesterol (25-OH) or 7-ketocholesterol (7-KC). In the present report we examine the role of the ubiquitin proteasomal pathway in this process. We show that treatment with 25-OH or 7-KC results in the accumulation of poly-ubiquitinated Akt, an effect that is enhanced by co-treatment with the proteasome inhibitor MG-132. Modification of Akt by the addition of a Gly-Ala repeat (GAr), a domain known to block ubiquitin-dependent targeting of proteins to the proteasome, resulted in a chimeric protein that is resistant to turn-over induced by 25-OH or 7-KC and provides protection from apoptosis induced by these oxysterols. These results uncover a new aspect of oxysterol regulation of Akt in macrophages; oxysterol-stimulated poly-ubiquitination of Akt and degradation by the proteasomal pathway. 25-Hydroxycholesterol 7-Ketocholesterol Akt apoptosis Gly-Ala repeat oxysterols proteasome ubiquitination Biomedical Sciences
6	The effect of α-tocopherol on the membrane dipole potential Le Nen Davey, Sterenn January 2011 (has links) α-Tocopherol has a well known antioxidant action but is also considered likely to exert significant non-antioxidant effects in cell membranes. Due to its lipophilic nature α-tocopherol inserts into biological membranes where it influences the organisation of the component lipids and may therefore influence biophysical parameters including the membrane dipole potential. The dipole potential has been demonstrated to modulate the function of several membrane associated proteins and perturbation of this physical parameter by α-tocopherol may prove to be a significant non-antioxidant mechanism underlying several of its cellular effects. This study investigates the influence of α-tocopherol, and the non-antioxidant structural analogue α-tocopherol succinate, on the membrane dipole potential employing fluorescence spectroscopy techniques with the dipole potential sensitive probe Di-8-ANEPPS. Similar techniques are utilised with the surface potential sensitive probe FPE to investigate the interaction of the charged α-tocopherol succinate molecule with membranes. α-Tocopherol and α-tocopherol succinate are shown to decrease the dipole potential of egg-phosphatidylcholine vesicles and Jurkat T-lymphocyte cell membranes. This effect is placed in the context of the significant influence of membrane cholesterol oxidation on the dipole potential. 7-ketocholesterol, an oxidised form of cholesterol, significantly influences several cellular processes and is thought to mediate these effects, in part, through its physical effects on the cell membrane. These include altering the composition, and therefore biophysical properties, of rafts; structures which are considered to support the function of a host of membrane proteins. This study attempts to correlate the effect of 7-ketocholesterol on the dipole potential of microdomains with the influence of the oxysterol on the function of two microdomains associated receptors: P-glycoprotein and the insulin receptor, assessed by determining the extent of ligand binding using flow fluorocytometry. α-Tocopherol has been suggested to inhibit the raft-mediated effects of 7-ketocholesterol and the influence of this molecule on the effect of 7-ketocholesterol on the dipole potential are investigated as a potential mechanism for this inhibition. It is hypothesized that α-tocopherols may protect against the deleterious effects of cholesterol oxidation in cell membranes by excluding 7-ketocholesterol from specific microdomains, of which rafts are a subset, acting to preserve their dipole potential and maintain the function of the proteins they support. However, where significant cholesterol oxidation has previously occured the concurrent changes in the microdomain landscape of the membrane is suggested to prevent α-tocopherol succinate from eliciting this protective effect. 572
7	Extraction, caractérisation physicochimique, profil lipidique et activité cytoprotectrice d'huiles de Chardon-Marie de Tunisie / Extraction, physicochemical characterization, lipid profile and cytoprotective activity of milk thistle seeds oil from Tunisia Meddeb, Wiem 04 December 2018 (has links) La famille des Astéracées est économiquement très importante, car beaucoup de ses plantessont cultivées principalement pour leurs valeurs alimentaires dont la laitue (Lactuca), lachicorée (Cichorium) et le tournesol (Heliantus annuus) cultivé pour son huile. Une despropriétés typiques de cette famille, dont fait partie le Silybum marianum, est la richesse deses huiles en divers composés naturels bénéfiques pour la santé. Actuellement et pour lesdécennies à venir, les maladies liées à l’âge constituent un problème majeur de santépublique. Prévenir leur apparition ou s'opposer à leur évolution est un objectif majeur. Dansce contexte, les activités cytoprotectrices de l'huile de graines de Silybum marianumoriginaires de différentes régions de la Tunisie ont été étudiées sur le modèled’oligodendrocytes murins 158N en utilisant le 7-cétocholestérol (7KC) comme agentcytotoxique. Le 7KC a été utilisé car il est augmenté dans le plasma, le liquide céphalorachidienet/ou certains tissus (paroi vasculaire et intestinale, rétine, cristallin, cerveau) depatients atteints de maladies liées à l’âge (maladies cardiovasculaires, maladie d'Alzheimer,dégénérescence maculaire liée à l’âge, cataracte) ou de maladies inflammatoires évolutives del’intestin. Le 24S-hydroxycholestérol (24S-OHC) a aussi été utilisé car il est augmenté dans lecerveau aux stades précoces de la maladie d’Alzheimer. Afin de déterminer la composition del'huile de Silybum marianum (acides gras, tocophérols, polyphénols, phytostérols) diversestechniques physicochimiques et de chromatographie liquide et gazeuse ont été utilisées. Lespropriétés anti-oxydantes de l'huile de Silybum marianum ont été définies par les tests KRL,FRAP et DPPH et les propriétés cytoprotectrices par des techniques complémentaires demicroscopie, de cytométrie en flux et de biochimie. Les études sur la compositionphysicochimique des huiles des graines de Silybum marianum de différentes régions de laTunisie (Bizerte, Sousse, Zaghouan) ont montré que ces dernières sont riches en Vitamine E(α-tocophérol) et sont fortement anti-oxydantes. Les acides gras majeurs sont l'acidelinoléique (C18:2) (valeurs comprises entre 57,0% et 60,3%) et l'acide oléique (C18:1) (lesvaleurs se situent entre 15,5% et 22,4%). Trois acides phénoliques ont également étéidentifiés (vanillique, p-coumarique et silybine), avec une prédominance de l'acide vanillique.Sur les cellules 158N, ces huiles atténuent la cytotoxicité du 7KC et du 24S-OHC: perted'adhérence cellulaire, altération de la membrane plasmique, dysfonctionnementmitochondrial, surproduction d’espèces réactives de l’oxygène, induction de l'apoptose(condensation et / ou fragmentation nucléaire, activation de la caspase-3 et clivage PARP) etautophagie (activation de LC3-I en LC3-II). L'atténuation des effets cytotoxiques du 7KC etdu 24S-OHC observée avec les huiles de Silybum marianum est de l'ordre de celle observéeavec l’α-tocophérol utilisé comme témoin positif. La composition chimique et les résultatsobtenus cellules 158N sont en faveur d’effets bénéfiques de l’huile de Chardon-Marie sur lasanté humaine et la prévention de certaines maladies liées à l’âge. / The family Asteraceae is economically very important because many of its plants are grownmainly for their food values including lettuce (Lactuca), chicory (Cichorium) and sunflower(Heliantus annuus) grown for its oil. One of the typical properties of this family, whichincludes Silybum marianum, is the richness of its oils in various natural compounds beneficialto health. Currently and for decades to come, age-related diseases are a major public healthproblem. Preventing their appearance or opposing their evolution is a major objective. In thiscontext, the cytoprotective activities of Silybum marianum seed oil originating from differentarea of Tunisia were studied on the 158N murine oligodendrocyte model using 7-ketocholesterol (7KC) and 24S-hydroxycholesterol (24S-OHC) as a cytotoxic agent. The 7KChas been used because it is increased in plasma, cerebrospinal fluid and / or tissues (vascularand intestinal wall, retina, lens, brain) of patients with age-related diseases (cardiovasculardiseases, Alzheimer's disease, age-related macular degeneration, cataract) or inflammatorybowel disease. The 24S-OHC was used because it is increased in the brain at the early stagesof Alzheimer’s disease. In order to determine the composition of Silybum marianum oil (fattyacids, tocopherols, polyphenols, phytosterols) various liquid and gas chromatographytechniques were used. The anti-oxidant properties of Silybum marianum oil were defined byKRL, FRAP and DPPH tests and cytoprotective properties by complementary microscopy,flow cytometry and biochemistry techniques. Studies on the physicochemical composition ofSilybum marianum seeds oils from different regions of Tunisia (Bizerte, Sousse, Zaghouan)have shown that the latter are rich in vitamin E (α-tocopherol) and are strongly antioxidant.The major fatty acids are linoleic acid (C18:2) (values between 57.0% and 60.3%) and oleicacid (C18:1) (values between 15.5% and 22.4%).. Three phenolic acids have also beenidentified (vanillic, p-coumaric and silybin), with a predominance of vanillic acid. On 158Ncells, these oils attenuate the cytotoxicity of 7KC and 24S-OHC: loss of cell adhesion,alteration of the plasma membrane, mitochondrial dysfunction, overproduction of reactiveoxygen species, induction of apoptosis (nuclear condensation and / or fragmentation). ,activation of caspase-3 and PARP cleavage) and autophagy (activation of LC3-I in LC3-II).The attenuation of cytotoxic effects of 7KC and 24S-OHC observed with Silybum marianumoils is of the order of that observed with α-tocopherol used as a positive control. The chemicalcomposition and results obtained on 158N cells are in favor of the beneficial effects of milkthistle oil on human health and on its ability to prevent some age-related diseases. Caractérisation physico-Chimique Oligodendrocytes murins 158N Maladies liées à l’âge 7-Cétocholestérol 24S-Hydroxycholestérol Silybum Marianum seed oil from Tunisia Physcochemical characteristics Agerelated diseases 158N murine oligodendrocytes 7-Ketocholesterol 24S-Hydroxycholesterol 572 571.6 612
8	Implication du canal potassium Kv3.1 dans la lipotoxicité du 7-cétocholestérol, 24S-hydroxycholestérol et de l’acide tétracosanoïque sur des cellules nerveuses 158N et BV-2 : Etude des relations entre Kv3.1, homéostasie potassique et métabolisme peroxysomal dans la maladie d’Alzheimer / Involvement of Kv3.1 potassium chanels in 7-ketocholesterol, 24S-hydroxycholesterol and C24 : 0-induced lipotoxicity on 158N and BV-2 cells : relationships between KV3.1 homeostasis, peroxisomal metabolism and Alzheimer's disease Bezine, Maryem 06 October 2017 (has links) Le potassium (K+) est impliqué dans la régulation de l’excitabilité cellulaire, la régulation du cycle cellulaire, la viabilité cellulaire, la neuroprotection et le maintien des fonctions microgliales et oligodendrocytaires. Le dysfonctionnement des canaux potassiques, décrit dans plusieurs maladies neurodégénératives comme la Maladie d’Alzheimer (MA), la sclérose en plaques (SEP), la maladie de Parkinson et la maladie de Huntington, pourrait être une potentiel cible thérapeutique. Les mécanismes toxiques sous-jacents de ces pathologies neurodégénératives impliquent des oxystérols, dérivés oxydés du cholestérol, et des acides gras en relation avec le métabolisme peroxysomal. Le 7-cétocholestérol (7KC), le 24S-hydroxycholestérol (24S-OHC) et l'acide tétracosanoïque (C24: 0), souvent trouvés à des taux élevés au niveau du cerveau et dans le plasma de patients atteints de maladies neurodégénératives (MA, maladie de Nieman-Pick, SEP, maladie de Parkinson, maladie de Huntington et X-ALD conduisent une rupture de l’équilibre Redox qui aboutirait à la neurodégénérescence. Dans ce contexte, il est intéressant de déterminer l’éventuelle connexion entre environnement lipidique et homéostasie potassique. L’étude in vitro a été réalisée sur des olygodendrocytes murins 158N et les cellules microgliale BV-2. Nous avons montré que la lipotoxicité du 7KC, 24S-OHC et C24:0 implique une rétention du K+ faisant intervenir les canaux potassium voltage dépendant (Kv). Ces résultats ont montré que l'inhibition des canaux Kv conduisant à une augmentation la [K+]i contribue à la cytotoxicité du 7KC, 24S-OHC et C24:0. Nous nous sommes focalisés sur le canal Kv3.1b. La retention du K+ induite par les oxystérols (7KC et 24S-OHC) serait sous le contrôle de Kv3.1b. L’étude clinique réalisée sur du plasma de MA a révélé une corrélation négative entre le taux d’acide docosahexaénoïque (DHA) et la concentration de K+. Chez les souris transgéniques J20, modèle de la MA, l’étude de la topographie d’expression de Kv3.1b et d’Abcd3, au niveau de l’hippocampe et du cortex, a montré une baisse de l’expression de ces deux marqueurs. Dans leur ensemble, les résultats obtenus ont établi des relations entre lipotoxicité, métabolisme peroxysomal et altération de l’homéostasie potassique dans la neurodégénérescence et suggèrent une possible modulation de l’expression et de l’activité de kv3.1b dans la physiopathologie des maladies neurodégénératives. / Potassium (K+) is involved in the regulation of cellular excitability, cell cycle regulation, cell viability, neuroprotection and maintenance of microglial and oligodendrocytic functions. Potassium dysfunction, described in several neurodegenerative diseases such as Alzheimer's Disease (AD), multiple sclerosis (MS), Parkinson's disease and Huntington's disease, may be a potential therapeutic target. The underlying toxic mechanisms of these neurodegenerative pathologies involve oxysterols, which are oxidized cholesterol derivatives, and fatty acids including those associated with peroxisomal metabolism. 7-ketocholesterol (7KC), 24S-hydroxycholesterol (24S-OHC) and tetracosanoic acid (C24:0), often found at increased levels in the brain and plasma of patients with neurodegenerative diseases (Nieman-Pick disease, MS, Parkinson's disease, Huntington's disease and X-ALD) lead to a breakdown of the redox equilibrium leading to neurodegeneration. In this context, it is interesting to determine the possible connection between the lipid environment and potassium homeostasis The in vitro study was carried out on 158N murine oligodendrocytes and microglial BV-2 cells. We have shown that the lipotoxicity of 7KC, 24S-OHC and C24:0 implies retention of K+ involving the voltage dependent potassium channels (Kv). These results have shown that inhibition of Kv channels lead to an increase in [K +] i contributing to the cytotoxicity of 7KC, 24S-OHC and C24:0. The retention of K+ induced by oxysterols (7KC and 24S-OHC) would be under the control of Kv3.1b. A clinical study, on plasma of patients with Alzheimer’s disease, revealed a negative correlation between docosahexaenoic acid (DHA) and K+ concentration. In the J20 mice, a transgenic model of Alzheimer’s disease, the expression of Kv3.1b and Abcd3 was decreased in the hippocampus and cortex. Overall, the results obtained established relationships between lipotoxicity, peroxisomal metabolism and potassium homeostasis in neurodegeneration and suggest a possible modulation of the expression and activity of kv3.1b in the pathophysiology of neurodegenerative diseases. So, modulation of Kv3.1 could constitute a new therapeuthic approach against some neurodegenerative diseases. 7-cétocholestérol 24S-hydroxycholestérol Acide tétracosanoïque (C24:0) Potassium Canaux Kv Kv3.1b Neurodégénérescence Maladie d’Alzheimer Oligodengrocytes murins 158N Cellules microgliales murines BV-2 7-ketocholesterol 24S-hydroxycholesterol Tetracosanoic acid (C24:0) Potassium Kv channels Kv3.1b Neurodegeneration Alzheimer’s disease 158N murine oligodendrocytes Murine microglial BV-2 cells 571.6 572 610

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