Implication de l'acide docosanoïque (C22 0) et des acides gras à très longue chaîne (acide tétracosanoïque (C24 0), acide hexacosanoïque ( C26 0) dans la maladie d'Alzheimer : aspects biologiques et cliniques / Involvment of docosanoïc acid (C22=0), and of very long chain fatty acids (tetracosanoïc acid (C24=0), hexacosanoïc acid (C26=0) in Alzheimer's disease : biological and clinical aspects

Zarrouk, Amira

19 December 2013

Au niveau du cerveau et dans le plasma de malades atteints de maladie d’Alzheimer (MA), l’accumulation de C22:0 et d’acides gras à très longue chaîne (C24:0 ; C26:0), la diminution d’acide docosahexaenoique (C22:6 n-3) et les modifications quantitatives et qualitatives de plasmalogènes suggèrent l’implication de dysfonctions peroxysomales. En fonction de ces constatations, les activités biologiques de C22:0, C24:0 et C26:0 ont été recherchées sur des cellules neuronales humaines SK-N-BE. La lipotoxicité des acides gras (C22:0, C24:0 et C26:0) induit divers effets au niveau des mitochondries (modifications topographiques, morphologiques et fonctionnelles), conduit à une rupture de l’équilibre RedOx (surproduction d’espèces radicalaires de l’oxygène, modification de l’activité des enzymes anti-oxydantes : catalase, SOD, GPx), à une peroxydation lipidique et à une désorganisation du cytosquelette (microfilaments d’actine, tubuline, neurofilaments). Ces acides affectent aussi l’amyloïdogenèse et la tauopathie. L’amyloïde béta favorise aussi l’accumulation intracellulaire de C22:0, C24:0 et C26:0. A fortes concentrations, ces acides gras induisent une mort cellulaire non apoptotique. Par ailleurs, les données immunohistochimiques en relation avec l’expression de marqueurs peroxysomaux (ABCD1, ABCD2, ABCD3, ACOX1 et catalase) au niveau du cerveau de souris transgéniques APP PS1 ΔE9 ainsi que les profil d’acide gras obtenus sur le cerveau et le sang de ces souris suggèrent qu’elles pourraient constituer un bon modèle pour l’étude des relations entre MA et métabolisme peroxysomal. L’étude clinique réalisée sur plasma et érythrocytes de malades déments (MA, démences vasculaires, autres démences) montre une forte accumulation de C22:0, C24:0 et C26:0. Le C26:0 pourrait constituer un excellent biomarqueur de la MA. Le C18:0 à est aussi augmenté ainsi que les acides gras n-6. De forts indices de stress oxydant sont aussi révélés. Dans son ensemble, le travail réalisé suggère que les acides gras (C22:0, C24:0 et C26:0) ainsi que le métabolisme des acides gras en relation avec le métabolisme peroxysomal pourraient contribuer à la neurodégénéréscence associée aux démences incluant la MA / In the brain and in the plasma of patients with Alzheimer’s disease (AD), marked accumulation of C22:0 and of very long chain fatty acids (C24:0 ; C26:0) have been reported. Important decreases of docosahexaenoic acid (DHA; C22:6 n-3) have also been described as well as quantitative and qualitative modifications of plasmalogens. Altogether, these lipid modifications suggest an implication of peroxisomal metabolism disorders in the physiopathology of AD. Therefore, the biological activities of C22:0, C24:0 and C26:0 have been studied on human neuronal cells SK-N-BE. On these cells, the lipotoxicity of fatty acids (C22:0, C24:0 and C26:0) leads to various cellular modifications: topographical, morphological and functional changes at the mitochondrial level, rupture of RedOx equilibrium (overproduction of reactive oxygen species, modification of the activity of enzymes involved in anti-oxidant defenses: catalase, SOD, GPx), lipid peroxidation, cytoskeleton disorganization (actin microfilaments, tubulin, neurofilaments). These fatty acids also favor amyloidogenesis and tauopathy. At elevated concentrations, these fatty acids trigger a non apoptotic mode of cell death. Moreover, data obtained by immunohistochemistry with antibodies raised against peroxisomal components (ABCD1, ABCD2, ABCD3, ACOX1 and catalase) on histological tissue sections of the brain of transgenic mice APP PS1 ΔE9 as well as lipidomic analysis performed on the blood and the brain of these mice suggest that they could constitute interesting model to study the relationships between AD and peroxisomal metabolism. The clinical study performed on the plasma and on the erythrocytes of patients with dementia (AD, vascular dementia, other dementia) revealed an important accumulation of C22:0, C24:0 and C26:0. Hexacosanoic acid (C26:0) might constitute an excellent biomarker of AD. The fatty acid C18:0 and (n-6) fatty acids have also been found at increased concentrations. A strong oxidative stress has also been revealed. Altogether, our data support that the fatty acids (C22:0, C24:0 and C26:0) as well as the fatty acid metabolism depending on the peroxisome might contribute to neurodegeneration leading to various types of dementia including AD

Acide docosanoIque (C22:0)

Acides gras à très longue chaîne

Acide tétracosanoique (C24:0)

Acide hexacosanoique (C26:0)

Lipotoxicité

Biomarqueurs

Souris transgénique APP PS1 ΔE9

Peroxysome

Maladie d’Alzheimer

Démences

Docosanoic acid (C22:0)

Very long chain fatty acids

Tetracosanoic acid (C24:0)

Hexacosanoic acid (C26:0)

Lipotoxicity

Biomarkers

Transgenic mouse APP PS1 ΔE9

Peroxisome

Alzheimer’s disease

Demencia

571.6

572

616.8

Oxidative Stress Induces Mitochondrial Compromise in CD4 T Cells From Chronically HCV-Infected Individuals

Schank, Madison B., Zhao, Juan, Wang, Ling, Nguyen, Lam N., Cao, Dechao, Dang, Xindi, Khanal, Sushant, Zhang, Jinyu, Zhang, Yi, Wu, Xiao Y., Ning, Shunbin, Elgazzar, Mohamed A., Moorman, Jonathan P., Yao, Zhi Q.

01 January 2021

We have previously shown that chronic Hepatitis C virus (HCV) infection can induce DNA damage and immune dysfunctions with excessive oxidative stress in T cells. Furthermore, evidence suggests that HCV contributes to increased susceptibility to metabolic disorders. However, the underlying mechanisms by which HCV infection impairs cellular metabolism in CD4 T cells remain unclear. In this study, we evaluated mitochondrial mass and intracellular and mitochondrial reactive oxygen species (ROS) production by flow cytometry, mitochondrial DNA (mtDNA) content by real-time qPCR, cellular respiration by seahorse analyzer, and dysregulated mitochondrial-localized proteins by Liquid Chromatography-Mass Spectrometry (LC-MS) in CD4 T cells from chronic HCV-infected individuals and health subjects. Mitochondrial mass was decreased while intracellular and mitochondrial ROS were increased, expressions of master mitochondrial regulators peroxisome proliferator-activated receptor 1 alpha (PGC-1α) and mitochondrial transcription factor A (mtTFA) were down-regulated, and oxidative stress was increased while mitochondrial DNA copy numbers were reduced. Importantly, CRISPR/Cas9-mediated knockdown of mtTFA impaired cellular respiration and reduced mtDNA copy number. Furthermore, proteins responsible for mediating oxidative stress, apoptosis, and mtDNA maintenance were significantly altered in HCV-CD4 T cells. These results indicate that mitochondrial functions are compromised in HCV-CD4 T cells, likely the deregulation of several mitochondrial regulatory proteins.

adult

aged

CD4-positive t-lymphocytes (immunology)

DNA

mitochondrial

female

hepatitis c

chronic (immunology)

humans

male

middle aged

mitochondria (genetics

immunology)

oxidative stress

reactive oxygen species (immunology)

young adult

mtDNA

mtTFA

HCV

mitochondrial respiration

oxidative stress

Internal Medicine

From Mammalian Cell Culture to Aquatic Species: Deciphering the role of the Kynurenine-Tryptophan Ratio under Environmental Stress / Kynurenine-Tryptophan Ratio in Stress: Cells to Species

Jamshed, Laiba

January 2024

Monitoring the impact of anthropogenic activities, particularly in industrial regions, requires ecological screening tools and frameworks that provide a comprehensive understanding of ecosystem responses to environmental changes. Biological indicators, organisms like algae, insects, fish, and sentinel mammals, are critical for assessing ecosystem health, particularly in areas of high industrial activity. The aim of this thesis was to identify a cross-species biomarker that can assess organismal health and environmental stress across various species, organs, and biological matrices. A range of biological systems and signaling pathways related to xenobiotic metabolism, energy homeostasis, immune responses, and stress adaptation were explored, leading to the identification of the Tryptophan-Kynurenine Pathway, which consumes 60-90% of tryptophan in vertebrates. Tryptophan and its metabolites play key roles in diverse physiological processes, including cell growth and maintenance, immunity, disease states, and the coordination of adaptive responses to environmental and dietary cues. This adaptive response suggests that kynurenine-tryptophan ratio (KTR) may serve as a marker for exposure to a variety of environmental stress conditions, including toxicants, nutrient scarcity, predatory stress, and habitat loss—stressors that are prevalent in areas of high industrial activity. In recent years, the KTR is increasingly recognized as a sensitive biomarker in human diseases induced or exacerbated by stress; however, its role in environmental exposure and wildlife health remains unexplored. This thesis explores the question of whether KTR can be utilized as a cross-species biomarker for environmental stress or environmental exposure to toxicants, particularly focusing on the Athabasca Oil Sands Region (AOSR). In vitro studies with mammalian hepatocytes exposed to polycyclic aromatic compounds (PACs): benzo[a]pyrene (BaP), and a Bitumen Water Accommodated Fraction (BitWAF) demonstrated that KTR increases were driven by elevated kynurenine levels, indicating disruption of tryptophan metabolism via the aryl hydrocarbon receptor (AhR). Further studies using acid extractable organics from Oil Sands Process-Affected Water (OSPW), Naphthenic Acid Fraction Components (NAFCs) showed metabolic reprogramming, including altered glucose and fatty acid uptake and mitochondrial dysfunction, mediated through PPARα activation and upregulation of Tdo2, the enzyme responsible for kynurenine production. In vivo studies of longnose and white suckers from the AOSR were conducted to assess the relationship between KTR and CYP1 enzyme activity (EROD). These studies revealed species-specific responses, with an inverse correlation between KTR and EROD in longnose suckers and a direct correlation in white suckers. These findings validate KTR as a biomarker for environmental exposure in wildlife, with significant implications for monitoring ecosystem health. Collectively, this work demonstrates the potential of KTR as a novel biomarker for environmental toxicology, offering a valuable tool for assessing organismal stress across species in response to environmental contaminants. / Thesis / Doctor of Philosophy (PhD) / Human activities, especially industrial operations, can significantly impact the environment. To monitor these effects, scientists use various tools and organisms to assess ecosystem health. This research introduces a new approach to measuring environmental stress in wildlife by focusing on two key molecules: tryptophan and kynurenine. These molecules are part of a conserved biological pathway that helps all organisms manage stress, repair cells, adapt to their environment, and maintain overall health. Tryptophan, an essential amino acid, is broken down into kynurenine, and the balance between them— known as the kynurenine-tryptophan ratio (KTR)—can indicate the level of stress an organism is experiencing. This thesis investigates whether KTR can detect environmental stress caused by industrial activity, particularly from petroleum-derived chemicals in the Athabasca Oil Sands Region (AOSR). In laboratory experiments, mammalian liver cells were exposed to oil sands compounds and complex mixtures from oil sands wastewater. These compounds changed KTR, showing that the liver’s stress response was activated, and tryptophan metabolism was disrupted. The study also found that these chemicals affected cellular energy use and the way cells process fats and sugars. Furthermore, we examined fish species in the AOSR: longnose and white suckers. Results showed that KTR varied depending on the species and the location of exposure. In white suckers, KTR increased in response to stress, while in longnose suckers, it decreased, indicating species-specific responses to environmental changes. Overall, our findings suggest that KTR could serve as a useful tool for measuring environmental stress in different species and ecosystems, especially in areas affected by anthropogenic or industrial activity. Understanding how KTR changes in response to pollution can help scientists better monitor and protect wildlife and ecosystem health.

Toxicology

Stress

Biomarker

Environmental Contaminants

Oil Sands

Tryptophan Metabolism

Metabolic Reprogramming

Mitochondrial Dysfunction

Kynurenine

Aryl-Hydrocarbon Receptor

Ligand-Activated Receptors

Kynurenine-Tryptophan Ratio

Mammalian Model

Fish

Polycyclic Aromatic Compounds

Rat Hepatocytes

Naphthenic Acid Fraction Component

Bitumen

Water Accommodated Fraction

Oil Sands Process Affected Water

Neonatal Cardiac Fatty Acid Metabolism

Lam, Victoria Hol Mun

Unknown Date

No description available.

1 Introduction

6 General discussion