Impact du diabète et de l'obésité sur la pathologie Tau dans la maladie d'Alzheimer

La maladie d’Alzheimer (MA) est la démence la plus répandue dans le monde. Les deux marqueurs histopathologiques de la MA sont les plaques amyloïdes, formées d'agrégats du peptide bêta-amyloïde, et les enchevêtrements neurofibrillaires, composés de la protéine Tau anormalement hyperphosphorylée. La pathologie Tau a un rôle important dans la maladie puisque son étendue corrèle avec le degré du déficit cognitif des patients. La majorité des cas de MA est d’origine sporadique dont les causes demeurent encore méconnues; elles semblent être multifactorielles, avec des facteurs externes, biologiques et/ou génétiques qui accélèrent la manifestation de la maladie. Des études épidémiologiques ont démontré que le statut métabolique des individus au cours de leur vie influence le risque de MA. En effet, des altérations métaboliques comme un diabète de type 2 (DT2) ou une obésité sont reconnus comme facteurs de risque de la MA. Or, le nombre de cas de DT2 et d’obésité est en pleine croissance à cause de la sédentarisation des populations, ce qui suggère que l’incidence de la MA pourrait suivre cette inquiétante augmentation. Il est donc indispensable de mieux comprendre l’impact de ces altérations métaboliques sur la MA afin d’espérer ralentir son évolution. De nombreuses études ont évalué l’impact du DT2 et de l’obésité sur la pathologie amyloïde in vivo, mais les études sur la pathogenèse de Tau sont plus rares et présentent une importante divergence des résultats. Dans ce contexte, notre hypothèse est que le diabète et de l’obésité peuvent promouvoir la pathologie Tau in vivo. Notre 1e objectif était donc d’examiner la phosphorylation de la protéine Tau dans deux modèles murins qui développent spontanément une obésité et un DT2 : les souris ob/ob et db/db. Une hyperphosphorylation de Tau est observée dans le cerveau des deux modèles, principalement due à une hypothermie. En effet, ces souris sont hypothermiques et la normothermie restaure une phosphorylation de Tau semblable aux souris contrôles. Comme la caféine s'est révélée bénéfique pour le diabète, l'obésité et la phosphorylation de Tau, nous l'avons utilisé comme traitement thérapeutique chez les souris ob/ob. Cependant, la consommation de caféine chronique a exacerbé l'hyperphosphorylation de Tau en favorisant une hypothermie plus profonde. Notre 2e objectif était d’évaluer l’impact du DT2 et de l’obésité sur pathogenèse de Tau dans des conditions plus proches de la pathologie humaine. Pour cela, nous avons nourri des souris hTau, exprimant la protéine Tau humaine, avec des régimes riches en graisses, cholestérol et/ou sucre, reconnus pour induire l’obésité et le DT2 chez l’humain. D'autre part, la restriction calorique et l'exercice physique ont été caractérisés pour réduire l'incidence et l’évolution des troubles métaboliques ainsi que la MA. Nous avons évalué leur impact sur la pathologie Tau chez ces souris obèses comme stratégies thérapeutiques. Nous n'avons trouvé aucun effet du gras, du sucre et du cholestérol, même combinés, sur la phosphorylation, l'O-GlcNAcylation, l'épissage, le clivage et l'agrégation de Tau, suggérant que leur surconsommation n’aggrave pas la pathologie Tau chez ces souris. De plus, nous avons observé un effet bénéfique de l'exercice sur la phosphorylation Tau et un effet délétère de la restriction calorique sur l'agrégation de Tau chez les souris hTau obèses. Enfin, notre 3e objectif était d’explorer les effets d’une déficience en insuline sur la pathologie Tau chez les souris hTau par injection de streptozotocine, une toxine qui détruit les cellules productrices d'insuline. Les souris hypoinsulinémiques présentent une hyperphosphorylation de Tau dans le cerveau sans agrégation, par inhibition de PP2A, la phosphatase majeur de Tau. L’ensemble de ces résultats suggère que i) les perturbations métaboliques peuvent induire l'hyperphosphorylation de Tau de manière indirecte, en perturbant la thermorégulation; ii) les régimes hypercaloriques ne semblent pas modifier l'homéostasie de Tau en conditions strictement contrôlées; iii) la déficience en insuline peut induire l'hyperphosphorylation de Tau sans pour autant conduire à son agrégation. Nous révélons également que les stratégies utilisées pour réduire la MA doivent être adapté avec le statut métabolique des patients pour éviter l'exacerbation des diverses neuropathologies de la MA. Ces données se confrontent à certains travaux publiés et montrent que les relations entre le métabolisme et la MA peuvent être moins directes que pensées. Ce travail pose des bases de rigueur et de méthodologie qui pourrait contribuer à éviter certains biais pour les études futures.Alzheimer's disease (AD) is the leading form of dementia worldwide. The two histopathological markers of AD are senile plaques composed of amyloid- peptide, and neurofibrillary tangles of abnormally hyperphosphorylated Tau protein. Tau pathology is important since it correlates with the degree of cognitive impairment in AD patients. The majority of AD cases are of sporadic form whose causes are still unknown; it seems to be multifactorial, with external, biological and/or genetic, which accelerate the manifestation of the disease. Epidemiological studies have shown that metabolic status of individuals during their life strongly increases the risk of developing AD. Indeed, metabolic disorders such as type 2 diabetes (T2D) or obesity are described as risk factors for AD. New cases of T2D and obesity is increasing because of people sedentarization, suggesting that the incidence of AD cases could follow this worrying growth. Therefore, it is essential to better understand the impact of these metabolic disorders on AD. Many studies have evaluated the impact of T2D and obesity in vivo on amyloid pathology, but there are fewer studies on the pathogenesis of Tau and they exhibit some discrepencies between results. In this context, our hypothesis is that diabetes and obesity could promote Tau pathology in vivo. Our first aim was thus to evaluate the phosphorylation of Tau protein in two mouse models that spontaneously develop obesity and DT2: the ob/ob and db/db mice. Significant hyperphosphorylation of Tau was observed in the brain of these two models, mainly due to hypothermia. Indeed, ob/ob and db/db mice were hypothermic and normothermia restored Tau phosphorylation similar to control levels. As caffeine has been shown to be beneficial for diabetes, obesity and Tau phosphorylation, we used it as a therapeutic treatment in ob/ob mice. Unexpectedly, chronic caffeine consumption exacerbated Tau hyperphosphorylation in ob/ob mice by promoting deeper hypothermia. Then, our second aim was to assess the impact of T2D and obesity on Tau pathogenesis in conditions closer to human pathology. For this purpose, we fed hTau mice, expressing the human Tau protein, with high-fat, high-cholesterol and/or high-sugar diets, described to induce obesity and DT2 in humans. On the other hand, caloric restriction and physical activity have been characterized to reduce the incidence and outcome of metabolic disorders as well as AD. We evaluated their impact on Tau pathology in obese hTau mice as therapeutic strategies. Surprisingly, we found no effect of fat, sugar and cholesterol, even combined, on Tau phosphorylation, O-GlcNAcylation, splicing, cleavage and aggregation, suggesting that their overconsumption does not worsen Tau pathology in these mice. Moreover, we observed a beneficial effect of exercise on Tau phosphorylation and a deleterious effect of caloric restriction on Tau aggregation in obese hTau mice. Finally, our last aim was to examin the effects of insulin deficiency on Tau pathology in hTau mice using streptozotocin injection, a toxin that destroys insulin producing cells. Hypoinsulinemic mice exhibited Tau hyperphosphorylation in the brain without aggregation through inhibition of PP2A, the main Tau phosphatase. All these results suggest that i) metabolic alterations can induce Tau hyperphosphorylation indirectly, by disrupting thermoregulation; ii) hypercaloric diets do not appear to modify Tau homeostasis under strictly controlled conditions; iii) insulin deficiency may induce Tau hyperphosphorylation without, however, leading to its aggregation. We also revealed that the strategies used to reduce AD have to be adapted to the meatbolic status of patients to avoid the exacerbation of some neuropathologies of AD. These data object to some published research and show that the relationship between metabolism and AD may be less direct than thought. This work establishes a basis of rigor and methodology, which could help to avoid some biases for future studies

Impact of TREM2R47H variant on tau pathology-induced gliosis and neurodegeneration

Alzheimer\u27s disease (AD) is characterized by plaques containing amyloid-β (Aβ) and neurofibrillary tangles composed of aggregated, hyperphosphorylated tau. Beyond tau and Aβ, evidence suggests that microglia play an important role in AD pathogenesis. Rare variants in the microglia-expressed triggering receptor expressed on myeloid cells 2 (TREM2) gene increase AD risk 2- to 4-fold. It is likely that these TREM2 variants increase AD risk by decreasing the response of microglia to Aβ and its local toxicity. However, neocortical Aβ pathology occurs many years before neocortical tau pathology in AD. Thus, it will be important to understand the role of TREM2 in the context of tauopathy. We investigated the impact of the AD-associated TREM2 variant (R47H) on tau-mediated neuropathology in the PS19 mouse model of tauopathy. We assessed PS19 mice expressing human TREM2CV (common variant) or human TREM2R47H. PS19-TREM2R47H mice had significantly attenuated brain atrophy and synapse loss versus PS19-TREM2CV mice. Gene expression analyses and CD68 immunostaining revealed attenuated microglial reactivity in PS19-TREM2R47H versus PS19-TREM2CV mice. There was also a decrease in phagocytosis of postsynaptic elements by microglia expressing TREM2R47H in the PS19 mice and in human AD brains. These findings suggest that impaired TREM2 signaling reduces microglia-mediated neurodegeneration in the setting of tauopathy

New insights into the role of TREM2 in Alzheimer’s disease

Abstract Alzheimer’s disease (AD) is the leading cause of dementia. The two histopathological markers of AD are amyloid plaques composed of the amyloid-β (Aβ) peptide, and neurofibrillary tangles of aggregated, abnormally hyperphosphorylated tau protein. The majority of AD cases are late-onset, after the age of 65, where a clear cause is still unknown. However, there are likely different multifactorial contributors including age, enviornment, biology and genetics which can increase risk for the disease. Genetic predisposition is considerable, with heritability estimates of 60–80%. Genetic factors such as rare variants of TREM2 (triggering receptor expressed on myeloid cells-2) strongly increase the risk of developing AD, confirming the role of microglia in AD pathogenesis. In the last 5 years, several studies have dissected the mechanisms by which TREM2, as well as its rare variants affect amyloid and tau pathologies and their consequences in both animal models and in human studies. In this review, we summarize increases in our understanding of the involvement of TREM2 and microglia in AD development that may open new therapeutic strategies targeting the immune system to influence AD pathogenesis

Mutual relationship between Tau and central insulin signalling: consequences for AD and Tauopathies ?

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Relation mutuelle entre Tau et signalisation centrale de l’insuline

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Astrocytic APOE4 removal confers cerebrovascular protection despite increased cerebral amyloid angiopathy

International audienceAlzheimer Disease (AD) and cerebral amyloid angiopathy (CAA) are both characterized by amyloid-β (Aβ) accumulation in the brain, although Aβ deposits mostly in the brain parenchyma in AD and in the cerebrovasculature in CAA. The presence of CAA can exacerbate clinical outcomes of AD patients by promoting spontaneous intracerebral hemorrhage and ischemia leading to CAA-associated cognitive decline. Genetically, AD and CAA share the ε4 allele of the apolipoprotein E (APOE) gene as the strongest genetic risk factor. Although tremendous efforts have focused on uncovering the role of APOE4 on parenchymal plaque pathogenesis in AD, mechanistic studies investigating the role of APOE4 on CAA are still lacking. Here, we addressed whether abolishing APOE4 generated by astrocytes, the major producers of APOE, is sufficient to ameliorate CAA and CAA-associated vessel damage. Methods We generated transgenic mice that deposited both CAA and plaques in which APOE4 expression can be selectively suppressed in astrocytes. At 2-months-of-age, a timepoint preceding CAA and plaque formation, APOE4 was removed from astrocytes of 5XFAD APOE4 knock-in mice. Mice were assessed at 10-months-of-age for Aβ plaque and CAA pathology, gliosis, and vascular integrity. Results Reducing the levels of APOE4 in astrocytes shifted the deposition of fibrillar Aβ from the brain parenchyma to the cerebrovasculature. However, despite increased CAA, astrocytic APOE4 removal reduced overall Aβ-mediated gliosis and also led to increased cerebrovascular integrity and function in vessels containing CAA. Conclusion In a mouse model of CAA, the reduction of APOE4 derived specifically from astrocytes, despite increased fibrillar Aβ deposition in the vasculature, is sufficient to reduce Aβ-mediated gliosis and cerebrovascular dysfunction. </jats:sec

Parenchymal border macrophages regulate tau pathology and tau-mediated neurodegeneration

International audienceParenchymal border macrophages (PBMs) reside close to the central nervous system parenchyma and regulate CSF flow dynamics. We recently demonstrated that PBMs provide a clearance pathway for amyloid-β peptide, which accumulates in the brain in Alzheimer’s disease (AD). Given the emerging role for PBMs in AD, we explored how tau pathology affects the CSF flow and the PBM populations in the PS19 mouse model of tau pathology. We demonstrated a reduction of CSF flow, and an increase in an MHCII + PBM subpopulation in PS19 mice compared with WT littermates. Consequently, we asked whether PBM dysfunction could exacerbate tau pathology and tau-mediated neurodegeneration. Pharmacological depletion of PBMs in PS19 mice led to an increase in tau pathology and tau-dependent neurodegeneration, which was independent of gliosis or aquaporin-4 depolarization, essential for the CSF-ISF exchange. Together, our results identify PBMs as novel cellular regulators of tau pathology and tau-mediated neurodegeneration

Age-dependent impact of streptozotocin on metabolic endpoints and Alzheimer's disease pathologies in 3xTg-AD mice

International audienceAlzheimer's disease (AD) is a multifactorial neurodegenerative disease with a complex origin, thought to involve a combination of genetic, biological and environmental factors. Insulin dysfunction has emerged as a potential factor contributing to AD pathogenesis, particularly in individuals with diabetes, and among those with insulin deficiency or undergoing insulin therapy. The intraperitoneal administration of streptozotocin (STZ) is a widely used rodent model to explore the impact of insulin deficiency on AD pathology, although prior research predominantly focused on young animals, with no comparative analysis across different age groups. Our study aimed to fill this gap by analyzing the impact of insulin dysfunction in 7 and 23 months 3xTg-AD mice, that exhibit both amyloid and tau pathologies. Our objective was to elucidate the age-specific consequences of insulin deficiency on AD pathology. STZ administration led to insulin deficiency in the younger mice, resulting in an increase in cortical amyloid-β (Aβ) and tau aggregation, while tau phosphorylation was not significantly affected. Conversely, older mice displayed an unexpected resilience to the peripheral metabolic impact of STZ, while exhibiting an increase in both tau phosphorylation and aggregation without significantly affecting amyloid pathology. These changes were paralleled with alterations in signaling pathways involving tau kinases and phosphatases. Several markers of blood-brain barrier (BBB) integrity declined with age in 3xTg-AD mice, which might facilitate a direct neurotoxic effect of STZ in older mice. Overall, our research confirms the influence of insulin signaling dysfunction on AD pathology, but also advises careful interpretation of data related to STZ-induced effects in older animals