Investigating the deleterious effects of type 1 diabetes mellitus on microvascular repair in the mouse cortex

Mehina, Eslam

25 May 2021

Microglia and brain-resident macrophages are the sentinel immune cells of the central nervous system (CNS), and are ideally situated to respond to any damage to the brain parenchyma or vasculature. Circulating leukocytes are generally excluded from the CNS environment under homeostatic conditions but can gain access to this region in diseases that disrupt immune system function and blood-brain barrier integrity. Although these diverse immune cells exhibit properties that may engender them to be well-suited to resolve microcirculatory insults, their relative contributions to the recanalization of capillary rupture in the cortex, known as cerebral microbleeds (CMBs), has yet to be described. CMBs are particularly concerning in conditions, such as diabetes mellitus (DM), in which these insults occur more frequently and potentially underlie the onset and progression of cognitive decline. Using in vivo 2-photon microscopy and confocal imaging, here I highlight the compromised repair of CMBs in a mouse model of type 1 DM and characterize the robust, heterogeneous macrophage response to these insults. Specifically, 20% of damaged capillaries were eliminated from the circulation in the diabetic cortex and chronic insulin treatment failed to prevent this microvascular loss. Administration of interferon-α or interferon-γ neutralizing antibodies to dampen inflammatory signalling, or dexamethasone to reduce global inflammation, also failed to improve repair rates of damaged microvessels in diabetic mice. In contrast, CMBs in nondiabetic mice repaired without exception. Interestingly, depletion of CNS macrophages using the colony stimulating factor-1 receptor antagonist PLX5622 resulted in microvascular elimination in nondiabetic mice. Given the robust depletion of brain macrophage populations with this treatment, at first these data suggested that these cells were necessary for microvascular repair since their elimination produced vessel loss. However, by parsing the data I identified that microvessels repaired in all cases where macrophages were not identified at the CMB; when CX3CR1+ aggregate was localized to the injury, ~20% of microvessels were eliminated. These findings show that CNS macrophages are not required for microvascular repair following CMB. Immunofluorescent co-labelling of various microglial and macrophage markers within the diabetic CMB milieu revealed a novel population of Mac2+/TMEM119- cells, distinct from homeostatic TMEM119+ microglia. These cells reliably localized to CMBs that failed to repair and rarely associated with vessels that recanalized; Mac2+/TMEM119- cells were not found within nondiabetic CMBs. Treatment of diabetic mice with clodronate liposomes (CLR) to deplete circulating phagocytic leukocytes prevented aggregation of Mac2+/TMEM119- cells to CMBs and improved capillary repair rates. The efficacy of CLR in excluding these cells from the CMB aggregate, coincident with eradication of monocytes from circulation, indicated that these cells likely arose from the periphery. In vivo 2-photon imaging revealed significant increases in lipofuscin at the site of diabetic CMBs relative to the nondiabetic context; other phagocytic markers including CD68 and TREM2 were also upregulated. Mac2+/TMEM119- cells showed elevated lipofuscin content relative to homeostatic microglia; their association with CMBs may thus signal an increase in phagocytosis that contributes to capillary pruning. Taken together, these data identify a novel Mac2+/TMEM119- macrophage associated with pathological microvascular elimination following CMB in the diabetic neocortex. These findings highlight the diversity of immune cell responses to CNS injury and provide insights into the cellular mechanisms of capillary pruning. Furthermore, these advances in our understanding of the regulation of microvascular elimination in the diabetic brain may have clinical implications for patients with DM as they provide evidence for putative adjuvant anti-inflammatory treatments, such as CLR, in mitigating cerebrovascular pathology. / Graduate / 2022-05-06

microvessel

cerebral microbleed

vascular repair

inflammation

immune cells

microglia

macrophage

Mac2

type 1 diabetes mellitus

2-photon

confocal

in vivo imaging

clodronate

phagocytosis

Plaque deposition and microglia response under the influence of hypoxia in a murine model of Alzheimer\'s disease

Viehweger, Adrian

10 January 2013

Clinical findings have linked multiple risk factors and associated pathologies to Alzheimer\''s disease (AD). Amongst them are vascular risk factors such as hypertension and pathologies such as stroke. Coexistence of AD and these associated pathologies worsenes dementia, the clinical hallmark of the disease, as compared to pure AD. One general common denominator of these associated pathologies is the presence of hypoxic tissue conditions. It was asked the question, whether there exists a mutual, causal interaction between hypoxia and AD pathology, that could explain the clinical observations. Alternatively, the worsened clinical state of multiple brain pathologies could \"simply\" be the consequence of multimorbidity, i.e. accumulated disease load, without any causal interaction between the constituents. To approach this question whether hypoxia influences AD progression, use was made of a murine animal model of AD (transgenic mice: APPswe, PSEN1dE). Animals of two ages (8 and 14 months, \"young\" and \"old\" respectively) and two genotypes (transgenic and wild- type) were either treated under hypoxia or normoxia, corresponding to 8% and 21% oxygen, for 20 consecutive days. The resulting changes in the brain were assessed with a variety of techniques, namely by histology, ELISA, dot and Western blotting. Additional experiments in primary cell cultures were performed. Animals exposed to hypoxia showed an increased hematocrit (HCT), weight loss, reactive angiogenesis, but no infarctions. This illustrates that our hypoxic treatment put significant stress on the animals, without causing major pathologies. A large number of variables exists that could potentially be measured to assess the effect of hypoxia on AD. The focus was put on three of them: First, there is the Abeta1-42- protein, known to be the Abeta- isoform associated with the most detrimental disease progression. In AD, the self-combinatory Amyloid- beta peptide (Abeta) accumulates in the brain in so- called plaques, which is a main histologic finding of the disease. Its quantity was determined through histology and ELISA. Secondly, it was attempted to estimate the structural quality of the Abeta- protein by assessing the amount of A!- oligomers present. Abeta- protein does self- accumulate in various grades of complexity, i.e. as monomer, oligomer or fibril. Since oligomers are known to be the most neurotoxic \"species\" of the Abeta- protein, it was hypothesized that under hypoxic treatment their quantity could increase. And third, the organism\''s response to the Abeta- protein stimulus was investigated. Microglial cells have been described as the first cells to encounter the Abeta- protein \"threat\" in the shape of plaques, i.e. Abeta- protein aggregates. They then try to encapsulate and subsequently degrade them. Therefore, the attention was put on this cellular population. It was asked whether hypoxia could change the Abeta- protein quantity in the brain. This was assessed in two ways: First histologically, by staining for Abeta- protein depositions and quantifying them. Second, an ELISA was performed. Our findings state that hypoxic treatment does not alter the Abeta1-42 protein load in the brain, neither in young nor old animals, as assessed by histology and by total ELISA quantification of Abeta1-42 protein. Since hypoxia did not alter the quantity of the Abeta- protein, it was asked whether it influenced it qualitatively? If hypoxia increased oligomer formation, this change in the spectrum of the Abeta- species could, without any change in total Abeta- protein load, lead to increased neurotoxicity in animals under hypoxia. Initial experiments showed that oligomer formation in the brain seems to increase. However, this was not statistically significant and future experiments are necessary to evaluate this hypothesis further. It was then asked, whether hypoxia alters the cellular response to the protein. The total number of microglia in the hippocampal dentate gyrus, our structure of interest for practical purposes, and, it can be argued, by extension the brain, changes dynamically with various factors. First, transgenic animals present an increase in microglia. Second, microglia increase with age. Third, microglia decrease under hypoxia, but only do so significantly in old animals. Next, a parameter called \"plaque occupancy\" was coined to assess the microglia function to confront Abeta- plaques. Plaque occupancy is defined as the number of microglia in spatial proximity to one square millimeter of Abeta- plaque. This means, that microglia restricting one plaque are counted, and then normalized to this plaque\''s area. It was hypothesized that hypoxia would decrease plaque occupancy. Indeed, plaque occupancy roughly halved under hypoxia. Summarizing, our results demonstrate that long- term exposure to hypoxia significantly reduces the number of microglia. The reduced number results in significantly reduced plaque occupancy and compromizes the function of microglia to confront Abeta- plaques. The Abeta1-42 load, however, is not affected. On the other hand, Abeta shows an increased trend towards oligomer formation. A variety of possible explanations to these phenomena have been presented, that in our opinion deserve further investigation.

info:eu-repo/classification/ddc/600

ddc:600

Inebriated Immunity: Alcohol Affects Innate Immune Signaling in the Gut-Liver-Brain Axis

Lowe, Patrick P.

18 July 2018

Alcohol is a commonly consumed beverage, a drug of abuse and an important molecule affecting nearly every organ-system in the body. This project seeks to investigate the interplay between alcohol’s effects on critical organ-systems making up gut-liver-brain axis. Alcohol initially interacts with the gastrointestinal tract. Our research describes the alterations seen in intestinal microbiota following alcohol consumption in an acute-on-chronic model of alcoholic hepatitis and indicates that reducing intestinal bacteria using antibiotics protects from alcohol-induced intestinal cytokine expression, alcoholic liver disease and from inflammation in the brain. Alcohol-induced liver injury can occur due to direct hepatocyte metabolic dysregulation and from leakage of bacterial products from the intestine that initiates an immune response. Here, we will highlight the importance of this immune response, focusing on the role of infiltrating immune cells in human patients with alcoholic hepatitis and alcoholic cirrhosis. Using a small molecule inhibitor of CCR2/CCR5 chemokine receptor signaling in mice, we can protect the liver from damage and alcohol-induced inflammation. In the brain, we observe that chronic alcohol leads to the infiltration of macrophages in a region-specific manner. CCR2/CCR5 inhibition reduced macrophage infiltration, alcohol-induced inflammation and microglial changes. We also report that chronic alcohol shifts excitatory/inhibitory synapses in the hippocampus, possibly through complement-mediated remodeling. Finally, we show that anti-inflammasome inhibitors altered behavior by reducing alcohol consumption in female mice. Together, these data advance our understanding of the gut-liver-brain axis in alcoholism and suggest novel avenues of therapeutic intervention to inhibit organ pathology associated with alcohol consumption and reduce drinking.

Alcohol

central nervous system

liver

intestine

microbiome

macrophage

microglia

immunology

innate immunity

chemokine

cytokine

CCR2

Cellular and Molecular Physiology

Immunity

Medicine and Health Sciences

The Effects of Two Novel Anti-Inflammatory Compounds On Prepulse Inhibition and Neural Microglia Cell Activation in a Rodent Model of Schizophrenia

Shelton, Heath W

01 May 2019

Recent studies have shown elevated neuroinflammation in a large subset of individuals diagnosed with schizophrenia. A pro-inflammatory cytokine, tumor necrosis factor-alpha (TNFα), has been directly linked to this neuroinflammation. This study examined the effects of two TNFα modulators (PD2024 and PD340) produced by our collaborators at P2D Bioscience, Inc., to alleviate auditory sensorimotor gating deficits and reduce microglial cell activation present in the polyinosinic:polycytidylic (Poly I:C) rodent model of schizophrenia. Auditory sensorimotor gating was assessed using prepulse inhibition and microglial activation was examined and quantified using immunohistochemistry and confocal microscopy, respectively. Both PD2024 and PD340 alleviated auditory sensorimotor gating deficits and reduced microglia activation and thereby demonstrated the ability to treat both the behavioral and neuroinflammatory aspects of the disorder. These results are significant and suggest that neural TNFα is a potential pharmacological target for the treatment of schizophrenia.

Schizophrenia

Neuroinflammation

TNF-alpha

Prepulse Inhibition

Microglia

Poly I:C

Behavioral Neurobiology

Behavior and Behavior Mechanisms

Biological Psychology

Developmental Neuroscience

Mental Disorders

Links between abnormal lipid metabolism and inflammation in Alzheimer’s disease

Mangahas, Chenicka Lyn

12 1900

La recherche sur la maladie d’Alzheimer (MA) est concentrée, en grande partie, sur l’étude de ses principales caractéristiques histologiques, les plaques β-amyloïdes (Aβ) et les enchevêtrements neurofibrillaires. Cependant, les thérapies ciblant directement ces caractéristiques n’empêchent pas la progression de la MA. En plus de ces caractéristiques, la génétique a mis en évidence l’implication du métabolisme des lipides et de la réponse immunitaire dans la MA. Les perturbations du métabolisme lipidique est le prédicteur génétique le plus puissant du développement de la MA, mais ses mécanismes restent un mystère. Des travaux récents dans notre laboratoire ont montré que les triglycérides s’accumulent dans le cerveau des patients atteints de MA et des souris 3xTg, un modèle murin de la MA. Chez les souris 3xTg, ces triglycérides sont enrichis en acide oléique (AO), un acide gras monoinsaturé, et l’inhibition de l’enzyme de synthèse de l’AO, le stéaryle-CoA désaturase (SCD), réduit leur accumulation et contrecarre la perte précoce de la neurogenèse hippocampique et les troubles de mémoire. Nous avons donc testé si l’inhibition de la SCD peut inverser les changements dans le transcriptome et rétablir la fonction de l’hippocampe chez les souris 3xTg symptomatiques. En comparant aux souris contrôles, l’hippocampe de souris 3xTg possède des altérations transcriptomiques impliquées dans les processus reconnus pour être perturbés dans la MA. Leur hippocampe a également montré une baisse significative des épines dendritiques. De manière remarquable, les données de séquençage de l’ARN montrent que le traitement des souris 3xTg pendant un mois avec un inhibiteur de la SCD a sauvé des gènes liés à l’immunité et aux synapses. Les analyses tissulaires ont révélé que ce traitement a conduit à des améliorations de la densité des épines dendritiques. Nous avons également établi un modèle de microglie en culture et nos données préliminaires suggèrent que les oligomères Aβ pourrait être responsable de perturbations du métabolisme des lipides chez les microglies. En somme, ces études soulignent le potentiel d’un nouveau médicament ciblant SCD pour le traitement de la MA. / Alzheimer’s disease (AD) research has mainly focused on studying its main histological hallmarks, β-amyloid (Aβ) plaques, and neurofibrillary tangles. However, therapies directly targeting these hallmarks do not prevent AD progression. In addition to these hallmarks, genetics have highlighted the implication of lipid metabolism and immunity in AD. Disturbances in lipid metabolism are the single strongest genetic predictor of developing AD, but the underlying mechanisms remain poorly understood. Recent work in our laboratory showed that triglycerides accumulate in the brains of both AD patients and 3xTg mice, a mouse model of AD. In 3xTg mice, these triglycerides are enriched with monounsaturated fatty acid oleic acid (OA), and the inhibition of the OAsynthesizing enzyme stearoyl-CoA desaturase (SCD) reduced their accumulation and counteracts the early loss of hippocampal neurogenesis and memory deficits. Here, we tested whether SCD inhibition can reverse changes in the transcriptome and rescue hippocampal function in symptomatic 3xTg mice. Compared to their strain controls, the hippocampus of middle-aged, preplaque 3xTg mice showed transcriptomic alterations involved in processes recognized to be disrupted in AD. Their hippocampus also displayed significant reduction in dendritic spines. Remarkably, RNA sequencing data show that treatment of middle-aged 3xTg mice for one month with an SCD inhibitor rescued genes related to immunity and synapses. Tissue analyses revealed that this treatment led to improvements in dendritic spine density. We also established a model of microglia in culture and our preliminary data suggest that Aβ oligomers may be responsible for disruptions in microglial lipid metabolism. Together, these studies shed light on the potential of a novel drug target SCD for the treatment of AD.

Alzheimer’s disease

Microglia

Inflammation

Synapse

Stearoyl-CoA desaturase

Lipid

Metabolism

Maladie d’Alzheimer

Métabolisme

Lipide

Microglie

Stéaryle-coA désaturase

Early life stress effects on neuroimmune function in limbic brain regions and mood-related behavior in male and female Sprague-Dawley rats

Saulsbery, Angela I.

January 2019

No description available.

Neurosciences

Psychobiology

Psychology

early life stress

brain-resident immune cells

mast cells

microglia

risk assessment behaviors

Sprague-Dawley rats

microglial phagocytosis

early deprivation stress

stress

Paclitaxel Chemotherapy and Mammary Tumors Independently Disrupt Circadian Rhythmicity in Mice

Sullivan, Kyle Alexander

06 November 2020

No description available.

Neurosciences

Biomedical Research

Immunology

Neurobiology

Biology

cancer

chemotherapy

antineoplastic

circadian

hippocampus

corticosterone

adrenal gland

clock genes

paclitaxel

in vivo imaging

inflammation

microglia

astrocyte

suprachiasmatic

SCN

Transcriptional and Distributional Profiling of Microglia in Retinal Angiomatous Proliferation

Schlecht, Anja, Wolf, Julian, Boneva, Stefaniya, Prinz, Gabriele, Braunger, Barbara M., Wieghofer, Peter, Agostini, Hansjürgen, Schlunck, Günther, Lange, Clemens

07 February 2024

Macular neovascularization type 3, formerly known as retinal angiomatous proliferation (RAP), is a hallmark of age-related macular degeneration and is associated with an accumulation of myeloid cells, such as microglia (MG) and infiltrating blood-derived macrophages (MAC). However, the contribution of MG and MAC to the myeloid cell pool at RAP sites and their exact functions remain unknown. In this study, we combined a microglia-specific reporter mouse line with a mouse model for RAP to identify the contribution of MG and MAC to myeloid cell accumulation at RAP and determined the transcriptional profile of MG using RNA sequencing. We found that MG are the most abundant myeloid cell population around RAP, whereas MAC are rarely, if ever, associated with late stages of RAP. RNA sequencing of RAP-associated MG showed that differentially expressed genes mainly contribute to immune-associated processes, including chemotaxis and migration in early RAP and proliferative capacity in late RAP, which was confirmed by immunohistochemistry. Interestingly, MG upregulated only a few angiomodulatory factors, suggesting a rather low angiogenic potential. In summary, we showed that MG are the dominant myeloid cell population at RAP sites. Moreover, MG significantly altered their transcriptional profile during RAP formation, activating immune-associated processes and exhibiting enhanced proliferation, however, without showing substantial upregulation of angiomodulatory factors.

info:eu-repo/classification/ddc/610

ddc:610

Harnessing retinal phagocytes to combat pathological neovascularization in ischemic retinopathies?

Klotzsche‑von Ameln, Anne, Sprott, David

02 February 2024

Ischemic retinopathies (IR) are vision-threatening diseases that affect a substantial amount of people across all age groups worldwide. The current treatment options of photocoagulation and anti-VEGF therapy have side effects and are occasionally unable to prevent disease progression. It is therefore worthwhile to consider other molecular targets for the development of novel treatment strategies that could be safer and more efficient. During the manifestation of IR, the retina, normally an immune privileged tissue, encounters enhanced levels of cellular stress and inflammation that attract mononuclear phagocytes (MPs) from the blood stream and activate resident MPs (microglia). Activated MPs have a multitude of effects within the retinal tissue and have the potential to both counter and exacerbate the harmful tissue microenvironment. The present review discusses the current knowledge about the role of inflammation and activated retinal MPs in the major IRs: retinopathy of prematurity and diabetic retinopathy. We focus particularly on MPs and their secreted factors and cell–cell-based interactions between MPs and endothelial cells. We conclude that activated MPs play a major role in the manifestation and progression of IRs and could therefore become a promising new target for novel pharmacological intervention strategies in these diseases.

info:eu-repo/classification/ddc/610

ddc:610

info:eu-repo/classification/ddc/590

ddc:590

Immunosenescence in Choroidal Neovascularization (CNV): Transcriptional Profiling of Naïve and CNV-Associated Retinal Myeloid Cells during Aging

Schlecht, Anja, Thien, Adrian, Wolf, Julian, Prinz, Gabriele, Agostini, Hansjürgen, Schlunck, Günther, Wieghofer, Peter, Boneva, Stefaniya, Lange, Clemens

02 February 2024

Immunosenescence is considered a possible factor in the development of age-related macular degeneration and choroidal neovascularization (CNV). However, age-related changes of myeloid cells (MCs), such as microglia and macrophages, in the healthy retina or during CNV formation are illdefined. In this study, Cx3cr1-positive MCs were isolated by fluorescence-activated cell sorting from six-week (young) and two-year-old (old) Cx3cr1GFP/+ mice, both during physiological aging and laser-induced CNV development. High-throughput RNA-sequencing was performed to define the age-dependent transcriptional differences in MCs during physiological aging and CNV development, complemented by immunohistochemical characterization and the quantification of MCs, as well as CNV size measurements. These analyses revealed that myeloid cells change their transcriptional profile during both aging and CNV development. In the steady state, senescent MCs demonstrated an upregulation of factors contributing to cell proliferation and chemotaxis, such as Cxcl13 and Cxcl14, as well as the downregulation of microglial signature genes. During CNV formation, aged myeloid cells revealed a significant upregulation of angiogenic factors such as Arg1 and Lrg1 concomitant with significantly enlarged CNV and an increased accumulation of MCs in aged mice in comparison to young mice. Future studies need to clarify whether this observation is an epiphenomenon or a causal relationship to determine the role of immunosenescence in CNV formation.

info:eu-repo/classification/ddc/610

ddc:610