Project description:Microglia, the innate immune cells of the brain, play a defining role in the progression of Alzheimer’s disease (AD). The microglial response to amyloid plaques can be either neuroprotective or neurotoxic. Here we show that the protective function of microglia is associated with and functionally linked to a transcriptional shift toward lymphoid gene expression. Microglial contact with the plaques induces downregulation of PU.1, a lineage-specifying transcription factor. PU.1 downregulation plays a key role in mitigating the severity of AD, as evidenced by a reduction in neurotoxic microglia activation, preservation of neuronal connections, maintenance of cognitive function, and increased survival in mice with genetically reduced PU.1 expression in microglia. The neuroprotective effect of PU.1 downregulation is linked to the de-repression of lymphoid-specific proteins, particularly CD28—a surface protein critical for T cell activation. Microglia-specific deficiency in CD28, which is expressed exclusively in a small subset of plaque-associated PU.1low microglia, promotes an inflammatory microglial state and associated increase in amyloid plaque load. Our findings suggest that PU.1low lymphoid/CD28-expressing microglia that emerge in response to AD pathology exert a suppressive, anti-inflammatory effect during AD. This novel role of CD28 -and potentially other lymphoid co-stimulatory or co-inhibitory receptor proteins- in governing microglia responses in AD points to possible new immunotherapy approaches for AD treatment.

Project description:Microglia, the innate immune cells of the brain, play a defining role in the progression of Alzheimer’s disease (AD). The microglial response to amyloid plaques can be either neuroprotective or neurotoxic. Here we show that the protective function of microglia is associated with and functionally linked to a transcriptional shift toward lymphoid gene expression. Microglial contact with the plaques induces downregulation of PU.1, a lineage-specifying transcription factor. PU.1 downregulation plays a key role in mitigating the severity of AD, as evidenced by a reduction in neurotoxic microglia activation, preservation of neuronal connections, maintenance of cognitive function, and increased survival in mice with genetically reduced PU.1 expression in microglia. The neuroprotective effect of PU.1 downregulation is linked to the de-repression of lymphoid-specific proteins, particularly CD28—a surface protein critical for T cell activation. Microglia-specific deficiency in CD28, which is expressed exclusively in a small subset of plaque-associated PU.1low microglia, promotes an inflammatory microglial state and associated increase in amyloid plaque load. Our findings suggest that PU.1low lymphoid/CD28-expressing microglia that emerge in response to AD pathology exert a suppressive, anti-inflammatory effect during AD. This novel role of CD28 -and potentially other lymphoid co-stimulatory or co-inhibitory receptor proteins- in governing microglia responses in AD points to possible new immunotherapy approaches for AD treatment.

Project description:Microglia, the innate immune cells of the brain, play a defining role in the progression of Alzheimer’s disease (AD). The microglial response to amyloid plaques can be either neuroprotective or neurotoxic. Here we show that the protective function of microglia is associated with and functionally linked to a transcriptional shift toward lymphoid gene expression. Microglial contact with the plaques induces downregulation of PU.1, a lineage-specifying transcription factor. PU.1 downregulation plays a key role in mitigating the severity of AD, as evidenced by a reduction in neurotoxic microglia activation, preservation of neuronal connections, maintenance of cognitive function, and increased survival in mice with genetically reduced PU.1 expression in microglia. The neuroprotective effect of PU.1 downregulation is linked to the de-repression of lymphoid-specific proteins, particularly CD28—a surface protein critical for T cell activation. Microglia-specific deficiency in CD28, which is expressed exclusively in a small subset of plaque-associated PU.1low microglia, promotes an inflammatory microglial state and associated increase in amyloid plaque load. Our findings suggest that PU.1low lymphoid/CD28-expressing microglia that emerge in response to AD pathology exert a suppressive, anti-inflammatory effect during AD. This novel role of CD28 -and potentially other lymphoid co-stimulatory or co-inhibitory receptor proteins- in governing microglia responses in AD points to possible new immunotherapy approaches for AD treatment.

Project description:Microglia, the innate immune cells of the brain, play a defining role in the progression of Alzheimer’s disease (AD). The microglial response to amyloid plaques can be either neuroprotective or neurotoxic. Here we show that the protective function of microglia is associated with and functionally linked to a transcriptional shift toward lymphoid gene expression. Microglial contact with the plaques induces downregulation of PU.1, a lineage-specifying transcription factor. PU.1 downregulation plays a key role in mitigating the severity of AD, as evidenced by a reduction in neurotoxic microglia activation, preservation of neuronal connections, maintenance of cognitive function, and increased survival in mice with genetically reduced PU.1 expression in microglia. The neuroprotective effect of PU.1 downregulation is linked to the de-repression of lymphoid-specific proteins, particularly CD28—a surface protein critical for T cell activation. Microglia-specific deficiency in CD28, which is expressed exclusively in a small subset of plaque-associated PU.1low microglia, promotes an inflammatory microglial state and associated increase in amyloid plaque load. Our findings suggest that PU.1low lymphoid/CD28-expressing microglia that emerge in response to AD pathology exert a suppressive, anti-inflammatory effect during AD. This novel role of CD28 -and potentially other lymphoid co-stimulatory or co-inhibitory receptor proteins- in governing microglia responses in AD points to possible new immunotherapy approaches for AD treatment.

Project description:Two microglial TAM receptor tyrosine kinases - Axl and Mer - have been linked to Alzheimer’s disease, but their roles in disease have not been tested experimentally. We find that in Alzheimer’s disease and its mouse models, induced expression of Axl and Mer in amyloid plaque-associated microglia is coupled to induced plaque decoration by the TAM ligand Gas6 and its co-ligand phosphatidylserine. In the APP/PS1 mouse model of Alzheimer’s disease, sIngle cell RNAseq analysis comparing wild type microglia with those with Axl and Mer deficiency reveals a similar disease state transitional program of microglia but a dampened differential expression of numerous AD siganture genes in microglia lacking TAM receptors. In line with the transcriptomic data, using two-photon microscopy, we show that genetic ablation of Axl and Mer results in microglia that are unable to normally detect, respond to, organize, or phagocytose amyloid beta plaques. These major deficits notwithstanding, and contrary to expectation, TAM-deficient APP/PS1 mice develop fewer dense-core plaques than APP/PS1 mice with normal microglia. Our findings reveal that the TAM system is an essential mediator of microglial recognition and engulfment of amyloid plaques, and that TAM-driven microglial phagocytosis does not constrain, but rather promotes, plaque development.

Project description:GFAP and vimentin deficiency alters gene expression in astrocytes and microglia in wild-type mice and changes the transcriptional response of reactive glia in mouse model for Alzheimer's disease. Reactive astrocytes with an increased expression of intermediate filament (IF) proteins Glial Fibrillary Acidic Protein (GFAP) and Vimentin (VIM) surround amyloid plaques in Alzheimer's disease (AD). The functional consequences of this upregulation are unclear. To identify molecular pathways coupled to IF regulation in reactive astrocytes, and to study the interaction with microglia, we examined WT and APPswe/PS1dE9 (AD) mice lacking either GFAP, or both VIM and GFAP, and determined the transcriptome of cortical astrocytes and microglia from 15- to 18-month-old mice. Genes involved in lysosomal degradation (including several cathepsins) and in inflammatory response (including Cxcl5, Tlr6, Tnf, Il1b) exhibited a higher AD-induced increase when GFAP, or VIM and GFAP, were absent. The expression of Aqp4 and Gja1 displayed the same pattern. The downregulation of neuronal support genes in astrocytes from AD mice was absent in GFAP/VIM null mice. In contrast, the absence of IFs did not affect the transcriptional alterations induced by AD in microglia, nor was the cortical plaque load altered. Visualizing astrocyte morphology in GFAP-eGFP mice showed no clear structural differences in GFAP/VIM null mice, but did show diminished interaction of astrocyte processes with plaques. Microglial proliferation increased similarly in all AD groups. In conclusion, absence of GFAP, or both GFAP and VIM, alters AD-induced changes in gene expression profile of astrocytes, showing a compensation of the decrease of neuronal support genes and a trend for a slightly higher inflammatory expression profile. However, this has no consequences for the development of plaque load, microglial proliferation, or microglial activation. 2 cell types from 6 conditions: cortical microglia and cortical astrocytes from 15-18 month old APPswe/PS1dE9 mice compared to wildtype littermates. Biological replicates: microglia from APPswe/PS1dE9, N=7, microglia from WT, N=7, astrocytes from APPswe/PS1dE9, N=4, microglia from WT, N=4

Project description:Microglial dysfunction is a key pathological feature of Alzheimer´s disease (AD), but little is known about proteome-wide changes in microglia during the course of AD pathogenesis and their consequences for microglial function. Here, we performed an in-depth proteomic characterization of microglia in two AD mouse models, the overexpression APPPS1 and the knock-in AppNL-G-F (APP-KI) model. Proteome changes were followed from pre-deposition to early, middle and advanced stages of amyloid plaque pathology, revealing a large panel of Microglial Amyloid Response Proteins (MARPs) that reflect a heterogeneity of microglial alterations triggered by Adeposition. We demonstrate that the occurrence of MARPs coincided with the deposition of fibrillar A, recruitment of microglia to amyloid plaques and phagocytic dysfunction. While the proteomic and functional microglial changes were already markedly seen in 3 months old APPPS1 mice, they were delayed in the APP-KI model that generates substantially less fibrillar A. The identified microglial proteomic fingerprints of AD provide a valuable resource for functional studies of novel molecular targets and potential biomarkers for monitoring AD progression or therapeutic efficacy.

Project description:Anti-amyloid β-peptide (Aβ) immune therapy was developed as treatment for Alzheimer’s disease (AD) to reduce and prevent amyloid plaque pathology. This approach has proven successful in phase 3 clinical trials of Aducanumab, Lecanemab and Donanemab. These antibodies induce robust amyloid plaque clearance, slow memory decline, and have beneficial effects on daily living activities. The therapeutic effects correlate with the efficacy of plaque removal. Treatment is associated with adverse side-effects, such as oedema and haemorrhages (ARIA-E and -H), which are potentially linked to the induced immune response. To improve therapeutic safety, it is therefore imperative to understand the effects of anti-Aβ antibody treatment on immune cell function. We investigated the effects of long-term chronic Aducanumab treatment on amyloid plaque pathology and microglial response in the APP-SAA triple knock-in mouse model. Mice were treated weekly with Aducanumab from 4-8 months of age. Long-term treatment with Aducanumab results in a robust and dose-dependent removal of amyloid plaque pathology. Analysis of the CSF proteome indicates a reduction of markers for neurodegeneration including tau and α-synuclein. Consistent with a reduction of glucose uptake, the therapeutic effects were accompanied by reduced microglial activation. RNAseq confirmed a dose-dependent decrease in the disease-associated microglia (DAM) transcriptional signature of microglia, which is supported by a parallel decrease of Trem2 protein. However, genes associated with antigen-presentation were still increased after treatment. IHC confirms that Aducanumab treatment increases microglial clustering, as well as MHC-II expression around plaques and ELISA confirmed increased cytokine levels. These findings demonstrate that long-term chronic Aducanumab-mediated removal of Aβ leads to a dose dependent decrease in microglial activation and neurodegeneration, but induces a unique antibody treatment-related microglial phenotype associated with antigen presentation, which may be related to plaques still present after the 4 months treatment period.

Project description:Alzheimer's disease (AD) is characterized by a sequential progression of amyloid plaques (A), neurofibrillary tangles (T) and neurodegeneration (N), constituting ATN pathology. While microglia are considered key contributors to AD pathogenesis, their contribution in the combined presence of ATN pathologies remains incompletely understood. As sensors of the brain microenvironment, microglial phenotypes and contributions are importantly defined by the pathologies in the brain, indicating the need for their analysis in preclinical models that recapitulate combined ATN pathologies, besides their role in A and T models only. Here, we report a new tau-seed model in which amyloid pathology facilitates bilateral tau propagation associated with brain atrophy, thereby recapitulating robust ATN pathology. Single-cell RNA sequencing revealed that ATN pathology exacerbated microglial activation towards disease-associated microglia (DAM) states, with a significant upregulation of Apoe as compared to amyloid-only models (A). Importantly, Colony-Stimulating Factor 1 Receptor inhibition preferentially eliminated non-plaque-associated versus plaque associated microglia. The preferential depletion of non-plaque-associated microglia significantly attenuated tau pathology and neuronal atrophy, indicating their detrimental role during ATN progression. Together, our data reveal the intricacies of microglial activation and their contributions to pathology in a model that recapitulates the combined ATN pathologies of Alzheimer's disease. Our data may provide a basis for microglia-targeting therapies selectively targeting detrimental microglial populations, while conserving protective populations.

Project description:The e4 allele of the apolipoprotein E (APOE) gene is the strongest genetic risk factor for late-onset Alzheimer's disease and has been shown to increase amyloid pathology relative to the presence of the e2 and e3 alleles. In the brain, apoE is primarily produced by astrocytes and under pathological conditions also by microglia. The cell-type-specific role of apoE in amyloid pathology, especially after amyloid plaque deposition, has not been fully elucidated. We generated APPPS1-21/Aldh1l1-Cre/ERT2/apoE4flox/flox and APPPS1-21/apoE4flox/flox mice. At 3.8-months-of-age, during the phase of rapid plaque growth, we administered tamoxifen to reduce astrocytic APOE4 and assessed mice at 6-months-of-age. One day before tamoxifen treatment, mice were injected with methoxy-X04, a blood-brain-barrier permeant fluorescent marker that labeled the pre-existing fibrillar amyloid plaques. By using this strategy, we were able to characterize pre-existing plaques prior to the loss of astrocytic APOE4 and to also analyze newly-formed amyloid plaques after the loss of astrocytic APOE4. Interestingly, astrocytic APOE4 deletion strongly reduced pre-existing plaques. It also prevented new plaque formation and decreased glial reactivity. Importantly, the removal of astrocytic APOE4 resulted in enhanced microglial and astrocytic phagocytic ability, which may contribute to the reduction of the amyloid pathology.