Project description:Astrocytes maintain neuronal homeostasis through cellular programs that are frequently disrupted early in neurodegenerative disease, many of which are regulated by the circadian clock. The core clock transcription factor BMAL1 is required for normal astrocyte function, yet whether its regulatory activity is altered during neurodegeneration remains unclear. Moreover, astrocyte circadian gene expression patterns are profoundly reprogrammed in disease, yet the underlying mechanisms remain unclear, primarily due to a lack of methods for identifying DNA binding sites of BMAL1 in specific cell types in the brain. Here, we have developed an in vivo strategy to record transcription factor genomic occupancy specifically in astrocytes (MACS-Calling Cards, MACS-CC), and used it to map BMAL1 binding. We applied this strategy to the Cln3Δex7/8 mouse model of CLN3 disease, a fatal neurodegenerative disorder, which exhibits early astrocyte dysfunction prior to widespread neuronal loss as well as circadian dysregulation. This allowed us to test how the progressive pathological cascade caused by CLN3 deficiency reprograms BMAL1 binding in astrocytes. BMAL1 binding was extensively redistributed, with comparable numbers of wild-type-specific and disease-specific sites. Wild-type-specific BMAL1 binding was enriched near genes involved in circadian regulation and astrocyte differentiation, whereas disease-specific sites lacked coherent functional enrichment. Consistent with these changes, RNA-seq of sorted astrocytes revealed reduced expression of mature astrocyte markers in Cln3Δex7/8 mice. To define the mechanisms underlying BMAL1 retargeting in Cln3Δex7/8 astrocytes, we tested whether changes in chromatin accessibility could explain disease-associated gains and losses of BMAL1 binding. Although chromatin accessibility was broadly remodeled, differential accessibility did not predict BMAL1 binding gains or losses. Instead, motif analyses supported a model in which loss of normal cooperative transcription factor partnerships contributes to BMAL1 retargeting. Together, these findings demonstrate that MACS-CC enables in vivo transcription factor occupancy mapping in astrocytes and reveals the mechanisms behind early rewiring of circadian regulatory programs within a model of progressive pathology leading to neurodegeneration. Our data also shed new light on astrocyte dysfunction in CLN3 disease.

Project description:Purpose: The core clock protein BMAL1 serves as the primary positive circadian transcriptional regulator and its depletion in astrocytes not only disrupts circadian function, but also leads to a unique cell-autonomous activation phenotype. We have undertaken RNAsequencing of isolated astrocytes from young wildtype and BMAL1 astrocyte-specific knockout mice (Bmal1fl/fl, ALDH1L1-CreERT2, termed BMAL1 aKO) to uncover changes to gene expression as a result of BMAL1 disruption in astrocytes. Methods: BMAL1 aKO mice and wildtype littermates were given tamoxifen at 2 months of age and harvested around 7 months of age and brains were collected. After collagenase digestion and debris removal, astrocytes were isolated from the rest of the brain cells (termed "flowthrough") using Miltenyi MACS Anti-ACSA-2 magnetic beads. RNA was extracted in Trizol reagent and sent for sequencing. Samples from BMAL1 aKO and wildtype astrocytes were compared and flowthrough samples were compared to astrocytes to confirm cell-type purity. Results: BMAL1 aKO results in both up- and down-regulation of many astrocyte genes. GO pathway analysis points to lysosomal pathways as dysregulated by knockout of BMAL1 in astrocytes. While astrocytes are enriched by our isolation methods, there is some degree of contamination from neurons and oligodendrocytes. Conclusions: While our astrocyte isolation method has some caveats in terms of purity, BMAL1 aKO appears to dysregulate lysosomal pathways, which will be investigated by further experiments.

Project description:Purpose: The core clock protein BMAL1 serves as the primary positive circadian transcriptional regulator and its depletion in astrocytes not only disrupts circadian function, but also leads to a unique cell-autonomous activation phenotype. We have undertaken RNAsequencing of isolated astrocytes from aged wildtype and BMAL1 astrocyte-specific knockout mice (Bmal1fl/fl, ALDH1L1-CreERT2, termed BMAL1 aKO) to uncover changes to gene expression as a result of BMAL1 disruption in astrocytes and to confirm those changes persist during aging. Methods: BMAL1 aKO mice and wildtype littermates were given tamoxifen at 2 months of age and harvested around 20 months of age and brains were collected. After collagenase digestion and debris removal, astrocytes were isolated from the rest of the brain cells (termed "flowthrough") using Miltenyi MACS Anti-ACSA-2 magnetic beads. RNA was extracted in Trizol reagent and sent for sequencing. Samples from BMAL1 aKO and wildtype astrocytes were compared and flowthrough samples were compared to astrocytes to confirm cell-type purity. Results: BMAL1 aKO results in both up- and down-regulation of many astrocyte genes. GO pathway analysis points to lysosomal pathways as dysregulated by knockout of BMAL1 in astrocytes. While astrocytes are enriched by our isolation methods, there is some degree of contamination from neurons and oligodendrocytes. Conclusions: While our astrocyte isolation method has some caveats in terms of purity, BMAL1 aKO appears to dysregulate lysosomal pathways, which will be investigated by further experiments.

Project description:Astrocyte circadian regulation in neurodegeneration: in vivo BMAL1 occupancy mapping using MACS-Calling Cards

Project description:An emerging link between circadian clock function and neurodegeneration has indicated a critical role for the molecular clock in brain health. We previously reported that deletion of the core circadian clock gene Bmal1 abrogates clock function and induces cell-autonomous astrocyte activation. Regulation of astrocyte activation has important implications for protein aggregation, inflammation, and neuronal survival in neurodegenerative conditions such as Alzheimer's disease (AD). Here, we investigated how astrocyte activation induced by Bmal1 deletion regulates astrocyte gene expression, amyloid-beta (Aβ) plaque-associated activation, and plaque deposition. To address these questions, we crossed astrocyte-specific Bmal1 knockout mice (Aldh1l1-CreERT2;Bmal1(fl/fl), termed BMAL1 aKO), to the APP/PS1-21 and the APP(NL-G-F) models of Aβ accumulation. Transcriptomic profiling showed that BMAL1 aKO induced a unique transcriptional profile affecting genes involved in both the generation and elimination of Aβ. BMAL1 aKO mice showed exacerbated astrocyte activation around Aβ plaques and altered gene expression. However, this astrogliosis did not affect plaque accumulation or neuronal dystrophy in either model. Our results demonstrate that the striking astrocyte activation induced by Bmal1 knockout does not influence Aβ deposition, which indicates that the effect of astrocyte activation on plaque pathology in general is highly dependent on the molecular mechanism of activation.

Project description:Circadian rhythm dysfunction is a hallmark of Parkinson Disease (PD), and diminished expression of the core clock gene Bmal1 has been described in PD patients. BMAL1 is required for core circadian clock function, but also serves non-rhythmic functions. Germline Bmal1 deletion can cause brain oxidative stress and synapse loss in mice, and can exacerbate dopaminergic neurodegeneration in response to MPTP. Here we examined the impact of cell type-specific Bmal1 deletion on dopaminergic neuron viability in vivo. We observed that global, post-natal deletion of Bmal1 caused spontaneous loss of tyrosine hydroxylase-positive (TH+) dopaminergic neurons in the substantia nigra pars compacta (SNpc). This was not due to disruption of behavioral circadian rhythms, and was not induced by astrocyte- or microglia-specific Bmal1 deletion. However, either pan-neuronal or TH neuron-specific Bmal1 deletion caused cell-autonomous loss of TH+ neurons in the SNpc. Finally, global Bmal1 deletion exacerbated TH+ neuron loss following injection of alpha-synclein fibrils. Transcriptomic analysis of neuron-specific Bmal1 KO brain revealed dysregulation of pathways involved in oxidative phosphorylation and Parkinson Disease.

Project description:In vivo BMAL1 occupancy mapping using MACS-Calling Cards reveals disease-associated retargeting in Cln3Δex7/8 astrocytes

Project description:To understand how the circadian clock regulates astrocyte physiology, we conducted a circadian transcriptome analysis in cultured mouse cortical astrocytes

Project description:The molecular circadian clock is a ubiquitous transcriptional-translational feedback loop that regulates CNS function, glial responses, and neurodegenerative pathology. The druggable nuclear receptors REV-ERB-ɑ (gene: Nr1d1) and REV-ERB-.Beta. (gene: Nr1d2) are components of the core circadian clock. REV-ERB proteins regulate neuroinflammatory responses, synaptic pruning, and protein aggregation, though the cell type-specific effects and relative compensatory effects of REV-ERB-ɑ AND -.Beta. in the brain are unknown. To study the CNS functions of REV-ERBs, we developed mouse lines with global or astrocyte-specific, conditional knockout of both REV-ERB-ɑ and -.Beta.. We demonstrate that inducible post-natal global deletion of REV-ERB-ɑ and -.Beta. in vivo results in robust spontaneous astrocyte activation and increases gene expression of disease-relevant pathways such as protein catabolism, complement, and oxidative stress. Furthermore, in vivo astrocyte-specific deletion of REV-ERB-ɑ/-.Beta. recapitulates the spontaneous astrocyte activation phenotype seen in global REV-ERB-ɑ/-.Beta. KO mice, as well as in mice with deletion of key core clock gene Bmal1, indicating that REV-ERBs regulate astrocyte activation in a cell-autonomous manner downstream of the core circadian clock. REV-ERB-ɑ/-.Beta. repress transcription of Stat3 in the brain, and deletion of REV-ERBs in astrocytes induces increased astrocytic STAT3 expression and downstream STAT3-mediated gene changes, a mechanistic link to the astrocyte reactivity shift. This astrocyte activation phenotype decreases alpha-synuclein pathology in an in vivo model of Parkinson’s Disease-related alpha-synucleinopathy and increases astrocytic protein uptake and degradation in vitro. This study therefore provides insight into astrocyte function and could elucidate novel regulatory mechanisms that are candidates for therapeutic manipulation through modulating REV-ERB activity.

Project description:The molecular circadian clock is a ubiquitous transcriptional-translational feedback loop that regulates CNS function, glial responses, and neurodegenerative pathology. The druggable nuclear receptors REV-ERB-ɑ (gene: Nr1d1) and REV-ERB-.Beta. (gene: Nr1d2) are components of the core circadian clock. REV-ERB proteins regulate neuroinflammatory responses, synaptic pruning, and protein aggregation, though the cell type-specific effects and relative compensatory effects of REV-ERB-ɑ AND -.Beta. in the brain are unknown. To study the CNS functions of REV-ERBs, we developed mouse lines with global or astrocyte-specific, conditional knockout of both REV-ERB-ɑ and -.Beta.. We demonstrate that inducible post-natal global deletion of REV-ERB-ɑ and -.Beta. in vivo results in robust spontaneous astrocyte activation and increases gene expression of disease-relevant pathways such as protein catabolism, complement, and oxidative stress. Furthermore, in vivo astrocyte-specific deletion of REV-ERB-ɑ/-.Beta. recapitulates the spontaneous astrocyte activation phenotype seen in global REV-ERB-ɑ/-.Beta. KO mice, as well as in mice with deletion of key core clock gene Bmal1, indicating that REV-ERBs regulate astrocyte activation in a cell-autonomous manner downstream of the core circadian clock. REV-ERB-ɑ/-.Beta. repress transcription of Stat3 in the brain, and deletion of REV-ERBs in astrocytes induces increased astrocytic STAT3 expression and downstream STAT3-mediated gene changes, a mechanistic link to the astrocyte reactivity shift. This astrocyte activation phenotype decreases alpha-synuclein pathology in an in vivo model of Parkinson’s Disease-related alpha-synucleinopathy and increases astrocytic protein uptake and degradation in vitro. This study therefore provides insight into astrocyte function and could elucidate novel regulatory mechanisms that are candidates for therapeutic manipulation through modulating REV-ERB activity.