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Item APOE4 Drives Impairment in Astrocyte-Neuron Coupling in Alzheimer's Disease and Works Through Mechanisms in Early Disease to Influence Pathology(2023-05) Brink, Danika Marie Tumbleson; Lamb, Bruce; Bissel, Stephanie; Herbert, Brittney-Shea; Landreth, Gary; Puntambekar, Shweta; Saykin, Andrew; Zhang, ChiAlzheimer’s disease (AD) is a neurodegenerative disorder resulting in progressive memory loss, brain atrophy, and eventual death. AD pathology is characterized by the accumulation of neurotoxic amyloid-beta (Aβ) plaques, synapse loss, neurofibrillary tangles (NFTs), and neurodegeneration. The APOE4 allele is associated with a 3-fold increased risk for AD and results in increased Aβ plaque deposition, reduced Aβ clearance, and reduced synaptic plasticity. Although APOE expression is upregulated in microglia in AD, APOE is expressed primarily by astrocytes in the CNS. It is not well understood how astrocytic APOE drives the mechanisms that result in worsened AD outcomes. Here, digital spatial profiling and bioinformatics data suggest that APOE4 causes transcriptional dysregulation in early AD and may disrupt neuronal processes via astrocytes. Whole transcriptome data from plaque and non-plaque regions in the cortices and hippocampus of 4- and 8-month-old AD model mice expressing humanized APOE4/4 or APOE3/3 (control) were analyzed. Transcriptional dysregulation was increased in APOE4/4 AD mice compared to that in APOE3/3 at 4 but not 8 months of age, suggesting that early dysregulation of APOE4-driven disease mechanisms may shape degenerative outcomes in late-stage AD. Additionally, APOE4/4 potentially functions via plaque-independent mechanisms to influence neuronal function in early AD before the onset of pathology. Single-nuclei RNA sequencing data were obtained from human post-mortem astrocytes and the bioinformatic analyses revealed a novel astrocyte subtype that highly expresses several top genes involved in functional alterations associated with APOE4, including neuronal generation, development, and differentiation, and synaptic transmission and organization. Overall, our findings indicate that APOE4 may drive degenerative outcomes through the presented astrocyte candidate pathways. These pathways represent potential targets for investigations into early intervention strategies for APOE4/4 patients.Item Astrocytes modulate neurodegenerative phenotypes associated with glaucoma in OPTN(E50K) human stem cell-derived retinal ganglion cells(Elsevier, 2022) Gomes, Cátia; VanderWall, Kirstin B.; Pan, Yanling; Lu, Xiaoyu; Lavekar, Sailee S.; Huang, Kang-Chieh; Fligor, Clarisse M.; Harkin, Jade; Zhang, Chi; Cummins, Theodore R.; Meyer, Jason S.; Medical and Molecular Genetics, School of MedicineAlthough the degeneration of retinal ganglion cells (RGCs) is a primary characteristic of glaucoma, astrocytes also contribute to their neurodegeneration in disease states. Although studies often explore cell-autonomous aspects of RGC neurodegeneration, a more comprehensive model of glaucoma should take into consideration interactions between astrocytes and RGCs. To explore this concept, RGCs and astrocytes were differentiated from human pluripotent stem cells (hPSCs) with a glaucoma-associated OPTN(E50K) mutation along with corresponding isogenic controls. Initial results indicated significant changes in OPTN(E50K) astrocytes, including evidence of autophagy dysfunction. Subsequently, co-culture experiments demonstrated that OPTN(E50K) astrocytes led to neurodegenerative properties in otherwise healthy RGCs, while healthy astrocytes rescued some neurodegenerative features in OPTN(E50K) RGCs. These results are the first to identify disease phenotypes in OPTN(E50K) astrocytes, including how their modulation of RGCs is affected. Moreover, these results support the concept that astrocytes could offer a promising target for therapeutic intervention in glaucoma.Item Astrocytes Regulate the Development and Maturation of Retinal Ganglion Cells Derived from Human Pluripotent Stem Cells(Elsevier, 2019-02-12) VanderWall, Kirstin B.; Vij, Ridhima; Ohlemacher, Sarah K.; Sridhar, Akshayalakshmi; Fligor, Clarisse M.; Feder, Elyse M.; Edler, Michael C.; Baucum, Anthony J.; Cummins, Theodore R.; Meyer, Jason S.; Biology, School of ScienceRetinal ganglion cells (RGCs) form the connection between the eye and the brain, with this connectivity disrupted in numerous blinding disorders. Previous studies have demonstrated the ability to derive RGCs from human pluripotent stem cells (hPSCs); however, these cells exhibited some characteristics that indicated a limited state of maturation. Among the many factors known to influence RGC development in the retina, astrocytes are known to play a significant role in their functional maturation. Thus, efforts of the current study examined the functional maturation of hPSC-derived RGCs, including the ability of astrocytes to modulate this developmental timeline. Morphological and functional properties of RGCs were found to increase over time, with astrocytes significantly accelerating the functional maturation of hPSC-derived RGCs. The results of this study clearly demonstrate the functional and morphological maturation of RGCs in vitro, including the effects of astrocytes on the maturation of hPSC-derived RGCs.Item Cellular Sources and Neuroprotective Roles of Interleukin-10 in the Facial Motor Nucleus after Axotomy(MDPI, 2022-10-09) Runge, Elizabeth M.; Setter, Deborah O.; Iyer, Abhirami K.; Regele, Eric J.; Kennedy, Felicia M.; Sanders, Virginia M.; Jones, Kathryn J.; Anatomy, Cell Biology and Physiology, School of MedicineFacial motoneuron (FMN) survival is mediated by CD4+ T cells in an interleukin-10 (IL-10)-dependent manner after facial nerve axotomy (FNA), but CD4+ T cells themselves are not the source of this neuroprotective IL-10. The aims of this study were to (1) identify the temporal and cell-specific induction of IL-10 expression in the facial motor nucleus and (2) elucidate the neuroprotective capacity of this expression after axotomy. Immunohistochemistry revealed that FMN constitutively produced IL-10, whereas astrocytes were induced to make IL-10 after FNA. Il10 mRNA co-localized with microglia before and after axotomy, but microglial production of IL-10 protein was not detected. To determine whether any single source of IL-10 was critical for FMN survival, Cre/Lox mouse strains were utilized to selectively knock out IL-10 in neurons, astrocytes, and microglia. In agreement with the localization data reflecting concerted IL-10 production by multiple cell types, no single cellular source of IL-10 alone could provide neuroprotection after FNA. These findings suggest that coordinated neuronal and astrocytic IL-10 production is necessary for FMN survival and has roles in neuronal homeostasis, as well as neuroprotective trophism after axotomy.Item EphB2 Signaling Is Implicated in Astrocyte-Mediated Parvalbumin Inhibitory Synapse Development(Society for Neuroscience, 2024-11-06) Sutley-Koury, Samantha N.; Taitano-Johnson, Christopher; Kulinich, Anna O.; Farooq, Nadia; Wagner, Victoria A.; Robles, Marissa; Hickmott, Peter W.; Santhakumar, Vijayalakshmi; Mimche, Patrice N.; Ethell, Iryna M.; Dermatology, School of MedicineImpaired inhibitory synapse development is suggested to drive neuronal hyperactivity in autism spectrum disorders (ASD) and epilepsy. We propose a novel mechanism by which astrocytes control the development of parvalbumin (PV)-specific inhibitory synapses in the hippocampus, implicating ephrin-B/EphB signaling. Here, we utilize genetic approaches to assess functional and structural connectivity between PV and pyramidal cells (PCs) through whole-cell patch-clamp electrophysiology, optogenetics, immunohistochemical analysis, and behaviors in male and female mice. While inhibitory synapse development is adversely affected by PV-specific expression of EphB2, a strong candidate ASD risk gene, astrocytic ephrin-B1 facilitates PV→PC connectivity through a mechanism involving EphB signaling in PV boutons. In contrast, the loss of astrocytic ephrin-B1 reduces PV→PC connectivity and inhibition, resulting in increased seizure susceptibility and an ASD-like phenotype. Our findings underscore the crucial role of astrocytes in regulating inhibitory circuit development and discover a new role of EphB2 receptors in PV-specific inhibitory synapse development.Item Induction of astrocyte reactivity promotes neurodegeneration in human pluripotent stem cell models(Elsevier, 2024) Gomes, Cátia; Huang, Kang-Chieh; Harkin, Jade; Baker, Aaron; Hughes, Jason M.; Pan, Yanling; Tutrow, Kaylee; VanderWall, Kirstin B.; Lavekar, Sailee S.; Hernandez, Melody; Cummins, Theodore R.; Canfield, Scott G.; Meyer, Jason S.; Medical and Molecular Genetics, School of MedicineReactive astrocytes are known to exert detrimental effects upon neurons in several neurodegenerative diseases, yet our understanding of how astrocytes promote neurotoxicity remains incomplete, especially in human systems. In this study, we leveraged human pluripotent stem cell (hPSC) models to examine how reactivity alters astrocyte function and mediates neurodegeneration. hPSC-derived astrocytes were induced to a reactive phenotype, at which point they exhibited a hypertrophic profile and increased complement C3 expression. Functionally, reactive astrocytes displayed decreased intracellular calcium, elevated phagocytic capacity, and decreased contribution to the blood-brain barrier. Subsequently, co-culture of reactive astrocytes with a variety of neuronal cell types promoted morphological and functional alterations. Furthermore, when reactivity was induced in astrocytes from patient-specific hPSCs (glaucoma, Alzheimer's disease, and amyotrophic lateral sclerosis), the reactive state exacerbated astrocytic disease-associated phenotypes. These results demonstrate how reactive astrocytes modulate neurodegeneration, significantly contributing to our understanding of a role for reactive astrocytes in neurodegenerative diseases.Item PD-L1 signaling in reactive astrocytes counteracts neuroinflammation and ameliorates neuronal damage after traumatic brain injury(BMC, 2022-01-08) Gao, Xiang; Li, Wei; Syed, Fahim; Yuan, Fang; Li, Ping; Yu, Qigui; Neurological Surgery, School of MedicineBackground: Tissue damage and cellular destruction are the major events in traumatic brain injury (TBI), which trigger sterile neuroimmune and neuroinflammatory responses in the brain. While appropriate acute and transient neuroimmune and neuroinflammatory responses facilitate the repair and adaptation of injured brain tissues, prolonged and excessive neuroimmune and neuroinflammatory responses exacerbate brain damage. The mechanisms that control the intensity and duration of neuroimmune and neuroinflammatory responses in TBI largely remain elusive. Methods: We used the controlled cortical impact (CCI) model of TBI to study the role of immune checkpoints (ICPs), key regulators of immune homeostasis, in the regulation of neuroimmune and neuroinflammatory responses in the brain in vivo. Results: We found that de novo expression of PD-L1, a potent inhibitory ICP, was robustly and transiently induced in reactive astrocytes, but not in microglia, neurons, or oligodendrocyte progenitor cells (OPCs). These PD-L1+ reactive astrocytes were highly enriched to form a dense zone around the TBI lesion. Blockade of PD-L1 signaling enlarged brain tissue cavity size, increased infiltration of inflammatory Ly-6CHigh monocytes/macrophages (M/Mɸ) but not tissue-repairing Ly-6CLowF4/80+ M/Mɸ, and worsened TBI outcomes in mice. PD-L1 gene knockout enhanced production of CCL2 that is best known for its ability to interact with its cognate receptor CCR2 on Ly-6CHigh M/Mϕ to chemotactically recruit these cells into inflammatory sites. Mechanically, PD-L1 signaling in astrocytes likely exhibits dual inhibitory activities for the prevention of excessive neuroimmune and neuroinflammatory responses to TBI through (1) the PD-1/PD-L1 axis to suppress the activity of brain-infiltrating PD-1+ immune cells, such as PD-1+ T cells, and (2) PD-L1 intrinsic signaling to regulate the timing and intensity of astrocyte reactions to TBI. Conclusions: PD-L1+ astrocytes act as a gatekeeper to the brain to control TBI-related neuroimmune and neuroinflammatory responses, thereby opening a novel avenue to study the role of ICP-neuroimmune axes in the pathophysiology of TBI and other neurological disorders.