Microglia induce neurogenic protein expression in primary cortical cells by stimulating PI3K/AKT intracellular signaling in vitro

AbstractEmerging evidence suggests that microglia can support neurogenesis. Little is known about the mechanisms by which microglia regulate the cortical environment and stimulate cortical neurogenesis. We used an in vitro co-culture model system to investigate the hypothesis that microglia respond to soluble signals from cortical cells, particularly following mechanical injury, to alter the cortical environment and promote cortical cell proliferation, differentiation, and survival. Analyses of cortical cell proliferation, cell death, neurogenic protein expression, and intracellular signaling were performed on uninjured and injured cortical cells in co-culture with microglial cell lines. Microglia soluble cues enhanced cortical cell viability and proliferation cortical cells. Co-culture of injured cortical cells with microglia significantly reduced cell death of cortical cells. Microglial co-culture significantly increased Nestin + and α-internexin + cortical cells. Multiplex ELISA and RT-PCR showed decreased pro-inflammatory cytokine production by microglia co-cultured with injured cortical cells. Inhibition of AKT phosphorylation in cortical cells blocked microglial-enhanced cortical cell viability and expression of neurogenic markers in vitro. This in vitro model system allows for assessment of the effect of microglial-derived soluble signals on cortical cell viability, proliferation, and stages of differentiation during homeostasis or following mechanical injury. These data suggest that microglia cells can downregulate inflammatory cytokine production following activation by mechanical injury to enhance proliferation of new cells capable of neurogenesis via activation of AKT intracellular signaling. Increasing our understanding of the mechanisms that drive microglial-enhanced cortical neurogenesis during homeostasis and following injury in vitro will provide useful information for future primary cell and in vivo studies.

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Microglia induce neurogenesis by stimulating PI3K/AKT intracellular signaling in vitro

10.21203/rs.2.11343/v2 ◽

2019 ◽

Author(s):

Kristi Lorenzen ◽

Nicholas W. Mathy ◽

Erin R. Whiteford ◽

Alex Eischeid ◽

Jing Chen ◽

...

Keyword(s):

Cell Proliferation ◽

Cell Viability ◽

Intracellular Signaling ◽

Cortical Cell ◽

Model System ◽

Microglial Cells ◽

Cortical Cells ◽

Akt Phosphorylation ◽

Cortical Neurogenesis

Abstract Background: Emerging evidence suggests that microglia can support neuronal survival, synapse development, and neurogenesis in classic neurogenic niches. Little is known about the ability of microglia to regulate the cortical environment and stimulate cortical neurogenesis outside classic neurogenic niches. We used an in vitro co-culture model system to investigate the hypothesis that microglia respond to soluble signals from cortical cells, particularly following injury, to alter the cortical environment and promote cortical cell proliferation, differentiation, and maintain cortical cell survival via activation of specific cortical intracellular signaling pathways. Results: Analyses of cell proliferation, apoptosis, protein expression, and intracellular signaling pathway activation were performed on uninjured and injured cortical cells in co-culture with EOC2 microglia. EOC2 microglia in co-culture enhanced cortical cell viability and proliferation of uninjured and injured cortical cells. Co-culture of injured cortical cells with EOC2 microglial cells significantly reduced cortical cell apoptosis. Microglial co-culture significantly increased Nestin+ and a-internexin+ cells within and outside of the injury site. NeuN+ cells increased in injured cortical cultures with microglia. Multiplex ELISA assays showed decreased levels of inflammatory cytokines in conditioned media from injured cortical cell and microglial co-culture. RTPCR analysis of microglial mRNA was performed. EOC2 microglial co-culture environment increased AKT phosphorylation in cortical cells particularly following injury. Inhibition of AKT phosphorylation in cortical cells blocked the microglial-enhanced cortical cell viability and expression of neurogenic markers in vitro. Conclusion: The in vitro model system presented here allows for assessment of the effect of microglial-derived soluble signals, independent of cell-cell contact, on cortical cell viability, proliferation, and stages of differentiation during homeostasis or following injury. These data suggest that microglia downregulate inflammatory cytokine production following activation by acute cortical injury to enhance proliferation of new cells capable of neurogenesis. Inhibition of AKT signaling in cortical cells blocks the enhanced proliferation and expression of neurogenic markers in cortical cells. Increasing our understanding of the mechanisms that drive cortical neurogenesis stimulated by microglial cells during homeostasis and following injury will provide insight into the potential mechanisms of neuroprotective role of immune activity in the central nervous system (CNS).

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Microglia induce neurogenesis by stimulating PI3K/AKT intracellular signaling in vitro

10.21203/rs.2.11343/v1 ◽

2019 ◽

Author(s):

Kristi Lorenzen ◽

Nicholas W. Mathy ◽

Erin R. Whiteford ◽

Alex Eischeid ◽

Jing Chen ◽

...

Keyword(s):

Cell Viability ◽

Intracellular Signaling ◽

Cortical Cell ◽

Model System ◽

Pcr Analysis ◽

Cell Contact ◽

Cortical Cells ◽

Akt Phosphorylation ◽

Cortical Neurogenesis

Abstract Background Emerging evidence suggests that microglia can support neuronal survival, synapse development, and neurogenesis in classic neurogenic niches. Little is known about the ability of microglia to regulate the cortical environment and stimulate cortical neurogenesis outside of the classic neurogenic niches. We used an in vitro co-culture model system to test the hypothesis that microglia respond to soluble signals from injured cortical cells to alter the cortical environment in order to promote cortical neurogenesis and maintain cell survival. Results Our model system allows for assessment of how microglial soluble signals influence mechanically injured cortical cells in vitro. These data demonstrate that microglia responding to soluble signals from uninjured and, to a greater extent, injured cortical cells enhanced cortical cell viability and proliferation. Co-culture of injured cortical cells with microglia significantly reduced apoptosis as shown by TUNEL immunocytochemistry. Microglial-derived soluble cues enhanced the proliferation of cells expressing neurogenic markers nestin, glial fibrillary acidic protein, and α-internexin as determined by western blot and immunocytochemistry. Significantly increased NeuN expression was observed in injured cortical cultures co-cultured with microglia. Multiplex ELISA assays and RT-PCR analysis revealed significant increase of MCP-1/CCL2 and downregulation of IFN-γ, MIP-1α, TNFα and RANTES in media from microglial and injured cortical co-cultures compared to uninjured controls. Microglia soluble cues increase AKT phosphorylation in cortical cells particularly following injury. Inhibition of AKT phosphorylation in cortical cells blocked the microglial-enhanced cortical cell viability and expression of neurogenic markers in vitro. Conclusion An in vitro model system allows for assessment of microglial-derived soluble signals, independent of cell-cell contact, on cortical cell viability, proliferation, and differentiation during homeostasis or following injury. While many intracellular signaling pathways may be activated in neurons by neurogenic microglial-derived soluble cues, these data suggest that microglial-derived soluble signals produced during homeostasis and following activation by acute cortical injury enhance neurogenesis by upregulating AKT signaling. Increasing our understanding of the mechanisms that drive cortical neurogenesis stimulated by microglia during homeostasis and following injury will provide insight into neuroprotective role of immune activity in the CNS.

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Microglia induce neurogenesis by stimulating PI3K/AKT intracellular signaling in vitro

10.21203/rs.2.11343/v3 ◽

2020 ◽

Author(s):

Kristi Lorenzen ◽

Nicholas W. Mathy ◽

Erin R. Whiteford ◽

Alex Eischeid ◽

Jing Chen ◽

...

Keyword(s):

Cell Viability ◽

Intracellular Signaling ◽

Microglial Cell ◽

Cortical Cell ◽

Model System ◽

Microglial Cells ◽

Cortical Cells ◽

Akt Phosphorylation ◽

Cortical Neurogenesis

Abstract Background: Emerging evidence suggests that microglia can support neuronal survival, synapse development, and neurogenesis in classic neurogenic niches. Little is known about the ability of microglia to regulate the cortical environment and stimulate cortical neurogenesis outside classic neurogenic niches. We used an in vitro co-culture model system to investigate the hypothesis that microglia respond to soluble signals from cortical cells, particularly following injury, by altering the cortical environment to promote cortical cell proliferation, differentiation, and survival. Results: Analyses of cell proliferation, apoptosis, protein expression, and intracellular signaling were performed on uninjured and injured cortical cells in co-culture with an EOC2 microglial cell line. Microglia soluble cues enhanced cortical cell viability and proliferation of uninjured and injured cortical cells. Co-culture of injured cortical cells with microglial cells significantly reduced cortical cell apoptosis. Microglial significantly increased Nestin+ and a-internexin+ cells within and outside the injury site. NeuN+ cells increased in injured cortical cultures with microglia. Multiplex ELISA assays showed decreased levels of inflammatory cytokines in conditioned media collected from injured cortical cell and microglial co-culture. RTPCR analysis of microglial mRNA was performed. AKT phosphorylation in uninjured, and particularly injured cortical cells, significantly increased when co-cultured with EOC2 microglia. Inhibition of AKT phosphorylation in cortical cells blocked the microglial-enhanced cortical cell viability and expression of neurogenic markers in vitro . Conclusion: This in vitro model system allows for assessment of the effect of microglial-derived soluble signals on cortical cell viability, proliferation, and stages of differentiation during homeostasis or following injury. These data suggest that EOC2 microglia downregulate inflammatory cytokine production following activation by acute cortical injury to enhance proliferation of new cells capable of neurogenesis. Inhibition of AKT signaling in cortical cells blocks the microglial-derived enhanced proliferation and expression of neurogenic markers in injured cortical cultures. This in vitro system is useful for continued studies with other microglial cell lines and primary microglial cells. Increasing our understanding of the mechanisms that drive cortical neurogenesis stimulated by microglial cells during homeostasis and following injury will provide insight into the potential mechanisms of the neuroprotective role of immune activity in the central nervous system (CNS).

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