Your search keyword '"Molofsky M"' showing total 2 results

1. Clec7a Worsens Long‐Term Outcomes after Ischemic Stroke by Aggravating Microglia‐Mediated Synapse Elimination.

Author

Wan, Hanxi, He, Mengfan, Cheng, Chun, Yang, Kexin, Wu, Huanghui, Cong, Peilin, Huang, Xinwei, Zhang, Qian, Shi, Yufei, Hu, Ji, Tian, Li, and Xiong, Lize

Subjects

ISCHEMIC stroke, CENTRAL nervous system, PHAGOCYTOSIS, BRAIN injuries, NEURONAL differentiation

Abstract

Ischemic stroke (IS) is a leading cause of morbidity and mortality globally and triggers a series of reactions leading to primary and secondary brain injuries and permanent neurological deficits. Microglia in the central nervous system play dual roles in neuroprotection and responding to ischemic brain damage. Here, an IS model is employed to determine the involvement of microglia in phagocytosis at excitatory synapses. Additionally, the effects of pharmacological depletion of microglia are investigated on improving neurobehavioral outcomes and mitigating brain injury. RNA sequencing of microglia reveals an increase in phagocytosis‐associated pathway activity and gene expression, and C‐type lectin domain family 7 member A (Clec7a) is identified as a key regulator of this process. Manipulating microglial Clec7a expression can potentially regulate microglial phagocytosis of synapses, thereby preventing synaptic loss and improving neurobehavioral outcomes after IS. It is further demonstrat that microglial Clec7a interacts with neuronal myeloid differentiation protein 2 (MD2), a key molecule mediating poststroke neurological injury, and propose the novel hypothesis that MD2 is a ligand for microglial Clec7a. These findings suggest that microglial Clec7a plays a critical role in mediating synaptic phagocytosis in a mouse model of IS, suggesting that Clec7a may be a therapeutic target for IS. [ABSTRACT FROM AUTHOR]

Published

2024

2. Microglia promote maladaptive plasticity in autonomic circuitry after spinal cord injury in mice.

Author

Brennan, Faith H., Swarts, Emily A., Kigerl, Kristina A., Mifflin, Katherine A., Guan, Zhen, Noble, Benjamin T., Wang, Yan, Witcher, Kristina G., Godbout, Jonathan P., and Popovich, Phillip G.

Subjects

SPINAL cord injuries, MICROGLIA, MOLECULAR mechanisms of immunosuppression, FRACTALKINE, MYELOID cells, PATHOLOGY, NEURAL circuitry

Abstract

Robust structural remodeling and synaptic plasticity occurs within spinal autonomic circuitry after severe high-level spinal cord injury (SCI). As a result, normally innocuous visceral or somatic stimuli elicit uncontrolled activation of spinal sympathetic reflexes that contribute to systemic disease and organ-specific pathology. How hyperexcitable sympathetic circuitry forms is unknown, but local cues from neighboring glia likely help mold these maladaptive neuronal networks. Here, we used a mouse model of SCI to show that microglia surrounded active glutamatergic interneurons and subsequently coordinated multi-segmental excitatory synaptogenesis and expansion of sympathetic networks that control immune, neuroendocrine, and cardiovascular functions. Depleting microglia during critical periods of circuit remodeling after SCI prevented maladaptive synaptic and structural plasticity in autonomic networks, decreased the frequency and severity of autonomic dysreflexia, and prevented SCI-induced immunosuppression. Forced turnover of microglia in microglia-depleted mice restored structural and functional indices of pathological dysautonomia, providing further evidence that microglia are key effectors of autonomic plasticity. Additional data show that microglia-dependent autonomic plasticity required expression of triggering receptor expressed on myeloid cells 2 (Trem2) and α2δ-1–dependent synaptogenesis. These data suggest that microglia are primary effectors of autonomic neuroplasticity and dysautonomia after SCI in mice. Manipulating microglia may be a strategy to limit autonomic complications after SCI or other forms of neurologic disease. Editor's summary: Spinal cord injuries (SCIs) above the mid-thoracic vertebrae disrupt central control over spinal autonomic circuits. The cellular drivers of the subsequent circuit remodeling that can lead to autonomic dysfunctions remain to be identified. Here, Brennan et al. used a mouse model of thoracic SCI and demonstrated that microglia depletion prevented SCI-associated autonomic circuit expansion as well as neuroendocrine dysregulation, immune dysfunction, and autonomic dysreflexia (AD). These results identify microglia as potential target to prevent maladaptive autonomic circuit remodeling. —Daniela Neuhofer [ABSTRACT FROM AUTHOR]

Published

2024