Mathew Blurton‐Jones scite author profile

Investigation of axonal biology in the central nervous system (CNS) is hindered by a lack of an appropriate in vitro method to probe axons independently from cell bodies. Here we describe a microfluidic culture platform that polarizes the growth of CNS axons into a fluidically isolated environment without the use of targeting neurotrophins. In addition to its compatibility with live cell imaging, the platform can be used to (i) isolate CNS axons without somata or dendrites, facilitating biochemical analyses of pure axonal fractions and (ii) localize physical and chemical treatments to axons or somata. We report the first evidence that presynaptic (Syp) but not postsynaptic (Camk2a) mRNA is localized to developing rat cortical and hippocampal axons. The platform also serves as a straightforward, reproducible method to model CNS axonal injury and regeneration. The results presented here demonstrate several experimental paradigms using the microfluidic platform, which can greatly facilitate future studies in axonal biology.Neurons in the CNS extend axons over considerable distances and through varying extracellular microenvironments to form synapses, the basis of neuronal connectivity. Axonal damage is critical to the etiology of CNS injuries and neurodegenerative disease (for example, spinal cord injury and Alzheimer disease) 1-3 ; therefore, considerable effort focuses on the molecular and cellular mechanisms that influence axonal plasticity and response to injury. In vitro models facilitate the study of axonal biology in the peripheral nervous system (PNS), but no suitable method has been developed for the study of the CNS because of the challenges associated with culturing CNS neurons.In vitro studies using compartmentalized 'Campenot' chambers have greatly improved the understanding of axonal biology within the PNS 4-6 . Campenot chambers use a compartmented Teflon divider attached to a collagen-coated petri dish via a thinly applied silicone grease layer; typically nerve growth factor (NGF) promotes neuritic growth through the grease layer. Much of the work involving Campenot chambers focused on the influence and transport of NGF.

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iPSC-Derived Human Microglia-like Cells to Study Neurological Diseases

Abud

Ramirez

Martínez

et al. 2017

Neuron

836

1,000

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Summary Microglia play critical roles in brain development, homeostasis, and neurological disorders. Here, we report that human microglial-like cells (iMGL) can be differentiated from iPSCs to study their function in neurological diseases, like Alzheimer’s disease (AD). We find that iMGLs develop in vitro similarly to microglia in vivo and whole transcriptome analysis demonstrates that they are highly similar to cultured adult and fetal human microglia. Functional assessment of iMGLs reveals that they secrete cytokines in response to inflammatory stimuli, migrate and undergo calcium transients, and robustly phagocytose CNS substrates. iMGLs were used to examine the effects of Aβ fibrils and brain-derived tau oligomers on AD-related gene expression and to interrogate mechanisms involved in synaptic pruning. Furthermore, iMGLs transplanted into transgenic mice and human brain organoids resemble microglia in vivo. Together, these findings demonstrate that iMGLs can be used to study microglial function, providing important new insight into human neurological disease.

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Neural stem cells improve cognition via BDNF in a transgenic model of Alzheimer disease

Blurton‐Jones

Kitazawa²,

Martínez-Coria³

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

765

583

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Neural stem cell (NSC) transplantation represents an unexplored approach for treating neurodegenerative disorders associated with cognitive decline such as Alzheimer disease (AD). Here, we used aged triple transgenic mice (3xTg-AD) that express pathogenic forms of amyloid precursor protein, presenilin, and tau to investigate the effect of neural stem cell transplantation on AD-related neuropathology and cognitive dysfunction. Interestingly, despite widespread and established Aß plaque and neurofibrillary tangle pathology, hippocampal neural stem cell transplantation rescues the spatial learning and memory deficits in aged 3xTg-AD mice. Remarkably, cognitive function is improved without altering Aß or tau pathology. Instead, the mechanism underlying the improved cognition involves a robust enhancement of hippocampal synaptic density, mediated by brainderived neurotrophic factor (BDNF). Gain-of-function studies show that recombinant BDNF mimics the beneficial effects of NSC transplantation. Furthermore, loss-of-function studies show that depletion of NSC-derived BDNF fails to improve cognition or restore hippocampal synaptic density. Taken together, our findings demonstrate that neural stem cells can ameliorate complex behavioral deficits associated with widespread Alzheimer disease pathology via BDNF.beta-amyloid ͉ neurotrophin ͉ synapse ͉ tau ͉ memory

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Eliminating microglia in Alzheimer’s mice prevents neuronal loss without modulating amyloid-β pathology

Spangenberg

Lee

Najafi

et al. 2016

Brain

559

529

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In addition to amyloid-β plaque and tau neurofibrillary tangle deposition, neuroinflammation is considered a key feature of Alzheimer's disease pathology. Inflammation in Alzheimer's disease is characterized by the presence of reactive astrocytes and activated microglia surrounding amyloid plaques, implicating their role in disease pathogenesis. Microglia in the healthy adult mouse depend on colony-stimulating factor 1 receptor (CSF1R) signalling for survival, and pharmacological inhibition of this receptor results in rapid elimination of nearly all of the microglia in the central nervous system. In this study, we set out to determine if chronically activated microglia in the Alzheimer's disease brain are also dependent on CSF1R signalling, and if so, how these cells contribute to disease pathogenesis. Ten-month-old 5xfAD mice were treated with a selective CSF1R inhibitor for 1 month, resulting in the elimination of ∼80% of microglia. Chronic microglial elimination does not alter amyloid-β levels or plaque load; however, it does rescue dendritic spine loss and prevent neuronal loss in 5xfAD mice, as well as reduce overall neuroinflammation. Importantly, behavioural testing revealed improvements in contextual memory. Collectively, these results demonstrate that microglia contribute to neuronal loss, as well as memory impairments in 5xfAD mice, but do not mediate or protect from amyloid pathology.

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Microglia states and nomenclature: A field at its crossroads

Paolicelli

Sierra

Stevens

et al. 2022

Neuron

848

504

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