Injured Axons Instruct Schwann Cells to Build Constricting Actin Spheres to Accelerate Axonal Disintegration

Vaquié, Adrien; Sauvain, Alizée; Duman, Mert; Nocera, Gianluigi; Egger, Boris; Meyenhofer, Felix; Falquet, Laurent; Bartesaghi, Luca; Chrast, Roman; Lamy, Christophe; Bang, Seokyoung; Lee, Seung Ryeol; Ruff, Sophie; Jacob, Claire

doi:10.1016/j.celrep.2019.05.060

Cited by 50 publications

(85 citation statements)

References 50 publications

(81 reference statements)

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“…Although they are unable to fully predict what happens at the whole organ level, primary SC/neuron cocultures have been useful PNS models to investigate the molecular mechanisms involved in axonal regrowth fostered by SCs and remyelination. Moreover, microfluidic devices, which allow the compartmentalization of neuronal cell bodies, axons and myelinating cells, have demonstrated to be useful in in vitro research [15,16].…”

Section: Nerve Injury and Methods In Regeneration Researchmentioning

confidence: 99%

“…The presence of persistent axon fragments inhibits the regeneration of axon branches [21] and leads to delayed axonal regrowth [16,41,42]. We recently showed that after a peripheral nerve lesion, SCs form constricting actomyosin spheres along unfragmented distal cut axons to accelerate their disintegration [16]. Interestingly, this mechanism is triggered by distal cut axons that upregulate the VEGFR1 agonist PlGF by injury-induced local translation, resulting in the activation of a VEGFR1/Pak1/F-actin axis in SCs [16].…”

Section: Axon and Myelin Clearancementioning

confidence: 99%

“…We recently showed that after a peripheral nerve lesion, SCs form constricting actomyosin spheres along unfragmented distal cut axons to accelerate their disintegration [16]. Interestingly, this mechanism is triggered by distal cut axons that upregulate the VEGFR1 agonist PlGF by injury-induced local translation, resulting in the activation of a VEGFR1/Pak1/F-actin axis in SCs [16]. Moreover, after injury myelin in the distal injured axon site breaks down into small intracellular and extracellular fragments and debris.…”

Section: Axon and Myelin Clearancementioning

confidence: 99%

“…Indeed, they are characterized by de-novo expression of genes that include Olig1 and Shh and by the upregulation of many proteins involved in the regeneration process. Among those, (1) c-Jun, the main driver of the SC-dependent repair program, glial cell-derived neurotrophic factor (GDNF), brain-derived neurotrophic factor (BDNF), neurotrophin-3 (NT3), artemin, nerve growth factor (NGF), vascular endothelial growth factor (VEGF), and VEGF receptor 1 support the survival of injured neurons and promote the regrowth of proximal axons [ 1 , 16 , 18 – 20 ]; (2) leukemia inhibitory factor (LIF), interleukin-1α (IL-1α) and -1β (IL-1β), tumor necrosis factor-α (TNF-α) and monocyte chemotactic protein 1 (MCP-1) initiate the immune response, promote macrophage invasion and activation, blood vessel formation and myelin breakdown [ 1 , 21 – 24 ]; (3) c-Jun, SRY-box 2 (Sox2) and neuregulin 1 (NRG1) are involved in SC morphological changes and axoglial interactions, in the formation of a nerve bridge in case of nerve transection and of the regeneration tracks along which axons regrow; (4) zinc finger E-box-binding homeobox 2 (Zeb2), nuclear factor-kappa B (NF-kB) and histone deacetylases 1 and 2 (HDAC1/2) are involved in the remyelination of the regenerated axon [ 25 – 29 ]. A summary of the main factors involved in the regeneration process is illustrated in Fig.…”

Section: Schwann Cell Reprogrammingmentioning

confidence: 99%

“…To be efficient, the regenerative process requires the generation of a favorable environment that fosters axonal repair. Rapidly after injury, SCs promote the disintegration of distal cut axons [ 16 ] and their clearance, together with invading macrophages [ 38 – 40 ]. The presence of persistent axon fragments inhibits the regeneration of axon branches [ 21 ] and leads to delayed axonal regrowth [ 16 , 41 , 42 ].…”

Section: Axon and Myelin Clearancementioning

confidence: 99%

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Mechanisms of Schwann cell plasticity involved in peripheral nerve repair after injury

Nocera

Jacob

2020

Cell. Mol. Life Sci.

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279

204

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The great plasticity of Schwann cells (SCs), the myelinating glia of the peripheral nervous system (PNS), is a critical feature in the context of peripheral nerve regeneration following traumatic injuries and peripheral neuropathies. After a nerve damage, SCs are rapidly activated by injury-induced signals and respond by entering the repair program. During the repair program, SCs undergo dynamic cell reprogramming and morphogenic changes aimed at promoting nerve regeneration and functional recovery. SCs convert into a repair phenotype, activate negative regulators of myelination and demyelinate the damaged nerve. Moreover, they express many genes typical of their immature state as well as numerous de-novo genes. These genes modulate and drive the regeneration process by promoting neuronal survival, damaged axon disintegration, myelin clearance, axonal regrowth and guidance to their former target, and by finally remyelinating the regenerated axon. Many signaling pathways, transcriptional regulators and epigenetic mechanisms regulate these events. In this review, we discuss the main steps of the repair program with a particular focus on the molecular mechanisms that regulate SC plasticity following peripheral nerve injury.

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Section: Nerve Injury and Methods In Regeneration Researchmentioning

confidence: 99%

Section: Axon and Myelin Clearancementioning

confidence: 99%

Section: Axon and Myelin Clearancementioning

confidence: 99%

Section: Schwann Cell Reprogrammingmentioning

confidence: 99%

Section: Axon and Myelin Clearancementioning

confidence: 99%

See 3 more Smart Citations

Mechanisms of Schwann cell plasticity involved in peripheral nerve repair after injury

Nocera

Jacob

2020

Cell. Mol. Life Sci.

Self Cite

279

204

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show abstract

Advances in Nerve Injury Models on a Chip

2023

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Regeneration and functional recovery of the damaged nerve are challenging due to the need for effective therapeutic drugs, biomaterials, and approaches. The poor outcome of the treatment of nerve injury stems from the incomplete understanding of axonal biology and interactions between neurons and the surrounding environment, such as glial cells and extracellular matrix. Microfluidic devices, in combination with various injury techniques, have been applied to test biological hypotheses in nerve injury and nerve regeneration. The microfluidic devices provide multiple advantages over the in vitro cell culture on a petri dish and in vivo animal models because a specific part of the neuronal environment can be manipulated using physical and chemical interventions. In addition, single‐cell behavior and interactions between neurons and glial cells can be visualized and quantified on microfluidic platforms. In this article, current in vitro nerve injury models on a chip that mimics in vivo axonal injuries and the regeneration process of axons are summarized. The microfluidic‐based nerve injury models could enhance the understanding of the physiological and pathophysiological mechanisms of nerve tissues and simultaneously serve as powerful drug and biomaterial screening platforms.

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Emerging Brain‐Pathophysiology‐Mimetic Platforms for Studying Neurodegenerative Diseases: Brain Organoids and Brains‐on‐a‐Chip

Bang

Lee

Choi

et al. 2021

Adv Healthcare Materials

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Neurodegenerative diseases are a group of disorders characterized by progressive degeneration of the structural and functional integrity of the central and peripheral nervous systems. Millions of people suffer from degenerative brain diseases worldwide, and the mortality continues to increase every year, causing a growing demand for knowledge of the underlying mechanisms and development of therapeutic targets. Conventional 2D‐based cell culture platforms and animal models cannot fully recapitulate the pathophysiology, and this has limited the capability for estimating drug efficacy. Recently, engineered platforms, including brain organoids and brain‐on‐a‐chip, have emerged. They mimic the physiology of brain tissue and reflect the fundamental pathophysiological signatures of neurodegenerative diseases, such as the accumulation of neurotoxic proteins, structural abnormalities, and functional loss. In this paper, recent advances in brain‐mimetic platforms and their potential for modeling features of neurodegenerative diseases in vitro are reviewed. The development of a physiologically relevant model should help overcome unresolved neurodegenerative diseases.

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Injured Axons Instruct Schwann Cells to Build Constricting Actin Spheres to Accelerate Axonal Disintegration

Cited by 50 publications

References 50 publications

Mechanisms of Schwann cell plasticity involved in peripheral nerve repair after injury

Mechanisms of Schwann cell plasticity involved in peripheral nerve repair after injury

Advances in Nerve Injury Models on a Chip

Emerging Brain‐Pathophysiology‐Mimetic Platforms for Studying Neurodegenerative Diseases: Brain Organoids and Brains‐on‐a‐Chip

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