After Nerve Injury, Lineage Tracing Shows That Myelin and Remak Schwann Cells Elongate Extensively and Branch to Form Repair Schwann Cells, Which Shorten Radically on Remyelination

Gomez-Sanchez, Jose A.; Pilch, Kjara S; Lans, Milou van der; Fazal, Shaline V.; Benito, Cristina; Wagstaff, Laura; Mirsky, Rhona; Jessen, Kristján R.

doi:10.1523/jneurosci.1453-17.2017

Cited by 210 publications

(218 citation statements)

References 41 publications

Supporting

Mentioning

208

Contrasting

Order By: Relevance

“…As detailed in the following section, Schwann cells provide a further example of adaptive cellular reprogramming. In this case also, cells with a repair‐supportive phenotype, which are normally absent, are generated directly from resident differentiated cells of the injured tissue (Gomez‐Sanchez et al, ) and function to restore tissue homeostasis.…”

Section: Adaptive Cellular Reprogrammingmentioning

confidence: 99%

“…(c) Structural reorganization, generating extremely elongated, cells, which are about threefold longer than myelin and Remak cells. Lineage tracing has shown that these cells are generated directly from myelin and Remak cells, and that they can convert directly to myelin cells following regeneration (Gomez‐Sanchez et al, ). These cells often carry long, parallel processes, which together with their length, allows repair cells to partly overlap and promotes the formation of the compact cellular columns (Bungner bands—Figures and ), which are obligatory regeneration tracks for regenerating axons (Gomez‐Sanchez et al, ).…”

Section: Adaptive Cellular Reprogrammingmentioning

confidence: 99%

“…Denervated adult Schwann cells have also been shown to express de novo molecular markers that are low/absent during development, including Sonic Hedgehog (Shh), and Olig1 (Lu et al, ; Bosse et al, ; Arthur‐Farraj et al, ; Fontana et al, ; Lin, Oksuz, Edward Hurley, Wrabetz, & Awatramani, ; reviewed in Jessen & Mirsky, ). Again in contrast to developing cells, denervated cells express high levels of cytokines, recruit macrophages, and activate myelin autophagy to clear myelin (Gomez‐Sanchez et al, ; reviewed in Martini, Fischer, López‐Vales, & David, ; Rotshenker, ; Stratton & Shah, ), Denervated adult cells also adopt a striking elongated and often branched morphology, which is very different from that of Schwann cells in developing nerves, and which enables them to form regeneration tracks, which guide regrowing axons (Gomez‐Sanchez et al, ).…”

Section: Introduction: the Changing View On The Schwann Cell Injury Rmentioning

confidence: 99%

See 2 more Smart Citations

Repair Schwann cell update: Adaptive reprogramming, EMT, and stemness in regenerating nerves

Jessen

Arthur‐Farraj

2019

Glia

247

260

View full text Add to dashboard Cite

Schwann cells respond to nerve injury by cellular reprogramming that generates cells specialized for promoting regeneration and repair. These repair cells clear redundant myelin, attract macrophages, support survival of damaged neurons, encourage axonal growth, and guide axons back to their targets. There are interesting parallels between this response and that found in other tissues. At the cellular level, many other tissues also react to injury by cellular reprogramming, generating cells specialized to promote tissue homeostasis and repair. And at the molecular level, a common feature possessed by Schwann cells and many other cells is the injury‐induced activation of genes associated with epithelial–mesenchymal transitions and stemness, differentiation states that are linked to cellular plasticity and that help injury‐induced tissue remodeling. The number of signaling systems regulating Schwann cell plasticity is rapidly increasing. Importantly, this includes mechanisms that are crucial for the generation of functional repair Schwann cells and nerve regeneration, although they have no or a minor role elsewhere in the Schwann cell lineage. This encourages the view that selective tools can be developed to control these particular cells, amplify their repair supportive functions and prevent their deterioration. In this review, we discuss the emerging similarities between the injury response seen in nerves and in other tissues and survey the transcription factors, epigenetic mechanisms, and signaling cascades that control repair Schwann cells, with emphasis on systems that selectively regulate the Schwann cell injury response.

show abstract

Section: Adaptive Cellular Reprogrammingmentioning

confidence: 99%

Section: Adaptive Cellular Reprogrammingmentioning

confidence: 99%

Section: Introduction: the Changing View On The Schwann Cell Injury Rmentioning

confidence: 99%

See 1 more Smart Citation

Repair Schwann cell update: Adaptive reprogramming, EMT, and stemness in regenerating nerves

Jessen

Arthur‐Farraj

2019

Glia

247

260

View full text Add to dashboard Cite

show abstract

“…Repair Schwann cells activate autophagy and phagocytosis mechanisms to remove myelin debris, which inhibit axon regrowth and branching (Brosius Lutz et al 2017; Gomez-Sanchez et al 2015; Mukhopadhyay et al 1994; Shen et al 1998), and promote recruitment of macrophages that further facilitate myelin removal and regeneration (Cattin et al 2015; Fischer et al 2008; Niemi et al 2013). Elongated Schwann cells distal to the injury site form Bands of Bungner, which serve as tracks for axonal regeneration (Arthur-Farraj et al 2012; Gomez-Sanchez et al 2017). …”

Section: Introductionmentioning

confidence: 99%

Polycomb repression regulates Schwann cell proliferation and axon regeneration after nerve injury

Duong

Moran

et al. 2018

Glia

View full text Add to dashboard Cite

The transition of differentiated Schwann cells to support of nerve repair after injury is accompanied by remodeling of the Schwann cell epigenome. The EED-containing polycomb repressive complex 2 (PRC2) catalyzes histone H3K27 methylation and represses key nerve repair genes such as Shh, Gdnf and Bdnf, and their activation is accompanied by loss of H3K27 methylation. Analysis of nerve injury in mice with a Schwann cell-specific loss of EED showed the reversal of polycomb repression is required and a rate limiting step in the increased transcription of Neuregulin 1 (type I), which is required for efficient remyelination. However, mouse nerves with EED-deficient Schwann cells display slow axonal regeneration with significantly low expression of axon guidance genes, including Sema4f and Cntf. Finally, EED loss causes impaired Schwann cell proliferation after injury with significant induction of the Cdkn2a cell cycle inhibitor gene. Interestingly, PRC2 subunits and CDKN2A are commonly co-mutated in the transition from benign neurofibromas to malignant peripheral nerve sheath tumors (MPNST’s). RNA-seq analysis of EED-deficient mice identified PRC2-regulated molecular pathways that may contribute to the transition to malignancy in neurofibromatosis.

show abstract

“…The regeneration of axons as well as motor and sensory target innervation after injury is dependent on the capacity of Schwann cells to switch into and maintain a repair phenotype (Büngner cell) . These repair Schwann cells support axonal growth and path‐finding.…”

Section: Discussionmentioning

confidence: 99%

Motor and sensory Schwann cell phenotype commitment is diminished by extracorporeal shockwave treatment in vitro

Hercher

Redl

Schuh

2020

J Peripheral Nervous Sys

View full text Add to dashboard Cite

The gold standard for peripheral nerve regeneration uses a sensory autograft to bridge a motor/sensory defect site. For motor nerves to regenerate, Schwann cells (SC) myelinate the newly grown axon. Sensory SCs have a reduced ability to produce myelin, partially explaining low success rates of autografts. This issue is masked in pre‐clinical research by the excessive use of the rat sciatic nerve defect model, utilizing a mixed nerve with motor and sensory SCs. Aim of this study was to utilize extracorporeal shockwave treatment as a novel tool to influence SC phenotype. SCs were isolated from motor, sensory and mixed rat nerves and in vitro differences between them were assessed concerning initial cell number, proliferation rate, neurite outgrowth as well as ability to express myelin. We verified the inferior capacity of sensory SCs to promote neurite outgrowth and express myelin‐associated proteins. Motor Schwann cells demonstrated low proliferation rates, but strongly reacted to pro‐myelination stimuli. It is noteworthy for pre‐clinical research that sciatic SCs are a strongly mixed culture, not representing one or the other. Extracorporeal shockwave treatment (ESWT), induced in motor SCs an increased proliferation profile, while sensory SCs gained the ability to promote neurite outgrowth and express myelin‐associated markers. We demonstrate a strong phenotype commitment of sciatic, motor, and sensory SCs in vitro, proposing the experimental use of SCs from pure cultures to better mimic clinical situations. Furthermore we provide arguments for using ESWT on autografts to improve the regenerative capacity of sensory SCs.

show abstract

After Nerve Injury, Lineage Tracing Shows That Myelin and Remak Schwann Cells Elongate Extensively and Branch to Form Repair Schwann Cells, Which Shorten Radically on Remyelination

Cited by 210 publications

References 41 publications

Repair Schwann cell update: Adaptive reprogramming, EMT, and stemness in regenerating nerves

Repair Schwann cell update: Adaptive reprogramming, EMT, and stemness in regenerating nerves

Polycomb repression regulates Schwann cell proliferation and axon regeneration after nerve injury

Motor and sensory Schwann cell phenotype commitment is diminished by extracorporeal shockwave treatment in vitro

Contact Info

Product

Resources

About