The Extracellular Environment of the CNS: Influence on Plasticity, Sprouting, and Axonal Regeneration after Spinal Cord Injury

Quraishe, Shmma; Forbes, Lindsey H.; Andrews, Melissa R.

doi:10.1155/2018/2952386

Cited by 72 publications

(60 citation statements)

References 197 publications

(244 reference statements)

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“…In previous studies, CSPGs were highly expressed in the site of spinal cord injury. 54,55 In the present study, we found that the fluorescence intensity of CS56 has been decreased after the supplementation of pure ChABC into the spinal cord section. In addition, the fluorescence intensity of CS56 of the spinal cord section was also decreased by the culture medium of PEI-SPIONs/ChABC/ SCs.…”

Section: Discussionsupporting

confidence: 60%

<p>Magnetic Field Promotes Migration of Schwann Cells with Chondroitinase ABC (ChABC)-Loaded Superparamagnetic Nanoparticles Across Astrocyte Boundary in vitro</p>

Gao

Xia

et al. 2020

IJN

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These authors contributed equally to this workPurpose: The clinical outcome of spinal cord injury is usually poor due to the lack of axonal regeneration and glia scar formation. As one of the most classical supporting cells in neural regeneration, Schwann cells (SCs) provide bioactive substrates for axonal migration and release molecules that regulate axonal growth. However, the effect of SC transplantation is limited by their poor migration capacity in the astrocyte-rich central nervous system. Methods: In this study, we first magnetofected SCs with chondroitinase ABCpolyethylenimine functionalized superparamagnetic iron oxide nanoparticles (ChABC/PEI-SPIONs) to induce overexpression of ChABC for the removal of chondroitin sulfate proteoglycans. These are inhibitory factors and forming a dense scar that acts as a barrier to the regenerating axons. In vitro, we observed the migration of SCs in the region of astrocytes after the application of a stable external magnetic field. Results: We found that magnetofection with ChABC/PEI-SPIONs significantly up-regulated the expression of ChABC in SCs. Under the driven effect of the directional magnetic field (MF), the migration of magnetofected SCs was enhanced in the direction of the magnetic force. The number of SCs with ChABC/PEI-SPIONs migrated and the distance of migration into the astrocyte region was significantly increased. The number of SCs with ChABC/PEI-SPIONs that migrated into the astrocyte region was 11.6-and 4.6-fold higher than those observed for the intact control and non-MF groups, respectively. Furthermore, it was found that SCs with ChABC/PEI-SPIONs were in close contact with astrocytes and no longer formed boundaries in the presence of MF. Conclusion: The mobility of the SCs with ChABC/PEI-SPIONs was enhanced along the axis of MF, holding the potential to promote nerve regeneration by providing a bioactive microenvironment and relieving glial obstruction to axonal regeneration in the treatment of spinal cord injury.

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Section: Discussionsupporting

confidence: 60%

<p>Magnetic Field Promotes Migration of Schwann Cells with Chondroitinase ABC (ChABC)-Loaded Superparamagnetic Nanoparticles Across Astrocyte Boundary in vitro</p>

Gao

Xia

et al. 2020

IJN

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“…Among these key inhibitory molecules, CSPGs are the most prominent. CSPGs, a proteoglycan family characterized by chondroitin sulfate side chains, are thought to be released predominantly from neurons and scar-forming astrocytes (Quraishe et al, 2018). It has long been thought that CSPGs are crucial inhibitory factors of CNS axonal regeneration, making them a primary cause of the inhibitory roles of the glial scar (McKeon et al, 1991).…”

Section: Chondroitin Sulfate Proteoglycansmentioning

confidence: 99%

Dissecting the Dual Role of the Glial Scar and Scar-Forming Astrocytes in Spinal Cord Injury

Yang

Dai

Chen

et al. 2020

Front. Cell. Neurosci.

162

161

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Recovery from spinal cord injury (SCI) remains an unsolved problem. As a major component of the SCI lesion, the glial scar is primarily composed of scar-forming astrocytes and plays a crucial role in spinal cord regeneration. In recent years, it has become increasingly accepted that the glial scar plays a dual role in SCI recovery. However, the underlying mechanisms of this dual role are complex and need further clarification. This dual role also makes it difficult to manipulate the glial scar for therapeutic purposes. Here, we briefly discuss glial scar formation and some representative components associated with scar-forming astrocytes. Then, we analyze the dual role of the glial scar in a dynamic perspective with special attention to scar-forming astrocytes to explore the underlying mechanisms of this dual role. Finally, taking the dual role of the glial scar into account, we provide several pieces of advice on novel therapeutic strategies targeting the glial scar and scar-forming astrocytes.

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“…Perineuronal nets around neurons regulate neuritic growth and synaptogenesis during early life. Maturation of these extracellular matrices restricts synaptic plasticity and stabilizes functional synapses (Bikbaev et al, 2015;Clarris et al, 2000;Lensjø et al, 2017;Quraishe et al, 2018;Sorg et al, 2016;Valenzuela et al, 2014;van 't Spijker & Kwok, 2017) and disrupting them can extend early sensitive periods (e.g., monocular deprivation in the cerebral cortex or thalamus; Lensjø et al, 2017) and allow synaptic potentiation of normally plasticityresistant neurons (Carstens, Phillip, Pozzo-Miller, Weinberg, & Dudek, 2016). Substantial regional differences in the expression of extracellular matrix proteins during development have been reported (Dauth et al, 2016;Sonntag, Blosa, Schmidt, Rübsamen, & Morawski, 2015).…”

Section: Discussionmentioning

confidence: 99%

“…These mesh-like extracellular structures envelop neuronal processes and regulate the number and types of synapses. Their maturation is associated with the end of early critical periods of synaptogenesis in several brain regions (Bikbaev, Frischknecht, & Heine, 2015;Clarris, Uwe Rauch, & Key, 2000;Lensjø, Lepperød, Dick, Hafting, & Fyhn, 2017;Quraishe, Forbes, & Andrews, 2018;Sorg et al, 2016;Valenzuela et al, 2014;van 't Spijker & Kwok, 2017). Finally, the rapid changes associated with growth in the structure necessitate substantial energy: a small study addressed this issue by examining age-related changes in vasculature.…”

Section: Introductionmentioning

confidence: 99%

The mouse olfactory peduncle 4: Development of synapses, perineuronal nets, and capillaries

Collins

Brunjes

2019

J of Comparative Neurology

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Olfaction is critical for survival in neonatal mammals. However, little is known about the neural substrate for this ability as few studies of synaptic development in several olfactory processing regions have been reported. Odor information detected in the nasal cavity is first processed by the olfactory bulb and then sent via the lateral olfactory tract to a series of olfactory cortical areas. The first of these, the anterior olfactory nucleus pars principalis (AONpP), is a simple, two layered cortex with an outer plexiform and inner cell zone (Layers 1 and 2, respectively). Five sets of studies examined age‐related changes in the AONpP. First, immunocytochemistry for glutamatergic (VGlut1 and VGlut2) and GABAergic (VGAT) synapses demonstrated that overall synaptic patterns remained uniform with age. The second set quantified synaptic development with electron microscopy and found different developmental patterns between Layers 1 and 2. As many of the interhemispheric connections in the olfactory system arise from AONpP, the third set examined the development of crossed projections using anterograde tracers and electron microscopy to explore the maturation of this pathway. A fourth study examined ontogenetic changes in immunostaining for the proteoglycans aggrecan and brevican, markers of mesh‐like extracellular structures known as perineuronal nets whose maturation is associated with the end of early critical periods of synaptogenesis. A final study found no age‐related changes in the density of vasculature in the peduncle from P5 to P30. This work is among the first to examine early postnatal changes in this initial cortical region of the olfactory system.

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The Extracellular Environment of the CNS: Influence on Plasticity, Sprouting, and Axonal Regeneration after Spinal Cord Injury

Cited by 72 publications

References 197 publications

<p>Magnetic Field Promotes Migration of Schwann Cells with Chondroitinase ABC (ChABC)-Loaded Superparamagnetic Nanoparticles Across Astrocyte Boundary in vitro</p>

<p>Magnetic Field Promotes Migration of Schwann Cells with Chondroitinase ABC (ChABC)-Loaded Superparamagnetic Nanoparticles Across Astrocyte Boundary in vitro</p>

Dissecting the Dual Role of the Glial Scar and Scar-Forming Astrocytes in Spinal Cord Injury

The mouse olfactory peduncle 4: Development of synapses, perineuronal nets, and capillaries

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