Cells transplanted onto the surface of the glial scar reveal hidden potential for functional neural regeneration

Sekiya, Takao; Holley, Matthew C.; Hashido, Kento; Ono, Kazuya; Shimomura, Koichiro; Horie, Rie; Hamaguchi, Kozo; Yoshida, Atsuhiro; Sakamoto, Tatsunori; Ito, Juichi

doi:10.1073/pnas.1501835112

Cited by 25 publications

(56 citation statements)

References 59 publications

(76 reference statements)

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“…A number of reports supporting the role of scar tissue as a barrier have shown that its removal facilitates neural restoration [16–18]. However, recent studies have also suggested that scar tissue is not necessarily an obstacle for regeneration and may even be necessary for neural restoration [19]. In the present work, we demonstrated that INDP alone promotes motor recovery, although this effect is augmented with glial scar removal.…”

Section: Discussionsupporting

confidence: 57%

Immunization with neural derived peptides plus scar removal induces a permissive microenvironment, and improves locomotor recovery after chronic spinal cord injury

et al. 2017

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BackgroundImmunization with neural derived peptides (INDP) as well as scar removal—separately—have shown to induce morphological and functional improvement after spinal cord injury (SCI). In the present study, we compared the effect of INDP alone versus INDP with scar removal on motor recovery, regeneration-associated and cytokine gene expression, and axonal regeneration after chronic SCI. Scar removal was conducted through a single incision with a double-bladed scalpel along the stump, and scar renewal was halted by adding α,α′-dipyridyl.ResultsDuring the chronic injury stage, two experiments were undertaken. The first experiment was aimed at testing the therapeutic effect of INDP combined with scar removal. Sixty days after therapeutic intervention, the expression of genes encoding for TNFα, IFNγ, IL4, TGFβ, BDNF, IGF1, and GAP43 was evaluated at the site of injury. Tyrosine hydroxylase and 5-hydroxytryptamine positive fibers were also studied. Locomotor evaluations showed a significant recovery in the group treated with scar removal + INDP. Moreover; this group presented a significant increase in IL4, TGFβ, BDNF, IGF1, and GAP43 expression, but a decrease of TNFα and IFNγ. Also, the spinal cord of animals receiving both treatments presented a significant increase of serotonergic and catecholaminergic fibers as compared to other the groups. The second experiment compared the results of the combined approach versus INDP alone. Rats receiving INDP likewise showed improved motor recovery, although on a lesser scale than those who received the combined treatment. An increase in inflammation and regeneration-associated gene expression, as well as in the percentage of serotonergic and catecholaminergic fibers was observed in INDP-treated rats to a lesser degree than those in the combined therapy group.ConclusionsThese findings suggest that INDP, both alone and in combination with scar removal, could modify the non-permissive microenvironment prevailing at the chronic phase of SCI, providing the opportunity of improving motor recovery.

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Section: Discussionsupporting

confidence: 57%

Immunization with neural derived peptides plus scar removal induces a permissive microenvironment, and improves locomotor recovery after chronic spinal cord injury

et al. 2017

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“…Whereas glial scars are neuroprotective (against severe inflammation) they also inhibit axon regrowth (Frisén et al, ; Liu et al, ; Rowland, Hawryluk, Kwon, & Fehlings, ). Despite numerous efforts to reduce the negative impact of the glial scar, improvements to functional recovery remain limited (Sekiya et al, ; Shen, Wang, & Gu, ; Zhao & Fawcett, ).…”

Section: Introductionmentioning

confidence: 99%

Neural stem/progenitor cells are activated during tail regeneration in the leopard gecko (Eublepharis macularius)

Gilbert

Vickaryous

2017

J of Comparative Neurology

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As for many lizards, the leopard gecko (Eublepharis macularius) can self-detach its tail to avoid predation and then regenerate a replacement. The replacement tail includes a regenerated spinal cord with a simple morphology: an ependymal layer surrounded by nerve tracts. We hypothesized that cells within the ependymal layer of the original spinal cord include populations of neural stem/progenitor cells (NSPCs) that contribute to the regenerated spinal cord. Prior to tail loss, we performed a bromodeoxyuridine pulse-chase experiment and found that a subset of ependymal layer cells (ELCs) were label-retaining after a 140-day chase period. Next, we conducted a detailed spatiotemporal characterization of these cells before, during, and after tail regeneration. Our findings show that SOX2, a hallmark protein of NSPCs, is constitutively expressed by virtually all ELCs before, during, and after regeneration. We also found that during regeneration, ELCs express an expanded panel of NSPC and lineage-restricted progenitor cell markers, including MSI-1, SOX9, and TUJ1. Using electron microscopy, we determined that multiciliated, uniciliated, and biciliated cells are present, although the latter was only observed in regenerated spinal cords. Our results demonstrate that cells within the ependymal layer of the original, regenerating and fully regenerate spinal cord represent a heterogeneous population. These include radial glia comparable to Type E and Type B cells, and a neuronal-like population of cerebrospinal fluid-contacting cells. We propose that spinal cord regeneration in geckos represents a truncation of the restorative trajectory observed in some urodeles and teleosts, resulting in the formation of a structurally distinct replacement.

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“…Given the abundance of data showing that reactive astrocytes can, indeed, form a barrier to highly invasive glioblastoma as well as oligodendrocyte progenitor cells (Lau et al, 2012;Keough et al, 2016), macrophages (Wanner et al, 2013), neural precursor cells (Karimi-Abdolrezaee et al, 2010), auditory neuroblasts (Sekiya et al, 2015), fibroblasts (Wanner et al, 2008), Schwann cells (Fouad et al, 2005;Kanno et al, 2014) and regenerating olfactory sensory and other axons (Anders and Hurlock, 1996;Silver and Miller, 2004;Zhang et al, 2006;Schachtrup et al, 2010;Cregg et al, 2014), it seems likely that they could at least participate in the formation of an additional constraint to severed axons after spinal cord injury as they encircle the lesion core.…”

mentioning

confidence: 99%

“…In the special case of a very narrow lesion when core cells are lacking and there is less need to "corral" them (Wanner et al, 2013), scar forming astrocytes may be made permissive in response to the presence of an abundance of robustly growing axons . It was also made clear beginning long ago that reactive astrocytes can be a substrate for axonal outgrowth under the right circumstances (Reier, 1979;Silver and Ogawa, 1983;Smith et al, 1986;Hoke et al, 1994;McKeon et al, 1995;East et al, 2010;Sekiya et al, 2015) and, therefore, it should have been no surprise that they could serve as a permissive substrate into the lesion (which is clinically irrelevant) when axons were highly stimulated and especially before the glia became hyper dense. Thus, in the fashion of a drawbridge, reactive scar astrocytes can be either a barrier or, on occasion, a roadway depending on the conditions present normally or created experimentally inside or outside of the lesion penumbra.…”

mentioning

confidence: 99%

The glial scar is more than just astrocytes

Silver

2016

Experimental Neurology

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Cells transplanted onto the surface of the glial scar reveal hidden potential for functional neural regeneration

Cited by 25 publications

References 59 publications

Immunization with neural derived peptides plus scar removal induces a permissive microenvironment, and improves locomotor recovery after chronic spinal cord injury

Immunization with neural derived peptides plus scar removal induces a permissive microenvironment, and improves locomotor recovery after chronic spinal cord injury

Neural stem/progenitor cells are activated during tail regeneration in the leopard gecko (Eublepharis macularius)

The glial scar is more than just astrocytes

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