Treatment modality affects allograft-derived Schwann cell phenotype and myelinating capacity

We used peripheral nerve allografts, already employed clinically to reconstruct devastating peripheral nerve injuries, to study Schwann cell (SC) plasticity in adult mice. By modulating the allograft treatment modality we were able to study migratory, denervated, rejecting, and reinnervated phenotypes in transgenic mice whose SCs expressed GFP under regulatory elements of either the S100b (S100-GFP) or nestin (Nestin-GFP) promoters. Well-differentiated SCs strongly expressed S100-GFP, while Nestin-GFP expression was stimulated by denervation, and in some cases, axons were constitutively labeled with CFP to enable in vivo imaging. Serial imaging of these mice demonstrated that untreated allografts were rejected within 20 days. Cold preserved (CP) allografts required an initial phase of SC migration that preceded axonal regeneration thus delaying myelination and maturation of the SC phenotype. Mice immunosuppressed with FK506 demonstrated mild subacute rejection, but the most robust regeneration of myelinated and unmyelinated axons and motor endplate reinnervation. While characterized by fewer regenerating axons, mice treated with the co-stimulatory blockade (CSB) agents anti-CD40L mAb and CTLAIg-4 demonstrated virtually no graft rejection during the 28 day experiment, and had significant increases in myelination, connexin-32 expression, and Akt phosphorylation compared with any other group. These results indicate that even with SC rejection, nerve regeneration can occur to some degree, particularly with FK506 treatment. However, we found that co-stimulatory blockade facilitate optimal myelin formation and maturation of SCs as indicated by protein expression of myelin basic protein (MBP), connexin-32 and phospho-Akt.     

A double-transgenic mouse used to track migrating Schwann cells and regenerating axons following engraftment of injured nerves

We propose that double-transgenic thy1-CFP(23)/S100-GFP mice whose Schwann cells constitutively express green fluorescent protein (GFP) and axons express cyan fluorescent protein (CFP) can be used to serially evaluate the temporal relationship between nerve regeneration and Schwann cell migration through acellular nerve grafts. Thy1-CFP(23)/S100-GFP and S100-GFP mice received non-fluorescing cold preserved nerve allografts from immunologically disparate donors. In vivo fluorescent imaging of these grafts was then performed at multiple points. The transected sciatic nerve was reconstructed with a 1-cm nerve allograft harvested from a Balb-C mouse and acellularized via 7 weeks of cold preservation prior to transplantation. The presence of regenerated axons and migrating Schwann cells was confirmed with confocal and electron microscopy on fixed tissue. Schwann cells migrated into the acellular graft (163+/-15 intensity units) from both proximal and distal stumps, and bridged the whole graft within 10 days (388+/-107 intensity units in the central 4-6 mm segment). Nerve regeneration lagged behind Schwann cell migration with 5 or 6 axons imaged traversing the proximal 4 mm of the graft under confocal microcopy within 10 days, and up to 21 labeled axons crossing the distal coaptation site by 15 days. Corroborative electron and light microscopy 5 mm into the graft demonstrated relatively narrow diameter myelinated (431+/-31) and unmyelinated (64+/-9) axons by 28 but not 10 days. Live imaging of the double-transgenic thy1-CFP(23)/S100-GFP murine line enabled serial assessment of Schwann cell-axonal relationships in traumatic nerve injuries reconstructed with acellular nerve allografts.     

Labeled Schwann cell transplantation: cell loss, host Schwann cell replacement, and strategies to enhance survival

Although transplanted Schwann cells (SCs) can promote axon regeneration and remyelination and improve recovery in models of spinal cord injury, little is known about their survival and how they interact with host tissue. Using labeled SCs from transgenic rats expressing human placental alkaline phosphatase (PLAP), SC survival in a spinal cord contusion lesion was assessed. Few PLAP SCs survived at 2 weeks after acute transplantation. They died early due to necrosis and apoptosis. Delaying transplantation until 7 days after injury improved survival. A second wave of cell death occurred after surviving cells had integrated into the spinal cord. Survival of PLAP SCs was enhanced by immunosuppression with cyclosporin; delayed transplantation in conjunction with immunosuppression resulted in the best survival. In all cases, transplantation of SCs resulted in extensive infiltration of endogenous p75+ cells into the injury site, suggesting that endogenous SCs may play an important role in the repair observed after SC transplantation.     

Fibroblast‐derived tenascin‐C promotes Schwann cell migration through β1‐integrin dependent pathway during peripheral nerve regeneration

Peripheral nerve regeneration requires precise coordination and dynamic interaction among various types of cells in the tissue. It remains unclear, however, whether the cellular crosstalk between fibroblasts and Schwann cells (SCs) is related to phenotype modulation of SCs, a critical cellular process after peripheral nerve injury. In this study, microarray analysis revealed that a total of 6,046 genes were differentially expressed in the proximal nerve segment after sciatic nerve transection in rats, and bioinformatics analysis further identified tenascin‐C (TNC), an extracellular matrix (ECM) protein, as a key gene regulator. TNC was abundantly produced by nerve fibroblasts accumulating at the lesion site, rather than by SCs as usually expected. TNC significantly promoted SC migration without effects on SC proliferation in primary culture. In co‐culture of fibroblasts and SCs, inhibition of TNC expression either by siRNA transfection or antibody blockade could suppress SC migration, while TNC‐stimulated SC migration was mediated by TNC binding to β1‐integrin receptor in SCs through activation of Rac1 effectors. The in vivo evidence showed that exogenous TNC protein enhanced SC migration and axonal regrowth. Our results highlight that TNC‐mediated cellular interaction between fibroblasts and SCs may regulate SC migration through β1‐integrin‐dependent pathway during peripheral nerve regeneration. GLIA 2016;64:374–385     

Indefinite survival of peripheral nerve allografts after temporary Cyclosporine A immunosuppression

It is hypothesized that unlike solid organ transplants immunosuppression of peripheral nerve allografts is needed only for the finite time period required for regeneration of proximal host nerve axons through the allograft and subsequent re-establishment of host end-organ connections. The aim of this study was to explore the consequences of temporary and continuous systemic Cyclosporine A (CsA) immunosuppression upon peripheral nerve allograft survival. Buffalo rats received Lewis nerve allografts under CsA immunosuppression (5 mg/kg/day) either continuously for 20 weeks, or for only 10 weeks followed by abrupt withdrawal. At 20 weeks, the nerve segments from both groups were regrafted into na?ve Buffalo or Lewis recipients without further immunosuppression. These grafts were compared with isografts, unimmunosuppressed allografts and allografts immunosuppressed for 10 weeks in situ. By eight weeks following regrafting, the secondary Lewis recipients had rejected the temporarily immunosuppressed allografts and accepted the continuously immunosuppressed allograft, while the secondary Buffalo recipients accepted both the temporarily and continuously immunosuppressed allografts as assessed by histology and morphometry. Functional recovery was earlier in secondary recipient strain animals that received temporarily immunosuppressed allografts in comparison to those that received continuously immunosuppressed allografts. Analysis of secondary recipients of temporarily immunosuppressed allografts demonstrated greater in vitro MLR and LDA reactivity than did those receiving continuously immunosuppressed allografts. These findings support the hypothesis that donor alloantigens are lost or replaced by the recipient after immunosuppression withdrawal. Moreover, the change to recipient antigenicity in the nerve allograft is retarded and incomplete under continuous CsA immunosuppression, resulting in acceptance by both secondary donor and recipient strains upon regraftment.     

Rejection and regeneration through peripheral nerve allografts: immunoperoxidase studies with laminin, S100 protein and neurofilament antisera

The pattern and temporal sequence of histopathological events in a rat nerve allograft model were evaluated. Following grafting and varying survival periods (from 1 to 30 weeks), the host and donor nerve were removed and assessed by light and electron microscopy. Nerve allografts underwent Wallerian degeneration and rejection. Wallerian degeneration was the dominant pathologic process at weeks 1 and 2 after engraftment. Histologic rejection started as an epineurial process at weeks I and 2, became progressively endoneurial and was most prominent at 4 and 6 weeks after engraftment. Rejection was accompanied by evidence of graft Schwann cell and endoneurial tube loss. The rejection process delayed, but did not prevent, nerve regeneration by the host. Regeneration of fine neurofilament-positive axonal sprouts into the proximal portions of the graft was observed as early as week 2. Subsequently, regeneration occurred through the periphery and around the exterior of the rejected nerve allograft fascicle. Regenerating axons were accompanied by S100 protein reactive Schwann cells and newly synthesized laminin-positive endoneurial tubes. Regenerating axons reinnervated the distal host segment at week 8 and increased in number and myelination thereafter. The observations of rejection and regeneration through nerve allograft segments are discussed in reference to previous studies.     

The fate of cryopreserved nerve isografts and allografts in normal and immunosuppressed rats

Donor Schwann cells, perineurial cells, and vasculature are known to survive in grafts of peripheral nerve. In the present study, we attempted to cryopreserve nerve to determine whether these cellular components of nerve would survive after transplantation and support host axonal regeneration through the graft. Four-centimeter lengths of peroneal nerves were removed from inbred adult American Cancer Institute (ACI) rats and placed into vials that contained a cryoprotective mixture of dimethyl sulfoxide and formamide (DF) at room temperature. Each vial with nerves in DF was cooled at a rate of 1–1.5°C/minute down to –40°C at which point the vials were plunged into liquid nitrogen at –196°C. After 5 weeks of storage, the nerves were thawed and DF removed. Some of the cryopreserved-thawed ACI nerves were transplanted as isografts into the legs of ACI rats. Other ACI nerves were used as allografts and inserted into immunologically normal Fischer (FR) rats that were untreated or were immunosuppressed with the drug Cyclosporin A (Cy-A). At surgery, only one end of the nerve graft was joined to the cut proximal end of the peroneal nerve of the host. The cellular elements of ACI grafts were present at 5 weeks in grafts removed from ACI rats and FR rats treated with Cy-A. Non-immunosuppressed FR rats rejected ACI nerves as did FR rats in whom Cy-A was stopped after 5 weeks of treatment. All surviving ACI grafts underwent Wallerian degeneration and consisted of columns of Schwann cells, which in their proximal portion were associated with regenerating host axons. The donor perineurial sheath and vasculature were also present in surviving grafts. ACI isografts only were examined 20 weeks postoperatively. All normal tissue components survived in these older grafts and contained regenerated and myelinated host axons throughout their 4 cm lengths. These results demonstrated that the cellular elements of nerve can be cryopreserved, and after transplantation, survive and function. Because nerves survived after prolonged cryopreservation, it seems feasible to establish a nerve bank from which grafts can be withdrawn to repair gaps in injured nerves. However, cryopreserved nerves used as allografts remain immunogenic and require immunosuppression for their survival. Published in 1993 by Wiley-Liss, Inc.     

Transduced Schwann cells promote axon growth and myelination after spinal cord injury

We sought to directly compare growth and myelination of local and supraspinal axons by implanting into the injured spinal cord Schwann cells (SCs) transduced ex vivo with adenoviral (AdV) or lentiviral (LV) vectors encoding a bifunctional neurotrophin molecule (D15A). D15A mimics actions of both neurotrophin-3 and brain-derived neurotrophic factor. Transduced SCs were injected into the injury center 1 week after a moderate thoracic (T8) adult rat spinal cord contusion. D15A expression and bioactivity in vitro; D15A levels in vivo; and graft volume, SC number, implant axon number and cortico-, reticulo-, raphe-, coerulo-spinal and sensory axon growth were determined for both types of vectors employed to transduce SCs. ELISAs revealed that D15A-secreting SC implants contained significantly higher levels of neurotrophin than non-transduced SC and AdV/GFP and LV/GFP SC controls early after implantation. At 6 weeks post-implantation, D15A-secreting SC grafts exhibited 5-fold increases in graft volume, SC number and myelinated axon counts and a 3-fold increase in myelinated to unmyelinated (ensheathed) axon ratios. The total number of axons within grafts of LV/GFP/D15A SCs was estimated to be over 70,000. Also 5-HT, DbetaH, and CGRP axon length was increased up to 5-fold within D15A grafts. In sum, despite qualitative differences using the two vectors, increased neurotrophin secretion by the implanted D15A SCs led to the presence of a significantly increased number of axons in the contusion site. These results demonstrate the therapeutic potential for utilizing neurotrophin-transduced SCs to repair the injured spinal cord.     

Migration of cells into and out of peripheral nerve isografts in the peripheral and central nervous systems of the adult mouse

Peripheral nerve (PN) isografts provide a favourable environment for axon regeneration after peripheral and central nervous system (CNS) injury, but definitive information on the extent of cellular intermixing between donor and host tissues is lacking. We wished to compare migration patterns in fresh and predegenerate PN grafts, and also compare the extent of cell migration after transplantation to peripheral nervous system (PNS) versus CNS. To discern how host and donor cells interact after PN transplantation, sciatic nerve segments were transplanted from inbred adult mice into PN defects (PN-PN grafts) or into lesioned cerebral cortex of opposite gender siblings. Migrating male cells were identified using a Y-chromosome-specific probe and in situ hybridization methods, and characterized immunohistochemically. The extent of donor and host cellular intermixing was similar in fresh and predegenerate PN-PN isografts. There was substantial intermixing of donor and host cells by 8 days. Many host cells migrating into epineurial regions of grafts were immunopositive for F4/80 (macrophages). The endoneurium of grafted PN was also colonized by host cells; some were F4/80+ but many were immunostained with S-100 (Schwann cell marker). Donor S-100+ Schwann cells rapidly migrated out into proximal and distal host PN and by 12 weeks were found at least 2 mm from the grafts. Endoneurial microvessels in grafts were mostly donor-derived. By comparison, in male PN grafts to female CNS, even after 6 weeks few donor cells had migrated out into surrounding host cortex, despite the observation that almost all grafts contained regenerating axons and were thus attached to host CNS tissue.     

Interaction between Schwann cells and other cells during repair of peripheral nerve injury

Peripheral nerve injury(PNI) is common and, unlike damage to the central nervous system injured nerves can effectively regenerate depending on the location and severity of injury. Peripheral myelinating glia, Schwann cells(SCs), interact with various cells in and around the injury site and are important for debris elimination, repair, and nerve regeneration. Following PNI, Wallerian degeneration of the distal stump is rapidly initiated by degeneration of damaged axons followed by morphologic changes in SCs and the recruitment of circulating macrophages. Interaction with fibroblasts from the injured nerve microenvironment also plays a role in nerve repair. The replication and migration of injury-induced dedifferentiated SCs are also important in repairing the nerve. In particular, SC migration stimulates axonal regeneration and subsequent myelination of regenerated nerve fibers. This mobility increases SC interactions with other cells in the nerve and the exogenous environment, which influence SC behavior post-injury. Following PNI, SCs directly and indirectly interact with other SCs, fibroblasts, and macrophages. In addition, the inter-and intracellular mechanisms that underlie morphological and functional changes in SCs following PNI still require further research to explain known phenomena and less understood cell-specific roles in the repair of the injured peripheral nerve. This review provides a basic assessment of SC function post-PNI, as well as a more comprehensive evaluation of the literature concerning the SC interactions with macrophages and fibroblasts that can influence SC behavior and, ultimately, repair of the injured nerve.     

Differential schwann cell migration in adult and old mice: an in vitro study

The influence of aging on Schwann cell (SC) proliferation, migration and viability was studied in vitro. SCs were cultured in Ham F-10 medium enriched with 20% fetal calf serum (FCS), 40% FCS or collagen I gel plus 20% FCS. The migration of adult mice derived SCs was stimulated with FCS and collagen. With aging, SC migration, multiplication and viability decreased, indicating that ideal culturing conditions should be adjusted.     

Schwann cell involvement in the neurological lesion of the dystonic mutant mouse: A nerve grafting study

Schwann cell function in the dystonic mutant mouse was studied by grafting peripheral nerve from normal into affected littermates of a C57/BL (Fa.) dt dystonic mouse colony and vice versa. In a control experiment, only unaffected animals of the colony were used, and nerve isografts were found to be ultrastructurally indistinguishable from normal nerve autografts. In addition, the isografts showed no features of the lymphocytic inflammatory rejection reaction observed in normal nerve allografts, and there was evidence that donor Schwann cells remained viable and were active in all the isografts examined. When nerve isografts from affected dystonic mutants were implanted into normal littermate nerves, the normal host axons regenerating through the grafted region acquired degenerative changes characteristic of naturally occurring dystonic peripheral nerve. These changes were not seen in the host axons regenerating either outside the dystonic graft regions, or more distally in the host nerve stumps. When normal nerve isografts were implanted into affected dystonic mutant nerves, the dystonic axons regenerated through the normal graft region and became normally myelinated. It is concluded that an underlying Schwann cell defect may be responsible for the abnormalities of the dystonic mouse peripheral neuropathy.     

Extensive cell migration, axon regeneration, and improved function with polysialic acid-modified Schwann cells after spinal cord injury

Schwann cell (SC) implantation after spinal cord injury (SCI) promotes axonal regeneration, remyelination repair, and functional recovery. Reparative efficacy, however, may be limited because of the inability of SCs to migrate outward from the lesion-implant site. Altering SC cell surface properties by overexpressing polysialic acid (PSA) has been shown to promote SC migration. In this study, a SCI contusion model was used to evaluate the migration, supraspinal axon growth support, and functional recovery associated with polysialyltransferase (PST)-overexpressing SCs [PST-green fluorescent protein (GFP) SCs] or controls (GFP SCs). Compared with GFP SCs, which remained confined to the injection site at the injury center, PST-GFP SCs migrated across the lesion:host cord interface for distances of up to 4.4 mm within adjacent host tissue. In addition, with PST-GFP SCs, there was extensive serotonergic and corticospinal axon in-growth within the implants that was limited in the GFP SC controls. The enhanced migration of PST-GFP SCs was accompanied by significant growth of these axons caudal to lesion. Animals receiving PST-GFP SCs exhibited improved functional outcome, both in the open-field and on the gridwalk test, beyond the modest improvements provided by GFP SC controls. This study for the first time demonstrates that a lack of migration by SCs may hinder their reparative benefits and that cell surface overexpression of PSA enhances the ability of implanted SCs to associate with and support the growth of corticospinal axons. These results provide further promise that PSA-modified SCs will be a potent reparative approach for SCI. © 2012 Wiley Periodicals, Inc.     

N-Cadherin inhibits Schwann cell migration on astrocytes.

Astrocytes exclude Schwann cells (SCs) from the central nervous system (CNS) at peripheral nerve entry zones and restrict their migration after transplantation into the CNS. We have modeled the interactions between SCs, astrocytes, and fibroblasts in vitro. Astrocytes and SCs in vitro form separate territories, with sharp boundaries between them. SCs migrate poorly when placed on astrocyte monolayers, but migrate well on various other surfaces such as laminin (LN) and skin fibroblasts. Interactions between individual SCs and astrocytes result in long-lasting adhesive contacts during which the SC is unable to migrate away from the astrocyte. In contrast, SC interactions with fibroblasts are much shorter with less arrest of migration. SCs adhere strongly to astrocytes and other SCs, but less well to substrates that promote migration, such as LN and fibroblasts. SC-astrocyte and SC-SC adhesion is mediated by the calcium-dependent cell adhesion molecule N-cadherin. Inhibition of N-cadherin function by calcium withdrawal, peptides containing the classical cadherin cell adhesion recognition sequence His-Ala-Val, or antibodies directed against this sequence inhibit SC adhesion and increase SC migration on astrocytes. We suggest that N-cadherin-mediated adhesion to astrocytes inhibits the widespread migration of SCs in CNS tissue.     

Axon and Schwann cell partnership during nerve regrowth

Regeneration of peripheral nerve involves an essential contribution by Schwann cells (SCs) in collaboration with regrowing axons. We examined such collaboration between new axons and Schwann cells destined to reform peripheral nerve trucks in a regeneration chamber bridging transected rat sciatic nerves. There was a highly intimate "dance" between axons that followed outgrowing and proliferating SCs. Axons without SCs only grew short distances and almost all axon processes had associated SC processes. When regeneration chambers were infused through an external access port with local mitomycin, a mitosis inhibitor, SC proliferation, migration and subsequent axon regrowth were dramatically reduced. Adding laminin to mitomycin did not reverse this regenerative lag and indicated that SCs provide more than laminin synthesis alone. Laminin infused alone supplemented endogenous laminin and facilitated first SC then axon regrowth. "Wrong way" misdirected axons were associated with misdirected SC processes and were more numerous in bridges exposed to mitomycin, but were fewer in laminin supplemented bridges. Later, by 21 days, there was myelinated axon repopulation of regenerative bridges but those exposed to mitomycin alone at early time points had substantial impairments in axon investment. Reforming peripheral nerve trucks involves a very close and intimate relationship between axons and SCs that must proliferate and migrate, facilitated by laminin.     

The impact of motor and sensory nerve architecture on nerve regeneration

Sensory nerve autografting is the standard of care for injuries resulting in a nerve gap. Recent work demonstrates superior regeneration with motor nerve grafts. Improved regeneration with motor grafting may be a result of the nerve's Schwann cell basal lamina tube size. Motor nerves have larger SC basal lamina tubes, which may allow more nerve fibers to cross a nerve graft repair. Architecture may partially explain the suboptimal clinical results seen with sensory nerve grafting techniques. To define the role of nerve architecture, we evaluated regeneration through acellular motor and sensory nerve grafts. Thirty-six Lewis rats underwent tibial nerve repairs with 5 mm double-cable motor or triple-cable sensory nerve isografts. Grafts were harvested and acellularized in University of Wisconsin solution. Control animals received fresh motor or sensory cable isografts. Nerves were harvested after 4 weeks and histomorphometry was performed. In 6 animals per group from the fresh motor and sensory cable graft groups, weekly walking tracks and wet muscle mass ratios were performed at 7 weeks. Histomorphometry revealed more robust nerve regeneration in both acellular and cellular motor grafts. Sensory groups showed poor regeneration with significantly decreased percent nerve, fiber count, and density (p < 0.05). Walking tracks revealed a trend toward improved functional recovery in the motor group. Gastrocnemius wet muscle mass ratios show a significantly greater muscle mass recovery in the motor group (p < 0.05). Nerve architecture (size of SC basal lamina tubes) plays an important role in nerve regeneration in a mixed nerve gap model.     

Fresh and predegenerate nerve allografts and isografts in trembler mice

In order to investigate whether Schwann cell or myelin was the principal antigen responsible for nerve graft reiection, fresh nerve grafts and those in which myelin had been previously allowed to degenerate (predegenerate grafts) from both isogeneic BALB/c and allogeneic C57/B1 mice were inserted into trembler BALB/c mice. Schwann cells within nerve allografts from C57/B1 mice were rejected, whether or not the grafts contained myelin. Nerve isografts from normal BALB/c animals produced normally myelinated trembler axons within the grafted segments, and across these segments conduction velocity was restored towards the normal value. It is concluded that Schwann cells, not myelin, constitute the principlal antigen within nerve allografts and it is Schwann-cell rejection that limits the sucessful use of nerve allografts.     

GDNF modifies reactive astrogliosis allowing robust axonal regeneration through Schwann cell-seeded guidance channels after spinal cord injury

Reactive astrogliosis impedes axonal regeneration after injuries to the mammalian central nervous system (CNS). Here we report that glial cell line-derived neurotrophic factor (GDNF), combined with transplanted Schwann cells (SCs), effectively reversed the inhibitory properties of astrocytes at graft–host interfaces allowing robust axonal regeneration, concomitant with vigorous migration of host astrocytes into SC-seeded semi-permeable guidance channels implanted into a right-sided spinal cord hemisection at the 10th thoracic (T10) level. Within the graft, migrated host astrocytes were in close association with regenerated axons. Astrocyte processes extended parallel to the axons, implying that the migrated astrocytes were not inhibitory and might have promoted directional growth of regenerated axons. In vitro, GDNF induced migration of SCs and astrocytes toward each other in an astrocyte–SC confrontation assay. GDNF also enhanced migration of astrocytes on a SC monolayer in an inverted coverslip migration assay, suggesting that this effect is mediated by direct cell–cell contact between the two cell types. Morphologically, GDNF administration reduced astrocyte hypertrophy and induced elongated process extension of these cells, similar to what was observed in vivo. Notably, GDNF treatment significantly reduced production of glial fibrillary acidic protein (GFAP) and chondroitin sulfate proteoglycans (CSPGs), two hallmarks of astrogliosis, in both the in vivo and in vitro models. Thus, our study demonstrates a novel role of GDNF in modifying spinal cord injury (SCI)-induced astrogliosis resulting in robust axonal regeneration in adult rats.