Transplantation of rat schwann cells grown in tissue culture into the mouse spinal cord

Injections of lysolecithin were used to produce acute focal demyelination in the dorsal columns of 2 strains of mice, the myelin mutant quaking and the normal C57BL/6J. A small collection of rat Schwann cells grown in tissue culture was transplanted with their collagen substrate into this demyelinated area. The host mice were immune-suppressed to prevent graft rejection. Evidence of remyelination by Schwann cells was seen in the dorsal columns from 2–18 weeks after implantation. Proof that these Schwann cells were foreign to the host was derived from their rejection after the recipient mice were allowed to recover immunological competence by discontinuation of the immune suppression and by transferring immune cells sensitized against the donor tissue. It was concluded that Schwann cells grown in vitro retain their potential to produce myelin when returned to an in vivo situation and can myelinate central axons of a xenogenic host.     

SCHWANN CELL MULTIPLICATION IN TREMBLER MICE

Peripheral nerves of the mutant mouse Trembler are characterized by a severe myelin deficit and an increased number of Schwann cells. On the basis of radioautographic and quantitative morphologic investigations, the present study documents: i an abnormal persistence of post-natal Schwann cell proliferation in Trembler mouse nerves which, in unaffected animals, are composed of myelinated fibres; ii normal morphology, numbers and proliferation of Schwann cells in the unmyelinated (Remak) fibres of Trembler mice; and iii replication of the increased rate of Schwann cell multiplication as well as the myelin deficit, when segments of Trembler sciatic nerves are transplanted into the sciatic nerves of normal mice. Thus, the continued proliferation of Trembler Schwann cells must be related to the primary inability of these cells to produce and maintain a normal myelin sheath; axonal or general systemic abnormalities do not appear to play a major role in the pathogenesis of these disorders in the Trembler mouse.     

Pure axonal neuropathy: nerve xenografts and clinicopathological study of a family with peripheral neuropathy, hereditary ataxia, focal necrotizing encephalopathy, and spongy degeneration of brain

Three family members had the unusual combination of severe peripheral neuropathy, atypical hereditary ataxia, spongy degeneration of cerbral hemispheres, and cerebellar and brainstem foci of necrotizing encephalopathy, proved pathologically in one autopsied case. A sural nerve from a patient, devoid of myelinated fibers, was transplanted into thymectomized, lethally irradiated, and bone marrow reconstituted adult mice. A normal number of myelinated fibers was present in the grafts eleven weeks later. Eighteen weeks after grafting, mice were reconstituted with syngeneic thymus to return immunocompetence. Schwann cells in the graft were rejected and axons became totally denuded of myelin after thymus reconstitution. The peripheral neuropathy is thus due to axonal disease since human Schwann cells were capable of normally myelinating regenerating mouse axons. A puzzling feature after rejection was the absence of myelin debris containing macrophages in the grafts. It is suggested that part of the rejection process in this model is mediated by antibody rather than by cellular mechanisms.     

Transplanted Schwann cells, not olfactory ensheathing cells, myelinate optic nerve fibres

In a previous study we found that olfactory ensheathing cells transplanted into complete retrobulbar transections of the rat optic nerve mediated regeneration of severed retinal ganglion cell axons through the graft region. Although the regenerating axons were ensheathed by the transplanted cells, none of the regenerating axons became myelinated by either central or peripheral type myelin. In the present study we used the same operative procedure but transplanted Schwann cells instead of olfactory ensheathing cells. As with the olfactory ensheathing cell transplants the Schwann cells transplants also induced regeneration of the severed retinal ganglion cell axons into the graft region. In contrast to the situation with the olfactory ensheathing cell transplants, however, a considerable number of the regenerating axons became myelinated by peripheral type myelin produced by the transplanted Schwann cells. This observation identifies a further distinction between these two cell types which are phenotypically similar in many ways, but which have been shown to have major functional differences with regard to regeneration in spinal cord lesions.     

Repair of a myelin lesion by Schwann cells transplanted in the adult mouse spinal cord

In multiple sclerosis and experimental demyelination, oligodendrocytes and Schwann cells are able to repair myelin lesions of the central nervous system. However, spontaneous myelin repair is often insufficient. Several approaches to enhance remyelination have been considered and transplantation of myelin-forming cells has been proposed as one of them. In this paper, we present results which confirm the ability of transplanted Schwann cells to remyelinate an induced lesion of the spinal cord. Schwann cells were either purified Schwann cells isolated from 1–day-old rat sciatic nerves, or immortalized Schwann cells (MSC80) arising from a purified culture of 7-day-old mouse sciatic nerves. They were transplanted into or at a distance from a lysolecithin-induced lesion of the Shiverer spinal cord. Labelling of the Schwann cells with the fluorochrome Hoechst 33342 enabled us to trace them after transplantation in their host and evaluate their ability to reach and to repair the demyelinated lesion. Using the Hoechst-Shiverer model, we show that when transplanted in the lesion, cultured Schwann cells, even immortalized, are able to remyelinate such a lesion efficiently. In addition, when transplanted at a distance from the lesion, they are able to reach and repair the lesion in time frames which allow them to complete actively with host oligodendrocytes.     

Myelin phagocytosis by peritoneal macrophages in organ cultures of mouse peripheral nerve. A new model for studying myelin phagocytosis in vitro

Organ cultures of degenerating nerve fascicles were exposed to cultured macrophages obtained by peritoneal lavage. Invasion of the nerve fascicle by phagocytes was shown by prelabeling with carbon and with electron microscopy. There was massive active phagocytosis of degenerating myelin sheaths. The invading phagocytic cell population was identified as Fc receptor-positive, Mac-1-positive macrophages by immunocytochemistry. The Schwann cell population persisted without significant myelin phagocytosis. The vitality of the Schwann cell population was shown by subsequent reimplantation of the organ cultures into host animals. The reimplants had retained their ability to remyelinate regenerating axon sprouts. These observations were made in cultures exposed to cytostatic agents. If cytostatic agents were omitted, there was proliferation of endogenous phagocytes in the nerve fascicles without added peritoneal cells. These endogenous phagocytes were identified as proliferating resident monocytes and were positive for the Fc receptor and Mac-1 markers. This model allows studies on how monocytes recognize and digest degenerating myelin apart from surviving Schwann cells.     

The fate of Schwann cells transplanted in the brain during development.

Purified rat Schwann cells labeled with Hoechst 33342 fluorescent fluorochrome were transplanted into the brain of the newborn shiverer mouse. The grafted cells survived and were able to migrate through the host parenchyma. However, Schwann cell migration was restricted to the grafted hemisphere and to structures adjacent to the graft. With time, Hoechst labeled cells, present at the site of implantation or dispersed in the host parenchyma, decreased progressively in number. Instead, they concentrated along the blood vessels, meninges and ventricles. Despite the presence of Hoechst labeled Schwann cells in white matter tracks during the process of central myelination, Schwann cell myelination could not be evidenced by immunodetection of the peripheral myelin protein or by ultrastructural observation of the typical Schwann cell basement membrane surrounding peripheral myelin. A series of additional transplantations involving Schwann cells of mouse or rat origin, grafted either as cell suspensions or as nerve fragments, demonstrated that transplanted Schwann cells formed myelin around developing host axons only when included in a nerve fragment. Immunodetection of GFAP in astrocytes and type IV collagen in basement membranes as well as electron microscopy showed that reactive astrocytes invaded the grafted area after the first week of transplantation and sometimes formed basement membranes isolating partially the graft from the host parenchyma. During host myelination, astrocytes, which were present in most white matter structures, surrounded grafted cells. Occasionally, they enclosed Schwann cells in basement membranes or encircled host axons. Later, reactive astrocytes were associated with Schwann cells restricted to blood vessel and ventricular walls, and meninges. Our results suggest that in the presence of competitive developing oligodendrocytes, astrocytes are able to limit migration and prevent myelination of Schwann cells transplanted in the newborn shiverer brain. In addition, astrocytes seem to be able to expel the grafted cells and finally exclude them from the host parenchyma.     

Behavior of Schwann cells from Trembler mouse unmyelinated fibers transplanted into myelinated nerves

In the peripheral nerves of Trembler mice, Schwann cells produce little or no myelin and continue to multiply beyond the normal neonatal period. However, in the unmyelinated (Remak) fibers of these mutants, Schwann cell morphology and multiplication are normal. To determine if such phenotypically normal Schwann cells would show the Trembler abnormalities when challenged to form myelin in nerve grafts, an unmyelinated nerve, the cervical sympathetic trunk, was transplanted into the richly myelinated sural nerve in a series of normal host animals. Two months after transplantation, regenerated grafts, composed of normal host axons and Trembler cervical sympathetic trunk Schwann cells, showed the characteristic Trembler abnormalities of myelination and multiplication whereas Schwann cells from normal cervical sympathetic trunks myelinated the host axons normally. Thus, the Trembler mutation appears to affect Schwann cell differentiation at a specific phase, the formation of myelin. This primary expression of the Schwann cell abnormality initiates a cycle of secondary effects that include demyelination, Schwann cell multiplication, and attempted remyelination.     

Involvement of intercellular adhesion molecule-1 in myelin recognition by macrophages

Macrophages play a crucial role in myelin removal during nerve degeneration and demyelination. The exact mechanisms of myelin recognition and uptake are not yet defined. The present experiments aimed at defining the role of intercellular adhesion molecule-1 (ICAM-1) in this process. Myelin phagocytosis was studied in an established in vitro model of cultured macrophages and sciatic nerves. Cocultures of wild-type C57BL macrophages with sciatic nerves resulted in a massive invasion of the nerves by macrophages with subsequent removal of myelin. In contrast, when macrophages of ICAM-1-deficient animals were cocultured with wild-type nerves, myelin phagocytosis was significantly retarded, whereas cell invasion was completely undisturbed. These data indicate that the ICAM-1 molecule acts as a costimulatory signal in myelin recognition and uptake by macrophages. Received: 3 January 2000 / Revised, accepted: 7 February 2000     

Changes of myelin proteins during Wallerian degeneration in situ and in millipore diffusion chambers preventing active phagocytosis

Changes of myelin proteins in mouse sciatic nerves were studied comparing nerves degenerating in situ with nerves enclosed in millipore diffusion chambers which eliminate invasion of non-resident cells. Nerves kept in chambers showed nearly complete preservation of myelin sheaths with a very slow degradation of myelin proteins. Nerves degenerating in situ showed rapid myelin phagocytosis by macrophages with almost complete disappearance of myelin proteins after 28 days. These data elucidate the role of macrophages for removal of myelin proteins.     

Myelin phagocytosis in Wallerian degeneration of peripheral nerves depends on silica-sensitive,bg/bg-negative and Fc-positive monocytes

Previous experiments with nerves enclosed in millipore diffusion chambers had shown that myelin degradation during Wallerian degeneration depends on invasion by non-resident cells. The present study was aimed at a more precise identification of the invading cell population. Monoclonal antibody studies of degenerating nerves showed many cells with the Fc marker; cells having the Lyt-1, Lyt-2, Ia or Mac-1 markers were sparse or absent. Nerves transplanted into mice of the Chediak-Higashi bg/bg strain were invaded by cells lacking the bg/bg marker (giant lysosomes), while cotransplanted muscle tissue was invaded by cells with the bg/bg marker. Blocking monocytes with silica reduced both cell invasion and myelin degradation in degenerating nerves. These observations show that Wallerian degeneration of peripheral nerve fibers involves a subset of monocytes which are silica-sensitive and have Fc receptors but no bg/bg giant lysosomes.     

Multipotentiality of Schwann cells in cross-anastomosed and grafted myelinated and unmyelinated nerves: quantitative microscopy and radioautography.

Cross-anastomoses and autogenous grafts of unmyelinated and myelinated nerves were examined by electron microscopy and radioautography to determine if Schwann cells are multipotential with regard to their capacity to produce myelin or to assume the configuration seen in unmyelinated fibres. Two groups of adult white mice were studied. (A) In one group, the myelinated phrenic nerve and the unmyelinated cervical sympathetic trunk (CST) were cross-anastomosed in the neck. From 2 to 6 months after anastomosis, previously unmyelinated distal stumps contained many myelinated fibres while phrenic nerves joined to proximal CSTs became largely unmyelinated. Radioautography of distal stumps indicated that proliferation of Schwann cells occurred mainly in the first few days after anastomosis but was also present to a similar extent in isolated stumps. (B) In other mice, CSTs were grafted to the myelinated sural nerves in the leg. One month later, the unmyelinated CSTs became myelinated and there was no radioautographic indication of Schwann cell migration from the sural nerve stump to the CST grafts. Thus, Schwann cell proliferation in distal stumps is an early local response independent of axonal influence. At later stages, axons from the proximal stumps cause indigenous Schwann cells in distal stumps from the previously unmyelinated nerves to produce myelin while Schwann cells from the previously unmyelinated nerves to produce myelin while Schwann cells from the previously myelinated nerves become associated with unmyelinated fibres. Consequently, the regenerated distal nerve resembled the proximal stump. It is suggested that this change is possible because Schwann cells which divide after nerve injury reacquire the developmental multipotentiality which permits them to respond to aoxonal influences.     

Myelin formation by Schwann cells in the absence of beta4 integrin.

The interaction of the Schwann cell with its basal lamina has been hypothesized to be an important prerequisite for the formation of a myelin sheath in the peripheral nervous system. One possible player in this interaction is beta4 integrin; it is up-regulated during myelin formation and, in association with alpha6 integrin, can interact with particular components of the Schwann cell basal lamina. In order to characterize the functional roles of beta4 integrin during myelination, we investigated myelination in the absence of beta4 integrin, i.e., in peripheral nerve tissue from beta4 integrin-deficient mice. Because the mutants die within several hours after birth, we cultured dorsal root ganglia from neonatal mutants under conditions that promote myelination, quantified the myelin segments by immunofluorescence, and investigated the ultrastructure of the cultured myelin sheaths. In another approach, we quantified the few myelin sheaths that are detectable in femoral nerves of newborn animals. Based on both approaches, we conclude that myelination by Schwann cells can occur in the absence of beta4 integrin demonstrating that this Schwann cell component is dispensable for myelin formation in peripheral nerves.     

p38 MAPK activation promotes denervated Schwann cell phenotype and functions as a negative regulator of Schwann cell differentiation and myelination

Physical damage to the peripheral nerves triggers Schwann cell injury response in the distal nerves in an event termed Wallerian degeneration: the Schwann cells degrade their myelin sheaths and dedifferentiate, reverting to a phenotype that supports axon regeneration and nerve repair. The molecular mechanisms regulating Schwann cell plasticity in the PNS remain to be elucidated. Using both in vivo and in vitro models for peripheral nerve injury, here we show that inhibition of p38 mitogen-activated protein kinase (MAPK) activity in mice blocks Schwann cell demyelination and dedifferentiation following nerve injury, suggesting that the kinase mediates the injury signal that triggers distal Schwann cell injury response. In myelinating cocultures, p38 MAPK also mediates myelin breakdown induced by Schwann cell growth factors, such as neuregulin and FGF-2. Furthermore, ectopic activation of p38 MAPK is sufficient to induce myelin breakdown and drives differentiated Schwann cells to acquire phenotypic features of immature Schwann cells. We also show that p38 MAPK concomitantly functions as a negative regulator of Schwann cell differentiation: enforced p38 MAPK activation blocks cAMP-induced expression of Krox 20 and myelin proteins, but induces expression of c-Jun. As expected of its role as a negative signal for myelination, inhibition of p38 MAPK in cocultures promotes myelin formation by increasing the number as well as the length of individual myelin segments. Altogether, our data identify p38 MAPK as an important regulator of Schwann cell plasticity and differentiation.     

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.     

Radiation-induced Reductions in Macrophage Recruitment Have Only Slight Effects on Myelin Degeneration in Sectioned Peripheral Nerves of Mice

Macrophage recruitment into the distal nerve stump of the cut or crushed sciatic or saphenous nerves of C57BL/6J mice was reduced by prior whole body irradiation. This procedure was successful in keeping the numbers of cells stained with the mouse macrophage-specific antibody F4/80 to the levels found in unsectioned nerves. Quantitative image analysis of immunostained sections showed that the rate of loss of myelin basic protein was identical in nerves from irradiated and unirradiated mice up to 5 days but thereafter was slower in macrophage-deprived nerves. Similar analysis of semithin sections stained with toluidine blue detected more undegenerated myelin in the nerves from irradiated mice 10 days after operation. Quantitative counts made from electron micrographs of the sectioned nerves at 7 days also showed slightly less extensive myelin breakdown in the nerves from irradiated mice. Complete removal of myelin from some Schwann cells can occur without macrophages, but macrophages accelerate the removal of myelin in the later stages of Wallerian degeneration. It is concluded that there are two phases to the breakdown of myelin in peripheral nerves undergoing Wallerian degeneration: an initial stage entirely dependent on the activity of Schwann cells and a later stage dependent on both Schwann cells and the presence of macrophages.     

Isolation, purification and expansion of myelination-competent, neonatal mouse Schwann cells

Most studies of peripheral nerve myelination using culture models are performed with dorsal root ganglion neurons and Schwann cells pre-purified from the rat. The potential of this model is severely compromised by the lack of rat myelin mutants and the published protocols work poorly with mouse cells, for which numerous myelin mutants are available. This is partly due to difficulties in obtaining sufficient quantities of myelination-competent mouse Schwann cells. Here, we describe the isolation, purification and expansion of wild-type, myelination-competent Schwann cells from the sciatic nerves of 4-day-old mouse pups. The method consistently yields 1.9-3.3 x 10(6) of approximately 95% pure Schwann cells from the sciatic nerves of 12-15 4-day-old mouse pups, within 14-20 days. The Schwann cell proliferation rate ranges from 2.7- to 4.30-fold growth/week. Proliferation ceases within 4 weeks, when the cells become quiescent. Growth is reinduced by the presence of neurons; neuregulin is not sufficient for this effect. The Schwann cells isolated by this protocol are able to form compact myelin in culture, as judged by the segregated expression patterns of early (myelin-associated glycoprotein) and late (myelin basic protein) myelination markers in a three-dimensional neuron/Schwann cell coculture model. The Schwann cell batch yields are sufficient to perform 100-150 individual myelinating coculture assays. Employing mixed phenotype/genotype mouse neuron/Schwann cell cocultures, it will be possible to analyse the cell specificity of a mutation, and the cumulative effects of different mutations, without having to cross-breed the animals.     

去细胞同种异体神经支架种植许旺细胞的体外培养

摘要 背景：前期的研究中分别探讨了使用复合酶消化法及差速贴壁法对许旺细胞培养的影响以及聚氧乙烯辛烷基酚(Triton X-100)制备同种异体神经支架。 目的：通过化学萃取法制备同种异体神经支架,并将培养的许旺细胞与支架进行体外结合培养。 方法：取Wistar大鼠双侧坐骨神经,运用30 g/L三硝基甲苯和40 g/L脱氧胆酸钠分别萃取1,2和3次,在萃取神经和未萃取神经的中段取材,行苏木精-伊红染色,S-100及Laminin免疫组织化学染色及透射电镜检测。取SD胎鼠坐骨神经及臂从神经,使用复合酶消化,差速贴壁及Arab-c抑制成纤维细胞生长的培养方法获得大量高纯度的许旺细胞。再把许旺细胞注入同种异体神经支架内,并行透射电镜及扫描电镜观察。 结果与结论：用三硝基甲苯和脱氧胆酸钠萃取后,坐骨神经内细胞和髓鞘被清除,神经基底膜被保留。电镜下可见萃取后的神经由空的神经基底膜管和管之间的胶原纤维构成。萃取次数增加后,神经内残留的S-100蛋白显著减少,但反复萃取后支架结构受破坏。去细胞同种异体神经支架适合许旺细胞体外生长,并有迁移排成行的特性。结果提示,用三硝基甲苯和脱氧胆酸钠萃取2次可去除细胞而保留神经基底膜管,是制备具有仿生结构神经支架的理想方法。神经支架种植许旺细胞后可能成为一种理想的神经缺损修复材料。     

NAKED AXON BUNDLES ENCLOSED BY SINGLE SEGMENTS OF MYELIN SHEATHS IN THE NERVES OF NON-DYSTROPHIC C57BL-ob/+ MICE

Bundles of axons enclosed by a single myelin sheath were found in the peripheral nerves of heterozygous obese C57BL-ob/+mice. Serial sections showed them to consist of two to forty naked axons encompassed by a common cuff of myelin formed by a single Schwann cell, with adjoining non-myelinated Schwann cells protruding from either side into the cuff. These structures are similar to those found in dystrophic mice, but there were no signs of dystrophy in the obese mice. It is suggested that the axon bundles result from a disturbance of early myelination, presumably of the phase of Schwann cell proliferation or of the communication between Schwann cells and axons.     

Interactions between Schwann cells and macrophages in injury and inherited demyelinating disease

In this article we first discuss the factors that regulate macrophage recruitment, activation, and myelin phagocytosis during Wallerian degeneration and some of the factors involved in the termination of inflammation at the end of the period of Wallerian degeneration after peripheral nerve injuries. In particular, we deal with the early events that trigger chemokine and cytokine expression; the role of phospholipase A(2) in initiating the breakdown of compact myelin, and chemokine, cytokine expression; and the role of MCP-1, MIP-1alpha, and IL-1beta in macrophage recruitment and myelin phagocytosis. We also discuss how inflammation may be switched off and the recently identified role of the Nogo receptor on activated macrophages in the clearance of these cells from the injured nerve. In the second half of the article we focus on the role of certain Schwann cell borne cytokines and chemokines, such as M-CSF and MCP-1 as well as intracellular signaling that regulate their expression in animal models of inherited demyelinating disease. Additionally, we present the preservation of sensory nerves fibers from macrophage attack in these animal models as a challenging paradigm for the development of putative treatment approaches. Finally, we also discuss the similarities and differences in these Schwann cell-macrophage responses in injury-induced Wallerian degeneration and inherited demyelinating diseases. Knowledge of the molecular mechanisms underlying Schwann cell-macrophage interaction under pathological conditions is an important prerequisite to develop effective treatment strategies for various peripheral nerve disorders.