SCIP/Oct-6, Krox-20, and desert hedgehog mRNA expression during CNS remyelination by transplanted olfactory ensheathing cells

Olfactory ensheathing cells (OECs), although having a separate developmental origin to Schwann cells, are able to generate myelin sheaths following transplantation into areas of CNS demyelination that are remarkably similar to those made by Schwann cells. The transcriptional control of Schwann cell myelination has been well documented, in particular the role of SCIP/Oct-6 and Krox-20. It is not known, however, whether these transcription factors are also expressed when OECs assume a myelinating phenotype. In this study, we addressed this question by using a transplantation approach to generate myelinating OECs and then examined the expression of SCIP/Oct-6 and Krox-20 mRNA by in situ hybridization using oligonucleotide probes. We also examined the expression of desert hedgehog (Dhh), a Schwann cell-derived signaling molecule that is responsible for regulating the development of the connective tissue elements in peripheral nerve, which bear similarities to the morphologies adopted by nonmyelinating transplanted cells. Our results indicate that both Krox-20 and Dhh mRNA are strongly expressed by transplanted OECs, with SCIP mRNA present at much lower levels. The expression of Krox-20 relative to the expression of P0 mRNA by the transplanted OECs is consistent with its playing a similar role in OEC myelination to that in Schwann cell myelination, while the expression of Dhh suggests a possible mechanism for the diverse morphologies that cells adopt following OEC transplantation into the damaged CNS. Taken together, our results provide further evidence for the close similarity of OECs and Schwann cells and suggest that, despite their separate origins, the manner in which they generate a peripheral-type myelin sheath involves similar regulatory mechanisms.

The effect of immunosuppressive protocols on spontaneous CNS remyelination following toxin-induced demyelination

Glial cell transplantation is a potential therapy for human demyelinating disease, though obtaining large numbers of human myelinating cells for transplantation remains a major stumbling block. Autologous transplantation is currently not possible, since the adult human CNS is not a good source of oligodendrocyte precursors, and long-term immunosuppression of engrafted allogeneic or xenogeneic cells is therefore likely to be necessary. Immunosuppressive drugs may need to be used in situations where more recent, active areas of demyelination are undergoing endogenous remyelination. It is therefore pertinent to establish the extent to which immunosuppressive protocols will suppress spontaneous remyelination. In order to investigate this issue, we created demyelinating lesions in the spinal cord of adult rats and compared the extent of remyelination in animals receiving different immunosuppressive treatments. In animals given only cyclosporin A, there was no difference in the extent of either Schwann cell or oligodendrocyte remyelination of ethidium bromide-induced demyelinating lesions. However, in animals given cyclophosphamide, either alone or in combination with cyclosporin, there was a significant reduction in the extent of oligodendrocyte-mediated remyelination. These results demonstrate that cyclophosphamide is deleterious to oligodendrocyte remyelination and for this reason should be used with caution in patients with demyelinating disease.

SpL201: a conditionally immortalized Schwann cell precursor line that generates myelin

Dramatic progress has been made over recent years toward the elucidation of the mechanisms regulating lineage determination and cell survival in the developing peripheral nervous system. However, our understanding of Schwann cell development is limited. This is partly due to the difficulties in culturing primary Schwann cell precursor cells, the earliest developmental stage of the Schwann cell lineage defined to date. Both the inability to maintain cultured Schwann cell precursor cells in an undifferentiated state and the technical difficulties involved in their isolation have hampered progress. We have conditionally immortalized rat Schwann cell precursor cells using a retrovirally encoded EGFR/neu fusion protein to circumvent these problems and to generate a source of homogeneous cells. The resulting SpL201 cell line expresses p75 and nestin, two proteins expressed by neural crest-derived cells, as well as peripheral myelin protein 22, protein zero, and Oct-6 as markers of the Schwann cell lineage. When cultured in EGF-containing medium, the SpL201 cells proliferate and maintain an undifferentiated, Schwann cell precursor cell-like state. The cell line is dependent on EGF for survival but can differentiate into early Schwann cell-like cells in response to exogenous factors. Like primary rat Schwann cells, SpL201 cells upregulate Oct-6 and myelin gene expression in response to forskolin treatment. Furthermore, the SpL201 cell line can form myelin in the presence of axons in vitro and is capable of extensively remyelinating a CNS white matter lesion in vivo. Thus, this cell line provides a valuable and unique tool to study the Schwann cell lineage, including differentiation from the Schwann cell precursor cell stage through to myelination.

Bridging the divide: spinal cord repair by cellular transplantation--from research laboratory to therapeutic application

Spinal cord injury remains a clinical problem for which new therapeutic options are required. Recent developments in spinal cord injury research have suggested that promotion of axonal regeneration by cellular transplantation may be a feasible future treatment modality and it is possible that small animal clinical patients may be the first to benefit from these new approaches. This article describes the experiments which have generated this optimism and considers the steps that will be required to make the transition from laboratory experiments to clinical application.

Macrophage depletion impairs oligodendrocyte remyelination following lysolecithin-induced demyelination

An association between macrophages and remyelination efficiency has been observed in a variety of different models of CNS demyelination. In order to test whether this association is causal or coincidental, we have examined the effects of macrophage depletion on the rate of remyelination of lysolecithin-induced demyelination in the spinal cord of young adult female rats. Macrophage depletion was achieved by reducing the monocyte contribution to the macrophages within the lesion using the clodronate-liposome technique. This technique not only resulted in a decrease in Ox-42-positive cells in the spleen of treated animals but also in the levels of macrophage scavenger receptor type B mRNA expression within the demyelinating lesion. In animals treated with clodronate-liposomes throughout the remyelination process, there was a significant decrease in the extent of oligodendrocyte remyelination at 3 weeks after lesion induction, but no effect on Schwann cell remyelination. If macrophage depletion was delayed until the second half of the remyelination phase, then there was no effect on the repair outcome, implying that macrophages are required for the early stages of CNS remyelination. The results of this study indicate that the macrophage response is an important component of successful CNS remyelination and that approaches to the treatment of demyelinating disease based on inhibition of the inflammatory response may also impair regenerative events that follow demyelination.

Progressive encephalomyelopathy and cerebellar degeneration in 10 captive-bred cheetahs

Progressive ataxia, with head tremor, developed in 10 captive-born cheetah cubs under six months of age. The condition was usually preceded by coryza and an ocular discharge. Initially the ataxia and weakness affected the hindquarters, then the forelegs, and head tremor developed later. Significant pathological changes were confined to the central nervous system. There was widespread Wallerian degeneration in the funiculi of the spinal cord (except those in the dorsal columns), in the medulla and in the cerebellum. In the cerebellum there was degeneration of Purkinje cells and of the molecular and granular cell layers. There was chromatolysis in the Purkinje cells, the ventral horn cells of the spinal cord and in the neurons of the lateral vestibular nucleus. The olivary nucleus was necrotic. There were foci of inflammatory cells in the molecular layer of the cerebellum and in the medulla. The cause of the disease remains unknown.

Expression of dominant-negative and chimeric subunits reveals an essential role for beta1 integrin during myelination

Myelination represents a remarkable example of cell specialization and cell-cell interaction in development. During this process, axons are wrapped by concentric layers of cell membrane derived either from central nervous system (CNS) oligodendrocytes or peripheral nervous system Schwann cells. In the CNS, oligodendrocytes elaborate a membranous extension with an area of more than 1000 times that of the cell body. The mechanisms regulating this change in cell shape remain poorly understood. Signaling mechanisms regulated by cell surface adhesion receptors of the integrin family represent likely candidates. Integrins link the extracellular environment of the cell with both intracellular signaling molecules and the cytoskeleton and have been shown to regulate the activity of GTPases implicated in the control of cell shape. Our previous work has established that oligodendrocytes and their precursors express a limited repertoire of integrins. One of these, the alpha6beta1 laminin receptor, can interact with laminin-2 substrates to enhance oligodendrocyte myelin membrane formation in cell culture. However, these experiments do not address the important question of integrin function during myelination in vivo, nor do they define the respective roles of the alpha and beta subunits in the signaling pathways involved. Here, we use a dominant-negative approach to provide, for the first time, evidence that beta1 integrin function is required for myelination in vivo and use chimeric integrins to dissect apart the roles of the extracellular and cytoplasmic domains of the alpha6 subunit in the signaling pathways of myelination.

Histological diagnosis of mucopolysaccharidosis IIIA in a wire-haired dachshund

A four-year-old wire-haired dachshund developed progressive neurological signs of ataxia, intention tremor and finally dysuria. Two years later, histopathology showed that neurons throughout the brain and spinal cord were distended with lipopigment which was also present in macrophages. Ultrastructurally, the pigment in the neurons occurred predominantly as electron-dense membranous whorls and stacks. There were a few vacuolated macrophages in the meninges. Hepatocytes were highly vacuolated and electron microscopy suggested that they were empty membrane-bound vesicles. The disease was diagnosed as mucopolysaccharidosis IIIA because of its similarity to other biochemically confirmed cases in the same breed and in a New Zealand huntaway dog. Additional lesions included calcium oxalate uroliths, severe secondary calcification of tissues including the brain and storage deposits in some neurons, and lesions which may have been associated with high levels of the substrate, heparan sulphate.

Remyelinating the demyelinated CNS

The CNS has an inherent capacity to generate remyelinating cells following episodes of myelin loss. However, persistent demyelination is the major pathology of multiple sclerosis and the leucodystrophies, and is also a feature of spinal cord trauma. There are potentially two approaches for achieving remyelination in situations where it fails; enhancement of the inherent remyelinating capacity of the CNS, or transplantation of an exogenous source of myelin forming cells. In experimental animals it is possible to remyelinate demyelinated CNS axons by transplanting cultures containing central or peripheral myelinogenic cells. Glial cell transplantation may thus provide a therapeutic strategy for remyelinating areas of chronic demyelination as well as for stimulating axon regeneration. This presentation will review four issues that have to be addressed before glial transplantation can be undertaken in humans: is the procedure safe, what cells would be used, where would the cells come from and can we predict how much remyelination will be achieved? It concludes that the most promising approach will be to use multipotent neural precursor cells that have been committed to oligodendrocyte lineage differentiation prior to implantation. However, even with such preparations, which have considerable myelinating potential, the extent of remyelination that would be achieved can not yet be predicted with any degree of certainty.

The re-expression of the homeodomain transcription factor Gtx during remyelination of experimentally induced demyelinating lesions in young and old rat brain

Since myelination and remyelination both involve investing an axon with a myelin sheath, a plausible hypothesis is that the two processes involve the expression of similar transcription factors. In this study we have addressed this hypothesis by comparing the expression of messenger RNA of Gtx, a homeodomain transcription factor expressed within oligodendrocytes during myelination, with the expression of messenger RNAs of the major myelin proteins, myelin basic protein and proteolipid protein during remyelination of experimentally induced demyelination in the adult rat brain. We have found a close temporal and spatial association between the expression patterns of the three messenger RNA species during remyelination. By comparing the expression patterns in rapidly remyelinating lesions in young adult rats with slowly remyelinating lesions in old adult rats, we have shown that Gtx messenger RNA expression follows the reappearance of myelin basic protein and proteolipid protein messenger RNAs regardless of the rate of remyelination. This observation demonstrates a clear association between the expression of Gtx messenger RNA and myelin repair. We have also shown that there is a decrease in constitutive levels of expression of myelin basic protein, proteolipid protein and Gtx messenger RNA in old adults compared with young adults. Taken together, our results indicate that Gtx, which has multiple binding sites in the promoter regions of both myelin basic protein and proteolipid protein genes, may have a similar role in the regulation of myelin protein gene expression during remyelination as has been proposed in myelination.

Depletion of endogenous oligodendrocyte progenitors rather than increased availability of survival factors is a likely explanation for enhanced survival of transplanted oligodendrocyte progenitors in X-irradiated compared to normal CNS

Oligodendrocyte progenitors (OPs) survive and migrate following transplantation into adult rat central nervous system (CNS) exposed to high levels of X-irradiation but fail to do so if they are transplanted into normal adult rat CNS. In the context of developing OP transplantation as a potential therapy for repairing demyelinating diseases it is clearly of some importance to understand what changes have occurred in X-irradiated CNS that permit OP survival. This study addressed two alternative hypotheses. Firstly, X-irradiation causes an increase in the availability of OP survival factors, allowing the CNS to support a greater number of progenitors. Secondly, X-irradiation depletes the endogenous OP population thereby providing vacant niches that can be occupied by transplanted OPs. In situ hybridization was used to examine whether X-irradiation causes an increase in mRNA expression of five known OP survival factors, CNTF, IGF-I, PDGF-A, NT-3 and GGF-2. The levels of expression of these factors at 4 and 10 days following exposure of the adult rat spinal cord to X-irradiation remain the same as the expression levels in normal tissue. Using intravenous injection of horseradish peroxidase, no evidence was found of X-irradiation-induced change in blood-brain barrier permeability that might have exposed X-irradiated tissue to serum-derived survival factors. However, in support of the second hypothesis, a profound X-irradiation-induced decrease in the number of OPs was noted. These data suggest that the increased survival of transplanted OPs in X-irradiated CNS is not a result of the increases in the availability of the OP survival factors examined in this study but rather the depletion of endogenous OPs creating 'space' for transplanted OPs to integrate into the host tissue.

Dyskinesia in an adult bichon frise

Dyskinesias are disorders of the central nervous system that result in involuntary movements in a fully conscious individual. This report describes a disorder in a five-year-old male neutered bichon frise characterised by episodic involuntary skeletal muscle activity with normal levels of consciousness that bears some similarity to the previously described movement disorder in boxer puppies and to the human condition descriptively referred to as paroxysmal dystonic choreoathetosis. The disorder was differentiated from partial motor seizure activity by the character of the episodes, absence of identifiable preceding aura, absence of autonomic signs and the fact that multiple limbs were affected in a varying pattern without generalisation and loss of consciousness. Movement disorders are a well documented group of disorders in human neurology, but only rarely described in the veterinary literature. The purpose of this report is to contribute to an increased awareness of movement disorders within veterinary practice.

Olfactory ensheathing cells and Schwann cells differ in their in vitro interactions with astrocytes

Transplanted olfactory ensheathing cells (OECs) are able to remyelinate demyelinated axons and support regrowth of transected axons after transplantation into the adult CNS. Transplanted Schwann cells (SCs) share these repair properties but have limitations imposed on their behavior by the presence of astrocytes (ACs). Because OECs exist alongside astrocytes in the olfactory bulb, we have hypothesized that they have advantages over SCs in transplant-mediated CNS repair due to an increased ability to integrate and migrate within an astrocytic environment. In this study, we have tested this hypothesis by comparing the interactions between astrocytes and either SCs or OECs, using a range of in vitro assays. We have shown that (1) astrocytes and SCs segregate into defined non-overlapping domains in co-culture, whereas astrocytes and OECs freely intermingle; (2) both SCs and OECs will migrate across astrocyte monolayers, but only OECs will migrate into an area containing astrocytes; (3) SCs spend less time in contact with astrocytes than do OECs; and (4) astrocytes undergo hypertrophy when in contact with SCs, but not with OECs. Expression of N-cadherin has been implicated as a key mediator of the failure of SCs to integrate with astrocytes. However, we found no differences in the intensity of N-cadherin immunoreactivity between SCs and OECs, suggesting that it is not the adhesion molecule that accounts for the observed differences. In addition, the number of astrocytes expressing chondroitin sulfate proteoglycans (CSPG) is increased when astrocytes are co-cultured with Schwann cells compared with the number when astrocytes are grown alone or with OECs. Taken together, these data support the hypothesis that OECs will integrate more extensively than Schwann cells in astrocytic environments and are therefore better candidates for transplant-mediated repair of the damaged CNS.

Delayed changes in growth factor gene expression during slow remyelination in the CNS of aged rats

In this study we have examined whether the slower rate of CNS remyelination that occurs with age is associated with a change in growth factor expression patterns, an association that would provide further support for a causal relationship between growth factors and remyelination. Using quantitative in situ hybridization we have shown that there are differences in IGF-I, TGF-beta 1, and PDGF-A mRNA expression during remyelination of lysolecithin-induced demyelination in the spinal cord of young adult and old adult rats. IGF-I and TGF-beta1 mRNA expression in old rats had a delayed and lower peak expression compared to young rats. The initial increase in PDGF-A mRNA expression was delayed in old rats compared to young rats, but after 5 days both age groups had similar patterns of expression, as was the expression pattern of FGF-2 mRNA at all survival times. In neither age group were increases in CNTF, NT-3, or GGF-2 mRNA expression detected. An analysis of the macrophage response using oligonucleotide probes for scavenger receptor-B mRNA indicated that differences in the macrophage response in young and old animals was the likely cause of the age related change in IGF-I and TGF-beta 1 mRNA expression patterns. On the basis of these data we suggest a model of remyelination in which PDGF is involved in the initial phase of oligodendrocyte progenitor recruitment, while IGF-I and TGF-beta 1 trigger the differentiation of the recruited cells into myelinating oligodendrocytes.

GM1-gangliosidosis in a cross-bred dog confirmed by detection of GM1-ganglioside using electrospray ionisation-tandem mass spectrometry

The post-mortem diagnosis of lysosomal storage diseases can be confounded by the unavailability of suitable material. Here we report the diagnosis of GM1-gangliosidosis in a cross-bred dog, from which only formalin-fixed brain was available, by a combination of electron microscopy and the detection of elevated levels of GM1-ganglioside within the tissue using the novel technique of electrospray ionisation tandem mass spectrometry. Electron microscopic examination of ultrathin sections of resin-embedded tissue revealed cytoplasmic inclusions (membranous cytoplasmic and zebra bodies) in brain stem and cerebellar neurons that were characteristic of a gangliosidosis. Glycolipids were extracted from the fixed tissue and analysed by tandem mass spectrometry. Two major ions were detected, which corresponded to GM1 (d18:1-C18:0) and Gm1 (d20:1-C18:0). Their identity was confirmed by comparison of their fragmentation patterns with those of authentic standards. The concentration of GM1 was approximately sixfold higher on a wet weight basis than in the brain of a normal control dog, confirming the diagnosis of GM1-gangliosidosis.

Schwann cells transplanted into normal and X-irradiated adult white matter do not migrate extensively and show poor long-term survival

Although Schwann cells are able to enter the central nervous system (CNS) when the integrity of the glia limitans is disrupted, their ability to migrate through intact CNS remains unclear. We have addressed this issue by transplanting lacZ-labeled Schwann cells into normal adult spinal cord white matter, and into X-irradiated spinal cord (an environment that, unlike normal spinal cord, permits the migration of transplanted oligodendrocyte progenitors). Schwann cell cultures, obtained from neonatal rat sciatic nerve and expanded using bovine pituitary extract and forskolin, were transfected by repeated exposure to retroviral vectors encoding the Escherichia coli lacZ gene. The normal behavior of the transduced cells was confirmed by transplantation into a nonrepairing area of demyelination in the spinal cord, where they formed myelin sheaths around demyelinated axons. A single microliter containing 4 x 10(4) cells was then transplanted into unlesioned normal and X-irradiated white matter of the spinal cord of adult syngeneic rats. One hour after injection, blue cells were observed as a discrete mass within the dorsal funiculus with a longitudinal distribution of 2-3 mm, indicating the extent of passive spread of the injected cells. At subsequent survival times (1, 2, and 4 weeks posttransplantation) blue cells had a distribution that was no more extensive than that seen 1 h after transplantation. However, the number of Schwann cells declined with time following transplantation such that at 4 weeks there were few surviving Schwann cells in both X-irradiated and nonirradiated spinal cord. These results indicate that transplanted Schwann cells do not migrate extensively and show poor long-term survival when introduced into a normal CNS environment.

Identification of a human olfactory ensheathing cell that can effect transplant-mediated remyelination of demyelinated CNS axons

The olfactory ensheathing cell (OEC) has attracted much interest recently because of its potential for transplantation-based therapy of CNS disease. Rat OECs are able to remyelinate demyelinated axons and support regeneration of damaged axons. Although OECs can be grown readily from the rat, a macrosmatic species, it has been uncertain whether it would be similarly straightforward to obtain these cells from the human, a microsmatic species with a relatively poorly developed olfactory system. In this study, we have identified a human OEC which shares many properties with its rat counterpart, including expression of the low-affinity nerve growth factor receptor (L-NGFr) and similar growth factor requirements. Purified populations of human OECs obtained by selection with L-NGFr antibodies have extremely high viability in tissue culture, and are capable of remyelinating persistently demyelinated CNS axons following transplantation into experimentally induced demyelinating lesions in the rat spinal cord. Thus, the human OEC represents an important new cell for the development of transplant therapy of CNS diseases.

Schwann cell remyelination is restricted to astrocyte-deficient areas after transplantation into demyelinated adult rat brain

The ability to generate large numbers of Schwann cells from a peripheral nerve biopsy makes them potential candidates for the clinical application of cell transplantation to enhance remyelination in human demyelinating disease. Transplant-derived Schwann cell remyelination has previously been demonstrated in the spinal cord but not for demyelinated axons in the brain, a more likely site for initial clinical intervention. We have transplanted Schwann cells from male neonatal rat sciatic nerves into ethidium bromide-induced areas of demyelination in the deep cerebellar white matter of adult female rats. The extent of Schwann cell remyelination 28 days after transplantation was significantly increased in lesions that received direct injections of Schwann cells compared with non-transplanted lesions. Using in situ hybridisation to identify the rat Y chromosome, transplanted male cells were found to co-localise with the P0 immunoreactive area of Schwann cell remyelination. Combined immunohistochemistry and in situ hybridisation confirmed that many remyelinating Schwann cells were transplant-derived. P0 immunoreactivity and transplanted male cells were found in GFAP-negative, astrocyte-free areas. Transplanted Schwann cells were not identified outside of transplanted lesions, nor did they did not contribute to remyelination of a lesion at a distance from the site of transplantation. Our findings indicate that demyelinated axons in the adult brain can be remyelinated by transplanted Schwann cells but that migration and remyelination are restricted to areas from which astrocytes are absent.

The Brown Animal Sanatory Institution--historical lessons for the present?

This article briefly reviews the history of the Brown Institution (1871-1944), a remarkable but short-lived and now largely forgotten veterinary centre of research and clinical practice. As well as providing a broad-based clinical service for the surrounding area of London, the Brown Institution was also the home of some of the most distinguished contributors to comparative medicine and physiology. Many of its aspirations, achievements and difficulties are relevant and comparable to those faced by the profession today.

Transplantation options for therapeutic central nervous system remyelination

Persistent demyelination, in addition to being the major pathology of multiple sclerosis and the leucodystrophies, is also a feature of spinal cord trauma where there is evidence that it contributes to the functional deficit. In experimental animals it is possible to remyelinate demyelinated CNS axons by transplanting cultures containing central or peripheral myelinogenic cells. Using functional testing we have been able to show that transplant-mediated remyelination results in restoration of function lost as a consequence of demyelination. Glial cell transplantation may therefore provide a therapeutic strategy for remyelinating areas of chronic demyelination. This article reviews issues that have to be addressed before glial transplantation can be undertaken in humans. These include: what cells to use, where would the cells come from, and can we predict how much remyelination will be achieved? It concludes that the most promising approach will be to use neural multipotential stem cells isolated from embryonic CNS, expanded in vitro as neurospheres and then committed to oligodendrocyte lineage differentiation prior to implantation. However, even with such preparations, which have considerable myelinating potential, the extent of remyelination that will be achieved cannot currently be predicted with any degree of certainty.

Robust regeneration of CNS axons through a track depleted of CNS glia

Transected CNS axons do not regenerate spontaneously but may do so if given an appropriate environment through which to grow. Since molecules associated with CNS macroglia are thought to be inhibitory to axon regeneration, we have tested the hypothesis that removing these cell types from an area of brain will leave an environment more permissive for axon regeneration. Adult rats received unilateral knife cuts of the nigrostriatal tract and ethidium bromide (EB) was used to create a lesion devoid of astrocytes, oligodendrocytes, intact myelin sheaths, and NG2 immunoreactive cells from the site of the knife cut to the ipsilateral striatum (a distance of 6 mm). The regenerative response and the EB lesion environment was examined with immunostaining and electron microscopy at different timepoints following surgery. We report that large numbers of dopaminergic nigral axons regenerated for over 4 mm through EB lesions. At 4 days postlesion dopaminergic sprouting was maximal and the axon growth front had reached the striatum, but there was no additional growth into the striatum after 7 days. Regenerating axons did not leave the EB lesion to form terminals in the striatum, there was no recovery of function, and the end of axon growth correlated with increasing glial immunoreactivity around the EB lesion. We conclude that the removal of CNS glia promotes robust axon regeneration but that this becomes limited by the reappearance of nonpermissive CNS glia. These results suggest, first, that control of the glial reaction is likely to be an important feature in brain repair and, second, that reports of axon regeneration must be interpreted with caution since extensive regeneration can occur simply as a result of a major glia-depleting lesion, rather than as the result of some other specific intervention.

Magnetic resonance imaging of transplanted oligodendrocyte precursors in the rat brain

The lack of any markers for oligodendrocyte precursors that can be visualized within the intact CNS is a significant barrier to trials of transplantation of these cells which aim to enhance remyelination in multiple sclerosis. We have therefore asked whether dextran-coated superparamagnetic iron oxide (SPIO) can be used to label cells prior to transplantation and then visualized within the brain using MRI. We have shown that an oligodendrocyte precursor cell line CG-4 will take up dextran-coated SPIO particles in vitro. The label remains within the cells after transplantation into adult rat brain, as assessed by electron microscopy, and is visible by MRI as a reduction in signal intensity at the transplant site at both 1 and 7 days after surgery. We conclude that MRI detection of SPIO-labelled cells represents a promising and novel approach to the analysis of oligodendroglial cell behaviour following transplantation that has very significant advantages over currently available methods.

Understanding CNS remyelination: clues from developmental and regeneration biology

A guiding principle in remyelination research has been to seek clues to its nature in developmental studies on myelination. This "recapitulation hypothesis" argues that the regenerative response involves rerunning much the same programme as occurs during the developmental process. Here we examine the extent to which current evidence supports this hypothesis and whether this is a useful conceptual framework within which to study remyelination and suggest that an equally fruitful approach is to look to regenerative processes in other tissues.

Remyelination occurs as extensively but more slowly in old rats compared to young rats following gliotoxin-induced CNS demyelination

Age is one of the many factors that influence remyelination following CNS demyelination, although it is not clear whether it is the extent or rate of remyelination that is affected. To resolve this issue we have compared remyelination in young and old adult rat CNS following gliotoxin-induced demyelination. Remyelination of areas of ethidium bromide-induced demyelination in the caudal cerebellar peduncle reached completion by 4 weeks in young adult rats (2 months) but was not complete until 9 weeks in old adult rats (9-12 months). We have also shown that remyelination of lysolecithin-induced demyelination in the spinal white matter of old adult rats (18 months) can be extensive, with longer survival times (8 weeks) than have previously been examined. Thus, it is the rate rather than the extent of remyelination that changes in the ageing CNS. These results have important implications for understanding the mechanisms of remyelination, indicating that remyelination need not occur rapidly for it to be extensive. The capacity for the process of remyelination to continue over many weeks must also be borne in mind when assessing remyelination-enhancement strategies either by transplantation or promotion of endogenous mechanisms.

Myelination and behaviour of tenascin-C null transgenic mice

The extracellular matrix glycoprotein tenascin-C is widely expressed during development and repair, making it surprising that few abnormalities have been found in transgenic mice lacking this molecule. We have therefore re-examined the transgenic mice described by Saga et al. [Saga, Y., Yagi, T., Ikawa, Y., Sakakura, T. & Aizawa, S. (1992) Genes Dev., 6 1821-1831] in which tenascin-C was knocked-out by homologous recombination, focusing on two aspects of the nervous system likely to reveal any abnormalities that might follow the loss of tenascin-C. First, we have determined the pattern of myelin and distribution of oligodendrocyte precursor cells in those areas, such as the optic nerve and retina where local concentrations of tenascin-C have been proposed to act as barriers to oligodendrocyte precursor migration and so prevent inappropriate myelination. Secondly, we have examined the behaviour of the mice in a number of well-characterized tests, e.g. beam-walking, passive avoidance and the Morris water maze. We find no abnormalities of myelination or oligodendrocyte precursor distribution in adult mice, showing that local concentrations of tenascin-C are not the sole mechanism responsible for the pattern of myelination in these regions of CNS. However, we do find a number of behavioural abnormalities in these mice and show that hyperlocomotion and deficits in coordination during beam walking can be ascribed to tenascin-C deficiency. The effects on coordination are, however, not seen on a 129 genetic background. Taken together, these results significantly extend the phenotype associated with tenascin-C deficiency but argue against a role in myelination.

Distinctive patterns of PDGF-A, FGF-2, IGF-I, and TGF-beta1 gene expression during remyelination of experimentally-induced spinal cord demyelination

Although remyelination is a well-recognized regenerative process following both experimental and naturally occurring CNS demyelination, remarkably little is known about the molecules involved in its orchestration. In this study we have examined the mRNA expression of seven growth factors that influence oligodendrocyte lineage cells, during the remyelination of lysolecithin-induced demyelination in the rat spinal cord. These lesions involve rapid demyelination of axons, which undergo extensive remyelination between 10 and 28 days. The distribution and levels of expression of PDGF-A, IGF-I, CNTF, FGF-2, TGF-beta1, GGF-2, and NT-3 mRNAs were examined at 2, 5, 7, 10, 14, 21, and 28 days post-lesion induction, both within the lesion and within dorsal root ganglia whose axons transverse the lesion, by quantitative in situ hybridization using 35S-labeled oligonucleotide probes. large increases in IGF-I and TGF-beta1 mRNAs were evident within the spinal cord by 5 days. These levels peaked at 10 days at a time when new myelin sheaths appear and had declined by 28 days. Increases in FGF-2 and PDGF-A mRNAs were less intense and less widely distributed than those of IGF-I and TGF-1, but remained elevated for a longer duration. There were no changes in expression of CNTF, NT-3, or GGF-2 mRNAs within the lesioned cords; neither were ther changes in levels of expression of any growth factor mRNAs in the dorsal root ganglia. This work therefore indicates that some but not all members of the family of growth factors that affect the oligodendrocyte lineage are expressed during remyelination of demyelinated spinal cord axons and provides the data on which future studies on the specific roles of these factors in orchestrating this important regenerative process will be based.

The expression of myelin protein mRNAs during remyelination of lysolecithin-induced demyelination

To gain insights into the mechanisms of myelin repair in the CNS and to establish the extent to which this process resembles myelination in development we have examined the patterns of expression of transcripts of the major myelin proteins, myelin basic protein (MBP) and proteolipid protein (PLP) during remyelination of lysolecithin-induced demyelination in the adult rat spinal cord. Injection of 1 microliter 1% lysolecithin into the dorsal funiculus caused a dramatic decrease in levels of MBP exon 1 and MBP exon 2-containing transcripts and PLP/DM20 transcripts. Between 10 and 21 days post-lesion induction there was a gradual increase in levels of expression of all transcripts, which had returned to levels associated with normally myelinated spinal cord white matter at 21 days. These increases in levels of expression corresponded to the appearance of remyelinated axons, detected on toluidine blue-stained resin sections. Foci of high levels of expression occurred in regions of the lesion in which new myelin sheath formation was occurring, although the level of expression throughout the lesion never exceeded levels associated with myelin sheath maintenance in normal white matter due to the asynchronous pattern of remyelination. The changes in levels of expression of MBP exon 2 closely followed those of MBP exon 1. Our results indicate that (i) myelin protein gene expression associated with myelinogenesis during remyelination follows a similar pattern to that of myelinogenesis during development and that (ii) in rat models of demyelination changes of expression of MBP exon 1 and exon 2-containing transcripts are of equal value, an observation relevant to quantifying the effects of putative remyelination-enhancing strategies using the lysolecithin model.

Demyelination and remyelination of the caudal cerebellar peduncle of adult rats following stereotaxic injections of lysolecithin, ethidium bromide, and complement/anti-galactocerebroside: a comparative study

Experimentally induced demyelination due to the direct injection of gliotoxic agents has provided powerful models for studying the biology of remyelination. For the most part, these models have involved injection into white matter tracts of the spinal cord. However, the spinal cord has a number of limitations, such as the size of lesions that it is possible to make and its unsuitability for long-term direct cannulation for the delivery of putative remyelination-enhancing agents. In this study, we describe the natural history of three new models of demyelination/remyelination based on the stereotaxic injection of three gliotoxins: lysolecithin, ethidium bromide, and a combination of anti-galactocerebroside antibody and complement (GalC-ab/comp) into the caudal cerebellar peduncle of adult rats. All three agents produced large areas of demyelination with minimal axonal damage, which undergo extensive remyelination. Ethidium bromide- and GalC-ab/comp-induced lesions remyelinated more slowly than those induced by lysolecithin. The contribution to the remyelination of the lesion by Schwann cells reflects the degree of astrocyte damage incurred within the demyelinated area and is greatest for ethidium bromide-induced demyelination. These new models not only provide further insights into the mechanisms of CNS remyelination but also provide a valuable new resource for addressing a series of key issues relevant to current efforts to promote CNS remyelination either by the enhancement of intrinsic processes or by the transplantation of myelinogenic cells.

Trapidil-mediated inhibition of CNS remyelination results from reduced numbers and impaired differentiation of oligodendrocytes

In a previous study, we described the inhibitory effects of the growth factor-antagonist, trapidil, on spontaneously occurring oligodendrocyte remyelination in the rat spinal cord following lysolecithin-induced demyelination [30]. The objective of the present study was to further investigate the mechanisms of trapidil-mediated impairment of remyelination and thus obtain greater insight into the steps at which growth factors may be involved in remyelination. To this end, an ultrastructural analysis of the cellular composition of lesions from control and trapidil-treated animals was undertaken. Demyelination was created in the dorsal funiculus of 6-week-old female rats by the injection of 1.0 microliter of 1% lysolecithin. The animals received daily intraperitoneal injections of trapidil (80 mg/kg) or saline for 21 days, beginning on the day of lesion induction. Quantitative electron microscopic examination of lesions from both groups of animals showed that trapidil-treated lesions had reduced numbers of oligodendrocytes (P = 0.02) with a higher relative proportion of immature phenotypes, but increased numbers of microglia (P = 0.0009) and dystrophic axons (P0.02). In addition, the numbers of myelin lamellae around remyelinated axons were fewer in trapidil-treated animals. These results suggest that trapidil-mediated impairment of CNS remyelination is due to a blockage of growth factor-mediated proliferation and/or recruitment of remyelinating cells. Furthermore, the presence of oligodendrocytes with a more immature phenotype and the decreased thickness of the myelin sheaths of remyelination in the trapidil-treated animals indicate an impairment of growth factor-mediated differentiation.

Paralysis in hedgehogs (Erinaceus europaeus) associated with demyelination

Paraplegia affected 14 hedgehogs (Erinaceus europaeus) in a wildlife rescue hospital over a period of six months. Postmortem examination revealed demyelination in the brain and spinal cord and an inflammatory response in the meninges, choroid plexus and CNS. The peripheral nervous system was not affected. In the spleen, lungs and liver there was an accumulation of megakaryocytes and other evidence of extramedullary haemopoiesis, but there was no haematological evidence of anaemia. The pattern of disease incidence and the nature of the changes in the CNS suggest they were of viral origin, but no causal agent was isolated and the possibility of a neurotoxin cause cannot be ruled out.

Transplanting myelin-forming cells into the central nervous system: principles and practice

Although transplantation of myelin-forming cells into the central nervous system (CNS) has recently attracted much attention as a potential therapy for repairing persistent demyelination found in the demyelinating diseases such as multiple sclerosis and the leukodystrophies, it is worth remembering that the technique was originally conceived of as an experimental technique for manipulating in vivo environments to study interactions between different cell types in either repair or development. It is in this capacity that the technique is still predominantly used. Nevertheless, information, both technical and biological, that the continued use of the technique yields also often provides material for assessing the feasibility of glial cell transplantation as a therapeutic procedure. In this article, we describe some of the guiding principles of transplantation of myelinogenic cells into the mammalian CNS, focusing initially on the recipient environment and then considering the donor material. The division of the discussion into recipient and donor is one of convenience since in reality the interactions between the two cannot be considered in isolation.

The expression of myelin basic protein exon 1 and exon 2 containing transcripts during myelination of the neonatal rat spinal cord--an in situ hybridization study

During myelination, myelin proteins are expressed in a highly coordinated sequence. Of the four major isoforms of myelin basic protein, the proportion of the 21.5kDa and 17 kDa isoforms (which contain sequences encoded by myelin basic protein [MBP] exon 2) is enriched during active myelination in the mouse, suggesting that the alternative splicing of MBP transcripts containing exon 2 information is developmentally regulated. In this study, we compare the expression of MBP exon 1 and MBP exon 2 mRNAs in the neonatal rat spinal cord to establish whether developmental regulation of exon 2 mRNAs occurs in the rat in a manner similar to that previously described in the mouse. The expression of MBP mRNAs, together with that of proteolipid protein (PLP/DM-20) mRNA, in the developing white matter tracts increased dramatically between P7 and P10, corresponding to an increase in the extent of myelination. High levels of expression of each mRNA species examined were maintained between P10 and P14 as myelination proceeded. At P21, the expression of MBP exons 1 and 2 was reduced in the ventrolateral funiculi but was maintained at high levels in the dorsal funiculus. At P45, a further downregulation of both MBP mRNAs was apparent. By contrast, high levels of PLP/DM-20 expression were maintained from P10 onwards. In the grey matter, expression of MBP and PLP/DM-20 mRNAs increased more gradually and peak expression occurred later than in the white matter tracts. In this study, we therefore provide a description of myelin protein gene expression during post-natal development of the rat spinal cord. We have also shown that in the rat spinal cord, changes in the levels of MBP exon 2 expression associated with myelination reflect the changes of all MBP transcripts.

Peptidomimetic aminomethylene ketone inhibitors of interleukin-1 beta-converting enzyme (ICE)

Pyridone-based peptidomimetic inhibitors of recombinant human Interleukin-1 beta-converting enzyme (ICE, caspase-1) with an aminomethylene ketone activating group in the P1' position are described. Several analogues with sub-nanomolar Ki's versus ICE and improved aqueous solubility are reported.

Do olfactory glia have advantages over Schwann cells for CNS repair?

To a large extent the success of axon regeneration and sustained remyelination which distinguishes the PNS from the CNS is attributable to differences in their respective glial environments. For this reason, many have been attracted to the idea that repair of the CNS might be achieved by transplanting Schwann cells into areas of CNS pathology. Schwann cells will not only promote regeneration but will also myelinate axons thereby making them an appropriate cell type to mediate repair of lesions characterised by demyelination as well as axotomy. The recent discovery that olfactory glia are capable of forming myelin sheaths, together with their well-documented ability to support axon regeneration, means that these cells have a range of repair properties similar to that of Schwann cells. It is not clear at present which of these two alternatives, the Schwann cells or the olfactory glial cell, would be of greater benefit for achieving regeneration of axons or remyelination of persistent demyelination following transplantation into the CNS. In this article we review the repair properties of olfactory glia and identify the areas in which their use for repairing the CNS may have advantages over Schwann cells.

Local recruitment of remyelinating cells in the repair of demyelination in the central nervous system

The distance over which remyelinating cells within surrounding intact tissue are stimulated to respond to a demyelinating lesion and migrate toward it is unknown. To address this issue we have conducted a series of experiments in which the generation of remyelinating cells in tissue surrounding a spontaneously repairing area of demyelination induced in the adult rat spinal cord is suppressed by exposure to X-irradiation. By regulating the area of X-irradiation relative to the length of the demyelinating lesion within dorsal white matter we have shown that remyelinating cells are not recruited over distances greater than 2 mm into areas of demyelination, implying that most of the remyelinating cells are locally generated. This result indicates that there is only a narrow rim of normal tissue surrounding an area of demyelination from which remyelinating cells can be recruited. The depletion of cells within this rim may account for the poor remyelination associated with large areas of demyelination and following repeated episodes of demyelination. We have also shown that, in contrast to Schwann cells, oligodendrocyte lineage cells recruited into lesions have a limited ability to rapidly repopulate large areas of demyelination. Attempts to enhance remyelination in situations where it fails should therefore focus on increasing the size of the surrounding area from which remyelinating cells can be recruited by augmenting the level of recruitment signal, and preventing premature differentiation of oligodendrocytes so as to maximize their migratory and proliferative potential.

Remyelination in demyelinating disease

In multiple sclerosis, partial remyelination is conspicuous in many lesions, and is thought to contribute significantly to lasting recovery from acute relapse. However, myelin repair ultimately fails during progression of the disease, as disability and handicap accumulate. In this chapter we explore the biological background to myelin repair in CNS demyelinating disease, and the reasons underlying the failure of more widespread and lasting remyelination in multiple sclerosis. Experimental studies provide clear evidence that therapies promoting myelin repair can be highly successful in the CNS, and we discuss the clinical approaches which might allow the translation of these laboratory studies to neurological practice, together with some of the potential hazards and pitfalls likely to arise.

To what extent is oligodendrocyte progenitor migration a limiting factor in the remyelination of multiple sclerosis lesions?

In this article we describe a series of experimental approaches, involving the use of gliotoxin-induced demyelination, X-irradiation and glial cell transplantation, which examine the size of the area around demyelinating lesions from which new remyelinating cells are generated, and the distance over which they are able to migrate. Taken together, these studies suggest that the recruitment of remyelinating cells takes place over a very limited area and that long distance migration of remyelinating cells is not a feature of remyelination. The implications of these findings for spontaneous remyelination of multiple sclerosis plaques, and the development of strategies for enhancing remyelination are discussed.

Growth factors and remyelination in the CNS

It is now well established that there is an inherent capacity within the central nervous system (CNS) to remyelinate areas of white matter that have undergone demyelination. However this repair process is not universally consistent or sustained, and persistent demyelination occurs in a number of situations, most notably in the chronic multiple sclerosis (MS) plaque. Thus there is a need to investigate ways in which myelin deficits within the CNS may be restored. One approach to this problem is to investigate ways in which the inherent remyelinating capacity of the CNS may be stimulated to remyelinate areas of long-term demyelination. The expression of growth factors, which are known to be involved in developmental myelinogenesis, in areas of demyelination strongly suggests that they are involved in spontaneous remyelination. Therefore delivery of exogenous growth factors into areas of persistent demyelination is a potential therapeutic strategy for stimulating remyelination. This review will discuss the evidence that growth factors may have a role in promoting CNS remyelination by enhancing the survival and stimulating the proliferation and recruitment of remyelinating oligodendrocytes.

The effects of the growth factor-antagonist, trapidil, on remyelination in the CNS

In this study we describe the effects of trapidil, a putative platelet-derived growth factor-antagonist, on spontaneously occurring remyelination in rat spinal cord. Demyelination was created in the dorsal funiculus of 6- and 11-week-old female rats by the direct injection of 1.0 microliter of 1% lysolecithin. The animals received daily intra-peritoneal injections of either trapidil or saline for 21 days, commencing on the day of lesion induction. The 11-week-old rats receiving trapidil (60 mg/kg) showed a significant decrease in the extent of oligodendrocyte remyelination. Moreover, those axons that were remyelinated by oligodendrocytes tended to have thinner myelin sheaths than axons remyelinated by oligodendrocytes in the control group. In the 6-week-old group, the dose of trapidil which inhibited oligodendrocyte remyelination in the 11-week-old animals had a minimal effect on the extent of oligodendrocyte remyelination and no effect on the quality of myelin sheath formation. A higher dose of trapidil (80 mg/kg) was required before significant impairment of oligodendrocyte remyelination was achieved in the younger age group, implying an age-dependent effect of growth factor-inhibition of CNS remyelination. These results indicate an important role for growth factors, and in particular PDGF, in the orchestration of oligodendrocyte remyelination in the rodent CNS.

Contrasting effects of mitogenic growth factors on oligodendrocyte precursor cell migration

We have examined the effects of the mitogenic growth factors platelet derived growth factor (PDGF), basic fibroblast growth factor (bFGF) and glial growth factor-2 (GGF-2) on oligodendrocyte precursor migration. In an agarose drop migration assay PDGF and bFGF stimulated migration while GGF-2 had no effect. The migration-enhancing effect of bFGF cannot be blocked by neutralising antibodies against PDGF, confirming that this effect is direct and not mediated via upregulation of PDGF receptors. Based on our results, we propose a model in which the differing effects of PDGF and GGF-2 ensure appropriate numbers of oligodendrocyte precursor cells in the vicinity of axons to be myelinated during development.

Transplanting oligodendrocyte progenitors into the adult CNS

This review covers a number of aspects of the behaviour of oligodendrocyte progenitors following transplantation into the adult CNS. First, an account is given of the ability of transplanted oligodendrocyte progenitors, grown in tissue culture in the presence of PDGF and bFGF, to extensively remyelinate focal areas of persistent demyelination. Secondly, we describe how transplanted clonal cell lines of oligodendrocyte progenitors will differentiate into astrocytes as well oligodendrocytes following transplantation into pathological environments in which both oligodendrocytes and astrocytes are absent, thereby manifesting the bipotentially demonstrable in vitro but not during development. Finally, a series of studies examining the migratory behaviour of transplanted oligodendrocyte progenitors (modelled using the oliodendrocyte progenitor cell line CG4) are described. These show that CG4 cells do not survive (or migrate) when transplanted into the normal adult CNS. However, if they are transplanted into CNS tissue that has previously been exposed to 40 Gy of x-irradiation then transplanted CG4 cells survive, divide and migrate over large distances. Moreover, within an x-irradiated environment, migrating transplanted CG4 cells are able to enter remotely located foci of demyelination and contribute to the remyelination of the demyelinated axons within. These studies demonstrate that although the normal adult CNS does not appear to support survival and migration of the CG4 cell line, it is possible to manipulate the environment in such a way that these nonpermissive properties of the environment can be overcome.

Schwann cell-like myelination following transplantation of an olfactory bulb-ensheathing cell line into areas of demyelination in the adult CNS

In this study we have transplanted a clonal olfactory bulb-ensheathing cell line into focal areas of the rat spinal cord which contain demyelinated axons but neither oligodendrocytes nor astrocytes. The cell line was created by retroviral incorporation of the temperature-sensitive Tag gene into FACS-sorted 04+ cells from 7-day-old rat pup olfactory bulb. The spinal cord lesions were obtained by injecting small volumes of ethidium bromide into the dorsal white matter of spinal cord previously exposed to 40 Grays of X-irradiation. Many of the axons were remyelinated by PO+ myelin sheaths 21 days after transplantation. Light and electron microscopy revealed cells engaging and myelinating axons in a manner highly reminiscent of Schwann cells within similar lesions. GFAP+ cells were also present within the lesion. This study provides the first in vivo evidence that olfactory bulb-ensheathing cells are able to produce peripheral-type myelin sheaths around axons of the appropriate diameter.

Remyelination in the CNS of the hypothyroid rat

A number of studies have provided good evidence to indicate a role for thyroid hormone in myelination. Since myelination and remyelination have many shared objectives, and may therefore involve similar mechanisms, we examined whether thyroid hormone may also have a role in remyelination by both Schwann cells and oligodendrocytes of spinal cord axons that had been demyelinated by the injection of ethidium bromide in thyroidectomized rats. Neither the extent of oligodendrocyte remyelination nor the thickness of myelin sheath formed by remyelinating oligodendrocytes was affected by hypothyroidism. However, the extent of remyelination carried out by Schwann cells was decreased in hypothyroid rats compared with normal control animals.

Transplanted CG4 cells (an oligodendrocyte progenitor cell line) survive, migrate, and contribute to repair of areas of demyelination in X-irradiated and damaged spinal cord but not in normal spinal cord

In this study, we have examined the behavior of a lac-Z-transfected O- 2A progenitor cell line, CG4, following transplantation into normal and X-irradiated adult rat spinal cord, and we have also addressed the issue of whether CG4 cells transplanted remotely from ethidium bromide-induced demyelinating lesions in both X-irradiated and nonirradiated spinal cord are able to contribute to their repair. Following transplantation into X-irradiated spinal cord, CG4 cells survive, divide, and migrate extensively. The migration occurs mainly within the parenchymal tissue of the cord without preference for white or gray matter. Moreover, CG4 cells migrating away from their point of introduction are able to enter areas of demyelination and remyelinate the demyelinated axons therein. In contrast, when CG4 cells are transplanted into nonirradiated spinal cord, their survival is limited to areas of damage created by the injection procedure. The CG4 cells do not survive in undamaged, nonirradiated spinal cord. When transplanted remotely from areas of demyelination they are unable to traverse intervening areas of normal white matter, although they may enter lesions if transplanted into their close vicinity. These results have important implications for the development of potential therapeutic strategies for the treatment of multifocal demyelinating disorders that are based on glial cell transplantation.