Migration of cultured fetal spinal cord astrocytes into adult host cervical cord and medulla following transplantation into thoracic spinal cord

Stem and Progenitor Cell-Derived Astroglia Therapies for Neurological Diseases

Astroglia are a major cellular constituent of the central nervous system (CNS) and play crucial roles in brain development, function, and integrity. Increasing evidence demonstrates that astroglia dysfunction occurs in a variety of neurological disorders ranging from CNS injuries to genetic diseases and chronic degenerative conditions. These new insights herald the concept that transplantation of astroglia could be of therapeutic value in treating the injured or diseased CNS. Recent technological advances in the generation of human astroglia from stem and progenitor cells have been prominent. We propose that a better understanding of the suitability of astroglial cells in transplantation as well as of their therapeutic effects in animal models may lead to the establishment of astroglia-based therapies to treat neurological diseases.

Integration of genetically modified adult astrocytes into the lesioned rat spinal cord

Combination of ex vivo gene transfer and cell transplantation is now considered as a potentially useful strategy for the treatment of spinal cord injury. In a perspective of clinical application, autologous transplantation could be an option of choice. We analyzed the fate of adult rat cortical astrocytes genetically engineered with a lentiviral vector transplanted into a lesioned rat spinal cord. Cultures of adult rat cortical astrocytes were infected with an HIV-1-derived vector (TRIP-CMV-GFP) and labeled with the fluorescent dye Hoechst. Transfected and labeled astrocyte suspension was injected at T11 in rats in which spinal cord transection at T7-T8 levels had been carried out 1 week earlier. Six weeks after grafting, the animals were sacrificed and transplants were retrieved either by Hoechst fluorescence or by immunohistochemistry for detection of glial fibrillary acidic protein (GFAP) and vimentin. Grafted astrocytes expressing green fluorescent protein (GFP) were found both at the injection and transection sites. Genetically modified astrocytes thus survived, integrated, and migrated within the host parenchyma when grafted into the completely transected rat spinal cord. In addition, they retained some ability to express the GFP transgene for at least 6 weeks after transplantation. Adult astrocytes infected with lentiviral vectors can therefore be a valuable tool for the delivery of therapeutic factors into the lesioned spinal cord.

Collagen containing neonatal astrocytes stimulates regrowth of injured fibers and promotes modest locomotor recovery after spinal cord injury

The use of collagen as a vehicle to transplant neonatal astroglial cells into the lesioned spinal cord of the adult rat allows a precise application of these cells into the lesion gap and minimizes the migration of the transplanted cells. This approach might lead to anatomical and functional recovery. In the present study, 20 adult female Wistar rats were subjected to a dorsal hemisection at thoracic spinal cord levels. Cultured cortical neonatal rat astrocytes were transplanted into the lesion with collagen as a vehicle (N = 10). Prior to transplantation, the cultured astroglial cells were labelled with fast blue. Control rats received collagen implants only (N = 10). During 1 month of survival time, functional recovery of all rats was continuously monitored. Histological data showed that the prelabelled astroglial cells survived transplantation and were localized predominantly in the collagen implant. Virtually no fast blue-labelled GFAP-positive astroglial cells migrated out of the implant into the adjacent host spinal cord. The presence of transplanted neonatal astroglial cells resulted in a significant increase in the number of ingrowing neurofilament-positive fibers (including anterogradely labeled corticospinal axons) into the implant. Ingrowing fibers were closely associated with the transplanted astroglial cells. The implantation of neonatal astroglial cells did result in modest temporary improvements of locomotor recovery as observed during open-field locomotion analysis (BBB subscore) or during crossing of a walkway (catwalk).

Neurobiology of human neurons (NT2N) grafted into mouse spinal cord: implications for improving therapy of spinal cord injury

Emerging data suggest that current strategies for the treatment of spinal cord injury might be improved or augmented by spinal cord grafts of neural cells, and it is possible that grafted neurons might have therapeutic potential. Thus, here we have summarized recent studies of the neurobiology of clonal human (NT2N) neurons grafted into spinal cord of immunodeficient athymic nude mice. Postmitotic human NT2N neurons derived in vitro from an embryonal carcinoma cell line (NT2) were transplanted into spinal cord of neonatal, adolescent and adult nude mice where they became integrated into the host gray and white matter, did not migrate from the graft site, and survived for > 15 months after implantation. The neuronal phenotype of the grafted NT2N cells was similar in gray and white matter regardless of host age at implantation, and some of the processes extended by the transplanted NT2N neurons became ensheathed by oligodendrocytes. However, there were consistent differences between NT2N processes traversing white versus gray matter. Most notably, NT2N processes with a trajectory in white matter extended over much longer distances (some for > 2 cm) than those confined to gray matter. Thus, NT2N neurons grafted into spinal cord of nude mice integrated into gray as well as white matter, where they exhibited and maintained the morphological and molecular phenotype of mature neurons for > 15 months after implantation. Also, the processes extended by grafted NT2N neurons differentially responded to cues restricted to gray versus white matter. Further insight into the neurobiology of grafted human NT2N neurons in the normal and injured spinal cord of experimental animals may lead to novel and more effective strategies for the treatment of spinal cord injury.

Differential effects of spinal cord gray and white matter on process outgrowth from grafted human NTERA2 neurons (NT2N, hNT)

To investigate host effects on grafts of pure, postmitotic, human neurons, we assessed the morphologic and molecular phenotype of purified NTera2N (NT2N, hNT) neurons implanted into the spinal cord of athymic nude mice. NT2N neurons were implanted into both spinal cord gray matter and white matter of neonatal, adolescent, and adult mice and were evaluated at postimplantation times up to 15 months. NT2N neurons remained at the implantation site and showed process integration into all host areas, and each graft exhibited similar phenotypic features regardless of location or host age at implantation. Evidence of host oligodendrocyte ensheathment of NT2N neuronal processes was seen, and grafted NT2N neurons acquired and maintained the morphologic and molecular phenotype of mature neurons. The microenvironments of host gray matter and white matter appear to exert differential effects on implanted neuronal processes, because consistent differences were noted in the morphologies of graft processes extending into white matter versus gray matter. NT2N processes extended for long distances (>2 cm) within white matter, whereas NT2N processes located within gray matter had shorter trajectories. This suggests that NT2N neurons integrate similarly into spinal cord gray matter and white matter, but they extend processes that respond differentially to gray matter and white matter cues. Further studies of the model system described here may identify the host molecular signals that support and direct integration of grafted human neurons as well as the outgrowth of their processes in the nervous system.

Corticospinal tract regrowth

The natural ability of the adult central nervous system of higher vertebrates to recover from injury is highly limited. This limitation is most likely due to an inhospitable environment and/or intrinsic incapacities of the neurons to re-extend their neurites after injury or axotomy. The rat corticospinal tract is the largest tract leading from brain to spinal cord and is often used as a model in developmental and regeneration studies. The extensive know-how of factors involved in the development of the corticospinal tract did provide the foundation for many studies on corticospinal tract regrowth after injury in the adult spinal cord. The results of these experiments, as discussed in this review, have led to important contributions to the further understanding of central nervous system regeneration.

Glial and endothelial cell response to a fetal transplant of purified neurons

Astrocytes, microglia and endothelial cells display very specific phenotypic characteristics in the intact adult CNS, which appear quite versatile when grown in culture without neurons. Indirect evidence from in vitro co-culture studies and analysis of the effects of specific neuronal removal in vivo, does accordingly favour a role of neurons for the phenotypic repression of these cells in the intact brain. In order to provide more direct evidence for such neuronal influence, we attempted to induce, in the rat brain, a reversal of the post-lesional activation of astrocytes, microglia and endothelial cells by transplantation of fetal neurons purified by immunopanning. Host microglial cells which have been activated by the lesion process, penetrated the neuronal graft during the few days after the transplantation. Reactive astrocytes began to appear in the lesioned parenchyma and gathered around the transplant. Thereafter they first sent their processes in the direction of the neuronal graft, before they migrated into the graft a few days later. At this time, which was at the end of the first week post-transplantation, the host endothelial cells sprouted "streamers" of basal lamina within the graft forming small capillaries. During the second week post-transplantation, numerous astrocytes and microglial cells, both displaying a reactive hypertrophied morphology, were observed throughout the grafts. Finally, by the end of the first month, the activated cells differentiated towards a quiescent, resting morphology. At this time the grafts contained a vascular network with morphological characteristics comparable to those observed in the intact brain parenchyma. The results indicate that the interaction of activated astroglia and microglia and endothelial cells with neurons causes the cells to re-differentiate and regain phenotypic features characteristic of intact brain parenchyma, strongly suggesting that neurons play an essential role in the phenotypic restriction of glial and endothelial cells in the adult central nervous system.

Implantation of cultured human leptomeningeal cells into rat brain

Since previous studies have shown that cells cultured from human leptomeninges can express neuronal and glial antigens under appropriate culture conditions [DeGiorgio L. A. et al. (1994) J. Neurol. Sci. 124, 141 148; Bernstein J. J. et al. (1996) Int. J. Derl Neurosci. 14(5), 681 687], we have studied the developmental characteristics of these cells further by grafting them into young adult rat brains. Cells were labeled in culture with Fast Blue and were identified unequivocally by hybridization with nick-translated human DNA. Intensely Fast Blue positive human leptomeningeal cells were concentrated in the implant pocket and adjacent rat leptomeninges al one and two weeks postimplant. Human and rat leptomeningeal cells were similar morphologically and were equally immunopositive for vimentin and fibronectin. Implanted human cells did not express the neuronal and glial proteins they had in vitro. Cells which hybridized with human DNA corresponded to the intensely Fast Blue positive cells. Small groups of human DNA hybridizing cells were also observed in the choroid plexus. Less intensely Fast Blue positive neurons and glia were found in the brain but these hybridized with rat DNA. A minority of human leptomeningeal cells implanted into rat brain are subsequently found in host leptomeninges where they demonstrate properties characteristic of leptomeningeal fibroblasts. Small numbers of implanted cells can survive for two weeks.

Human leptomeningeal-derived cells express GFAP and HLADR when grafted into rat spinal cord

The following series of experiments explores the post-xenografting differentiation of a naturally occurring, non-neuronal cell cultured from the leptomeninges of an 84-year-old woman. In culture, flat process-bearing human cells from the leptomeninges were positive for GFAP and 200 kDa neurofilament protein (negative for 68, 160 kDa neurofilament protein). The C3 spinal cord was exposed in 30 adult athymic rats. The hindlimb dorsal columns were transected at C3 and the nerve fibers aspirated to form a pocket, into which 10(6) fast blue-labeled, human leptomeningeal-derived cells were placed. The C3 spinal cord was studied immunohistochemically over 60 days. Three days later the dorsal horn contained fast blue-GFAP-positive astrocyte-like cells that were negative for neurofilament protein. By 7 days, large, process-bearing, fast blue-GFAP-positive (neurofilament protein-negative), astrocyte-like cells joined the native astrocytes of the pia-glia membrane and were in the gray matter of the spinal cord. Some of these astrocyte-like cells were also positive for the human specific histocompatibility complex, HLADR. These data extend the age, species and tissue of origin for pluripotential cells for CNS transplantation.

Effects of astrocyte implantation into the hemisected adult rat spinal cord

Morphological and biochemical methods were applied to assess the effects of implanting cultured astrocytes into the hemisected adult rat spinal cord. Astrocytes were purified from neonatal rat cortex and introduced into the lesioned spinal cord either in suspension injection or cultured on gelfoam first. The control groups were rats which had hemisection with injection of culture media or with gelfoam grafted alone. At various time points after surgery (two weeks to two months), the spinal cord was removed and processed for routine light microscopy, immunofluorescence, gel electrophoresis and immunoblotting. As early as two weeks after surgery, a significantly smaller volume of scar tissue was consistently found in the experimental groups. This reduced scarring was also confirmed by immunofluorescence staining and immunoblotting for glial fibrillary acidic protein in the specimens two months after hemisection. Compared to the control groups, the experimental groups also had more intense staining for neurofilaments, which was confirmed by immunoblotting. However, labelling of the astrocytes with Phaseolus vulgaris leucoagglutinin conjugated with fluorescein showed that the astrocytes migrated at a rate of 0.6 mm/day from the original implanted site. The results therefore suggested that the cultured astrocytes probably exerted their effects over a short time period (less than two weeks) around the lesion site. They could have altered the microenvironment and as a result less scar tissue was formed. Hence, there was less barrier to the regrowth of nerve fibres.

Migration of genetically labeled glioma cells after implantation into murine brain

Murine RSV-M glioma cells were genetically labeled with a retroviral BAG vector carrying the Escherichia coli beta-galactosidase gene. The X-gal-positive stable cell line RSV-M/BAG was obtained by the FDG-FACS method. To examine the behavior of glioma cells in the brain, we homografted RSV-M/BAG cells into the brain of C3H/HeN mice as cell suspensions. Individual grafted glioma cells were easily detected by histochemical staining for B-galactosidase (beta-gal). Three days after grafting, the beta-gal-positive cells were mainly found in the subependymal zone of the lateral ventricle. In addition, some solitary labeled cells were found at locations distant from the injection sites. On the seventh day after implantation, tumor masses were observed and graft-derived glioma cells were migrating bilaterally along the fibers in the corpus callosum. Other labeled cells extended into the brain parenchyma via the perivascular (Virchow-Robin) spaces. Rapid and extensive migration of individual glioma cells was thus clearly demonstrated by intracerebral transplantation of RSV-M/BAG cells.

Astrocytes: form, functions, and roles in disease

Astrocytes, once relegated to a mere supportive role in the central nervous system, are now recognized as a heterogeneous class of cells with many important and diverse functions. Major astrocyte functions can be grouped into three categories: guidance and support of neuronal migration during development, maintenance of the neural microenvironment, and modulation of immune reactions by serving as antigen-presenting cells. The concept of astrocytic heterogeneity is critical to understanding the functions and reactions of these cells in disease. Astrocytes from different regions of the brain have diverse biochemical characteristics and may respond in different ways to a variety of injuries. Astrocytic swelling and hypertrophy-hyperplasia are two common reactions to injury. This review covers the morphologic and pathophysiologic findings, time course, and determinants of these two responses. In addition to these common reactions, astrocytes may play a primary role in certain diseases, including epilepsy, neurological dysfunction in liver disease, neurodegenerative disorders such as Parkinson's and Huntington's diseases, and demyelination. Evidence supporting primary involvement of astrocytes in these diseases will be considered.

Differential migration of astrocytes grafted into the developing rat brain

Fetal and neonatal astrocytes migrate in specific patterns when transplanted into the adult rat host brain. However, it is unclear whether these astrocytes demonstrate the same degree of mobility during early brain development. In the present study, neonatal cortical, hippocampal, and hypothalamic astrocytes were collected from the brains of 1- to 3-day-old rats and placed in tissue culture. After 14 to 21 days, cultures enriched in astrocytes were harvested and labelled with either the fluorescent dye Fast Blue or fluorescein-labelled latex beads. They were then transplanted into the right frontal cerebrum of neonatal rats at 2, 5, 8, and 11 days postpartum. Seven days after transplantation, animals were sacrificed and their brains were fixed by immersion in aldehydes, sectioned on a cryostat, and examined with fluorescence microscopy. Transplanted astrocytes migrated along the corpus callosum, internal capsule, glial limitans, ventricular linings, and hippocampal structure. Labelled cells were also found in the contralateral hemisphere in day 2 brains. Migration in a radial fashion from the injection site toward the periphery was a particularly obvious pattern, and was most pronounced in these younger hosts. In days 5 and 8 rat brains, astrocyte migration became more restricted to the hemisphere of implantation. In 11-day-old host brains, hemispheric restriction and other region-specific influences became manifest and specifically modulated migration. Radial migration was absent in the 11-day-old host group except for cells of cortical origin. The observed results demonstrate that neonatal cortical, hippocampal, and hypothalamic astrocytes transplanted into the neonatal cerebrum migrate in patterns that are more extensive than in the adult brain.(ABSTRACT TRUNCATED AT 250 WORDS)

Migration and differentiation of PC12 cells transplanted into the rat spinal cord

To test the hypothesis that transplanted neuronal or neuronal-like cell lines, grown in vitro, might survive and differentiate in the mammalian spinal grey matter, adult male Sprague-Dawley rats (N = 5) were injected with a suspension of between 3 x 10(5) and 1.0 x 10(6) DiI labeled, undifferentiated rat pheochromocytoma (PC12) cells in sterile phosphate buffered saline. The PC12 cell line was chosen since, in certain in vitro conditions, this cell line serves as a model of neuronal differentiation, which includes the ability to conduct action potentials and form functional synapses. After a survival time of 7 or 8 days, the spinal cords were removed, cryosectioned longitudinally and examined for detection of DiI labeled PC12 cells using fluorescent microscopy. The number of DiI labeled profiles and the proportions of the DiI cells which were differentiated were counted per section in at least five non-contiguous sections per animal. Differentiation was defined as cells with neurite-like extension which exceeded twice the soma diameter. Results demonstrated the following: (1) from 2 to 15% of the transplanted PC12 cells survived; (2) migration within the spinal grey matter occurred since PC12 cells were found as much as 510 microns away from the injection site; (3) of the surviving PC12 cell population, a proportion of between 60 and 80% were differentiated, many with two or more neurite-like processes, in all of the rats; (4) no mitotic profiles were observed in DiI labelled cells; (5) undifferentiated PC12 cells were juxtaposed to the lumens of small blood vessels or within the lesion cavity. Although the specific factors remain to be elucidated, the observed PC12 migration and differentiation within the host spinal grey matter appears to be controlled by factors in the microenvironment. These data support the use of a homogeneous in vitro population of neuronal or neuronal-like cells, which are readily accessible to transfection with the appropriate genes, as transplant sources for the injured spinal cord.

Directed migration of transplanted glial cells toward a spinal cord demyelinating lesion

To investigate the migration of transplanted glial cells in normal adult mice with a focal demyelinating lesion, we have used A2G mice which have the autosomal dominant Mx-1 allele as donor. Mx-1 protein expression is inducible by interferon and is detected in a dotted pattern in the nucleus of A2G cells. A/J mice were used as recipient animals as they express the same major histocompatibility antigens as A2G but cannot express the Mx-1 protein. An acute demyelinating lesion was produced in the A/J spinal cord by intraspinal injection of lysolecithin. Mixed glial cultures derived from newborn A2G brain were treated with alpha/beta interferon for 24 hr. These Mx-1 expressing glial cells were then transplanted two intervertebral spaces away from the demyelinating lesion. The fate of the grafted cells was followed over the next 13 days, during which the induced Mx-1 protein can still be detected by immunocytochemistry. Grafted cells were found between the transplantation site and the lesion at 24 hr and some of the Mx-1+ cells reached the lesion at 4 days. The majority of the Mx-1+ migrating cells expressed GFAP and were located in the myelinated white matter and around the blood vessels. Scattered MBP+, Mx-1+ cells were detected in the lesion indicating that some of the transplanted cells may participate in the repair process. The Mx-1 is a useful marker to follow the migration events in the days after grafting and to determined what factors may attract transplanted cells toward a demyelinating lesion.

The migration of astrocytes after implantation to immature brains

Using a species-specific marker, we have found that astrocytes, taken from donors of varying ages from fetal to adult, migrate in highly stereotypic patterns in immature host brains. Migration is primarily within and towards cell layers, although some cells are seen to migrate along fibre bundles. This contrasts with studies using the same approach in mature hosts, where migration is predominantly within fibre layers, largely excluding cellular regions.

Transplantation of cultured type 1 astrocyte cell suspensions into young, adult and aged rat cortex: cell migration and survival

The present study examined the fate and migration of transplanted astrocytes in different host ages. Additionally, the effect of donor cell age was examined in relation to cell migration. Cultured astrocytes from 5, 12 and 30 days in vitro were transplanted into young (postnatal day 5 and 21), adult (4.5 month), and aged (21 month) animals. The transplanted cells were labeled with Fast Blue, Fluorogold or DiI. The results confirmed previous studies demonstrating that transplanted cells were able to migrate successfully through host central nervous system and extended those findings to show that the age of the host significantly influenced donor cell migration distance. Migration was most extensive in young animals, as conditions supporting cell migration appeared to be lacking in older animals. Donor cells preferentially migrated on myelinated fiber tracts, rather than on unmyelinated fiber tracts or gray matter. The donor cells were not glial fibrillary acidic protein positive, indicating that either the cultured type 1 astrocytes did not survive transplantation or underwent significant remodeling of the intermediate filament network. It is also possible that a subpopulation of cells, possibly immature astrocytes which are present in the transplanted cell suspensions, flourished and subsequently migrated in the host brains.

In vitro differentiation inhibits the migration of cultured neonatal rat cortical astrocytes transplanted to the neonatal rat cerebrum

Neonatal rat astrocytes transplanted into the rat cerebrum migrate extensively. However, few of the molecular signals determining this migration have been defined. In the present study, in vitro modifications were designed to examine whether differentiation prior to transplantation would affect the magnitude or pattern of astrocyte migration in the neonatal host brain. Here, cortical astrocytes were collected from the brains of rats 1-3 days postpartum and purified by culturing them in DME medium supplemented with 10% calf serum. After 14-21 days, astrocytes were labelled with fluorescein-tagged latex microspheres for 16 hr; the label was then removed and replaced with either fresh medium or fresh serum-free medium plus 1 mM dbcAMP. After 48 hr, cells were harvested and then transplanted into the right frontal cerebrum of neonatal rats at 3 days postpartum by injection with a hand-held Hamilton syringe. Animals were sacrificed at 3, 6, 9, 15, 21 and 28 days after inoculation and their brains examined with fluorescence microscopy. Astrocytes not exposed to dbcAMP prior to implantation migrated along the corpus callosum, internal capsule, glial limitans, ventricular linings and the hippocampal structure. They also appeared to migrate in a radial fashion toward the periphery from the ventricular lining. Astrocytes treated with dbcAMP prior to transplantation did not appear to migrate into the neonatal parenchyma, remaining confined to the injection site for at least 6 days. Migration then appeared to commence at a normal rate after 9 days. Thus, neonatal cortical migrate outward in a pattern similar to that defined by the radial glia. Astrocytes differentiated by dbcAMP treatment, however, do not appear to migrate to any large degree in the neonatal brain until the treatment effect diminishes, suggesting that differentiation may represent an end-point to glial migration in the neonatal host brain.

Native astrocytes do not migrate de novo or after local trauma

While transplanted astrocytes migrate in specific patterns in the recipient brains, it is not known whether native astrocytes behave similarly. The ability of normal astrocytes to migrate under non-transplant conditions was therefore explored. Native astrocytes were labelled in situ with fluorescent latex beads. These latex spheres were actively endocytosed by astrocytes in vitro, and it was therefore anticipated that these spheres would also be endocytosed by native astrocytes exposed to them. Labelling was accomplished by dissecting the pia mater away from a small region of the cerebral cortex and overlaying the area with Gelfoam containing fluorescent beads. After 2-4 h, the Gelfoam was removed and the wound was closed. At the end of 2-4 weeks, manipulated brains were harvested for fluorescence microscopy. In this analysis, fluorescent polyspheres had been taken up by both pial fibroblasts and astrocytes at the pial-glial margin. Labelled astrocytes [identified by glial fibrillary acidic protein (GFAP) staining] were neither hyperplastic nor hypertrophic. They were confined to the area of the original labelling site, and did not migrate either laterally across the pial margin or ventrally into the cortical layers. Knife wounding at the time of label application, either in the region of the label or distant from it, produced reactive astrocytes that were hypertrophic. These cells also did not migrate from the label site. These results suggest that astrocytes labelled by this method do not migrate in the absence of some transplant-derived stimulus even when stimulated by local wounding.

Pathways of migration of transplanted Schwann cells in the demyelinated mouse spinal cord

We have studied the behavior of Schwann cells transplanted at a distance from an induced myelin lesion of the adult mouse spinal cord. These transplanted cells were mouse Schwann cells arising from an immortalized cell line (MSC80) which expresses several Schwann cell phenotypes including the ability to produce myelin. The behavior of MSC80 cells was compared to that of purified rat Schwann cells transplanted in the same conditions. Schwann cells were labeled in vitro with the nuclear fluorochrome Hoechst 33342 and were transplanted at distances of 2-8 mm from a lysolecithin-induced myelin lesion in the spinal cord of shiverer and normal mice. Our results show that transplanted MSC80 cells migrated toward the lesion, in both shiverer and normal mouse spinal cord, preferentially along the ependyma, meninges, and blood vessels. They also migrated along white matter tracts but traveled a longer distance in shiverer (8 mm) than in normal (2-3 mm) white matter. Using these different pathways, MSC80 cells arrived within the lesion of shiverer and normal mouse spinal cord at the average speed of 166 microns/hr (8 mm/48 hr). Migration was most efficient along the ependyma and the meninges where it attained up to 250 microns/hr. Migration was much slower in white matter tracts (95 microns/hr +/- 54 in the shiverer and only 38 microns/hr +/- 3 in the normal mouse). We also provide evidence for the specific attraction of MSC80 cells by the lysolecithin-induced lesion since 1) their number increased progressively with time in the lesion, and 2) MSC80 cells left their preferential pathways of migration specifically at the level of the lesion. Finally, combining the Hoechst Schwann cell labeling method with the immunohistochemical detection of the peripheral myelin protein, P0, we show that some of the MSC80 cells which have reached the lesion participate in myelin repair in both shiverer and normal lesioned mouse spinal cord. A series of control experiments performed with rat Schwann cells indicate that the migrating behavior of transplanted MSC80 cells was identical to that of purified but non-immortalized rat Schwann cells.

The reconstruction of an astrocytic environment in glia-deficient areas of white matter

Injection of ethidium bromide into X-irradiated spinal cord white matter produces a lesion in which demyelinated axons reside in an environment that is permanently depleted of glial cells. By transplanting defined populations of glial cells into this lesion it is possible to recreate normal or novel glial environments. In this study we have transplanted cultures of astrocytes into the X-irradiated ethidium bromide lesion in order to (1) assess the ability of these cells to relate to components within the lesion environment and thereby contribute to tissue reconstruction and (2) establish an astrocytic environment around demyelinated axons that resembles pathological states such as the chronic demyelinated plaques of multiple sclerosis. In order to focus attention on the interactions between astrocytes and demyelinated axons we developed a protocol for depleting astrocyte cultures of oligodendrocyte lineage cells and Schwann cells based on complement-mediated immunocytolysis and in vitro X-irradiation. In addition to establishing the ability of transplanted astrocytes to form an astrocytic matrix around demyelinated axons, this study has also revealed the diversity of cell types present within neonatal forebrain cultures.

In vitro labeling strategies for identifying primary neural tissue and a neuronal cell line after transplantation in the CNS

Potential labels for identifying embryonic raphe neurons and a clonal, neuronally differentiating, raphe-derived cell line, RN33B, in CNS transplantation studies were tested by first characterizing the labels in vitro. The labels that were tested included 4',6-diamidino-2-phenylindole hydrochloride, 1,1'-dioctadecyl-3,3,3'-tetramethylindocarbocyanine perchlorate, the Escherichia coli lacZ gene, Fast Blue, Fluoro-Gold, fluorescein-conjugated latex microspheres, fluorescein isothiocyanate-conjugated or nonconjugated Phaseolus vulgaris leucoagglutinin, methyl o-(6-amino-3'-imino-3H-xanthen-9-yl) benzoate monohydrochloride, or tetanus toxin C fragment. Subsequently, the optimal in vitro labels for embryonic raphe neurons and for RN33B cells were characterized in vivo after CNS transplantation. In vitro, 1,1'-dioctadecyl-3,3,3'-tetramethylindocarbocyanine perchlorate (DiI) optimally labeled embryonic neurons. The Escherichia coli lacZ gene optimally labeled RN33B cells. Most labels were rapidly diluted in cultures of embryonic astrocytes and proliferating RN33B cells. Some labels were toxic and were often retained in cellular debris. In vivo, DiI was visualized in transplanted, DiI-labeled raphe neurons, but not in astrocytes up to 1 mo posttransplant. DiI-labeled host cells were seen after transplantation of lysed, DiI-labeled cells. beta-Galactosidase was visualized in transplanted, Escherichia coli lacZ gene-labeled RN33B cells after 15 days in vivo. No beta-galactosidase was seen in host cells after transplantation of lysed, lacZ-labeled RN33B cells. The results demonstrate that labels for use in CNS transplantation studies should be optimized for the specific population of donor cells under study, with the initial step being characterization in vitro followed by in vivo analysis. Appropriate controls for false-positive labeling of host cells should always be assessed.

Human-specific c-neu proto-oncogene protein overexpression in human malignant astrocytomas before and after xenografting

Overexpression of human-specific c-neu proto-oncogene transmembrane tyrosine kinase receptor protein (p185) is an index of cell transformation and of poor patient survival in several malignancies. The authors studied this protein in low- and high-grade human malignant astrocytomas before and after xenografting into aspiration pockets in rat cortex. Human-specific p185c-neu-positive cells were found in tumor specimens from all grades of astrocytoma. Significantly fewer p185c-neu-positive cells were observed in the low-grade versus the high-grade astrocytomas examined (p < 0.05). Human specific p185c-neu-positive cells were also positive for the human major histocompatibility complex, human leukocyte antigen (HLA)-DR, as well as glial fibrillary acidic protein and S-100 protein. Fresh suspensions of tumor tissue were prelabeled with the plant lectin Phaseolus vulgaris leukoagglutinin and xenografted into pockets in rat cortex. A class of human p185c-neu-positive cells found in tissue samples from all grades of astrocytoma migrated in the rat brain along parallel and intersecting nerve fibre bundles and basement membrane-lined surfaces. Migrated p185c-neu-positive cells were also positive for HLA-DR, Phaseolus vulgaris leukoagglutinin, glial fibrillary acidic protein, and S-100 protein, suggesting that they were in fact human astrocytoma cells. Simultaneous expression of human p185c-neu, HLA-DR, and glial fibrillary acidic protein was observed in a class of human malignant astrocytoma cells in both tumor tissue and xenografted cells that migrated into rat brain. These molecules are signature proteins for the study of the spread of human malignant astrocytomas in an animal model, and indicate that transformed human malignant astrocytoma cells can migrate within the parenchyma of the central nervous system and could play a role in the development of multifocal tumors.

Mechanisms of C6 glioma cell and fetal astrocyte migration into hydrated collagen I gels

Fetal basal ganglia astrocytes and C6 glioma cells were plated on the surface of 1.5 cm thick hydrated collagen I wafers. Both cell types migrated through the entire thickness of the wafer within 1 day after plating. The collagen in the wafer was digested and the fine collagen I fibrils were clumped into large strands. By 2-3 days, the collagen strands were digested from the wafers and replaced by a mass of fetal astrocytes or C6 cells joined by their processes. The collagen I digestion and cell migration suggested protease production. In a second series of experiments, cultured C6 cells and E14 fetal astrocytes were immunohistochemically stained for the presence of plasminogen activators as an index of protease production. Both tissue (tPA) and urokinase (uPA) types were observed. Fetal astrocytes and C6 cells were also positive for guanidinobenzoatase, a serine protease associated with migrating cells. These data demonstrate that rapid migration of the cells on and through collagen I fibrils is concomitant with expression of plasminogen activators and proteases which can either activate or function as collagenases and release the cells from the substrate.

Migration of astrocytes transplanted to the midbrain of neonatal rats

Previous studies have indicated that transplanted astrocytes are able to survive, express glial fibrillary acidic protein (GFAP), and migrate in the host brain, and that the pattern and speed of astrocyte migration is largely determined by the location of the graft. We examine here the pattern of astrocyte migration in the midbrain by transplanting CD-1 mouse corpus callosum (P2-3) into the midbrain of neonatal rats. The location of the grafts and the distribution of donor astrocytes were assessed by using a monoclonal antibody (anti-M2) specific for mouse astrocytes. A characteristic donor astrocyte distribution was seen. The highest density of cells was in the region of the substantia nigra (SN); lower numbers were found in the medial geniculate nucleus (MGN). Donor astrocytes were also found in the superior colliculus (SC) and central gray region, but only when the body of a graft was located nearby. [3H]thymidine studies showed that the concentrations of donor astrocytes in the SN were not the result of high levels of mitotic activity: all indications were that the proportion of dividing donor cells closely matched that of host glia. The pattern of astrocyte migration in the midbrain did not follow the course established by radial glia and was not influenced by axonal degeneration in the SC after removal of eyes. Moreover, donor cells failed to migrate along the course of axonal outgrowth from co-grafted retinae. Reciprocally, axonal elongation from retinal grafts did not follow the pathway of astrocyte migration, thus suggesting that astrocyte migration and neuronal outgrowth follow different cues.

Survival and migration of transplanted male glia in adult female mouse brains monitored by a Y-chromosome-specific probe

A Y-chromosome-specific probe and in situ hybridization technology have been used to monitor the survival and migration of neonatal male glia isografted to the left cerebral hemisphere of adult female mice. More than 95% of the cultured donor glia were glial fibrillary acidic protein (GFAP)-positive astrocytes. By 4 weeks, large numbers of transplanted glia were found in both cerebral hemispheres; the extent of glial migration was greatest in white matter tracts. This method provides a new way of identifying all surviving donor cells within the brains of immunologically compatible hosts.

Neonatal host astrocyte migration into xenogeneic cerebral cortical grafts

Migration of host astrocytes into grafts was investigated by transplantation of rat cortex (E16) into the cortex or midbrain of neonatal mice. Host astrocytes, visualized by the mouse astrocyte-specific antibody, began to invade the grafted cortex during the first week post-transplantation and sequentially migrated substantial distances throughout the graft. Host cells in the grafts which were undergoing immune rejection became hypertrophic. These results have important implications when assessing interactions between host and graft cells.

Migration of grafted rat astrocytes: dependence on source/target organ

Neonatal rat cortical astrocytes migrate extensively after transplantation into the brains of adult hosts. However, the effects of cues provided by different sources of donor astrocytes and by different target sites of implantation on this migration is unknown. In order to investigate the significance of regional influences on glial migration, we established primary cultures of astrocytes derived from 1-3 day old rat cerebral cortex, hippocampus, and hypothalamus. After in vitro labelling with either Fast Blue or fluorescein-labelled latex beads, these astrocytes were inoculated into different target regions of the adult rat brain by stereotaxic injection with a Hamilton syringe. Astrocytes implanted into the cerebral cortex migrated extensively throughout the adult brain regardless of their donor source. These implanted cells were intimately associated with the ventricular wall, glial limitans, vasculature, and fiber bundles. Astrocytes homografted into the hippocampus and the hypothalamus migrated primarily within and around the respective homotopic target organs. Migration of astrocytes derived from cerebral cortex was also limited when injections were made into these two regions. In these latter cases, migration appeared to be less guided by other cellular or regional cues than was migration after implantation into the cerebral cortex. These results suggest that the migration patterns of astrocytes grafted after tissue culture are more dependent on the target implantation site than on the donor organ.

Migration patterns of donor astrocytes after reciprocal striatum-cerebellum transplantation into newborn hosts

Fragments of striatum or cerebellum from E 25 rabbit embryo were implanted into either the striatum or the mesencephalon of newborn mice. Implanted rabbit astrocytes were selectively identified by monoclonal antibodies to the GFAP which are unable to combine with mouse GFAP. Previous investigations had shown that xenogenic astrocytes have the capacity to migrate in host CNS. The purpose of this study was to compare the patterns of migration of transplant-derived astroglial cells according to the topographic origin of the transplant and location of the grafting site. We found that the migration pattern of the grafted cells from any of both selected sites of implantation was independent from the topographic origin of the transplant. The routes as well as the distances of migration were similar after homo- or heterotopic transplantation. We conclude that astroglial cells or their precursors do not express information which would direct them to move specifically toward a defined region in the host brain according to the region of origin in the donor.

Astrocytes colonize dorsal root ganglia transplanted into rat brain

Fragments of dorsal root ganglia (DRG) were grafted into rat brain and examined one month later. The autografts were similar to their normal counterparts when stained with toluidine blue or by indirect immunofluorescence with laminin and neurofilament antibodies. However, a major difference was observed with antibodies to the glial fibrillary acidic protein (GFAP). Normal DRG were GFAP-negative while the autografts were intensely and diffusely stained. The GFAP antibodies used in this study did not decorate Schwann cells or satellite cells in peripheral nerve and DRG, and thus appeared to recognize the "central" form of GFAP (17). Thus reactive astrocytes appear to be capable of migration into grafted nervous tissues without producing apparent neuronal damage.

Individual C6 glioma cells migrate in adult rat brain after neural homografting

Cultured C6 glioma cells were prelabeled with the plant lectin Phaseolus vulgaris leuco-agglutinin (PHAL) and grafted as a cell suspension (10(6) cells in 5.0 microliters) into freshly made cortical implantation pockets in adult host rats. Animals were killed 1-21 days post-implantation (DPI). The brains were removed, dehydrated, embedded in paraffin and sectioned at 8 microns. Paraffin sections were processed for light level immunofluorescent double labeling for PHAL, a marker for graft derived cells, and glial fibrillary acidic protein (GFAP), a specific marker for C6 glioma cells and astrocytes. Cells positive for both PHAL and GFAP were graft-derived C6 cells. By 7 DPI a large mass developed which extended above the surface of the brain and invaded (displacement of host tissue by a cell mass) the host parenchyma. This mass increased in size over the next 14 days. The invading tumor mass contained double labeled cells at all time periods examined. In addition to the invasion process, grafted C6 cells spread through the host parenchyma by migration (movement of single cells). Individual graft-derived C6 (GFAP/PHAL positive) cells migrated into host cortex surrounding the implantation pocket, corpus callosum ventral to the implantation pocket, ipsilateral internal capsule and bilaterally in the habenula.

Remyelination of demyelinated rat axons by transplanted mouse oligodendrocytes

The injection of the gliotoxic agent ethidium bromide (EB) into spinal white matter produces a CNS lesion in which it is possible to investigate the ability of transplanted glial cells to reconstruct a glial environment around demyelinated axons. This study demonstrates that transplanted mouse glial cells can repopulate EB lesions in rats provided tissue rejection is controlled. In X-irradiated EB lesions in cyclosporin-A-treated rats, mouse oligodendrocytes remyelinated rat axons and, together with mouse astrocytes, re-established a CNS environment. When transplanted into nonirradiated EB lesions in nude rats, mouse glial cells modulated the normal host repair by Schwann cells to remyelination by oligodendrocytes. In both X-irradiated and non-irradiated EB lesions, transplanted mouse glial cells behaved similarly to isogenic rat glial cell transplants (Blakemore and Crang Dev Neurosci, 1988;10:1-10; J Neurocytol, 1989;18:519-528). These findings indicate that the cell-cell interactions involved in reconstruction of a glial environment are common to both mouse and rat.

A nuclear marker for mammalian cells and its use with intracerebral transplants

The Hoechst dye staining method has been successfully applied to the central nervous system in mammals and its use has been demonstrated in intracerebral transplantation. The technique is rapid, simple and based on intrinsic nuclear properties. It was found to be permanent and valid whatever the animal strains or ages, allowing the distinction of rat cells from those of mouse, studied either separately or in a cross-transplantation model. It permitted the detection of grafted cells in the area of transplantation and the observation of early dispersion around the implantation site. Moreover, it can be combined with immunohistochemistry as demonstrated by a myelin marker in a relevant model. Immunodetection can thus help to directly observe grafted cells, at distance from the locus of transplantation, confirming their presence in the graft-type myelin patches. Because of its rapid performance, this technique can be used systematically after transplantation to check for the presence of grafted cells in the host.

Age-related decrease in sympathetic sprouting is primarily due to decreased target receptivity: implications for understanding brain aging

Aging of the nervous system is characterized by reduced anatomical plasticity. The cause of this decreased plasticity is not known because it is usually not possible to distinguish between extrinsic and intrinsic factors that affect neuronal growth. One example of age-related reduced neuronal plasticity that is amendable to such analysis is the growth of sympathetic axons into the rat hippocampal formation following septal denervation. This sprouting response can be elicited throughout the lifespan of the rat but is drastically reduced in aged animals. The age-related reduction in ingrowth could theoretically be due to decreased receptivity of the target (reduced trophic support or increased inhibition of growth), decreased responsivity of the sympathetic neurons or a combination of both factors. In order to test the relative contributions of the age of the target tissue and the age of the sympathetic neurons to the reduced growth observed in aged animals, superior cervical ganglia were transplanted from young animals into old animals (y/o) and from old animals into young animals (o/y) as well as autologously within the same animals (y/y and o/o). The extent of sympathetic ingrowth and the survival of transplanted neurons were assessed with fluorescence histochemical methods. The extent of ingrowth was significantly greater in young hosts compared with old hosts regardless of the age of the donor. In addition, the survival of transplanted neurons was greater in younger hosts than in aged hosts regardless of donor age. These results indicate that sympathetic ingrowth is reduced in aging primarily because of decreased receptivity of the hippocampal target tissue.

Embryonic motoneurons grafted into the adult CNS can differentiate and migrate

Embryonic mouse motoneurons were labelled by retrograde transport with a fluorescent dye (diI), partially purified on a density gradient and grafted into adult mouse CNS for a maximum of 10 weeks. In both the spinal cord and striatum, a small number of fluorescently labelled motoneurons were found to survive as judged by their round, bright appearance and also to differentiate as assessed by their ability to extend neurites. The motoneurons travelled long distances in the spinal cord (2 mm) and in the brain (4 mm) in both white and grey matter.

Timing and patterns of astrocyte migration from xenogeneic transplants of the cortex and corpus callosum

The timing, pattern, and pathway of astrocyte migration were investigated in vivo by transplantation of CD-1 mouse cerebral cortex (E13-14) or corpus callosum (P2-3) into neonatal rat cortex. A monoclonal antibody specific for a mouse astrocyte surface antigen (M2) was used to identify the location of the grafts and the migrated donor astrocytes. Within the host cortex, astrocytes from cortical grafts began migration at post-transplantation day (PTD) 7. Over the next 4 days, the most distant displaced donor cells were found progressively further away from the grafts, migrating at a rate of about 220 microns/day. After PTD 11, the migration rate for the farthest displaced donor cells slowed to 25 microns/day, and the cells appeared to stop at about PTD 16 at a distance of 1,100 microns from the edge of the graft. Astrocytes had a faster migration speed in the white matter and covered a longer distance (5 mm) than those in the gray matter, extending on occasion into the contralateral hemisphere. The patterns of astrocyte migration differed depending on local cues around the transplant. Donor astrocytes that had been implanted into the host cortex migrated toward the host cortical surface, sometimes in several radial lines. Astrocytes from grafts, especially callosal grafts, placed in the subcortical white matter migrated along the host fiber tracts. Many astrocytes transplanted into the hippocampus formed laminar patterns close to the hippocampal neuronal layers. These results suggest that the direction, pattern, and speed of astrocyte migration are influenced by local substrates in the host brain.

Direct neuronal and macroglial versus indirect macrophagic labeling in transplants of fetal neural tissue incubated with gold particles

In a recent light microscopic study based on the transplantation of fetal cells previously incubated with gold-loaded Sendai viruses, S. C. Ardizzoni, A. Michaels, and G. W. Arendash (1988, Science 239: 635-637) proposed that fetal neurons could migrate out into an adult host brain. This result was puzzling in view of several previous contradictory studies, and the light microscopic identification of labeled cells as neurons could be questioned. The present study was therefore undertaken to replicate this study but using electron microscopy to definitely identify migrating gold-labeled elements. Analysis was performed in a model of thalamic transplantation in which previous labeling studies, using thymidine or horseradish peroxidase, had failed to demonstrate any neuronal migration. Gold particles combined with wheat germ agglutinin peroxidase were used to label the fetal tissue prior to transplantation. Fetal cells did incorporate the protein gold complex, and the gold particles were visualized in transplants up to at least 2.5 months after grafting. Electron microscopy analysis reveals that the gold particles are internalized and retained in the lysosomes of grafted neurons and glial cells. In no transplant could labeled grafted neurons be observed intermingled with host neurons, outside the limits of the transplant. In contrast, heavily labeled macrophages were observed surrounding the transplants and sometimes migrating away from the transplant-host interface into the host tissue. These macrophages, presumably of host origin, can be recognized at the light microscopic level by their yellowish staining, a cellular characteristic already noted by Ardizzoni et al. for gold-labeled migrating elements.

Rapid migration of grafted cortical astrocytes from suspension grafts placed in host thoracic spinal cord

The cerebral cortices from 14-day gestation rat embryos were prelabeled with Phaseolus vulgaris leucoagglutin (PHAL) and homografted as a cell suspension into host thoracic spinal cord. Animals were sacrificed at 7, 14, 21 and 30 days postimplantation (DPI). Paraffin sections of cervical, thoracic and lumbar spinal cord were double-labeled for the presence of glial fibrillary acidic protein (GFAP) a specific marker for astrocytes, and PHAL, utilized as a marker for graft-derived cells. PHAL-GFAP positive cells were found throughout the thoracic spinal cord at all time periods, indicating that grafted astrocytes migrated along all 3 axes of the host spinal cord (rostral-caudal, dorsal-ventral and left-right). At 30 DPI, graft-derived astrocytes were found in host cervical and lumbar spinal cord. There appeared to be a minimal delay in the onset of migration.

Implantation of rabbit embryo brain fragments into newborn mice: integration and survival of xenogeneic astrocytes

Brain fragments containing embryonic rabbit glia were implanted into the brains of newborn mice. The hosts developed an astroglial reaction around the transplants and along the needle tracks. Transplant-derived astrocytes were identified in the operated brain by their expression of rabbit GFAP. During the first few days post-implantation (PI) glial cells were exchanged between the transplant and the host. Less than 3 to 5 days PI, the transplant was extensively invaded by host astrocytes. Xenogeneic astroglial cells were first detected 10 days PI in the immediate proximity of the transplant. At 2 to 11 weeks, they could be detected either close to or at distance from the point of implantation. Most often, transplant-derived astrocytes presented a morphology similar to that of neighboring host astrocytes. Xenogeneic glial cells were found to participate in various types of astroglial features: sub-pial, pericapillary, fibrous, and protoplasmic. This morphological integration suggests that they are physiologically integrated, at least to a certain degree, in the host tissue. In spite of their integration into the host, xenogeneic astrocytes disappear after 3 months without signs of an inflammatory reaction.

Maintenance of host medullary nucleus gracilis neurons after C3 homografting of fetal spinal cord into host fasciculus gracilis

The fasciculus gracilis (FG) of the third cervical spinal cord segment (C3) of adult rats was aspirated and fresh whole pieces of rat 14-day gestation cervical spinal cord, prelabeled with Phaseolus vulgaris leucoagglutinin, immediately placed in the pocket of one-half the operates. One to three months later there were no transplant derived rostro-caudal nerve fibers in the C1 or C2 segment of the aspiration-only or aspiration-graft FG. However, the neurons of the nucleus gracilis of the host medulla of the aspiration-only group were significantly atrophied whereas the neurons of the aspiration-graft group were not statistically different from normal. There were normal numbers of neurons in all groups. Using immunohistochemical double labeling for prelabeled astrocytes with PHAL and GFAP, graft-derived astrocytes were found in the nucleus gracilis of the host medulla. These data indicate that the trophic action of spinal graft-derived astrocytes maintained neurons in the medulla of the host nucleus gracilis.

Human malignant astrocytoma xenografts migrate in rat brain: a model for central nervous system cancer research

Fresh cells from two grade 3 human malignant astrocytomas were prelabeled with Phaseolus vulgaris leucoagglutin (PHAL) and then xenografted into freshly made implantation pockets in rat host cerebral cortex. Animals were sacrificed at 7, 14, 21 days, and 1 month postimplantation (DPI). Paraffin sections were double-labeled for the presence of glial fibrillary acidic protein (GFAP), a specific marker for astrocytes and differentiated astrocytoma cells, and PHAL, utilized as a marker for graft-derived cells. Grafted human astrocytoma cells were found on the glia limitans along the entire circumference of the brain, in the corpus callosum, internal capsule, entopeduncular nucleus, optic tract, and median eminence. In addition, astrocytoma cells were observed in the cingulum, habenula, arcuate, and supraoptic nucleus. Astrocytoma cells entered the spaces of Virchow-Robin, and migrated along parenchymal blood vessels and between the ependymal and subependymal layers of the third and lateral ventricles. The corpus callosum was a major migration route for the astrocytoma cells. The presence of basal lamina or parallel nerve fiber bundles was a common factor for these migration routes. The migration of the human astrocytoma xenografted cells in the rat brain followed the spread of human malignant astrocytomas in the human brain and is a valuable basic science tool in brain cancer research.

Graft derived reafferentation of host spinal cord is not necessary for amelioration of lesion-induced deficits: possible role of migrating grafted astrocytes

The present study explores the ability of fetal spinal cord homografts into lesioned host C3 fasiculus gracilis to influence the expected deterioration of hindlimb performance following this lesion. Rats were trained to traverse a narrow platform for a water reward. Animals were ranked for hindlimb performance utilizing slips, recovery and manner of traversing the platform. After training the animals, numbers were recorded, laminectomy performed at C3 and subject fasiculus gracilis (FG) bilaterally aspirated. Half the subjects were randomly selected for implantation of two, one mm segments of 14 day gestation cervical spinal cord. Recorded lesion-only and lesion-transplanted animals were tested 21, 30, 45, 60 and 90 days later. C3 fetal transplants significantly decreased the severity of hindlimb deficit at 21 and 90 days postlesion (p less than 0.05). The C1-FG of both groups contained no nerve fibers. However, the host nucleus gracilis of lesion-transplant animals contained normal sizes and numbers of neurons whereas the lesion-only group did not. This neuronal maintenance may have been due to factor(s) secreted by transplant derived astrocytes which migrated at 0.72-0.76 mm/day and reside in the host nucleus gracilis.

Fetal cortical astrocytes migrate from cortical homografts throughout the host brain and over the glia limitans

The cerebral cortices from 14-day gestation rat embryos were prelabeled with Phaseolus vulgaris leucoagglutin (PHAL) and then homografted into freshly made implantation pockets in the host cerebral cortex. Animals were sacrificed at 30 and 60 days postimplantation (DPI). Paraffin sections were double labeled for the presence of glial fibrillary acidic protein (GFAP), a specific marker for astrocytes, and PHAL, utilized as a marker for transplant-derived cells. Transplant-derived astrocytes were found on the glia limitans along the entire circumference of the brain, in the hippocampal commissure, corpus callosum, internal capsule, entopeduncular nucleus, habenular commissure, brachium of the superior colliculus, optic tract, optic chiasm, and sensory root of the trigeminal nerve. Transplanted astrocytes entered the spaces of Virchow-Robin, and migrated along parenchymal blood vessels and between the ependymal and subependymal layers of the third and lateral ventricles. The presence of basal lamina or parallel nerve fiber bundles was a common factor for these migration routes.