Differences in host serotonin innervation of intrastriatal grafts are not determined by a glial scar or chondroitin sulfate proteoglycans

Serotoninergic (5-HT) neurons of adult recipients provide a much denser innervation of striatal than ventral mesencephalic grafts implanted into the neostriatum of the rat. Moreover, grafts from both brain regions are more innervated by host 5-HT axons after implantation in neonatal than adult hosts. To test the hypothesis that differences in glial scarring or expression of the growth inhibitory molecules, chondroitin sulfate proteoglycans (CSPG), be responsible for these differences in 5-HT innervation of neural grafts, we examined the 5-HT innervation, the astroglial reaction and the expression of CSPG in ventral mesencephalic grafts implanted into newborn (1-5 days old), juvenile (15 days old), or adult rats and in striatal grafts implanted in adult rats, using immunohistochemistry against 5-HT, glial fibrillary acidic protein (GFAP) and CSPG. Immunostaining for GFAP showed a stronger initial gliosis (1-10 days after grafting) in neonatal than adult recipients of mesencephalic grafts, but this gliosis subsided gradually at later time points. Nevertheless, a glial scar formed at the graft-host interface in both neonatal and adult recipients, 5-10 days after transplantation, although it decreased over a longer time course--up to 60 days--in adults. Immunostained astrocytes appeared first in the host brain tissue around the graft and then immunoreactive processes and perikarya gradually invaded the graft. Immunoreactivity for CSPG was similar in neonatal and adult hosts: it was strongly expressed inside the graft early after transplantation, and almost completely down-regulated at 60 days. The reaction of adult hosts to striatal and mesencephalic grafts was similar, although GFAP was more heterogeneously distributed and CSPG immunoreactivity remained in patches inside striatal grafts, even after 60 days. The 5-HT innervation of mesencephalic grafts was much denser after implantation in newborns than in adults. It was also stronger in striatal than in mesencephalic grafts implanted in adults. Thus, the presence of a glial scar or the expression of CSPG cannot totally account for the different degrees of 5-HT innervation in the various types of neural grafts.     

Embryonic mesencephalic and striatal co-grafts: development of grafted dopamine neurons and functional recovery

Previous neural grafting studies have shown that embryonic dopamine neurons survive transplantation into the parenchyma of the brain; however, fiber outgrowth from those cells is often limited to the immediate vicinity of the graft. More extensive outgrowth is desirable for promoting and maintaining functional recovery of damaged neural systems in animal models as well as human neurodegenerative disorders. The present study examined the possibility of stimulating fiber outgrowth of grafted neurons by simultaneously grafting dopamine neurons with their embryonic target cells. Subsequent functional recovery was evaluated in concert with morphological characteristics of these grafts. Co-grafts of embryonic mesencephalic and striatal cells were implanted into the DA-denervated striatum of rats previously given unilateral 6-hydroxydopamine lesions of the nigrostriatal pathway. Two types of co-grafts were implanted into the DA-denervated striatum: mixed or separate cell suspensions. Tyrosine hydroxylase immunocytochemical analysis of brain sections containing co-grafts revealed extensive arborization of TH-positive neurons in both types of co-grafts. When mesencephalic and striatal nerve cells were implanted into separate sites, TH-positive neurons extended projections that appeared to preferentially reach regions occupied by embryonic striatal neurons. Moreover, the average size of TH-positive cell bodies found in mixed or separate co-grafts was significantly larger than the size of those found in single mesencephalic grafts. Amphetamine-induced rotational behavior was used to assess the degree of functional recovery. In the majority of co-grafted animals, rotational behavior was attenuated by 3 weeks and reversed (amphetamine-induced contralateral rotation) by 5 weeks.(ABSTRACT TRUNCATED AT 250 WORDS)     

Locus coeruleus promotes survival of dopamine neurons in ventral mesencephalon. An in oculo grafting study

Parkinson's disease is a neurodegenerative disorder where dopamine neurons in the substantia nigra of ventral mesencephalon undergo degeneration. In addition to the loss of dopamine neurons, noradrenaline neurons in the locus coeruleus degenerate, actually to a higher extent than the dopamine neurons. The interaction between these two nuclei is yet not fully known, hence this study was undertaken to investigate the role of locus coeruleus during development of dopamine neurons utilizing the intraocular grafting model. Fetal ventral mesencephalon and locus coeruleus were implanted either as single grafts or co-grafts, placed in direct contact or at a distance. The results revealed that the direct attachment of locus coeruleus to ventral mesencephalon enhanced graft volume and number of tyrosine hydroxylase (TH)-positive neurons in ventral mesencephalic grafts. Cell counts of subpopulations of TH-positive neurons also immunoreactive for aldehyde dehydrogenase 1-A1 (ALDH1) or calbindin, revealed improved survival of ALDH1/TH-positive neurons. However, the number of calbindin/TH-positive neurons was not affected. High density of dopamine-β-hydroxylase (DBH)-positive innervation in the ventral mesencephalon placed adjacent to locus coeruleus was correlated to the improved survival. Ventral mesencephalic tissue, implanted at a distance to locus coeruleus, did not demonstrate improved survival, although DBH-positive nerve fibers were detected. In conclusion, the direct contact of locus coeruleus resulting in dense noradrenergic innervation of ventral mesencephalon is beneficial for the survival of ventral mesencephalic grafts. Thus, when trying to rescue dopamine neurons in Parkinson's disease, improving the noradrenergic input to the substantia nigra might be worth considering.     

Pattern of synaptophysin immunoreactivity within mesencephalic grafts following transplantation in a parkinsonian primate model

The majority of investigations into the degree of restoration of neural circuitry following transplantation of the embryonic ventral mesencephalon to the striatum have focused upon the particular neurochemical subtypes of the fibers exchanged between graft and host. Visualization of neurites of specific neurotransmitter type while informative regarding the specificity of graft–host interactions, vastly underrepresents overall synaptogenesis as it may occur in the grafting situation. The present approach of using a molecular marker characteristic of all normal, functional synapses provides broader information about the synaptic remodeling that occurs after tissue grafting. Synaptophysin (SY), an integral membrane protein of the synaptic vesicle, is a reliable marker of nerve terminal differentiation. Immunohistochemical staining with antibodies directed against SY and the dopamine synthetic enzyme tyrosine hydroxylase (TH) was used to assess overall synaptic differentiation as well as the relationship between SY immunoreactivity and the distribution of grafted dopamine (DA) neurons and processes in mesencephalic grafts and mesencephalic-striatal co-grafts implanted in the striatum of MPTP-treated African green monkeys. Grafted embryonic cerebellar tissue was used as a comparison graft type that does not normally exchange prominent direct projections with striatum. Dense pericellular arrays of SY-positive terminals were associated with TH-positive neurons in mesencephalic grafts. In mixed mesencephalic-striatal co-grafts, TH-positive fiber patches within the striatal portion of the graft demonstrated a high degree of correspondence with SY immunoreactivity. In contrast, grafts of cerebellar tissue did not display the same pattern of prominent pericellular arrays of SY staining. These observations suggest that functional synapses are abundantly present within grafted mesencephalon, and that these contacts are enriched in areas of the graft occupied by DA neurons. Implantation of an inappropriate striatal target, the cerebellum, results in visibly diminished innervation. The pattern of SY labeling observed suggests that tissue grafts are extensively innervated, probably both from extrinsic and intrinsic sources, and that the pattern and density of this innervation corresponds to the appropriateness of the graft–host interaction.     

Behavioral and electrophysiological correlates of human mesencephalic dopaminergic xenograft function in the rat striatum

While human fetal xenografts placed into immunocompromised animal hosts have been shown to survive and grow, their ability to function and influence the host tissue has not been fully examined. Therefore, we implanted grafts of human fetal mesencephalic tissue intracranially into rats with unilateral 6-hydroxydopamine lesions of their nigrostriatal dopaminergic innervation and tested the rats behaviorally for reductions in apomorphine-induced rotations. The purpose of this study was to test the ability of these grafts to provide a functional reinnervation by comparing the behavioral changes with the morphology and presence of electrophysiologically active dopaminergic neurons within the graft and with firing rates of host striatal neurons. Adult Sprague-Dawley rats that had been unilaterally lesioned and that showed a stable two peak pattern of apomorphine-induced rotations received grafts of human fetal mesencephalic tissue placed directly into the lesioned striatum. These rats were then further tested each month for five months for reductions in their turning behavior. At 5 to 6 months postgrafting, electrophysiological recordings were made of cells within the graft and within the host striatum. The rats were then examined immunohistochemically to evaluate graft survival and extent of reinnervation of the host tissue. The rats receiving mesencephalic dopaminergic grafts demonstrated a 79% reduction in their apomorphine-induced rotations. Electrophysiological recordings revealed spontaneously active dopaminergic neurons within the graft as well as host striatal cell firing rates consistent with those of dopamine-innervated cells. Furthermore, immunohistochemical studies confirmed graft survival and revealed marked fiber outgrowth from the graft into and throughout the striatum. Taken together these findings provide evidence that grafts of human fetal mesencephalic tissue are able to produce behavioral improvements in lesioned animals which are associated with the presence of dopaminergic neurons within the graft and are consistent with normal host striatal cell activity levels.     

Target-specific outgrowth from human mesencephalic tissue grafted to cortex or ventricle of immunosuppressed rats.

Human fetal mesencephalic tissue was grafted to rats with unilateral lesions of the nigrostriatal pathway. The animals were immunosuppressed with cyclosporine A. Grafts were placed either into the lateral ventricle ipsilateral to the lesion or in the cingulate cortex above corpus callosum. The grafts and newly formed fibers were visualized by immunohistochemistry with antibodies against tyrosine hydroxylase (TH) and the human Thy-1 glycoprotein. TH-positive fibers covered the total volume of striatum when the graft was placed either in the ventricle or in the cortex. When the transplant was located in the ventricle, TH-positive cells migrated from the graft into host striatum. No cell migration was seen into any other areas than striatum. Cortex and septum were sparsely reinnervated by the graft, but not to a density higher than that normally seen. Globus pallidus was totally devoid of TH-positive fibers. When the graft was placed in cingulate cortex, fiber bundles penetrated through corpus callosum into either striatum, to arborize in its dorsal parts, or followed the medial side of the lateral ventricle to ventral limbic areas, where a fiber network also was formed. Human specific Thy-1-immunohistochemistry revealed positivity only on the lesioned side. These data suggest that dopamine neurons in human mesencephalic tissue, grafted to the rat brain, can migrate specifically into host striatum. Furthermore, TH-positive fiber outgrowth occurred only into dopamine denervated areas of the host, avoiding areas that are normally not innervated by nigral neurons, but also able to reach distant target cells.     

Implantation of bioactive growth factor-secreting rods enhances fetal dopaminergic graft survival, outgrowth density, and functional recovery in a rat model of Parkinson's disease

One of the drawbacks with fetal ventral mesencephalic (VM) grafts in Parkinson's disease is the limited outgrowth into the host striatum. In order to enhance graft outgrowth, epidermal growth factor (EGF) and basic fibroblast growth factor (bFGF) were administered by implantation of bioactive rods to the lateral part of the striatum to support grafted fetal VM implanted to the medial portion of the striatum. The polymer-based bioactive rods allow for a local secretion of neurotrophic factors over a time period of approximately 2 weeks. Moreover, glial cell line-derived neurotrophic factor (GDNF) and transforming growth factor-beta1 (TGFbeta1) were administered using the same technique. Concomitant administration of GDNF and TGFbeta1 was achieved by insertion of one GDNF and one TGFbeta1 rod. This was performed to investigate possible additive effects between GDNF and TGFbeta1. Rotational behavior, outgrowth from and nerve fiber density within the VM graft, and the number of TH-positive cells were studied. Functional compensation by reduction of rotational behavior was significantly enhanced in animals carrying bFGF and GDNF rods in comparison with animals carrying only VM graft. EGF and bFGF significantly increased the innervation density. Moreover, the nerve fiber density within the grafts was significantly enhanced by bFGF. Cell counts showed that a significantly higher number of TH-positive neurons was found in grafts treated with bFGF than that found in GDNF-treated grafts. An additive effect of TGFbeta1 and GDNF was not detectable. These results suggest that bioactive rods is a useful tool to deliver neurotrophic factors into the brain, and since bFGF was a potent factor concerning both functional, immunohistochemical and cell survival results, it might be of interest to use bFGF-secreting rods for enhancing the overall outcome of VM grafts into patients suffering from Parkinson's disease.     

Tyrosine hydroxylase-positive fibers and neurons in transplanted striatal tissue in rats with quinolinic acid lesions of the striatum

Using the quinolinic acid (QA) animal model of Huntington's disease (HD) the dopaminergic afferent input to intrastriatal striatal grafts was examined. After bilateral striatal lesions with QA (15 nmol), 4 microliters of fetal (E17) striatal tissue were delivered into the lesioned striata. Twenty-eight weeks posttransplantation the tissue was processed for TH immunocytochemistry and cresyl violet staining. In addition fetal intact brains (E17) were also processed for TH immunocytochemistry and cresyl violet staining. Viable striatal grafts were located within the host striatum and in some cases within the lateral ventricles. TH-positive fibers were present within the graft and also groups of TH-positive cell bodies were seen in some of the grafts. TH immunocytochemistry on E17 fetuses revealed several groups of TH-positive neurons one of which was placed immediately ventral to the developing striatal ridge. The origin of TH-positive innervation within the graft is discussed.     

Dopamine cells in nigral grafts differentiate prior to implantation

The yield of surviving dopamine cells in nigral grafts is typically low. It is unclear whether the dopamine neurons that do survive are postmitotic at the time of implantation, or are precursor cells that differentiate into dopamine neurons following transplantation in the host brain. We have therefore compared the survival of dopamine neurons in grafts that have been labelled with BrdU at different times prior to or following implantation in order to identify those cells that undergo final cell division at each stage of the procedure. Seven groups of rats were prepared with unilateral nigrostriatal lesions. Three groups received nigral grafts derived from E14 embryos labelled with BrdU in utero on either E12, E13 or E14 days of embryonic age (the E14 injection made 2 h prior to preparation of the graft cell suspension). Three further groups received nigral grafts from untreated E14 embryos, and then dividing cells within the grafts were labelled by injection of BrdU into the host lateral ventricle, 2 h, 1 day or 2 days after implantation (equivalent to E14, E15 and E16 days of embryonic age). The control group received standard (unlabelled) E14 grafts. Five weeks after the transplantation surgery, the host brains were processed using double immunohistochemical techniques to detect tyrosine hydroxylase (TH)-positive neurons which had incorporated BrdU. In the grafts labelled with BrdU prior to implantation, there was an increasing proportion of double-labelled cells (out of the total TH-positive cells surviving in the grafts) with birth dates on E12, E13 and E14 (1%, 12% and 10% per day, respectively). By contrast, grafts labelled following implantation, although containing many dividing neurons, had very few of these BrdU-labelled cells expressing a dopaminergic phenotype; < 1% surviving TH-positive cells were double-labelled from the 2 h post-transplant injection, and < 0.1% from each subsequent injection. This suggests not only that the great majority of TH-positive neurons in nigral grafts were already differentiated at the time of implantation, but also that transplantation of E14 ventral mesencephalic tissue either kills dopaminergic precursors or (more likely in our opinion) prevents their differentiation into a dopaminergic phenotype. Precursor cells that would differentiate into dopaminergic neurons beyond E14 if left in situ in the intact ventral mesencephalon do not readily differentiate into mature dopamine neurons following transplantation. If we are to enhance yields of functional dopamine-rich transplants, then we must identify strategies both to protect predifferentiated dopamine neurons in the grafts and to promote differentiation of a dopaminergic phenotype in precursor cells that continue to divide within the grafts following transplantation into an adult host environment.     

Specific outgrowth from neurons of ventral mesencephalic grafts to the catecholamine-depleted striatum of adult hosts.

Grafts of fetal ventral mesencephalon including substantia nigra have been used to correct some motor deficits produced by unilateral destruction of the dopaminergic nigrostriatal pathway in rats. Histochemical studies have shown that dopaminergic neurons within the graft send processes from the graft to the host neuropil, wherein they form synapses. The results of numerous immunocytochemical studies indicate, however, that a large proportion of neurons in grafts are not catecholaminergic. Whether or not the nondopaminergic neurons in grafts project to the host brain is unknown. The purpose of the present study was to combine immunocytochemistry and retrograde tracing with fluorogold to identify the cell types which project from grafts to the host striatum. Tissue from the ventral mesencephalon of E15 fetuses was placed into the 6-hydroxydopamine denervated striatum of graft recipients. Six weeks to 6 months following transplantation, fluorogold was pressure injected under stereotaxic control immediately adjacent to the ventral mesencephalic grafts; after 4 days CNS tissue was prepared for light microscopic immunocytochemistry. Ventral mesencephalic grafts contained cell bodies immunoreactive for enkephalin, GAD, substance P, and serotonin in addition to those immunoreactive for tyrosine hydroxylase. Some cells of each immunochemically defined type were retrogradely labeled by the fluorogold injection into the host brain. Nevertheless, more catecholaminergic and serotonergic cells projected from grafts to the fluorogold injection site than did other cell types. Since many of the nonmonoaminergic neurons in grafts are probably projection neurons, our results suggest that the extent of neurite outgrowth from grafted cells is influenced by the surrounding target tissue.     

Transplantation of fetal mesencephalic and medullary raphe tissues into the cerebellum of denervated adult rats--an immunohistochemical study.

Pieces of mesencephalic and medullary raphe tissues were transplanted into the cerebella of 5,6-dihydroxytryptamine-treated adult rats. The extent of axonal outgrowth of serotonergic and dopaminergic neurons in the grafts was immunohistochemically studied. At 3 months after transplantation, numerous dopaminergic neurons with many processes extending within the graft were detected in the mesencephalic raphe graft, but not in the medullary raphe graft. In contrast, both the mesencephalic and medullary raphe grafts contained numerous serotonergic neurons and a dense plexus of their fibers. The outgrowing serotonergic fibers from the mesencephalic raphe graft showed a hyperinnervation pattern in the cerebellar cortex adjacent to the graft. Furthermore, a glomerulus-like accumulation of serotonergic fibers was observed in the granular layer. In the cases of medullary raphe grafts, the relatively abundant outgrowing serotonergic fibers showed a laminar organization in the cerebellar cortex near the graft, which was similar to the normal distributional pattern. These results indicate that serotonergic and dopaminergic neurons located within the mesencephalic raphe graft clearly differed from each other in their ability to extend their processes into the host cerebellum, which provides further evidence for the existence of specific interactions between outgrowing serotonergic fibers and their terminal fields (targets).     

Long-term survival of mouse corpus callosum grafts in neonatal rat recipients, and the effect of host sensitization.

Previous studies have suggested that the incidence of spontaneous rejection among immunogenetically mismatched neural transplants in neonatal recipients varies significantly depending on the cellular composition of the graft material. For example, neuron-rich grafts of embryonic mouse retina generally survive for extended periods without showing signs of rejection after implantation into neonatal rats, whereas cortical xenografts, which contain abundant glial and endothelial cells as well as neurons, typically undergo rejection 4-6 weeks after implantation. To determine whether the presence of donor glia is responsible for this high incidence of spontaneous rejection, we examined the fate of a non-neuronal graft material composed predominantly of xenogeneic glial cells (post-natal day 3, PD3, CD-1 mouse corpus callosum) implanted into the mesencephalon of PD1 Sprague-Dawley rats. The distribution and survival of donor astrocytes were assessed using a monoclonal antibody specific for a mouse astrocyte surface antigen, M2. Thirteen of 16 animals sacrificed within 2 months of implantation had detectable transplants. In these animals, M2-positive cells frequently migrated well away from body of the graft, clustering in large numbers in several characteristic regions of the host brain. Unlike cortical grafts of similar age, the vast majority (93%) of callosal transplants showed no histological signs of rejection or major histocompatibility complex antigen expression in and around the transplant-derived cells. As previously noted in the neonatal retinal transplant paradigm, however, well-integrated 1-month-old corpus callosum grafts could be induced to reject by appropriate sensitization of the host immune system, implying that the host was not immunologically tolerant to the foreign neural graft. With longer survival times in unsensitized hosts, a progressively smaller percentage of animals had detectable donor astrocytes (5 of 10 animals at 3 months postimplantation and 4 of 16 animals at 4 months); in those 9 animals with surviving grafts, only small numbers of M2-positive cells were seen within the graft bed and surrounding host brain. However, only 2 of the 26 "long-term" animals showed evidence of graft rejection. These results indicate that mouse astrocytes show characteristic patterns of migration into the host brain when implanted into neonatal rats; however, these xenogeneic cells have a limited duration of survival. The infrequency with which even subtle signs of spontaneous rejection were detected in animals that had received corpus callosum xenografts suggests that an immune-mediated process is unlikely to be responsible for the time-dependent elimination of the donor astrocytes.(ABSTRACT TRUNCATED AT 400 WORDS)     

Effect of Prior Dopamine Denervation on Survival and Fiber Outgrowth from Intrastriatal Fetal Mesencephalic Grafts

[3H]Dopamine (DA) uptake radioautography and tyrosine hydroxylase (TH) immunocytochemistry were used to assess quantitatively the effects of the presence or absence of host mesostriatal DA afferents on the survival and fiber outgrowth from fetal ventral mesencephalic DA neurons grafted into the neostriatum of adult recipient rats. Rats received bilateral intrastriatal transplants of fetal ventral mesencephalic tissue 1 month after a unilateral injection of 6-hydroxydopamine (6-OHDA) into the right nigrostriatal bundle (denervated side). Five to six months later, some of the grafted rats received a second 6-OHDA injection in the left nigrostriatal bundle (acutely denervated or 'intact' side). After a further 7 days, slices of each hemisphere from the latter rats were incubated with [3H]DA and processed for film and high resolution radioautography. The density of the film radioautographs was measured with a computerized image analysis system and calibrated by silver grain cluster (i.e. DA terminal) counting over selected areas of the same sections in light microscope radioautographs. The brains of the remaining grafted rats were processed for TH immunoreactivity 6 - 12 months after graft surgery. Neither the size of the grafts, nor the number of surviving TH-positive graft neurons showed any significant difference between the nondenervated and the denervated sides. However, the size of the TH-positive cell bodies was significantly greater in the grafts on the denervated side. In the [3H]DA uptake radioautographs, considerable outgrowth of DA fibers was evident in the neostriatum on the 'intact' side in spite of the presence of an intact host DA innervation until 7 days before sacrifice. The overall DA fiber outgrowth was nevertheless almost two-fold greater on the denervated side, and extended deeper into the host neostriatum than on the 'intact' side; only 7% of the total neostriatal area, on average, was at background level compared to 30% on the 'intact' side, and the overall density of neostriatal DA innervation amounted to 36% of normal as compared to 20% on the 'intact' side. The correlation between the overall density of graft-derived DA innervation and the size of the grafts was linear on the 'intact' side, but reached a plateau with relatively small grafts on the denervated side. However, the ventral striatum on both sides was very poorly innervated by these grafts. These findings demonstrate that the mature neostriatal tissue can support axonal growth and innervation from grafted fetal DA neurons even in the presence of a normal complement of endogenous DA fibers. Prior removal of the host striatal DA innervation does not influence the overall size of the grafts nor the number of surviving DA neurons, but induces an increase in the cell body size and fiber outgrowth of the grafted DA neurons.     

Comparison of growth and reinnervation properties of cholinergic neurons from different brain regions grafted to the hippocampus

Grafts of five different types of central cholinergic neurons, from the septal-diagonal band region, the nucleus basalis magnocellularis region (NBM), the striatum, the pontomesencephalic tegmentum of the brainstem, and the spinal cord, were compared with respect to their ability to grow and to reinnervate the cholinergically denervated hippocampal formation of adult rats. The areas were dissected from 14 to 15-day-old rat fetuses, and the same number of viable cells (35 X 10(4) from each of the different regions were stereotaxically injected as cell suspensions into the hippocampus of rats subjected to a transection of the intrinsic septo-hippocampal cholinergic pathways. At 17-19 weeks after transplantation, the various graft types differed considerably in their volume, the total amount of acetylcholinesterase (AChE)-positive fiber outgrowth, and the innervation pattern and morphology of the AChE-positive fibers growing into the host hippocampus. On average the NBM and spinal cord grafts had grown to become three to four times larger than the septal and the brainstem grafts, and 15-20 times larger than the striatal grafts. By contrast, the total ingrowth score of AChE-positive fibers in the host hippocampus from the septal grafts was about twice that of the NBM and brainstem grafts, about five times greater than the striatal grafts, and about six times greater than that of the spinal cord grafts. The large NBM grafts thus exhibited similar fiber outgrowth to the much smaller brainstem grafts, and the AChE-positive neurons of the grafted spinal cord grew very poorly into the hippocampus despite the fact that they survived very well. The innervation pattern and morphological features of the ingrowing AChE-positive fibers in the host hippocampus proper and in the dentate gyrus resembled those of normal rats in animals with grafts from any of the three forebrain regions (i.e., septum, NBM, or striatum), whereas ingrowth from the brainstem and spinal cord grafts were markedly abnormal with respect to both innervation pattern and fiber morphology. These results provide further evidence that the overall survival, growth, and fiber outgrowth of intracerebral neural grafts depend on interactions with the surrounding host tissue. Since the ability to reinnervate the previously denervated host target was greatest for the neuron type normally innervating that area, i.e., the septal-diagonal band neurons, we conclude that neuronal properties beyond the transmitter type are essential for the optimal performance of implanted neurons in intracerebral grafting experiments.     

Trophic and tropic effects of striatal astrocytes on cografted mesencephalic dopamine neurons and their axons

Astrocytes from the ventral mesencephalon and from the striatum respectively promote the dendritic and axonal arborization of dopamine (DA) neurons in vitro. To test this response in vivo, astrocytes in primary cultures from the neonatal cerebral cortex, ventral mesencephalon, or striatum were coimplanted with fetal ventral mesencephalic tissue into the intact or DA-denervated striatum of adult rats and these cografts examined after 3–6 months by tyrosine hydroxylase (TH) immunohistochemistry (intact recipients) or after 5–6 months by in vitro [H]DA-uptake autoradiography (DA-denervated recipients). In contrast with single ventral mesencephalic grafts, all types of cograft displayed a rather uniform distribution of TH-immunoreactive perikarya. The average size of TH-immunoreactive cell bodies was not significantly different in cografts containing cortical or mesencephalic astrocytes and in single ventral mesencephalic grafts, but it was significantly larger in cografts containing striatal astrocytes. Nevertheless, the number of [H]DA-labeled terminals in the DA-lesioned host striatum was clearly smaller with cografts of striatal astrocytes than with single mesencephalic grafts or with cografts containing cortical astrocytes. On the other hand, cografts of striatal astrocytes contained much higher numbers of [H]DA-labeled terminals than the other types of graft or cograft. Thus, while cografted astrocytes in general influence the distribution of DA neurons within the graft, astrocytes from the neonatal striatum have a trophic effect on DA perikarya and a tropic effect on DA axons, keeping the latter within the graft.     

Solid human embryonic spinal cord xenografts in acute and chronic spinal cord cavities: a morphological and functional study

While therapeutic spinal cord grafting procedures are of interest in the chronic spinal cord injury stage, previous experimental grafting studies, including human spinal cord tissue, have mainly focused on the acute stage. Therefore, solid human embryonic spinal cord grafts were implanted in acute or chronic spinal cord aspiration cavities of immunodeficient rats to compare the morphological and locomotor outcome to that of lesion alone cases. Locomotor function was assessed using the Basso, Beattie, and Bresnahan open-field locomotor rating scale up to 6 months, while the morphological evaluation of graft survival, growth, and integration was performed at 6 weeks or 6 months after implantation. Graft survival was 94% in both lesion models, while graft growth was enhanced in the chronic compared to the acute cavity group. Human specific Thy-1 and neurofilament immunoreactive fibers were observed up to 7 mm into host white matter, while aminergic fibers were observed up to 1 mm into the grafts. Abundant calcitonin gene-related peptide immunoreactive fibers in the grafts in the absence both of immunoreactive cell bodies and colocalized human-specific neurofilament immunoreactivity, suggested host fiber ingrowth. At 6 months, the grafted cases presented less central canal deformation and lower glial fibrillary acidic protein immunoreactivity at the host cavity border compared to that of the nongrafted cases. The strong compensatory regain of locomotor function after unilateral spinal cord lesions was not affected by the human spinal cord grafts. In conclusion, solid human embryonic spinal cord tissue transplanted to a cavity in the adult injured spinal cord results in beneficial morphological effects in both the acute and chronic spinal cord lesion.     

Fetal transplants in rat hippocampus following kainic acid lesions: influence of post-lesion delay on graft survival and integration

Host brain receptivity to fetal hippocampal grafts was investigated following transplantation into unilateral kainic acid (KA) lesions of adult rat hippocampus. E18-E19 hippocampal cell suspensions were labeled with rhodamine dextran amine and transplanted bilaterally into hosts at various times following the KA-lesion. After one to three and one half months survival the grafts (contained within host hippocampal slices) were analyzed using intracellular electrophysiological techniques. A nonparametric graft index was developed which assessed the overall size and distribution of the graft. Using this grading system graft development was noted to be significantly enhanced for grafts placed into hosts with KA lesions at either 2-4 days or 11-12 days following the lesion, compared to grafts placed at either 6-7 days or 27-33 days after the lesion. Also, grafts implanted at delays of either 14-16 or 28-33 days appeared to have fewer surviving cells but were more dispersed within the host brain than grafts at shorter post-lesion implant times. Synaptic responses to host stimulation were noted in most grafts. Intracellular staining of transplanted neurons showed considerable development of cell processes but atypical pyramidal cell morphology and ectopic location; numerous axons traveled into the host tissue. The time course of lesion-induced host receptivity appeared to significantly influence graft development and maturation. In this study graft survival was partially independent from cell migration. This differential effect may be due to various aspects of host brain receptivity, which in turn is influenced by the delay between the host brain lesion and grafting.     

Long-term survival of fetal porcine lateral ganglionic eminence cells in the hippocampus of rats.

Embryonic porcine brain tissue from the lateral ganglionic eminence was transplanted into the adult rat hippocampus to determine whether fetal striatal cells could survive, differentiate, and integrate in a heterotopic site. The hippocampus, a common site of epileptic seizure activity, was chosen to determine if fetal striatal cells could supply inhibitory GABAergic neurons that may serve to block seizures. Cells were either implanted with a single deposit using a standard metal cannula or by five smaller disseminated deposits with a glass micropipette. At 20-24 weeks, animals immunosuppressed with cyclosporin showed long-term survival of porcine cells in the adult hippocampus. Analysis by immunohistochemistry and in situ hybridization showed that the grafts contained glial and neuronal cell types, including GABAergic neurons within graft core and networks of porcine neuronal fibers extending from the graft into the host parenchyma. In addition, a marker of porcine presynaptic terminals, synaptobrevin, was abundant within the grafts and was found associated with hippocampal structures and cell layers suggesting functional integration of grafted cells within the host. The survival of xenografts in the hippocampus and potential integration of inhibitory components provides evidence that these grafts may serve as an internal negative feedback mechanism to quench epileptiform activity.     

Cryopreservation and storage of embryonic rat mesencephalic dopamine neurons for one year: comparison to fresh tissue in culture and neural grafts

Blocks of embryonic rat ventral mesencephalic tissue containing the developing A8–A10 dopamine (DA) cell groups were cryopreserved and stored for approximately 1 year, at which time this tissue was thawed, dissociated into a cell suspension, and compared to a similar preparation of fresh mesencephalic tissue for viability in tissue culture and neural grafts. Estimates of total cell number immediately prior to plating in culture indicated that cryopreserved tissue yields fewer cells, but when this reduced cell number is compensated for, and equal numbers of cells were plated in culture, approximately equal total numbers of neurons, as well as tyrosine hydroxylase (TH)-positive neurons, were present in cultures from cryopreserved and fresh tissue. Grafting of equal numbers of fresh and cryopreserved mesencephalic cells into the striatum of adult rats with large unilateral lesions of the nigrostriatal DA pathway tended to yield smaller grafts with fewer surviving TH-positive cells with less extensive neuronal processes when tissue was previously cryopreserved. However, grafts derived from freeze-stored tissue provided a similar timecourse and extent of behavioral recovery in amphetamine-induced rotational tests to that provided by fresh tissue grafts. Taken together, our findings indicate that while cryopreservation of mesencephalic tissue has its costs — reduced cell yield in cultures and grafts, and compromised morphology in grafts — sufficient numbers of cryopreserved neurons survive the grafting procedure to ameliorate behavioral signs of DA depletion in the lesioned rat model.     

Function of intraventricular human mesencephalic xenografts in immunosuppressed rats: an electrophysiological and neurochemical analysis.

Solid pieces of human fetal mesencephalic tissue were grafted to the lateral ventricle adjacent to dopamine-depleted striata of rats immunosuppressed with cyclosporin A. Apomorphine-induced rotations were performed before and at monthly intervals after grafting. Reductions in rotations were seen at 2 months post-grafting and these reductions progressively increased. Spontaneously active dopaminergic cells were found within the grafts using extracellular single-unit recording techniques. Recordings of striatal cells ipsilateral to the graft revealed "normal" firing rates compared to those of neurons in the control striatum. In response to the local application of the dopamine antagonist cis-flupenthixol, both the dopaminergic and striatal neurons showed dose-dependent excitations. Potassium-evoked releases of electroactive species ipsilateral to the fetal human graft, measured using high-speed in vivo electrochemistry, revealed response amplitudes that were similar to control striatum when an electrode was placed adjacent to the graft; distal to the graft the responses showed smaller amplitudes but prolonged time courses. Much greater levels of dopamine and serotonin were detected in the grafts, compared to in normal rat substantia nigra, as measured with HPLC coupled to a 16-channel electrochemical array detector. Immunocytochemical studies using antibodies against tyrosine hydroxylase (TH), revealed not only TH-positive cells within the graft, but also a few positive neurons that migrated into the host striatum. Numerous TH-immunoreactive fibers penetrated into striatum and reinnervated its total volume. Taken together, these data suggest that intraventricular graft placement may be a highly efficacious technique for studying fetal brain tissues in terms of maturation, reinnervation, and function.