Evidence for target-specific nerve fiber outgrowth from subpopulations of grafted dopaminergic neurons: a retrograde tracing study using in oculo and intracranial grafting

Efforts have been made to counteract the symptoms of Parkinson's disease by substituting the loss of dopaminergic neurons with fetal ventral mesencephalic grafts. One of the postulated limiting factors in this treatment is the relatively poor cell survival and limited graft-derived fiber outgrowth. Recent results documenting enhanced survival of grafted dopaminergic neurons showed no positive correlation to enhanced innervation of the striatal target. Therefore this study was undertaken to investigate whether all surviving grafted dopaminergic neurons projected to the striatal target. Hence, fetal ventral mesencephalic tissue was implanted adjacent to mature versus immature striatal tissue using in oculo and intraventricular grafting techniques. In in oculo grafting, fetal ventral mesencephalon was implanted simultaneously with fetal lateral ganglionic eminence (immature striatal target) or to already matured striatal in oculo grafts (mature striatal target). Furthermore, fetal ventral mesencephalon was implanted into the lateral ventricle adjacent to mature dopamine-depleted striatum. The retrograde tracer fluorogold was injected into the striatal portion of the in oculo cografts and into reinnervated areas of the adult brain. Immunohistochemistry revealed that a significantly larger proportion of tyrosine hydroxylase-positive neurons in the ventral mesencephalic graft was innervating in oculo immature striatal tissue, and hence was fluorogold-positive, in comparison with the number of tyrosine hydroxylase-positive neurons innervating mature striatal tissue. Moreover, intracranial transplantations showed that tyrosine hydroxylase-positive neurons were distributed within the grafts in dense clusters of cells. In most clusters tyrosine hydroxylase-positive cells were fluorogold-negative but calbindin-positive. In a few tyrosine hydroxylase-positive cell clusters, neurons were coexpressing fluorogold but were calbindin-negative. In conclusion, significantly more dopamine neurons projected to immature than to mature striatal tissue and thus, a subpopulation of grafted dopaminergic neurons was not projecting into adult striatum. Thus, the results from this study show that further attempts to enhance survival of grafted dopamine neurons in purpose to enhance graft-derived fiber outgrowth and efficacy should also consider different subtypes of dopamine neurons.     

Reconstruction of the striato-nigro-striatal circuitry by simultaneous double dopaminergic grafts: a tracer study using fluorogold and horseradish peroxidase

The main strategy in neural transplantation for Parkinson's disease (PD) has been the ectopic placement of dopaminergic grafts in the striatum in order to restore dopaminergic innervation to the host striatum. Although intrastriatal transplants usually improve asymmetric rotational behavior in the 6-hydroxydopamine lesioned rodent model of PD, they are less likely to completely restore the more complex sensorimotor behavioral deficits induced by dopamine loss. Re-establishment of the nigrostriatal circuitry and dopaminergic reinnervation of the substantia nigra may be necessary to promote a more complete restoration of function in the dopamine depleted brain and improve the clinical efficacy of dopaminergic transplants. Recently, we demonstrated the reconstruction of the nigrostriatal pathway by simultaneous intrastriatal and intranigral dopaminergic transplants [Mendez et al., J. Neurosci. 16 (1996) 7216–7227.]. Using this strategy, it was found that placing a graft of embryonic ventral mesencephalic tissue in the striatum promoted the growth and guidance of axons from a similar graft placed homotopically in the ventral mesencephalon. Since it is apparent that developing tissue has the ability to promote axonal growth and guidance along the nigrostriatal pathway, the double grafting strategy may contribute to reestablishing host-graft connectivity. The current study provides evidence of reconstruction of the striato-nigro-striatal loop circuitry by simultaneous intrastriatal and intranigral dopaminergic transplants. Injection of the retrograde tracer fluorogold (FG) into the striatum resulted in fluorescent labeled cells within the intranigral grafts. Similarly injection of FG into the nigra resulted in fluorescent labeled cells within the intrastriatal graft and surrounding striatum. Injection of the anterograde tracer horseradish peroxidase (HRP) resulted in the presence of HRP reaction product throughout the target striatum. These results strongly support the re-establishment of nigrostriatal and striatonigral connections between simultaneous intrastriatal and intranigral dopaminergic transplants and suggest reconstruction of the striato-nigro-striatal loop circuitry.     

Human ventral mesencephalic xenografts to the catecholamine-depleted striata of athymic rats: ultrastructure and immunocytochemistry

On the basis of animal studies, grafts of fetal human dopaminergic cells have been suggested as a therapy for Parkinson's disease. The purpose of this study was to characterize the ultrastructure and immunocytochemistry of human ventral mesencephalic xenografts placed into the catecholamine-depleted striata of athymic "nude" rats. Human fetal tissue was obtained from tissue fragments derived from elective abortions during the first trimester of pregnancy. Small pieces of the basal mesencephalon were grafted into the catecholamine-depleted striata of four athymic nude rats. The rats were allowed to survive from 3 to 6 months after grafting; following fixation, the striatal tissue containing the grafts was labeled with antibodies against tyrosine hydroxylase and serotonin. Immunocytochemistry revealed tyrosine-hydroxylase-like-immunoreactive (THLI) and serotoninlike-immunoreactive (5HTLI) cell bodies within the human grafts. Both 5HTLI and THLI fibers crossed the graft-host interface and innervated the previously lesioned striatum. Both types of fibers also entered the host cortex from the adjacent human graft. At the ultrastructural level, THLI and 5HTLI fibers and synaptic terminals were observed in the host neuropil. THLI and 5HTLI dendrites and axon terminals were also observed in the neuropil of the grafts themselves. THLI axon terminals are not normally present in the substantia nigra. The results of our study indicate that human xenografts can survive in the neuropil of the host striatum and form morphologically appropriate synapses within the host brain.     

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.     

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.     

Anatomical and functional reconstruction of the nigrostriatal pathway by intranigral transplants

The main transplantation strategy in Parkinson's disease has been to place dopaminergic grafts not in their ontogenic site, the substantia nigra, but in their target area, the striatum with contrasting results. Here we have used green fluorescent protein transgenic mouse embryos as donors of ventral mesencephalic cells for transplantation into the pre-lesioned substantia nigra of an adult wild-type host. This allows distinguishing the transplanted cells and their projections from those of the host. Grafted cells integrated within the host mesencephalon and expressed the dopaminergic markers tyrosine hydroxylase, vesicular monoamine transporter 2 and dopamine transporter. Most of the dopaminergic cells within the transplant expressed the substantia nigra marker Girk2 while a lesser proportion expressed the ventral tegmental area marker calbindin. Mesencephalic transplants developed projections through the medial forebrain bundle to the striatum, increased striatal dopamine levels and restored normal behavior. Interestingly, only mesencephalic transplants were able to restore the nigrostriatal projections as dopamine neurons originating from embryonic olfactory bulb transplants send projections only in the close vicinity of the transplantation site that did not reach the striatum. Our results show for the first time the ability of intranigral foetal dopaminergic neurons grafts to restore the damaged nigrostriatal pathway in adult mice. Together with our previous findings of efficient embryonic transplantation within the pre-lesioned adult motor cortex, these results demonstrate that the adult brain is permissive to specific and long distance axonal growth. They further open new avenues in cell transplantation therapies applied for the treatment of neurodegenerative disorders such as Parkinson's disease.     

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.     

Neo-pathway formation of dissociated neural grafts demonstrated by immunocytochemistry, fluorescent microspheres, and retrograde transport

Embryonic neural tissues were taken from the ventral mesencephalon, the striatal anlage, the cerebellum, or the dorsal telencephalon. Prior to grafting these tissues were dissociated. This provided the opportunity to generate experimental cografts and allowed the introduction of neuronal tracers. Projections from grafts that contained dopaminergic neurons of the mesencephalon were identified immunocytochemically with antisera to tyrosine hydroxylase. Acetylcholinesterase histochemistry was employed to both stain the graft and to visualize graft efferent fibers. Moreover, dissociated tissues, with the exception of the ventral mesencephalon, were treated in vitro with rhodamine-conjugated microspheres. The immature cells incorporated the tracer in vitro. Labeled grafts were placed adjacent to large fiber tracts of the recipient brain or into the lateral ventricle and grown for one to two months. Different types of neurons within the grafts retained the rhodamine tracer. Some of the labeled neurons were positive for acetylcholinesterase. Efferent fibers from the different neural grafts followed similar routes within the host brain. Fibers containing microspheres projected commonly along the nearest host pathway or the labeled fibers followed the reactive glia along the original stab wound. Grafts that were located within the lateral ventricle projected their efferent fibers adjacent to the ventricular surface. Similar routes were followed by efferent fibers from transplanted dopaminergic neurons. One of the projection routes along the hosts corpus callosum was confirmed by horseradish peroxidase tracer transport. We conclude that elongation of graft pathways may occur along existing fiber tracts of the host brain, near structures of the ventricular surface, and alongside glia scars of a graft placement tract.     

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.     

Functional properties and synaptic integration of genetically labelled dopaminergic neurons in intrastriatal grafts

Intrastriatal grafts of fetal ventral mesencephalic tissue, rich in dopaminergic neurons, can reverse symptoms in Parkinson's disease. For development of effective cell replacement therapy, other sources of dopaminergic neurons, e.g. derived from stem cells, are needed. However, the electrophysiological properties grafted cells need to have in order to induce substantial functional recovery are poorly defined. It has not been possible to prospectively identify and record from dopaminergic neurons in fetal transplants. Here we used transgenic mice expressing green fluorescent protein under control of the rat tyrosine hydroxylase promoter for whole-cell patch-clamp recordings of endogenous and grafted dopaminergic neurons. We transplanted ventral mesencephalic tissue from E12.5 transgenic mice into striatum of neonatal rats with or without lesions of the nigrostriatal dopamine system. The transplanted cells exhibited intrinsic electrophysiological properties typical of substantia nigra dopaminergic neurons, i.e. broad action potentials, inward rectifying currents with characteristic 'sag', and spontaneous action potentials. The grafted dopaminergic neurons also received functional excitatory and inhibitory synaptic inputs from the host brain, as shown by the presence of both spontaneous and stimulation-evoked excitatory and inhibitory postsynaptic currents. Occurrence of spontaneous excitatory and inhibitory currents was lower, and of spontaneous action potentials was higher, in neurons placed in the dopamine-depleted striatum than of those in the intact striatum. Our findings define specific electrophysiological characteristics of transplanted fetal dopaminergic neurons, and we provide the first direct evidence of functional synaptic integration of these neurons into host neural circuitries.     

Intrastriatal grafting of dopamine-containing neuronal cell suspensions: effects of mixing with target or non-target cells

The effects of target and non-target cells on the growth and function of intrastriatal grafts of mesencephalic dopamine neurons have been studied in rats with unilateral 6-hydroxydopamine-induced lesions of the nigrostriatal dopamine pathway. Cell suspensions of ventral mesencephalon from 14-15-day-old rat fetuses (rich in developing dopamine neurons) were either grafted alone or grafted after mixing with equivalent numbers of cells obtained from the striatum (a major dopamine target area) or spinal cord (a non-target area for the mesencephalic dopamine neurons). The combined mesencephalic and striatal grafts gave rise to a greater area of dense innervation in the host caudate-putamen than grafts of mesencephalic cells alone or grafts of mesencephalic cells mixed with spinal cord cells. The number of surviving catecholamine-containing neurons did not differ significantly in the different types of grafts. In addition, there was an altered outgrowth pattern in the combined mesencephalic-striatal grafts consisting of small round islands of intensely fluorescent catecholamine-containing fibres, often in close association with the grafted dopamine neurons. In a subsequent biochemical study it was found that combined mesencephalic-striatal grafts exhibited dopamine levels and turnover that did not differ from grafts containing mesencephalic cells only. The mesencephalic-striatal cografts showed a trend toward enhanced behavioural effect, in terms of greater reduction in amphetamine-induced rotation asymmetry, when compared to other graft groups. It is suggested that the addition of embryonic striatal target cells can exert stimulatory effects on morphological development, and possibly functional parameters, of fetal dopamine cells also in vivo after intrastriatal grafting.(ABSTRACT TRUNCATED AT 250 WORDS)     

Survival and Differentiation of Rat and Human Epidermal Growth Factor-Responsive Precursor Cells Following Grafting into the Lesioned Adult Central Nervous System

Epidermal Growth Factor (EGF)-responsive stem cells isolated from the developing central nervous system (CNS) can be expanded exponentially in culture while retaining the ability to differentiate into neurons and glia. As such, they represent a possible source of tissue for neural transplantation, providing they can survive and mature following grafting into the adult brain. In this study we have shown that purified rat stem cells generated from either the embryonic mesencephalon or the striatum can survive grafting into the striatum of rats with either ibotenic acid or nigrostriatal dopamine lesions. However, transplanted stem cells do not survive as a large mass typical of primary embryonic CNS tissue grafts, but in contrast form thin grafts containing only a small number of surviving cells. There was no extensive migration of transplanted stem cells labeled with either thelac-zgene or bromodeoxyuridine into the host region surrounding the graft, although a small number of labeled cells were seen in the ventral striatum some distance from the site of implantation. Some of these appeared to differentiate into dopamine neurons, particularly when the developing mesencephalon was used as the starting material for generating the stem cells. EGF-responsive stem cells could also be isolated from the mesencephalon of developing human embryos and expanded in culture, but only grew in large numbers when the gestational age of the embryo was greater than 11 weeks. Purified human CNS stem cells were also transplanted into immunosuppressed rats with nigrostriatal lesions and formed thin grafts similar to those seen when using rat stem cells. However, when primary cultures of human mesencephalon were grown with EGF for only 10 days and this mixture of stem cells and primary neural tissue was transplanted into the dopamine-depleted striatum, large well-formed grafts developed. These contained mostly small undifferentiated cells intermixed with a number of well-differentiated TH-positive neurons. These results show that purified populations of rat or human EGF-responsive CNS stem cells do not form large graft masses or migrate extensively into the surrounding host tissues when transplanted into the adult striatum. However, modifications of the growth conditionsin vitromay lead to an improvement of their survivalin vivo.     

Non-dopaminergic neurons in ventral mesencephalic transplants make widespread axonal connections in the host brain

Motor dysfunction in Parkinson's disease (PD) can be effectively alleviated through intra-striatal transplantation of fetal ventral mesencephalic tissue. The success of this approach is dependent on the survival, axonal outgrowth and synaptic integration of newly grafted dopamine neurons with the host striatum. The functional outcome of transplantation therapy has, however, been highly variable, particularly in PD patients, but also in animal models of PD, and thus there is a need for a deeper understanding of possible mechanisms underlying this variability such as graft composition and the resulting graft–host connectivity. Here we describe a series of transplantation experiments whereby mouse VM tissue has been grafted into the striatum of 6-hydroxydopamine lesioned rats. Six weeks after grafting immunohistochemical analysis using the mouse specific ‘M2M6’ antibodies revealed both dopaminergic and non-dopaminergic components of graft-derived fibre outgrowth into the host brain. We report here that while dopaminergic outgrowth was predominately confined to the striatum, there was also a significant degree of non-dopaminergic outgrowth to extra-striatal structures including the thalamus, cortex and midbrain. Retrograde tracing experiments showed that grafted neurons of GABAergic identity contribute to this non-dopaminergic outgrowth. In line with our recent findings on the function of serotonergic neurons in fetal VM grafts, these results further underscore the potential impact that non-dopaminergic neurons may have on the functional outcome of intrastriatal fetal VM grafts.     

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.     

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.     

Survival and growth of fetal catecholamine neurons transplanted into primate brain

Dopamine and norepinephrine neuroblasts of the ventral mesencephalon, hypothalamus, and dorsolateral pons were transplanted from fetal African green monkeys into multiple brain sites in adult (host) African green monkeys. Tissue was grafted from both early and late gestational age fetuses. Immunohistochemical analysis, with antibodies to tyrosine hydroxylase, a marker of catecholamine-containing neurons, showed large numbers of transplanted catecholamine neurons in host cerebral cortex, corpus striatum and lateral ventricles up to 69 days after transplantation. Serial reconstructions revealed extensive outgrowth of neuronal processes from large numbers of transplanted neurons as well as expansion of the size of transplanted (solid) grafts of fetal brain tissue in the host brain. Some grafts extended from the caudate nucleus into the adjacent lateral ventricles or from the cerebral cortex into the underlying corpus callosum and ventricle. There were dense networks of varicose fibers emanating from the tyrosine hydroxylase positive neurons within intraparenchymal and intraventricular grafts. The size and shape of transplanted neurons retained characteristics common to catecholaminergic neurons from the dissected regions of fetal brain. Thus, a variety of fetal, catecholamine-containing neurons survive transplantation to primate brain and produce extensive neuritic outgrowths. Moreover, rejection of transplanted tissue was not apparent. These findings provide essential information on nerve cell grafting in a species closely related to humans as a prerequisite in the consideration of neural transplants as therapeutic measures in neurological disease.     

Host afferents into intrastriatal transplants of fetal ventral mesencephalon

Host afferents into fetal ventral mesencephalic tissue grafted to the neostriatum of adult rats have been studied by using anterograde transport of Phaseolus vulgaris leucoagglutinin (PHA-L) and immunocytochemistry for serotonin (5-HT), Substance P (SP), and dopamine-adenosine 3':5'-monophosphate-regulated-phosphoprotein-32 (DARPP-32). Numerous fibers of cortical origin were detected in the transplants following multiple (11-15) iontophoretic injections of PHA-L into the frontal and anterior cingulate cortex. The labeled fibers occurred with an apparently random distribution throughout the graft tissue. Their overall density was lower than that of the surrounding striatum but similar to that found in the host nigra-ventral tegmental area. The majority of the PHA-L-labeled fibers in the grafts were thin and tortuous with varicosities or lateral clubs with terminal boutons. Dual labeling showed frequent close appositions between PHA-L-labeled terminals and dopamine-immunoreactive cell bodies. In parallel electron microscopy, synaptic contacts were observed between PHA-L-labeled terminals and unlabeled neuronal profiles in the graft. Other labeled fibers in the grafts were thick and smooth, corresponding probably to labeled myelinated axons observed in the electron microscope. These thick fibers were often seen to give off collaterals of the thin type. The virtual absence of such thick fibers in the normal striatal neuropil suggests that at least some of the cortical afferents to the grafts may have sprouted from axons normally projecting to diencephalic or brain stem regions. Serotonin fibers occurred in patches or as scattered single fibers in both deep and superficial portions of the nigral transplants. In the electron microscope some of these terminals were seen to establish synaptic contacts with nonimmunoreactive elements in the graft. These fibers were present also when the graft tissue had been pretreated with 5,7-dihydroxytryptamine at the time of transplantation. This treatment eliminated all 5-HT-containing neurons from the grafts without any noticeable adverse effect on the survival of the dopaminergic neurons. The serotonin fibers in the grafts were thus most likely of host origin. SP-positive fibers formed a dense plexus inside the grafts. Since many SP-positive cell bodies were visualized inside the transplant after colchicine pretreatment, it is unclear, however, whether any of these fibers were of host origin. Intrastriatal injections of PHA-L or DARPP-32 immunocytochemistry indicated that the deep portions of the nigral grafts were entirely devoid of host striatal afferents.(ABSTRACT TRUNCATED AT 400 WORDS)     

Generation of tyrosine hydroxylase-immunoreactive neurons in ventral mesencephalic tissue of Nurr1 deficient mice

Nurr1 is an orphan nuclear receptor belonging to the family of evolutionary conserved steroid/thyroid hormone receptors. It has been shown that Nurr1 is required for development of ventral mesencephalic dopaminergic cells in vivo and that Nurr1 regulates the tyrosine hydroxylase (TH) gene. The aim of this study was to investigate the possibility of finding ventral mesencephalic TH-positive neurons in Nurr1 deficient tissue when developed in the presence of wild type (WT) striatum. Therefore, fetal ventral mesencephalic tissue from embryonic day (E) 9.5-10.5 fetuses from Nurr1 mutant mice was co-cultured with lateral ganglionic eminence (LGE) from WT fetuses using the 'roller-drum' culture technique. TH-immunohistochemistry revealed similar number of positive neurons in WT, heterozygous, and Nurr1 deficient tissue, respectively. When ventral mesencephalon, dissected from E10.5 fetuses, was cultured alone without the presence of LGE, significantly more TH-immunoreactive neurons were found in WT and Nurr1 +/- than that seen in Nurr1 -/- cultures. In single ventral mesencephalic cultures dissected from E15.5, TH-positive neurons were found in all tissue cultures derived from knockout animals. Interestingly, the formation of TH-positive nerve fiber bundles was obvious in WT cultures while not observed in cultures of knockout tissue. When ventral mesencephalon was cultured alone in serum-free medium, almost no TH-positive neurons were found in cultures of knockout tissue. The addition of the growth factors epidermal growth factor and fibroblast growth factor-8 did not induce TH-immunoreactivity in serum-free Nurr1 -/- tissue cultures. In conclusion, TH-positive neurons may be generated in ventral mesencephalic tissue of Nurr1 deficient mice, suggesting that Nurr1 is not required for TH gene expression in ventral midbrain in vitro.