Noradrenergic Components of Locomotor Recovery Induced by Intraspinal Grafting of the Embryonic Brainstem in Adult Paraplegic Rats

Intraspinal grafting of serotonergic (5-HT) neurons was shown to restore plantar stepping in paraplegic rats. Here we asked whether neurons of other phenotypes contribute to the recovery. The experiments were performed on adult rats after spinal cord total transection. Grafts were injected into the sub-lesional spinal cord. Two months later, locomotor performance was tested with electromyographic recordings from hindlimb muscles. The role of noradrenergic (NA) innervation was investigated during locomotor performance of spinal grafted and non-grafted rats using intraperitoneal application of α₂ adrenergic receptor agonist (clonidine) or antagonist (yohimbine). Morphological analysis of the host spinal cords demonstrated the presence of tyrosine hydroxylase positive (NA) neurons in addition to 5-HT neurons. 5-HT fibers innervated caudal spinal cord areas in the dorsal and ventral horns, central canal, and intermediolateral zone, while the NA fiber distribution was limited to the central canal and intermediolateral zone. 5-HT and NA neurons were surrounded by each other’s axons. Locomotor abilities of the spinal grafted rats, but not in control spinal rats, were facilitated by yohimbine and suppressed by clonidine. Thus, noradrenergic innervation, in addition to 5-HT innervation, plays a potent role in hindlimb movement enhanced by intraspinal grafting of brainstem embryonic tissue in paraplegic rats.

Synapsin I in Intraocular Hippocampal Transplants during Maturation and Aging: Effects of Brainstem Cografts

The role of target innervation for maintenance of synaptic proteins in the hippocampal formation during aging was investigated. Fetal CA1 tissue and brainstem tissue containing the nucleus locus coeruleus was dissected from albino rats and grafted sequentially into the anterior chamber of the eye of adult rat recipients. Synapsin protein distribution and levels were evaluated by immunohistochemistry and quantitative immunolabeling in single hippocampal grafts or brainstem-hippocampal double grafts at 6,12, or 24 mo postgrafting. The synapsin levels in 6-mo-old single hippocampal transplants were significantly lower than those in situ, and remained at these lower levels at 12 and 24 mo. On the contrary, synapsin levels were close to normal in the hippocampal portion of double grafts in the 6- and the 12-mo-group. However, in the 24-mo-old double transplants the levels had declined significantly, approaching levels seen in single hippocampal grafts. The immunoblot results were supported by morphological observations with synapsin antibodies and immunohistochemistry. The present data demonstrate that hippocampal tissue maintained near normal synapsin levels when grafted together with brainstem tissue, as compared to the lower levels seen in single hippocampal grafts. This normalization of synapsin levels was, however, not seen in the aged hippocampal-brainstem double grafts.

Brain stem cells adopt a pituitary fate after implantation into the adult rodent pituitary gland

Fetal brain stem cells (RSCs) have been induced to express pituitary phenotypes in vitro in co-cultures with GH(3) cells and by exposure to GH(3)-conditioned media. In the current studies, we graft RSCs into the pituitary glands of adult rat to investigate whether grafted RSCs can be induced by the native gland to acquire pituitary properties. Grafted cells survive for 4 weeks and express Pit-1, GH, FSH, LH, ACTH, TSH and to a lesser extent PRL indicating that inductive influences are operative in vivo as well. This demonstrates that pluripotential cells can be induced to acquire properties of tissues different from their organ of origin likely through the action of cell-cell contact and local tissue factors.

Regeneration and recovery of the hearing function of the central auditory pathway by transplants of embryonic brain tissue in adult rats

The present study is the first report of successful regeneration and recovery of hearing function of the central auditory pathway after transection in the adult rat. The ventral cochlear tract in the brain stem to pons was transected on one side in adult rats. Tissue from embryos (E14 to E16) was used to cover the lesion site. In 30% of the rats examined, the axons regrew beyond the transected site and regenerated into the denervated side and terminated at the normal targets. The hearing function of rats was elucidated by recording the auditory brain stem response (ABR). Rats with successful regeneration showed nearly normal ABR. In rats receiving simple transection without covering embryonic tissue, there was no regeneration and hearing function did not recover. Thus, the present findings contradict the widely held view that the adult mammalian central auditory system cannot be restored following damage.

Patterning signals acting in the spinal cord override the organizing activity of the isthmus

The regionalization of the neural tube along the anteroposterior axis is established through the action of patterning signals from the endomesoderm including the organizer. These signals set up a pre-pattern which is subsequently refined through local patterning events. The midbrain-hindbrain junction, or isthmus, is endowed with such an organizing activity. It is able to induce graded expression of the Engrailed protein in the adjacent mesencephalon and rhombencephalon, and subsequently elicits the development of tectal and cerebellar structures. Ectopically grafted isthmus was also shown to induce Engrailed expression in diencephalon and otic and pre-otic rhombencephalon. Fgf8 is a signalling protein which is produced by the isthmus and which is able to mimic most isthmic properties. We show here that the isthmus, when transposed to the level of either rhombomere 8 or the spinal cord, loses its ability to induce Engrailed and cerebellar development in adjacent tissues. This is accompanied by the down-regulation of fgf8 expression in the grafted isthmus and by the up-regulation of a marker of the recipient site, Hoxb-4. Moreover, these changes in gene activity in the transplant are followed by a transformation of the fate of the grafted cells which adjust to their novel environment. These results show that the fate of the isthmus is not determined at 10-somite stage and that the molecular loop of isthmic maintenance can be disrupted by exogenous signals.

Regeneration of the central auditory pathway in adult rats

Regeneration of the auditory pathway in the central nervous system, which has not been reported previously, was investigated in adult rats. The ventral cochlear tract (VCT) in the medulla oblongata of adult rats was completely transected unilaterally by a ventral approach through an opening in the basioccipital bone. After postoperative intervals of 1 day to 3 months, the cochlear tract was examined by an anterograde tracing method using wheat germ aggulutinin-conjugated horseradish peroxidase (WGA-HRP) injected unilaterally in the ventral cochlear nucleus (VCN) ipsilateral to the lesion. In this simple transection experiment no regeneration was observed. However, when embryo brainstem tissue was transplanted on the transected site, regeneration occurred in about 30% of the rats examined. These results indicate the occurrence of obvious regeneration in the central auditory pathway, which was previously thought not to be restored once damaged, and they raise hope for future treatment of humans.

Collateral sprouting of central noradrenergic neurons during aging: histochemical and neurochemical studies in intraocular triple transplants

The sprouting capacity of aged noradrenergic neurons of the brain-stem nucleus locus coeruleus (LC) was examined using intraocular transplants of fetal tissues. Fetal hippocampal tissue (E18) and LC tissue (E15) were transplanted together as a double transplant into the anterior chamber of the eye of young adult Fischer 344 rats. The double transplants were allowed to mature for 14-18 months, after which an additional fetal hippocampal transplant was placed next to the LC graft. The triple transplants were monitored for overall growth and vascularization for an additional 2-6 months. Immunohistochemical examinations showed that both young (2-6 months old) and aged (16-24 months old) hippocampal cografts contained a plexus of thin varicose tyrosine hydroxylase (TH)-immunoreactive fibers extending throughout the grafted hippocampal tissues. However, the aged hippocampal grafts contained a denser uniform plexus of TH-positive fibers compared to the young transplants. Immunohistochemistry with synapsin antibodies demonstrated that both the young and the aged hippocampal transplants contained much higher densities of synaptic elements than the LC grafts. In vivo electrochemical measurements of potassium-evoked overflow of norepinephrine (NE) in the grafts showed that similar amounts of NE overflow were detected in both the young and the aged hippocampal grafts. HPLC-EC measurements of NE levels in the grafts revealed that there were similar amounts of NE in the young and the aged grafts, and the grafts did not contain serotonin or dopamine. In summary, the findings of the present study show that aged LC neurons are capable of undergoing collateral sprouting producing a functional NE neuronal system when introduced to an appropriate young target.

Changes in multiple brain regions underlie species differences in a complex, congenital behavior

The evolutionary brain modifications that produce any complex, congenital behavioral difference between two species have never been identified. Evolutionary processes may (i) alter a single, "higher" brain area that generates and/or coordinates the diverse motor components of a complex act; (ii) separately change independent, "lower" brain areas that modulate the fine motor control of the individual components; or (iii) modify both types of areas. This study explores the brain localization of a species difference in one such behavior, the crowing of chickens (Gallus gallus domesticus) and Japanese quail (Coturnix coturnix japonica). Two major subcomponents of the behavioral difference can be independently transferred with interspecies transplantation of separate brain regions, despite the fact that these components, sound and patterned head movement, occur together in a highly integrated fashion. To our knowledge, this is the first experimental demonstration that species differences in a complex behavior are built up from separate changes to distinct cell groups in different parts of the brain and that these cell groups have independent effects on individual behavioral components.

Survival and maturation of heterotopic fetal brain stem xenografts after treatment with 2-chlorodeoxyadenosine and cyclosporine A

Brain stem halves from fetal rabbits were transplanted to the caudate nucleus area of adult rats. The animals were treated postoperatively with cyclosporine A (CsA) and 2-chlorodeoxyadenosine (CdA) for three days, and with CdA alone for the next 13 days. The treatment started at the day of implantation, and in some animals it was repeated starting at day 36 after grafting (at the time when signs of a light inflammatory reaction appeared in some grafts). Grafts survived and matured histologically, and no signs of acute rejection were observed up to the 90th day. In some grafts we recorded phasic neuronal activities similar to the respiratory-related neural activities characteristic for the adult brain stem. Immunosuppressive with CdA and CsA deserves further evaluation in fetal brain grafting.

[A study of transpial migration of implanted serotonergic neurons in rat spinal cord]

Transpial migration of implanted 5-HT neurons from the subarachnoid space into the spinal cord was studied in adult Wistar rats. Embryonic raphe tissue or cell suspension containing 5-HT cells was used as grafts. The implanted 5-HT cells were monitored by 5-HT immunohistochemical method. The results are as follows: (1) 10 d after cutting the spinal cord at lower thoracic level, 5-HT fibers disappeared in the transected spinal cord. (2) Raphe tissue was implanted into the subarachnoid space of the thoracic lumbar segment after the spinal cord was cut. One month later, 5-HT positive cells could be found in the transected spinal cord with fibers extending into both the grey and the white matters. (3) If the raphe cell suspension instead was implanted, a number of 5-HT positive cells appeared in the grey matter near the implanted region and the distribution of these cells in the grey matter was quite consistent with the implanted range of the cell suspension in the subarachnoid space. The 5-HT positive cells which had entered into the spinal cord sent out fibers and reestablished a new fiber network in the grey matter. (4) After implantation, the number of the 5-HT positive fibers in the transected grey matter became more and more sparsely distributed with increasing distance from the cell bodies and the 5-HT positive fibers reappeared in the white matter were much less than that in the grey matter. Present results show that the implanted 5-HT neurons are able to migrate transpially from the subarachnoid space into the spinal cord.

Human fetal xenografts of brainstem tissue containing locus coeruleus neurons: functional and structural studies of intraocular grafts in athymic nude rats

Fetal human brainstem tissue including the nucleus locus coeruleus was transplanted to the anterior eye chamber of athymic nude rats. Most transplants survived and grew in the anterior chamber of the eye. After 9-15 months, the host animals were anesthetized and electrophysiological or in vivo electrochemical recordings were performed. The brainstem transplants contained spontaneously active neurons with regular single-spike firing patterns. The neurons responded to ipsilateral light stimulation with an increase in firing rate and to the alpha 2-receptor agonist clonidine with significantly decreased firing rates. In vivo electrochemical studies demonstrated reproducible noradrenergic overflow after local application of potassium. Immunohistochemical evaluation of the brainstem transplants showed an abundance of tyrosine hydroxylase-positive neurons and neurites in all transplants and a dense network of neurofilament-, synapsin-, and glial fibrillary acidic protein-positive profiles throughout the grafts. Taken together, the present physiological and histochemical data indicate that it is possible to obtain transplants containing a specific monoaminergic population within the brainstem from human fetal fragments and to maintain these transplants in oculo in athymic nude rats for at least 15 months, during which time noradrenergic neurons develop.

Distribution of the Blood-Brain Barrier in Heterotopic Brain Transplants and its Relationship to the Lesions of EAE

The blood-brain barrier (BBB) is recognized as a barrier to the trafficking of molecules and cellular elements into the central nervous system (CNS). Horseradish peroxidase (HRP) exclusion is used as a measure of BBB integrity. The BBB is altered and becomes permeable during the course of experimental allergic encephalomyelitis (EAE). Heterotopic brain transplantation into the anterior eye chamber is a technique for studying genetic influences and the role of individual cell types on the development of EAE. Prior to EAE induction, HRP is excluded from the central portion of the transplant, demonstrating an intact BBB. In contrast, HRP localization is found at the periphery of the transplant, suggesting an incomplete barrier. However, EAE lesions typically occur within the more central regions of the transplant, where the BBB is intact, and not at peripherally located "leaky" areas. This suggests that endothelial cells at intact BBB sites may direct trafficking of lymphocytes (gating) into the CNS during the development of EAE, rather than the passive entry of lymphocytes into the CNS through a leaky BBB.

Explorations of otic transplantation

Embryonic rat inner ears were transplanted to the anterior chamber of the eyes of adult rats. While considerable development was evident, the structures present were limited to the vestibular division. We hypothesized that this selective survival could be due to the rate of vascularization. To test the effects of graft vascularization we made transplants in which the internal structures were exposed by removing the apex and base of the developing cochlea. The transplants were rapidly vascularized by the iris. Many of the soft labyrinthine structures of the cochlea from 1-day-old donors showed considerable development, including the spiral limbus, basilar membrane, and organ of Corti. To test the possibility that the cochlea requires inductive or trophic support beyond Embryonic Day 15 (E15), we cotransplanted the embryonic inner ear with developing brain stem. In these transplants, we observed improved development of the cochlea, with spiral ganglion cells and an organ of Corti possessing hair cells, Deiter's cells, and pillar cells. To further address the effect of developing CNS tissue on the development of grafted inner ear, we transplanted E15 inner ears to either the cortex or the brain stem of neonatal rats. In these experiments we have seen evidence of both vestibular and cochlear sensory surfaces. In the cochlea, an organ of Corti-like structure can be seen. The possibility of neural connections with the host brain has yet to be investigated.

Age-induced changes in single locus coeruleus brain transplants grown in oculo: an in vivo electrochemical study

Brain stem tissue from fetal Sprague-Dawley rats containing the nucleus locus coeruleus (LC) was transplanted into the anterior chamber of the eye of young adult host rats and was studied at 4-6 months (young control) or 24-28 months after grafting (old). High-speed in vivo electrochemical measurements were used to characterize the potassium-evoked synaptic overflow of norepinephrine (NE) in both young and aged LC brain grafts. The amplitudes of potassium-evoked NE overflow were attenuated in the aged grafts as compared to the young LC grafts. In addition, the rise times of potassium-evoked responses were longer in the old LC grafts than in the young transplants. In contrast, the NE content of aged LC grafts, as determined by high-performance liquid chromatography coupled with electrochemical detection (HPLC-EC), was only slightly diminished and not significantly different from the NE levels seen in young LC grafts. However, light microscopical evaluation using tyrosine-hydroxylase immunocytochemistry revealed pyknotic cell bodies and fluorescent accumulations in aged locus coeruleus transplants which were indicative of degeneration in these grafts. The present data demonstrate a significant age-related decline in the presynaptic function of NE-containing neurons in intraocular locus coeruleus transplants of Sprague-Dawley rats.

Rearrangement of serotonin-immunoreactive fibers in the denervated rat suprachiasmatic nucleus after transplantation of fetal raphe tissue

Pieces of fetal midbrain raphe tissue were transplanted into the third ventricle or the ventral hypothalamic region near the suprachiasmatic nucleus (SCN) of adult host rats that had previously been denervated by treatment with 5,6-dihydroxytryptamine. The ability of grafted serotonin neurons to reinnervate the SCN in the host rats was studied by means of immunohistochemistry 1 and 3 months after transplantation. In both the intraventricular and intraparenchymal transplant experiments, reinnervation by outgrowing serotonin fibers was observed in the hypothalamus of host rats at 1 and 3 months after surgery. At both survival periods, there was no abundant arborization of serotonin fibers in the SCN, while the preoptic and periventricular areas of the host rats displayed a pattern of serotonergic innervation resembling that in normal (untreated) rats. It is suggested that within the SCN the regenerating serotonin fibers may be exposed to an inhibitory environment.

Reafferentation of the subcortically denervated hippocampus as a model for transplant-induced functional recovery in the CNS

Subcortical deafferentation of the hippocampal formation is known to induce profound behavioural deficits. Transplants of fetal septal or brainstem tissue are capable of restoring some aspects of normal physiological and behavioural function in subcortically deafferented (i.e. fimbria-fornix or septal lesioned) rats. Such grafts have been shown to re-establish extensive new afferent inputs to the denervated hippocampal formation. As shown for grafted cholinergic and noradrenergic neurons, the ingrowing axons form laminar innervation patterns which closely mimic those of the normal cholinergic and noradrenergic innervations. The ingrowth appears to be very precisely regulated by the denervated target: each neuron type produces distinctly different innervation patterns; the growth is inhibited by the presence of an intact innervation of the same type; and it is stimulated by additional denervating lesions. Both ultrastructually and electrophysiologically the graft-derived fibres have been seen to form extensive functional synaptic contacts. Biochemically, cholinergic septal grafts and noradrenergic locus coeruleus grafts restore transmitter synthesis and turnover in the reinnervated hippocampus. Intracerebral microdialysis has revealed that acetylcholine and noradrenaline release is restored to normal or supranormal levels in the graft-reinnervated hippocampus, and that the grafted neurons can be activated in a normal way from the host through behavioural activation induced by sensory stimulation or electrical stimulation of the lateral habenula. These results indicate that the grafted monoaminergic neurons can restore tonic regulatory neurotransmission at previously denervated synaptic sites even when they are implanted into the ectopic brain sites. Such functional reafferentation may be sufficient for at least partial restoration of function in the subcortically deafferented hippocampus.

Immunohistochemical studies on the development of tyrosine hydroxylase- and serotonin-immunoreactive neurons in fetal dorsal raphe tissue transplanted into the anterior eye chamber of adult rats

Pieces of tissue containing dorsal raphe nuclei of fetal rat brains were transplanted into the anterior eye chambers of adult rats. The differences between the developmental patterns of catecholaminergic and serotonergic neurons--especially the extension of their axonal processes--in the grafts were immunohistochemically examined using tyrosine hydroxylase (TH) and serotonin antisera. At an early stage after transplantation (3 days), TH-positive neurons appeared in grafts that had and had not been pretreated with a monoamine oxidase inhibitor (MAOI, Nialamide), while serotonin-positive neurons were demonstrated only in the grafts that had undergone MAOI pretreatment. Morphological differences in the growth pattern in the experimental milieu between the TH and serotonin neurons were also demonstrated: at this early stage, the somata of the TH neurons were multipolar and stellate shaped and possessed several distinct processes, while the serotonin neurons were ovoid shaped and lacked such processes. One week to 1 month after transplantation, the number of TH-positive fibers gradually increased, but their distribution was restricted to the area surrounding the cell bodies of the TH neurons in the graft. However, the processes of the serotonin neurons formed a dense plexus in the graft, and a small number of these fibers extended into the host iris 1 week after transplantation. By one month after the operation, the density of the serotonin fibers had gradually increased throughout the graft, and protruding serotonin fibers formed a network of varicose fibers in the host uveal tissue.(ABSTRACT TRUNCATED AT 250 WORDS)

Immunological reaction and blood-brain barrier in mouse-to-rat cross-species neural graft

Pieces of brainstem tissue from mouse embryos were transplanted into the cerebellar vermis of 49 adult rats, which had or which had not been treated with Cyclosporin A (10 mg/kg/day). With no treatment of immunosuppressants survival rates of xenografts were low. However, when Cyclosporin A was administered, the rates increased from 40% (4/10) to 67% (8/12) 2 weeks after grafting and from 25% (3/12) to 60% (9/15) 4 weeks after grafting, although immunological reactions of varying severities were noted in all of the surviving grafts. The present immunocytochemical study elucidated the composition of cell infiltrations frequently seen in the grafts. The results showed that a large number of cytotoxic/suppressor T lymphocytes appeared, while the numbers of helper/inducer T lymphocytes were relatively small. In addition, increased staining of astrocytes and microglia was observed in areas of cell infiltration. These activated cells might play a certain role in the process of graft rejection in the brain. Formation of the blood-brain barrier in the xenografts was examined by means of peroxidase cytochemistry and immunohistochemistry. In brains containing surviving grafts limited leakage of peroxidase, following its injection into the host systemic circulation 30-75 min prior to sacrifice, was detectable at the graft-host interface and at the operation scar near the pial surface. In brains containing rejected grafts extensive extravasation of peroxidase was detected. The severity of the immunological reaction was correlated with the intensity of the rupture in the blood-brain barrier. The findings suggested that the immunological reaction contributed to the transendothelial permeability changes in the vessels of brains containing rejected grafts.

Intraparenchymal allografts in the mouse brain in relation to immunocytochemical identification of T lymphocyte subsets

In a study of intracerebellar allografts of mice brainstem anlagen (embryonic day 12-14), we examined immunocytochemically the expression of two different types of T lymphocytes in and around the grafts. Helper/inducer and cytotoxic/suppressor T cells were identified with anti-L3T4 and anti-Lyt-2 monoclonal antibodies, respectively. Allografts into major histocompatibility complex (MHC)-compatible recipients showed no histological signs of rejection such as marked neovascularization and cellular infiltrates even 6 months after transplantation, but those into MHC-incompatible recipients generally had rejection reactions within one month after transplantation. In the latter cases, the L3T4/Lyt-2 ratio for the T lymphocytes in the infiltrates of the grafts was 1.03 +/- 0.14 (mean +/- S.D.), suggesting that both helper/inducer and cytotoxic/suppressor T cells may play important roles in the mediation of intraparenchymal brain allograft rejection.

Histological signs of immune reactions against allogeneic solid fetal neural grafts in the mouse cerebellum depend on the MHC locus

Using an immunocytochemical method, we examined the immunological responses of adult mice to intracerebellar syngeneic and allogeneic fetal mouse brainstem transplants (embryonic days 12-14). Syngeneic grafts and major histocompatibility complex (MHC)-compatible and non-MHC-incompatible allogeneic grafts survived well, showing no histological signs of rejection even 6 months after transplantation, and with no expression of MHC antigens being observed in any of the grafts. However, most cases of both MHC- and non-MHC-incompatible allografts showed rejection responses, such as marked neovascularization, cellular infiltration and necrosis, two weeks to one month after transplantation. In animals showing rejection, Class I MHC antigens were found on grafted neuronal tissue. An increased number of reactive astrocytes was also observed in the grafts. High levels of Class I antigen expression and prominent gliosis correlated with vigorous cellular infiltration. A quantitative analysis of T cell subsets in the animals showing rejection revealed that the L3T4/Lyt-2 ratio was 1.02 +/- 0.21 (mean +/- S.D.), indicating that helper/inducer and cytotoxic/suppressor T cells appeared equally in the rejection of MHC- and non-MHC-incompatible allografts. We consider that in these experiments, the brain was not completely an immunologically privileged site, and that MHC- and non-MHC-incompatible intraparenchymal neural transplants were not shielded from host immune surveillance.

Growth of neural transplants in rats: effects of initial volume, growth potential, and fresh vs frozen tissues

Interactions between growth potential (as related to the age of donor embryos and type of tissue), initial volume, and fresh vs frozen conditions of neural transplants were studied in rats. Neural tissues with high growth potential (16-day gestation neocortical tissue) when used fresh yielded the best growth of the transplants, which was positively related to the initial volume of the tissue. At the other extreme, neural tissues with very low growth potential when used following their freezing and thawing yielded the poorest results. Changes in the initial volume of transplants did not seem to improve the final growth. Combination of these variables in between these two extremes yielded transplants of variable sizes.

Heterotopic brain transplants in the study of experimental allergic encephalomyelitis

A heterotopic transplant paradigm was developed for its potential usefulness in dissecting genetically determined immune and central nervous system (CNS) components in the induction of experimental allergic encephalomyelitis (EAE). EAE is a cell-mediated, organ-specific, autoimmune disease producing inflammatory demyelination in the CNS. Susceptibility to EAE is determined by multiple genes and reflects both immune competence and target tissue responses. Syngeneic fetal CNS was heterotopically transplanted into the anterior chamber of the eye or beneath the capsule of the kidney of adult SJL or (SJL X BALB/c)F1 mice. Transplants usually survived better in the eye than the kidney. Six to eight weeks after transplantation, some mice were immunized for EAE. Immunized mice developed clinical and pathological signs of EAE in 12 to 15 days. The placement of CNS tissue into the eye or kidney prior to immunization did not suppress induction of EAE. Transplants in either location, in immunized mice, manifested perivascular inflammation and demyelination similar to that seen in the host CNS. However, transplants in mice not immunized for EAE, but maintained an equal time period after transplantation, did not demonstrate these features. The ability to produce the specific pathologic lesions of EAE in CNS tissue transplanted outside the CNS allows the design of studies of the tissue localization of genetic restrictions to development of EAE.

Embryonic hippocampal grafts ameliorate the deficit in DRL acquisition produced by hippocampectomy

Transplants of fetal neural tissue survive and develop in lesion cavities produced in adult rats. The present experiment tested the effect of grafting fetal hippocampal or brainstem tissue on the ability of rats with hippocampal lesions to perform on a differential reinforcement of low response rate (DRL) operant schedule. The DRL interval was 20s. Eighty-six percent of the hippocampal grafts and 69% of the brainstem grafts developed to maturity. Inspection of sections from rats in which the mature transplant had been injected with Fast blue, indicated that these grafts formed connections with the host brain. Consistent with previous reports, rats with hippocampal lesions were impaired in performance of the DRL task. Rats given fetal grafts of hippocampal tissue into the hippocampal lesion site on the day of lesion production were significantly better in performance of the DRL requirement than were lesion-only rats or rats receiving grafts of fetal brainstem tissue. The results of this study confirm that grafts of fetal brain tissue can both develop in a lesion site in an adult brain and ameliorate lesion-induced behavioral deficits.

Transplantation of dissociated foetal serotonin neurons into the transected spinal cord of adult rats

Twenty adult rats underwent a complete section of the spinal cord at the lower thoracic level. One week later, 15 of them received a cell suspension obtained from raphe nuclei of 14-day-old foetuses into the distal fragment of the spinal cord. They were sacrificed after survival periods of 10-60 days, and vibratome sections of the spinal cord were processed for immunocytochemical detection of serotonin (5-HT). The control, non-transplanted animals showed a total absence of 5-HT immunoreactivity below the section, whereas the transplanted rats showed many immunoreactive 5-HT perikarya in the graft region, some at a distance of up to 10 mm, and a progressive innervation of the whole grey matter extending at least over 20 mm from the graft site.

Neural tissue grafts and repair of the injured spinal cord

Neural tissue grafting presently stands as one of the more intriguing experimental strategies being applied to the problem of spinal cord regeneration. The following annotation presents an overview of recent investigations which have shown: that peripheral nerve grafts can stimulate axonal outgrowth in many descending and ascending fibre populations of the injured spinal cord and that central nervous system (CNS) implants, derived from segmental and supraspinal levels of the embryonic neuraxis, may likewise have the potential for promoting repair of damaged intraspinal neural circuitries in adult and neonatal recipients.

Postnatal development of the serotonin innervation of the hippocampus and dentate gyrus following raphe implants

Serotoninergic (5-HT) neurons derived from the embryonic raphe nuclear area (brainstem, embryonic days (E 16-18) were implanted into the entorhinal cortex of 6-day-old (P6) neonatal rat recipients which had received a fimbria lesion and entorhinal cortex ablation on P3. The hippocampus, dentate gyrus, and the raphe implant area were examined with 5-HT immunohistochemistry 7, 14, 21, 30, and 60 days after implantation. The pattern of 5-HT reinnervation was compared to that of normal and lesioned animals, and to previous studies in which rats received septal or striatal implants. In the hippocampus adjacent to the implant 5-HT-immunoreactive fibers were first observed by 7 days postimplantation and increased in density and in their septotemporal and dorsoventral extent with increasing time postimplantation. Moderately dense fiber networks were diffusely distributed in the hippocampus and dentate gyrus at 30 and 60 days postimplant. Little, if any, indication of lamination was present. Retrogradely labeled neurons (the majority of which contained 5-HT immunoreactivity) were observed in the raphe implant following injections of Fast Blue into the hippocampal formation. A few retrogradely labeled cells did not contain 5-HT, methionine-enkephalin (ME), or substance P (SP) immunoreactivity, although ME- and SP- immunoreactive neurons were observed in the implants. The lamination patterns and the increased density of 5-HT-immunoreactive fibers following a raphe implant into the entorhinal cortex clearly differ from the normal 5-HT pattern and from the patterns of lamination following a striatal or septal implant.

Neural transplantation in the spinal cord of adult rats. Conditions, survival, cytology and connectivity of the transplants

Embryonic neural tissues of various types were transplanted into the intact, completely transected, and partially transected spinal cords of adult rats. The host animals were killed 4-6 months after the surgery, and the spinal cords and transplants examined. The best results were obtained when embryonic neocortical tissues obtained from 16-day rat embryos were used for transplantation into host animals that had been subjected to partial sectioning of the spinal cord. Use of other types of neural tissue, or transplantation of tissues into the intact or completely severed spinal cords was not successful. The successful neocortical transplants had survived, grown, differentiated, and established anatomical integration with the host spinal cords. The anatomical integration was established through an interface with the host spinal cord along the basal aspect. Along the lateral aspect glial scar tissue was present separating the transplants from the spinal cord parenchyma. The transplants contained well-differentiated and normal-looking neurons. They received afferents from the spinal cord only through the interface and not through the glial scar formations. The findings indicated that it is possible to transplant embryonic neocortical tissues into the spinal cords of the adult animals that become integrated with the spinal cord parenchyma. The axonal fibers in the adult spinal cord appear capable of regeneration and growing into the transplants only when an appropriate neural milieu, in the form of a healthy and viable interface, is available. In its absence the severed axons of the adult spinal cord do not grow into the neural transplants.

Adult age destruction versus neonatal age destruction of the serotonin system: two models to investigate the survival of serotonin neurons transplanted in adult rats

Mesencephalic raphe nuclei were transplanted via the cisterna magna in the IVth ventricle of adult rats having received either a neonatal or an adult age destruction of the serotonin system. In neonatally treated rats both serotonin (5-HT) and glial fibrillary acidic protein (GFA) immunocytochemistry showed an absence of survival of 5-HT neurons in the transplants. However, many 5-HT immunoreactive cell bodies and processes were detected in 10-month-old transplants in adult treated animals. These results suggest that recognition processes between the target tissue and the implant may be a prerequisite for the survival of grafted neurons.

Freezing of neural tissues and their transplantation in the brain of rats: technical details and histological observations

Embryonic neocortical and brainstem tissues were frozen, stored for variable periods, thawed and transplanted into the cerebellum of neonatal host rats. Various conditions related to freezing, media for freezing, DMSO as the cryoprotectant, and thawing were analyzed. The findings indicated that the following conditions yielded best results for neocortical transplantation: freezing at a rate of 1 degrees C/min, using rat amniotic fluid as the medium for freezing, using 10% DMSO as the cryoprotectant, storing the frozen tissues at -90 degrees C, thawing the tissues fast just prior to transplantation, and transplanting them in the host brain with little or no delay. Other conditions having adverse effects on the neural tissues were considered. Issues pertaining to transplantability and retainability of the neural tissues inside the host brain, and effects of freezing and thawing on the long-term viability of the neural tissues and their growth are discussed.

Reinnervation of the denervated adult spinal cord of rats by intraspinal transplants of embryonic brain stem neurons

Previous studies have revealed a remarkable capacity of intracerebral grafts of embryonic brain tissue to establish extensive axonal connections with denervated areas in the brains of adult rats. In the present study we have explored the possibilities of using grafts in the spinal cord to substitute for the loss of noradrenergic brain-stem inputs to the severed spinal cord. Intraspinal grafts of embryonic pontine noradrenergic neurons were made into the lower thoracic region of adult rats. Three different surgical techniques were tested: (i) grafting to a small central cavity in the spinal-cord grey matter; (ii) grafting to a small subpial cavity involving removal of the dorsolateral third of the spinal-cord matter; (iii) grafting to the gap between the rostral and caudal stumps of the spinal cord after a nearly complete subpial transection. The results indicate that direct contact with the vessel-rich pia is essential for good survival of the grafts. Provided that the pia was left intact, the scarring around the grafts was minimal and the grafts fused well with both the grey and white matter of the cord. In the subpially transected cord, a brain-stem graft taken from a young embryonic donor fused well with both the rostral and the caudal stumps of the severed cord and thus restored tissue continuity across the gap. Large numbers of catecholamine (CA)-containing and non-monoaminergic cells were present in the transplants after 3-6 months. CA fluorescence histochemistry in combination with injections of fluorescent retrograde tracers revealed that both noradrenergic and non-monoaminergic neurons in the grafts had grown to reinnervate large segments of the host spinal cord. In those cases where the transplant had fused well with the cord, abundant CA-fluorescent axons could be traced across the graft-cord junction. They course along the grey and white matter of the host cord to reestablish a new CA terminal plexus in the grey matter as far as 12 mm from the graft.

The viability of transplants of mesencephalic raphe nuclei in the IVth ventricle of the adult rat

Mesencephalic raphe nuclei were transplanted via the cisterna magna near the locus coeruleus. The transplants were observed at different time intervals ranging from 24 h to 4 months. Microscopic observations revealed that from 3 weeks to 4 months the transplant developed with a well-defined neural organization. Radioautographic results showed that some of the neurons in the implant at 3 weeks captured and retained [3H] serotonin. These results indicate that the intact IVth ventricle seems to be a likely culturing floor for mesencephalic raphe nuclei.

Studies of the cellular cure for osteopetrosis by transplanted cells: specificity of the cell type in ia rats

Spleen cells from normal rats are known to cure osteopetrosis in ia littermates within 3 weeks. In this study cell suspensions from liver, thymus, bone marrow, salivary gland, skeletal muscle and brain from normal rats were tested for their ability to cure osteopetrosis in ia littermates whose ability to reject these cells had been suppressed by whole-body irradiation. Cells from liver, thymus and bone marrow cured the disease as effectively as spleen cells from normal littermates. Mutants that received cells from salivary gland, muscle and brain remained osteopetrotic. These data suggest that some cell found in spleen, liver, thymus and bone marrow of 10-day-old normal rats, such as a lymphoid cell or stem cell, can restore hemopoiesis and bone resorption in osteopetrotic (ia) rats.