Development of an Intact Blood-Brain Barrier in Brain Tissue Transplants is Dependent on the Site of Transplantation

Transplantation of fetal septal forebrain tissue was performed to the anterior chamber of the eye, or intracranially to the rostral hippocampal formation in rats, to evaluate the impact of transplantation site on the development of an intact blood–brain barrier (BBB). The tissue was studied at 1, 2, 3, and 4 wk following transplantation by means of intravenous injection of Trypan blue, which is a vital stain not normally penetrating the BBB, as well as with an antibody specifically directed against the rat BBB, SMI71. In the intraocular septal transplants, there was a significant leakage of Trypan blue 1 wk postgrafting, associated with a few laminin-immunoreactive blood vessels that did not contain any SMI71-immunoreactivity. However, at 2 wk postgrafting, the intraocular grats exhibited an extensive plexus of thin-walled blood vessels expressing SMI71 immunoreactivity and no Trypan blue leakage. Thus, it appeared that a BBB had developed to some degree by 2 wk postgrafting in oculo. In the intracranial grafts, on the other hand, Trypan blue leakage could be seen as long as 3 wk postgrafting, and a dense plexus of blood vessels with SMI71 immunoreactivity was first seen at 4 wk postgrafting. Thus, the development of Trypan blue impermeability was delayed with 1 to 2 wk in the intracranial versus the intraocular grafts. Control experiments using psychological stress in adult rats as a means to transiently disrupt the BBB revealed that an increase in Trypan blue leakage correlated well with the disappearance of SMI71 immunoreactivity. Taken together, these studies demonstrate that the site of transplantation can influence the development of an intact BBB in neural tissue grafts.

Interneuron progenitors attenuate the power of acute focal ictal discharges

Interneuron progenitors from the embryonic medial ganglionic eminence (MGE) can migrate, differentiate, and enhance local inhibition after transplantation into the postnatal cortex. Whether grafted MGE cells can reduce ictal activity in adult neocortex is unknown. We transplanted live MGE or killed cells (control) from pan green fluorescent protein expressing mice into adult mouse sensorimotor cortex. One week, 2 and 1/2 weeks, or 6 to 8 weeks after transplant, acute focal ictal epileptiform discharges were induced by injection of 4-aminopyridine (4-AP) 2 mm away from the site of transplantation. The local field potential of the events was recorded with 2 electrodes, 1 located in the 4-AP focus and the other 1 in the transplantation site. In all control groups and in the 1-week live cell transplant, 4-AP ictal discharges revealed no attenuation in power and duration from the onset site to the site of transplantation. However, 2.5 or 6 ~ 8 weeks after MGE transplants, there was a dramatic decrease in local field potential power at the MGE transplanted site with little decrease in ictal duration. Surprisingly, there was no relationship between grafted cell distribution or density and the degree of attenuation. As remarkably low graft densities still significantly reduced discharge power, these data provide further support for the therapeutic potential of interneuron precursor transplants in the treatment of neocortical epilepsy.

Long-term culture and neuronal survival after intraspinal transplantation of human spinal cord-derived neurospheres

There is heterogeneity in neural stem and progenitor cell characteristics depending on their species and regional origin. In search for potent in vitro-expanded human neural precursor cells and cell therapy methods to repair the injured human spinal cord, the possible influence exerted by intrinsic cellular heterogeneity has to be considered. Data available on in vitro-expanded human spinal cord-derived cells are sparse and it has previously been difficult to establish long-term neurosphere cultures showing multipotentiality. In the present paper, human spinal cord-derived neurospheres were cultured in the presence of EGF, bFGF and CNTF for up to 25 passages (>350 days) in vitro. In contrast to the human first trimester subcortical forebrain, spinal cord tissue>9.5 weeks of gestation could not serve as a source for long-term neurosphere cultures under the present conditions. After withdrawal of mitogens, cultured neurospheres (at 18 passages) gave rise to cells with neuronal, astrocytic and oligodendrocytic phenotypes in vitro. After transplantation of human spinal cord-derived neurospheres to the lesioned spinal cord of immuno-deficient adult rats, large numbers of cells survived at least up to 6 weeks, expressing neuronal and astrocytic phenotypes. These results demonstrate that it is possible to expand and maintain multipotent human spinal cord-derived neurospheres in vitro for extended time-periods and that they have promising in vivo potential after engraftment to the injured spinal cord.

Generation of distinct types of periglomerular olfactory bulb interneurons during development and in adult mice: implication for intrinsic properties of the subventricular zone progenitor population

The subventricular zone (SVZ) of the lateral ventricle develops from residual progenitors of the embryonic lateral ganglionic eminence (LGE) and maintains neurogenic activity throughout life. Precursors from LGE/SVZ migrate to the olfactory bulb (OB) where they differentiate into local interneurons, principally in the granule layer and glomerular layer (GL). By in situ dye labeling, we show that neonatal and adult SVZ progenitors differentially contribute to neurochemically distinct types of periglomerular interneurons in the GL. Namely, calbindin-positive periglomerular cells are preferentially generated during early life, whereas calretinin- and tyrosine hydroxylase-expressing neurons are mainly produced at later ages. Furthermore, homochronic/heterochronic transplantation demonstrates that progenitor cells isolated from the LGE or SVZ at different stages (embryonic day 15 and postnatal days 2 and 30) engraft into the SVZ of neonatal or adult mice, migrate to the OB, and differentiate into local interneurons, including granule and periglomerular cells as well as other types of interneurons. The total number of integrated cells and the relative proportion of granule or periglomerular neurons change, according to the donor age, whereas they are weakly influenced by the recipient age. Analysis of the neurochemical phenotypes acquired by transplanted cells in the GL shows that donor cells of different ages also differentiate according to their origin, regardless of the host age. This suggests that progenitor cells at different ontogenetic stages are intrinsically directed toward specific lineages. Neurogenic processes occurring during development and in adult OB are not equivalent and produce different types of periglomerular interneurons as a consequence of intrinsic properties of the SVZ progenitors.

A roof plate-dependent enhancer controls the expression of Homeodomain only protein in the developing cerebral cortex

The smallest known homeodomain protein, Homeodomain only protein (Hop), was identified and described here as a temporally and spatially restricted gene in the neurogenic regions of the developing murine CNS including the cerebral cortex. Furthermore, an evolutionarily conserved 418 base pair upstream cis-regulatory DNA sequence was found to confine the Hop expression to the CNS of transgenic mice, but not to the heart which is the second major Hop expressing organ Chen, F., Kook, H., Milewski, R., Gitler, A.D., Lu, M.M., Li, J., Nazarian, R., Schnepp, R., Jen, K., Biben, C., Runke, G., Mackay, J.P., Novotny, J., Schwartz, R.J., Harvey, R.P., Mullins, M.C., Epstein, J.A., 2002. Hop is an unusual homeobox gene that modulates cardiac development. Cell 110, 713-723; Shin, C.H., Liu, Z.P., Passier, R., Zhang, C.L., Wang, D.Z., Harris, T.M., Yamagishi, H., Richardson, J.A., Childs, G., Olson, E.N., 2002. Modulation of cardiac growth and development by HOP, an unusual homeodomain protein. Cell 110, 725-735. The forebrain enhancer activity was successfully reproduced in vitro utilizing a combination of the electroporation and the organotypic brain culture method. Using this approach, the minimal requirement for the forebrain-specific enhancer sequence was delineated down to 200 base pairs. We further demonstrate that the Hop enhancer activity is inducible ectopically in a transgenic tissue by wild-type roof plate transplantation in vitro. Thus Hop is regulated in the forebrain by a so far unidentified paracrine signaling factor from the roof plate. Furthermore, the identified enhancer sequence provides an important tool for the targeted expression of transgenes in the medial cortex and the cortical hem.

Comparison between fetal spinal-cord- and forebrain-derived neural stem/progenitor cells as a source of transplantation for spinal cord injury

Recently, we have shown that the transplantation of spinal-cord-derived neural stem/progenitor cells (NSPCs) can contribute to the repair of injured spinal cords in adult rats, which may correspond to a behavioral recovery. To apply these results to clinical practice, a system for supplying human NSPCs on a large scale must be established. However, human spinal-cord-derived NSPCs are known to have a low proliferation rate, compared with forebrain-derived NSPCs. This low proliferative potency limits the feasibility of large-scale spinal cord-derived NSPC use. Thus, forebrain-derived NSPCs should be examined as an alternative to spinal-cord-derived NSPCs for the treatment of spinal cord injuries. In this study, we compared spinal-cord- and forebrain-derived NSPCs transplanted into injured spinal cords with respect to their fates in vivo as well as the animals' functional recovery. Both spinal-cord- and forebrain-derived NSPCs promoted functional recovery in rats with spinal cord injuries. While both spinal-cord- and forebrain-derived NSPCs survived, migrated and differentiated into neurons, astrocytes and oligodendrocytes in response to the microenvironment within the injured spinal cord after transplantation, forebrain-derived NSPCs differentiated into more neurons and fewer oligodendrocytes, compared to spinal-cord-derived NSPCs. Neurons that had differentiated from the transplanted forebrain-derived NSPCs were shown to be positive for neurotransmitters like GABA, glutamate and glycine, although authentic glycinergic neurons are not normally present within the forebrain. Thus, at least a subpopulation of the transplanted forebrain-derived NSPCs differentiated into spinal-cord-type neurons. In conclusion, forebrain-derived NSPCs could be used as an alternative to spinal-cord-derived NSPCs as a potential therapeutic agent for spinal cord injuries.

Neuronal differentiation following transplantation of expanded mouse neurosphere cultures derived from different embryonic forebrain regions

In vitro, expanded neurospheres exhibit multipotent properties and can differentiate into neurons, astrocytes and oligodendrocytes. In vivo, cells from neurospheres derived from mouse fetal forebrain have previously been reported to predominantly differentiate into glial cells, and not into neurons. Here we isolated stem/progenitor cells from E13.5 lateral ganglionic eminence (LGE), medial ganglionic eminence (MGE) and cortical primordium, of a green fluorescent protein (GFP)-actin transgenic mouse. Free-floating neurospheres were expanded in the presence of epidermal growth factor (EGF) and basic fibroblast growth factor (bFGF) and implanted after five to six passages into the striatum, hippocampus and cortex of neonatal rats. Cell suspensions of primary LGE tissue were prepared and grafted in parallel. Grafted cells derived from the primary tissue displayed widespread incorporation into all regions, as visualized with the mouse-specific antibody M2, or mouse satellite DNA in situ hybridization, and differentiated into both neurons, astrocytes and oligodendrocytes. Grafts of neurosphere cells derived from the LGE, MGE and cortical primordium differentiated primarily into astrocytes, but contained low but significant numbers of GFP-immunoreactive neurons. Neurons derived from LGE neurospheres were of three types: cells with the morphology of medium-sized densely spiny projection neurons in the striatum; cells with interneuron-like morphologies in striatum, cortex and hippocampus; and cells integrating into SVZ and migrating along the RMS to the olfactory bulb. MGE- or cortical primordium-derived neurospheres differentiated into interneuron-like cells in both striatum and hippocampus. The results demonstrate the ability of in vitro expanded neural stem/progenitor cells to generate both neurons and glia after transplantation into neonatal recipients, and differentiate in a region-specific manner into mature neurons with morphological features characteristic for each target site.

Neuroprotection by human neural progenitor cells after experimental contusion in rats

Neural progenitor/stem cells (HNPC) have been suggested to contribute essential trophic factors and promote survival of degenerating neurons after traumatic brain injury. For these reasons we hypothesize that the addition of HNPC to a post-injury region could possibly protect injured neurons. Experimental brain contusions were carried out in 18 rats. Immediately post-injury, rats were injected with 0.1 ml of medium (n=8), dead cells (n=4), or live cells (n=6) in the medial border of the lesion. The rats were sacrificed 6 days post-surgery and evaluated by immunohistochemistry using a human nuclear marker (huN), hematoxylin and Fluoro-Jade (FJ). Human neural stem cells showed engraftment detectable by positive huN staining in 5/6 animals. The non-grafted animal was excluded from further analyses. Those given dead HNPC or medium showed no detectable huN immunoreactivity. A statistical comparison between the numbers of FJ positive degenerating endogenous neurons was made between rats receiving vehicle and dead cells to evaluate whether the presence of human cells would increase neuronal degeneration in comparison to vehicle alone. The rats receiving vehicle had a median of 117.5 FJ positive cells and dead progenitor cell recipients 175.0 per counted section (P<0.05, Mann-Whitney). Consequently, the animals receiving dead human cells were chosen as controls to the animals receiving live progenitor cells. The rats that received live HNPC demonstrated significantly fewer FJ positive cells per counted section than controls (58.0 vs. 175.0, P<0.01, Mann-Whitney). The post-traumatic perilesional environment allowed for the engraftment of live HNPC. The stepwise analysis indicated that host neuronal degeneration was higher in animals transplanted with non-viable human neuronal progenitor cells than in those receiving vehicle, indicating a bystander effect from introducing foreign antigen. In contrast, transplantation of viable progenitor cells attenuated neuronal degeneration, indicating that a potentially beneficial effect in progenitor cell transplantation is not limited to restoration by transplanted cells, but also improving survival of host cells.

A transplantation study of expanded human embryonic forebrain precursors: evidence for selection of a specific progenitor population

Neural stem and progenitor cells can be expanded under growth factor stimulation in vitro. It is likely that different mitogens and different culturing techniques selectively expand specific subclasses of cells, but this selection has not been well studied. We have expanded human cells isolated from the lateral ganglionic eminence (LGE) of a 10-week-old embryo in the presence of serum and epidermal growth factor. We provide evidence that culturing in this manner favors expansion of cells with characteristics similar to a subpopulation of LGE cells, the olfactory bulb progenitors, as revealed by their expression of Er81 in vitro. After transplantation into neonatal rats, the cells displayed similar properties to endogenous olfactory bulb progenitors when exposed to local cues present in the subventricular zone (SVZ) and rostral migratory stream (RMS). However, the human LGE cells do not migrate or undergo region-specific differentiation when placed outside the SVZ and RMS.

Layer specification of transplanted interneurons in developing mouse neocortex

The six-layered neocortex is composed of excitatory projection neurons and inhibitory interneurons. Recent studies have established separate embryological origins for these two cellular populations. However, it remains uncertain how interneurons arising from the subcortical ganglionic eminences are able to participate in the orderly stratification of the cortical layers. A related question concerns whether or not early and late interneuron progenitors have equivalent developmental potentials. To address these issues, we performed transplantation experiments to test the fates of early-versus late-born interneuron populations using cells labeled with a genetic marker. Our results indicate that transplanted interneurons from the medial ganglionic eminence give rise to specific layers of the neocortex in an inside-out order. To test the potency of interneurons born at different ages, heterochronic transplantations were also performed. Both early- and late-born progenitors were able to switch their fates in the new environment, and, similar to projection neurons, fate-switching was dependent on progenitor receptivity to environmental cues during their last round of cell division. Our data also demonstrate, for the first time, that interneuron-layering cues are present within the medial ganglionic eminence, suggesting that, before the commencement of long-distance tangential migration, interneurons are already specified with respect to their future layer addresses. So, although the generation of diverse neuronal phenotypes in separate locations is an effective strategy to pursue separate developmental programs, our results indicate that excitatory and inhibitory neurons share similar mechanisms for integrating sequentially born neurons from two places into a single layered structure.

Restorative potential of cholinergic rich transplants in cholchicine induced lesioned rats: a comparative study of single and multiple micro-transplantation approach

Restorative potential of fetal neural transplantation in colchicine induced neurodegeneration was studied in rats; where colchicine (2.5mg per site) was administered bilaterally into the hippocampus followed by bilateral infusions of fetal neural cell suspension rich in cholinergic neurons as single macro- or multiple micro-transplants in the hippocampal region 3 weeks post-colchicine (2.5mg per site) lesion. Animals were studied for neuro behavioural and neurochemical recovery at 4 and 24 weeks post-transplantation and electrophysiological (single cell recording) and immunohistochemical parameters, choline acetyl transferase (ChAT) expression was studied in hippocampus at 24 weeks post-transplantation. Colchicine lesioned rats receiving single macro- or multiple micro-transplants exhibited significant restoration in cognitive dysfunction caused by colchicine after 4 weeks of transplantation which remain persistent in multiple micro-transplanted group upto 24 weeks post-transplantation, whereas, single macro-transplanted animals did not exhibit any significant recovery. Neurochemical studies revealed significant restoration in acetylcholine esterase activity and cholinergic (muscarinic) receptor binding after 24 weeks post-transplantation as compared to 4 weeks post-transplantation in multiple micro-transplanted group. Single cell recording studied at 24 weeks post-transplantation exhibited significant restoration in firing rates when compared with lesioned group. The viability of cholinergic fibre at transplanted sites has further been confirmed by increase in ChAT immuno positivity in hippocampal region using monoclonal antibody and quantified using image analyser Leica Qwin 500 software. The results suggest that intra-hippocampal multiple site cholinergic rich transplants provide better and long term restoration in the cholinergic deficits induced by colchicine lesion as compared to single site macro-transplantation.

Fibroblast growth factor-2 (FGF-2) and platelet-derived growth factor AB (PDGF AB) promote adult SVZ-derived oligodendrogenesis in vivo

The capacity of multipotential progenitor cells of the adult mammalian forebrain to generate myelin-forming oligodendrocytes was tested by grafting fragments of different regions of the subventricular zone (SVZ) of the lateral ventricle and the striatum of 6-month-old wild-type mice into the brain of neonate shiverer and wild-type mice. Without growth factor treatment, only few cells of the rostral SVZ survived and formed myelin after engraftment. Treating donors prior to transplantation with a single intraperitoneal injection of epidermal growth factor, basic fibroblast growth factor 2 (FGF-2), and platelet-derived growth factor AB (PDGF(AB)) vigorously promoted the survival, migration, and differentiation of the grafted SVZ cells into myelin-forming oligodendrocytes. In situ, both growth factors expanded the constitutively proliferative PSA-NCAM+ population and favored their differentiation toward the neuronal and oligodendroglial cell fate. The adult central nervous system thus harbors a focal reservoir of FGF-2 and PDGF(AB)-responsive cells which are able to generate substantial amounts of myelin-forming oligodendrocytes in vivo, opening a new prospective area for therapy in demyelinating diseases.

Fate map of the chicken neural plate at stage 4

A detailed fate map was obtained for the early chick neural plate (stages 3d/4). Numerous overlapping plug grafts were performed upon New-cultured chick embryos, using fixable carboxyfluorescein diacetate succinimidyl ester to label donor chick tissue. The specimens were harvested 24 hours after grafting and reached in most cases stages 9-11 (early neural tube). The label was detected immunocytochemically in wholemounts, and cross-sections were later obtained. The positions of the graft-derived cells were classified first into sets of purely neural, purely non-neural and mixed grafts. Comparisons between these sets established the neural plate boundary at stages 3d/4. Further analysis categorized graft contributions to anteroposterior and dorsoventral subdivisions of the early neural tube, including data on the floor plate and the eye field. The rostral boundary of the neural plate was contained within the earliest expression domain of the Ganf gene, and the overall shape of the neural plate was contrasted and discussed with regard to the expression patterns of the genes Plato, Sox2, Otx2 and Dlx5 (and others reported in the literature) at stages 3d/4.

Transplantation of human neural progenitor cells into the neonatal rat brain: extensive migration and differentiation with long-distance axonal projections

Here we examined the ability of human neural progenitors from the embryonic forebrain, expanded for up to a year in culture in the presence of growth factors, to respond to environmental signals provided by the developing rat brain. After survival times of up to more than a year after transplantation into the striatum, the hippocampus, and the subventricular zone, the cells were analyzed using human-specific antisera and the reporter gene green fluorescent protein (GFP). From grafts implanted in the striatum, the cells migrated extensively, especially within white matter structures. Neuronal differentiation was most pronounced at the striatal graft core, with axonal projections extending caudally along the internal capsule into mesencephalon. In the hippocampus, cells migrated throughout the entire hippocampal formation and into adjacent white matter tracts, with differentiation into neurons both in the dentate gyrus and in the CA1-3 regions. Directed migration along the rostral migratory stream to the olfactory bulb and differentiation into granule cells were observed after implantation into the subventricular zone. Glial differentiation occurred at all three graft sites, predominantly at the injection sites, but also among the migrating cells. A lentiviral vector was used to transduce the cells with the GFP gene prior to grafting. The reporter gene was expressed for at least 15 weeks and the distribution of the gene product throughout the entire cytoplasmic compartment of the expressing cells allowed for a detailed morphological analysis of a portion of the grafted cells. The extensive integration and differentiation of in vitro-expanded human neural progenitor cells indicate that multipotent progenitors are capable of responding in a regionally specific manner to cues present in the developing rat brain.

Long-term basal forebrain cholinergic-rich grafts derived from trisomy 16 mice do not develop beta-amyloid pathology and neurodegeneration but demonstrate neuroinflammatory responses

Patients with Down syndrome (human trisomy 21) develop neuropathological and cholinergic functional defects characteristic of Alzheimer's disease, which has been attributed to the location of the Alzheimer beta-amyloid precursor protein on chromosome 21. Due to the partial genetic homology between mouse chromosome 16 and human chromosome 21, murine trisomy 16 was used as a model to study functional links between increased expression of the amyloid precursor protein, neurodegeneration and neuroinflammatory responses. Basal forebrain cholinergic-rich tissue derived from trisomy 16 mice at embryonic age of day 16 was transplanted into the lateral ventricle of adult normal mice. At 1, 3, 6, 9 and 12 months after transplantation, the grafts were characterized by immunocytochemistry, molecular biological analysis, and stereological methods. Grafts survived up to one year and still demonstrated immunoreactivity for cholinergic, GABAergic and astroglial cells. Though a 1.5-fold neuronal over-expression of amyloid precursor protein was detected in brains from trisomy 16 embryos by Northern analysis, beta-amyloid deposits were found neither in control nor trisomic grafts. Detailed stereological analysis of trisomic grafts did not reveal any neurodegeneration or morphological changes of cholinergic and GABAergic neurons during the course of graft maturation up to one year, as compared to grafts derived from euploid tissue. However, both euploid and trisomic grafts demonstrated a strong infiltration with T- and B-lymphocytes and a significant micro- and astroglial activation (hypertrophic astrocytes) within and around the grafts. These observations further suggest that the trisomy 16-induced neurodegeneration is seemingly due to a lack of neuron supporting factors which are provided by either the metabolic interaction of trisomic graft with surrounding healthy host tissue or by cells of the immune system infiltrating the graft.

Correlation between tectum formation and expression of two PAX family genes, PAX7 and PAX6, in avian brains

Heterotopic transplantation of brain vesicles between chick and quail were performed, and the correlation between tectum formation and the expression of two PAX family genes, PAX7 and PAX6, analyzed. Reciprocal transplantation between the prosencephalon and mesencephalon showed that formation of the tectum always coincided with induction/maintenance of PAX7 and suppression of PAX6, indicating that switch-on or -off of these two PAX family genes in region specific manners are responsible for the differentiation of brain vesicles into the tectum. On the other hand, transplantation of the mesencephalic floor plate into the dorsal mesencephalon suppressed PAX7 expression in the dorsal mesencephalon and changed its fate from the tectum to the tegmentum, indicating that factors in the mesencephalic floor plate suppress PAX7 and limit tectum territory to the dorsal part of the mesencephalon.

Calbindin D28K and parvalbumin gene expression in rat embryonic ventral forebrain grafts

The present study characterizes expression of calbindin D28K (CB-D28K) and parvalbumin (PV) in ventral forebrain (VFB) grafts placed in the neocortex of adult rats bearing quisqualic acid lesions to the nucleus basalis magnocellularis. Three to nine months after transplantation surgery, rats were killed for in situ hybridization with probes to CB-D28K or PV and for immunohistochemistry with antibodies to CB-D28K or PV. In addition, an antibody to choline acetyltransferase (ChAT) was used to characterize the cholinergic component in the graft and an antibody to tyrosine hydroxylase (TH) to explore catecholaminergic innervation of the graft. Quantitative analysis of CB-D28K and PV messenger ribonucleic acid (mRNA) was based on counts of silver grains generated by emulsion autoradiography. Cells expressing CB-D28K mRNA were significantly larger than such cells in the adult VFB and the mean number of silver grains per cell was significantly greater than to such cells in the adult VFB. The level of CB-D28K mRNA expression as calculated by ratio of silver grains per unit area was also significantly increased. Quantification of PV mRNA showed no significant differences between the cells in the graft and in the adult VFB. In order to begin to interpret these findings, a comparison was made with such cells in the VFB of developing rats. Brain sections were sampled from embryonic day 17 and postnatal days 1, 5, 12, 19 and adult (6-12 months of age). Cells expressing CB-D28K mRNA were detected in ventral forebrain from postnatal day 5 and cells expressing PV mRNA were detected in ventral forebrain from postnatal day 19. In the course of normal development of the ventral forebrain, no CB-D28K cells were found that were as large or expressed such high levels of CB-D28K mRNA as observed in the grafts. We conclude that changes in grafted cells expressing CB-D28K do not reflect an arrest of developmental processes. TH immunohistochemistry revealed lack of catecholaminergic innervation of the graft, whereas adult mediolateral septal cells that express CB-D28K receive such innervation in addition to other neurotransmitter inputs. Imbalance in neurotransmitter inputs to grafted cells expressing CB-D28K is discussed as a possible factor in their increased size and gene expression.

Mouse-chick chimera: a developmental model of murine neurogenic cells

Chimeras were prepared by transplanting fragments of neural primordium from 8- to 8.5- and 9-day postcoital mouse embryos into 1.5- and 2-day-old chick embryos at different axial levels. Mouse neuroepithelial cells differentiated in ovo and organized to form the different cellular compartments normally constituting the central nervous system.The graft also entered into the development of the peripheral nervous system through migration of neural crest cells associated with mouse neuroepithelium. Depending on the graft level, mouse crest cells participated in the formation of various derivatives such as head components, sensory ganglia, orthosympathetic ganglionic chain, nerves and neuroendocrine glands. Tenascin knockout mice, which express lacZ instead of tenascin and show no tenascin production (Saga, Y., Yagi, J., Ikawa, Y., Sakakura, T. and Aizawa, S. (1992) Genes and Development 6, 1821–1838), were specifically used to label Schwann cells lining nerves derived from the implant. Although our experiments do not consider how mouse neural tube can participate in the mechanism required to maintain myogenesis in the host somites, they show that the grafted neural tube behaves in the same manner as the chick host neural tube. Together with our previous results on somite development (Fontaine-Perus, J., Jarno, V., Fournier Le Ray, C., Li, Z. and Paulin, D. (1995) Development 121, 1705–1718), this study shows that chick embryo constitutes a privileged environment, facilitating access to the developmental potentials of normal or defective mammalian cells. It allows the study of the histogenesis and precise timing of a known structure, as well as the implication of a given gene at all equivalent mammalian embryonic stages.

Nitric oxide synthase in ventral forebrain grafts and in early ventral forebrain development

Embryonic ventral forebrain (VFB) grafts to cortex contain neurons that synthesize acetylcholine and partially ameliorate behavioral deficits caused by excitotoxic damage to the nucleus basalis magnocelullaris in rats. An additional neurotransmitter, nitric oxide (NO), is synthesized by a subset of cholinergic neurons in rat ventral forebrain. If this neurotransmitter is expressed also by grafted cholinergic neurons (which include the embryonic medial septum and diagonal band), its functional contribution should be considered. Six to twelve months after transplantation of embryonic VFB tissue rats were sacrificed. Brain tissue was processed either for in situ hybridization of nNOS and neuropeptide Y (NPY) or for immunohistochemistry of choline acetyltransferase (ChAT) and neuronal nitric oxide synthase (nNOS). Quantification of messenger ribonucleic acid (mRNA) for nNOS was performed with radioactively labeled probes (silver grains were counted) and a preliminary comparison was made of graft sections to sections of the ventral forebrain of developing rats. Plots of silver grain counts against cell size revealed similar patterns in the grafts and in the ventral forebrain of developing rats. The rates of expression of mRNA for nNOS in the grafts were intermediate between those of the ventral forebrain of postnatal day 19 and those of postnatal day 12. Double immunohistochemical labeling revealed that 45.87 + 8.26% of cells expressing ChAT also expressed nNOS in the grafts, significantly higher than 33.16 + 3.9% which was the rate of co-expression observed in the adult ventral forebrain. This study suggests that possible contribution of NO to graft-associated modulation of behavior should be examined.

Changes in the sensitivity of frontal cortical neurones to acetylcholine after unilateral lesion of the nucleus basalis with alpha-amino-3-OH-4-isoxozole propionic acid (AMPA): effects of basal forebrain transplants into neocortex

Unilateral S-alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid (AMPA) lesions of the nucleus basalis magnocellularis (nbm), which produced persistent and extensive ChAT-positive cell loss within the nbm and depletion of cortical cholinergic markers in the frontal cortex, increased both the number and sensitivity of individual frontal cortical neurones responding to iontophoretic administration of ACh. The lesion also increased the sensitivity of individual neurones to carbachol but the increase in the number of neurones responding to carbachol was transient and had returned to normal 4 weeks after lesion. The sensitivity of individual neurones to glutamate was unchanged by the lesion. The percentage of cortical neurones responding to ACh, but not the sensitivity of individual neurones was restored to the prelesion level, 6-8 weeks after cholinergic transplants to the lesioned frontal cortex; cholinergic transplants to the more distant parietal cortex were only effective after 6 months whereas noncholinergic transplants were ineffective at both time intervals. Cholinergic transplants placed in the frontal cortex 6-8 weeks or 6 months before nbm lesion offered some protection from the effects of the lesion, particularly at 6 months but were ineffective when placed into the parietal cortex. Lesion of the nbm also reduced basal firing rate of spontaneously active neurones and this was not restored by any of the transplants. The results are discussed in the light of quantitative measurements of acetylcholinesterase-positive fibre outgrowth from the transplant into the recording area, which are described in the preceding manuscript [20].

Effects of combined ventral forebrain grafts to neocortex and amygdala on behavior of rats with damage to the nucleus basalis magnocellularis

In rats with damage to the nucleus basalis magnocellularis, transplantation of the embryonic ventral forebrain to the neocortex improves behavioral performance in some behavioral tasks. The present investigation focuses on improvement of behavioral performance by combined graft placement to both neocortex and amygdala. Male rats received unilateral microinjections of quisqualate to the nucleus basalis magnocellularis to produce cell damage. Embryonic ventral forebrain cell suspensions were placed in one group of rats in the frontal and parietal neocortex, in a second group in the amygdala, and in a third group in the frontal and parietal neocortex and in the amygdala. These groups were compared to a group of nonoperated rats and a group of rats with damage but with no grafts. Quisqualate-induced damage to the nucleus basalis magnocellularis reduced cholinergic innervation in the ipsilateral cortical hemisphere, impaired performance in the one-trial training version of passive avoidance, an increased motility and time spent in the open arms of the elevated plus maze. Combined graft placement to neocortex and amygdala normalized performance of passive avoidance and restored the normal time spent in the open arms of an elevated plus maze. These results suggest that after damage to the nucleus basalis magnocellularis, modulation of function in multiple brain regions may be necessary for optimization of adaptive behavior in situations involving induction of fear.

Behavioural specificity of neocortical grafts of fetal basal forebrain tissue after unilateral lesion of the nucleus basalis with alpha-amino-3-OH-4-isoxozole propionic acid (AMPA)

The previous articles in this series [4,9] have shown that unilateral AMPA lesions of the nucleus basalis magnocellularis (nbm) produced widespread morphological and functional changes to the forebrain cholinergic projection system that could be reversed by transplants of fetal cholinergic tissue. At earlier postgraft time points, the effects of cholinergic grafts were specific to the neocortical region (frontal or parietal cortex) into which the grafts were targeted. Here we report that nbm lesion-induced spatial learning and memory deficits in the Morris water maze were reversed at 6-8 weeks postsurgery only by cholinergic grafts placed in the frontal cortex or frontal and parietal cortices combined. Similar grafts to parietal cortex only and noncholinergic fetal transplants to any cortical site were ineffective. In contrast, using separate groups of animals, deficits in sensorimotor function could be reversed in only one measure (open field turning) by cholinergic transplants targeted to the parietal (somatosensory) cortex or frontal and parietal cortex combined. These behavioural dissociations demonstrate that the frontal cortical cholinergic innervation from the nbm is necessary for effective spatial cognitive performance.

Effects of GDNF on fetal septal forebrain transplants in oculo

Glial cell line-derived neurotrophic factor (GDNF) is a member of the TGF-beta superfamily of growth factors with marked neurotrophic activity on midbrain dopaminergic neurons. To investigate whether this trophic activity is shared by central cholinergic neurons, we investigated the effects of GDNF treatment during development of the medial septal area in rats. Adult Fischer 344 rats received intraocular transplants of fetal septal forebrain tissue (embryonic Day 17) which was preincubated for 20 min with either GDNF or vehicle. The two treatment groups subsequently received weekly intraocular injections of either GDNF (0.5 microgram in 5 microliters/injection) or vehicle for 6 weeks following transplantation. Transplants treated with GDNF grew twice as large as control grafts treated with vehicle. Immunohistochemical evaluations of the transplants revealed that there was no difference between the two groups in terms of acetylcholinesterase or low affinity neurotrophin receptor (p75) staining. In contrast, a significant increment in the number of GABA-ergic neurons was observed in transplants that received GDNF, as compared to vehicle-treated grafts. The overall number of neurons within the transplanted tissue was also elevated in the experimental group. There was no difference between the two groups in the distribution or density of astrocytes in the grafted tissue, as evidenced by immunohistochemistry with antibodies directed against glial fibrillary acidic protein. These results indicate that basal forebrain GABA-ergic neurons may be dependent on GDNF for their survival and/or for GABA synthesis, but that the cholinergic neurons in this area appear to be unaffected by GDNF administration during development.

Extensive reinnervation of the hippocampus by embryonic basal forebrain cholinergic neurons grafted into the septum of neonatal rats with selective cholinergic lesions

Reconstruction of the septohippocampal pathways by axons extending from embryonic cholinergic neuroblasts grafted into the neuron-depleted septum has been explored in the neonatal rat by using a novel lesioning and grafting protocol. Neonatal ablation of the basal forebrain cholinergic projection neurons, accompanied by extensive bilateral cholinergic denervation of the hippocampus and neocortex, was produced at postnatal day (PD) 4 by 192 immunoglobulin (IgG)-saporin intraventricularly. Four days later, cholinergic neuroblasts (from embryonic day 14 rats) were implanted bilaterally into the neuron-depleted septum by using a microtransplantation approach. The results show that homotopically implanted septal neurons survive and integrate well into the developing septal area, extending axons caudally along the myelinated fimbria-fornix and supracallosal pathways that are able to reach the appropriate targets in the denervated hippocampus and cingulate cortex as early as 4 weeks postgrafting. Moreover, the laminar innervation patterns established by the graft-derived axons closely resembled the normal ones and remained essentially unchanged up to at least 6 months, which was the longest postoperative time studied. The reinnervating fibers restored tissue choline acetyltransferase activity (up to 50% of normal) in the dorsal hippocampus and the parietooccipital cortex. Retrograde labeling with Fluoro-Gold from the host hippocampus combined with immunocytochemistry confirmed that most of the projecting neurons, indeed, were cholinergic. The results suggest that the graft-host interactions that are necessary for target-directed axon growth are present in the septohippocampal system during early postnatal maturation. Thus, the present approach may contribute to overcome the functional limitations inherent in the use of ectopically placed intrahippocampal transplants.

Further observations on the susceptibility of diencephalic prosomeres to En-2 induction and on the resulting histogenetic capabilities

It has been previously shown by chick/quail heterotopic grafts that En-2 expression and a mesencephalic phenotype can be induced within the avian primordial prosencephalic vesicle, although the induction appeared restricted to the caudal forebrain. The present experiments were aimed at further analyzing the competence of the prosencephalic neuroepithelium. Different types of grafts were performed between chick and quail embryos: (i) caudal forebrain grafts positioned in the midbrain/hindbrain junction (the En-2-positive domain); (ii) En-2-positive grafts integrated at different levels of the forebrain. In both cases, the grafts were transplanted either with a normal orientation or after inversion of their rostro-caudal axis. The chimeric embryos were analyzed at stages HH19-24 for expression of En-2 and Pax-6 homeobox-containing genes, normally expressed in the meso-isthmo-cerebellar and prosencephalic domains, respectively. A cytoarchitectonic analysis of grafted and surrounding host tissue was also performed at later developmental stages in chimeric embryos with caudal forebrain grafts. Our results show that the caudal diencephalon, including the prospective territories for prosomeres 1 and 2, is competent to express En-2 when in close contact to the En-2 polarizing region, whereas the more rostral neuroepithelium, including the prospective territories for the third prosomere and telencephalon, does not change its fate under similar conditions. The ectopic-induced neuroepithelium can develop mesencephalon, but also isthmus and cerebellum according to its site of integration rostrally or caudally to the mesencephalic/isthmo-cerebellar boundary. Our data also show that within the competent diencephalon, the induced En-2 expression can be arrested at the P1/P2 interneuromeric boundary. This arrest appears to be directionally oriented as it only takes place when the induction is produced within prosomere 1 but not when it comes from prosomere 2. These data can be considered as resulting from either a possible oriented permissiveness of cells which form the boundary separating prosomeres 1 and 2, or of a different permissiveness of the cells composing these two caudal prosomeres.

Transplantation of basal forebrain cells of foetal rats into the subarachnoid space: improvement of disturbance of passive avoidance memory due to injury of nucleus basalis magnocellularis

Basal forebrain cells of foetal rats were transplanted into the subarachnoid space of adult rats harbouring a kainic acid-induced unilateral lesion in the nucleus basalis magnocellularis. Passive avoidance response tests were performed eight weeks after the transplantation, and the results were compared with those of lesioned but non-transplanted rats and of non-lesioned control rats. Although acquisition impairments did not improve, retention impairments were significantly ameliorated in the transplanted rats. Histologically, transplanted foetal neurons survived and grew very well over the cortical surface, and exhibited facilitated neuritic elongation on acetylcholinesterase staining. Choline acetyl-transferase-immunoreactive neurons were found along the needle track as well as in the subarachnoid graft tissues. The results seem to indicate that not the re-innervation from the graft to the host cortex but the diffusional supply of neurotransmitters and/or their synthetic enzymes and neurotrophic factors were responsible for improvement of memory deficits. The subarachnoid space proved to be an adequate place for growth of transplanted neuronal and glial cells for reasons of ample supply of oxygen and nutrition and of low tissue pressure.

Behavioral effects of basal forebrain grafts after dorsal septo-hippocampal pathway lesions

There are many reports that basal forebrain grafts ameliorate behavioral impairments produced by dorsal septo-hippocampal pathway lesions, but several studies have either found that this recovery may be unrelated to concomitant restitution of cholinergic markers, may be modest and depend on certain experimental conditions or instead that grafts may actually exacerbate lesion-induced impairments. In this study, rats received one of three lesions of the dorsal septo-hippocampal pathways or a sham lesion, at 32 days of age, and intrahippocampal basal forebrain grafts or the vehicle control 10 days later. In grafted rats with total aspirative lesion of the fimbria-fornix, there was a substantial AChE-positive hippocampal reinnervation but no improvement of the severe lesion-induced spatial learning deficits, either reference memory or working memory, whether tested at 1 or 5 months post-grafting. In rats with bilateral medial fimbria lesions, grafts were successful, normal in appearance and produced substantial hippocampal cholinergic reinnervation; relative to non-grafted counterparts, however, grafted medial fimbria rats showed an early reference memory impairment and a persistent exacerbation of a working memory deficit. Exacerbation of learning impairments was also apparent in grafted rats with partial hippocampal denervation due to lesion of the cingulate and adjacent cortex above the fimbria-fornix. Nonetheless, basal forebrain grafts normalised general activity in these lesion groups, irrespective of whether the lesion-induced change was an increase or a decrease relative to controls. Graft-derived lesion groups, irrespective of whether the lesion-induced change was an increase or a decrease relative to controls. Graft-derived AChE-positive innervation was more marked than expected in both grafted cingulate-lesioned rats and grafted sham-lesioned rats, while control grafts of fetal cortex (above the septum) produced little or no AChE-positive innervation. Size of basal forebrain grafts, originally 3 microliters at two dorsal sites per hippocampus, increased markedly from rostral to caudal dorsal hippocampus in all groups but did not differ significantly across grafted groups, even with respect to non-lesioned rats. This study adds further evidence that basal forebrain grafts, successful with respect to cholinergic reinnervation, do not always enhance cognitive functions in rat hippocampal lesion models, and confirms that these grafts may have adverse effects after partial septo-hippocampal system lesions. It is important to attend to both the potential negative and positive effects of neural grafts.

Midline signaling in the primordium of the zebrafish anterior central nervous system

In all vertebrates the brain develops from the enlarged anterior part of the neural plate. However, in the zebrafish mutant cyclops, the girth of the central nervous system (CNS) is nearly uniform along its length. Changes in expression patterns of homeobox genes and neuronal markers reveal a massive deletion of the ventral forebrain, particularly the diencephalon, as well as its precursor region in the neural plate. The deletion is due to a nonautonomous action of the mutation: very few wild-type cells transplanted to the midline of a mutant embryo can rescue the forebrain phenotype, including cyclopia. Establishment of forebrain ventral positional coordinates may thus require inductive signaling by forebrain midline cells whose specification depends upon the cyclops gene product.

Cholinergic basal forebrain transplants restore diminished metabolic activity in the somatosensory cortex of rats with acetylcholine depletion

It has been known for several years that stimulus-evoked metabolic activity is reduced in the somatosensory cortex of animals with basal forebrain lesions that deplete the neocortex of acetylcholine (ACh). During 2-deoxyglucose (2-DG) experiments, animals with unilateral basal forebrain lesions demonstrate a decreased response to somatic stimulation, while background metabolic activity in the surrounding cortical regions remains normal. In an attempt to ameliorate these deficits, we examined the ability of embryonic cholinergic basal forebrain transplants inserted into neocortex to innervate surrounding cortical regions and restore functional 2-DG activity in adult host rats previously depleted of ACh by basal forebrain lesions. To accomplish this goal, a series of experiments were conducted in which we (1) depleted the cerebral cortex of ACh by injecting an excitotoxin into the rat basal forebrain, (2) transplanted embryonic basal forebrain or embryonic neocortical (control) tissue into the ACh-depleted cortex and, (3) 6-12 months later, used the 2-DG metabolic mapping technique to examine effects of the transplants on metabolic activity evoked by whisker stimulation in rat somatosensory (barrel) cortex. Histochemical analysis revealed that acetylcholinesterase (AChE) staining within 2 mm of the basal forebrain transplants was similar in density to the contralateral normal hemisphere. AChE staining farther than 2 mm from the basal forebrain transplants and throughout hemispheres containing neocortical (control) transplants was greatly reduced, with few AChE-positive fibers present, a finding typical of cerebral cortex in basal forebrain-lesioned animals. Stimulus-evoked 2-DG uptake in barrels adjacent to the basal forebrain transplants, and therefore within AChE-rich territory, was similar to that in corresponding barrels identically activated in the contralateral hemisphere. 2-DG activity was reduced, however, in stimulated barrels outside the region of dense AChE-positive staining, as well as in all activated barrels in hemispheres containing control transplants of embryonic neocortex. These results indicate that transplantation of cell suspensions containing embryonic cholinergic basal forebrain, but not neocortex, can ameliorate basal forebrain lesion-induced deficits in functional activity, and that the restoration of activity is influenced by proximity to the transplant.

Foetal grafts from hippocampal regio superior alleviate ischaemic-induced behavioural deficits

Transitory global cerebral ischaemia produced in rats by four vessel occlusion for 15 min produced substantial loss of CA1 cells in dorsal hippocampus and minimal other intra- and extra-hippocampal damage. Ischaemic rats showed a long-lasting impairment in spatial navigation in the water maze, and such impairment was sensitive to task difficulty. Groups of ischaemic animals were implanted with foetal tissue dissected from hippocampal regio superior (SUP--containing CA1 field), regio inferior (INF--containing dentate gyrus), and basal forebrain, with grafts sited in the alveus above the damaged CA1 region. Behavioral testing in the water maze (acquisition, retention and a working memory task) was conducted over a period of 4 to 12 weeks after grafting. Only rats receiving the SUP graft showed consistent improvement in water maze performance, relative to ischaemic controls, when tested in retention and working memory. Although the selective effect of CA1-containing grafts suggests repairing of the damaged host circuit, functional recovery may have been related to the greater ability of SUP grafts to survive and grow in the host ischaemic hippocampus.

[Transplantation of basal forebrain cells of fetal rats into the subarachnoid space: improvement of disturbance of passive avoidance memory due to injury of basal forebrain]

The memory disturbance of senile dementia of Alzheimer type has been thought to associate with marked degeneration and loss of cholinergic neurons of the basal forebrain (nucleus basalis of Meynert, NBM). Electrical or chemical destruction of the NBM causes memory deficits in rats. After unilateral lesioning of the NBM in adult rats with excitotoxic amino acid, kainic acid, basal forebrain cells of fetal rats were transplanted through a microsyringe needle, the tip of which was transcortically inserted to the subarachnoid space. Eight weeks after the transplantation, passive avoidance response test was performed, and the response was compared with those of non-transplanted lesioned rats and of non-operated control rats. Although acquisition impairment did not improve, retention impairment was significantly ameliorated in the transplanted rats. Transplanted fetal neurons survived and grew very well over the cortical surface and exhibited facilitated neuritic elongation (acetylcholinesterase staining), but the neurites penetrating the intact pia mater were not verified. Choline acetyltransferase-immunoreactive neurons were found along the needle tract as well as in the subarachnoidal graft. The innervated neurites from the needle tract were rare. The results indicate that the re-innervation from the graft to the host cortex is not necessarily indispensable for improvement of memory deficit due to injury of the NBM. We suppose that the diffusional supply of neurotransmitters and/or their synthetic enzymes and some kinds of neuronotrophic factors is more important. Moreover, we emphasize the participation of astroglias, which are simultaneously transplanted with neurons, in production of neuronotrophic factors.

Basal forebrain grafts in the rat neocortex restore in vivo acetylcholine release and respond to behavioural activation

Acetylcholine release in the frontal cortex of awake rats after acute or chronic lesions of the nucleus basalis magnocellularis and grafting of cholinergic-rich basal forebrain tissue was studied by in vivo microdialysis. Three to four weeks and five months after a unilateral quisqualic acid lesion of the nucleus basalis, and five months after lesion and cortical implantation of a basal forebrain cell suspension, acetylcholine release was characterized during a range of pharmacological and behavioural manipulations. Neostigmine (5 microM) was added to the perfusion fluid in order to inhibit the degradation of acetylcholine. The extracellular levels of acetylcholine in normal animals increased three- to four-fold when KCl (100 mM) was added to the perfusion medium and was reduced by 80% after addition of tetrodotoxin (1 microM). The nucleus basalis lesion resulted in a 60% reduction in baseline acetylcholine levels compared to normal and the response to KCl-evoked depolarization was significantly reduced. There were no differences between the acute and chronic lesion groups during any of the manipulations performed. Rats with grafts showed baseline levels of acetylcholine about 70% higher than normal, and responded to both KCl (two-fold increased acetylcholine release) and tetrodotoxin (85% reduced levels). All groups showed lower acetylcholine levels during halothane anaesthesia (on average 70-85% reduction). Sensory stimulation by handling resulted in a two-fold increase in acetylcholine release in normal animals, whereas the absolute responses in the lesioned controls were significantly weaker. Rats with grafts increased their acetylcholine release after handling to an extent not different to normal or lesioned controls. Immobilization stress induced an almost two-fold increase in cortical acetylcholine levels in normal rats, whereas the effect in the lesion-only groups was very weak. The grafts responded to the immobilization with an enhanced acetylcholine overflow that was significantly higher than in lesioned controls. The results showed that the reduction in frontocortical acetylcholine release induced by excitotoxic lesions of the nucleus basalis did not recover spontaneously over several months. Intracortical cholinergic-rich grafts obtained from the fetal basal forebrain provided a source of acetylcholine release with firing-dependent properties which could be modulated by behaviourally stressful stimuli. The ability of the grafts to respond to behavioural manipulation strongly suggests that the host brain can functionally influence graft neuronal activity during ongoing behaviour. Host control of graft activity may play a role in the recovery of the lesion-induced deficits seen with these types of grafts.

Retroviral infection coupled with tissue transplantation limits gene transfer in the chicken embryo

Gene transfer into early embryos is a powerful methodology for unraveling the molecular bases of developmental processes. One can attempt to minimize widespread effects of an exogenous gene by using tissue- or region-specific promoters in the few instances where they are available. We have developed a method that bypasses the requirement for specific targeting sequences to achieve regionally restricted gene transfer. Intraspecific chimeras have been created by transplantation of restricted portions of a chicken embryo from a donor strain to a host strain. The donor cells are infectable with a recombinant retroviral vector that carries the exogenous gene, whereas the host cells are not. We have demonstrated the feasibility of this approach using a histochemically distinct reporter gene, human placental alkaline phosphatase. The expression of retrovirally transduced alkaline phosphatase was limited to a transplanted hemiprosencephalon (forebrain and eye) in embryonic chickens. This technique can be applied to many other organ systems during avian embryogenesis to test the function(s) of molecules that are normally controlled through spatial and/or temporal regulation, such as many of the growth factor receptors or homeobox-containing proteins.

Effects of fetal forebrain transplants in ibotenic-injured nucleus basalis: an anatomical investigation

Survival of fetal basal forebrain transplant (TP) into ibotenic-injured nucleus basalis of rats was examined after a delay lesion and TP (1 or 2 weeks) and a delay between harvest and TP (1-4.5 hours). Optimal TP survival occurred for TP made 2 weeks postlesion and less than 2 hours after harvesting. In these cases large, healthy TP-neurons displayed robust cytochrome oxidase (CO) activity and sent cholinergic processes throughout the TP and occasionally into host tissue. A mild astrocytic reaction was observed within the TP and at the host-TP interface. Surviving TPs increased choline acetyltransferase innervation and CO activity within the ipsilateral frontoparietal cortex. Therefore data suggest that fetal cholinergic TPs into the damaged NBM reduced neuronal degeneration within the NBM and stimulated remaining neurons spared by the lesion.

Behaviour-dependent changes in acetylcholine release in normal and graft-reinnervated hippocampus: evidence for host regulation of grafted cholinergic neurons

Grafted neurons obtained from the fetal basal forebrain can provide a functional cholinergic reinnervation of the hippocampal formation in rats with a lesion of the intrinsic septal cholinergic afferents. In the present experiments graft-derived acetylcholine release in the hippocampus was studied by microdialysis in awake rats during different types of behaviours which are known to activate the innate septohippocampal cholinergic system and during different activity periods of the day-night cycle. Two types of basal forebrain grafts were studied: cell suspensions implanted into the hippocampus in rats with an aspirative lesion of the fimbria-fornix, and grafts of solid tissue implanted as a tissue bridge into the fimbria-fornix lesion cavity. Increased acetylcholine overflow was seen in both groups with grafts during sensory stimulation (by handling). The strongest response (50% increase in acetylcholine release) was seen in rats with solid basal forebrain grafts (equivalent to two-thirds of that seen in intact rats). Immobilization stress and motor activity (swimming) also resulted in increased, but more variable, acetylcholine release (+ 30%; about one-third of the normal response). None of these effects was seen in the control rats with fimbria-fornix lesion only. The two-fold difference in hippocampal acetylcholine release in normal animals between day and night was absent in both types of grafted rats. An acute knife-cut, transecting the connections between the solid basal forebrain graft and the host hippocampus, caused an immediate 75% reduction in acetylcholine release (similar to the effect of an acute fimbria-fornix transection in the normal rats) and the response to swimming was no longer evident. The results show that grafted cholinergic neurons can be functionally integrated into the host brain, allowing the grafted neurons to be activated in the correct behavioural contexts, although the changes in acetylcholine overflow were overall smaller and more variable than normal. The ability of the host to influence cholinergic graft activity, most probably mediated via activation of afferent host-graft connections, may contribute to the efficacy of basal forebrain grafts in the amelioration of behavioural impairments in animals with lesions of the forebrain cholinergic system.

Restoration of learning ability in fornix-transected monkeys after fetal basal forebrain but not fetal hippocampal tissue transplantation

Monkeys with bilateral transection of the fornix were severely but selectively impaired on learning and retention of visuospatial conditional discriminations, visual conditional discriminations and non-conditional spatial-response tasks. Bilateral transplantation of cholinergic-rich fetal basal forebrain tissue into the hippocampus abolished significant learning impairments on all those tasks impaired by fornix lesions when tested three to nine months after transplantation whereas bilateral transplants of non-cholinergic fetal hippocampal tissue into hippocampus showed no such beneficial effect. Acetylcholinesterase staining was severely depleted throughout the dentate gyrus and hippocampus in fornix-transected monkeys compared with animals with control corpus callosum ablations. Staining was largely restored to normal in the host hippocampus and dentate gyrus in monkeys with cholinergic transplants, whereas acetylcholinesterase staining was abnormal in those with non-cholinergic grafts. These experiments suggest that where a "higher order" cognitive function, in this case the acquisition of specific types of information into long-term memory, is disturbed by a neuropharmacologically simple lesion, cognitive function can be restored by transplantation of neurons containing appropriate neurotransmitters.

Projection of the retinal ganglion cells to the tectum differentiated from the prosencephalon

The alar plate of the prosencephalon differentiates into a tectum-like structure when transplanted into the mesencephalon around the 10-somite stage. Here, we report on the projection pattern of the retinal ganglion cells to the transplants. Optic nerve fibers were labeled with horseradish peroxidase (HRP) and 3H-proline, and the innervation of the optic nerve fibers to the chimeric tectum was analyzed by HRP histochemistry on whole-mounted specimens, by autoradiography and by electron microscopy on embryonic day 16. In the chimeric tectum, the transplant was distinguished from the host by difference in nuclear structure between the quail and the chick cells. It was shown that the transplant had the laminar pattern of the optic tectum when the transplant was integrated into the host mesencephalon. The whole-mount HRP histochemistry showed that the optic nerve fibers extend to the transplants. Autoradiography showed that the distribution pattern of silver grains was similar in both the host and the transplant. These results may indicate that the optic nerve fibers turn to the transplant and terminate on the transplant. Electron microscopy further confirmed that optic nerve fibers ended by making synaptic contacts with the dendrites in the transplant region of the tectum. These results indicate that the transplant with the laminar pattern of the optic tectum is a true tectum receiving input from the eye.

Diencephalic origin of the pineal gland of the chicken embryo

In the present paper, the diencephalic origin of the chick pineal gland was analyzed by a series of experiments: prosencephalic substitution; in vitro culture of isolated diencephalons; and total or partial excission of the diencephalic roof. The results indicate that the differentiation of the chick pineal gland in the rooof of the third ventricle is not influenced by the neighbouring brain vesicles and is of diencephalic origin. Moreover, in order to obtain chick embryos with pineal agenesia, the whole diencephalic roof has to be removed.