Interactions between donor and host tissue following cross-species septohippocampal transplants

Expression of Human Neurofilament-light Transgene in Mouse Neurons Transplanted into the Brain of Adult Rats

To investigate the expression of nerve cell-specific transgene products in neural transplants, we implanted into the hippocampus of immunosuppressed adult Sprague - Dawley rats cell suspensions obtained from the septal region of the fetal brain of mice that carry the human neurofilament-light (hNF-L) gene. In grafts examined between 3 weeks and 7 months after transplantation, axons and nerve cell somata immunoreacted to antibodies specific to the human NF-L subunit. Thus, the hNF-L protein appears to be a suitable marker of these grafted neurons. Transgenic mice bearing the hNF-L gene may be a convenient source of donor tissue or be used as hosts for neural transplantation studies. Furthermore, the hNF-L promoter/enhancer elements in this transgene may help direct neuronal expression of heterologous genes that could influence nerve cell responses in either the transplant or host tissues.

Remodeling of lesioned kitten visual cortex after xenotransplantation of fetal mouse neopallium

Remodeling of the mechanically injured cerebral cortex of kittens was studied in the presence of a neural xenograft taken from mouse fetuses. Solid neural tissue from the neopallium of a 14-day-old fetus was transferred into a cavity prepared in visual cortical area 18 of 33-day-old kittens. Injections of bromodeoxyuridine (BrdU) were used to monitor postoperative cell proliferation. Two months after transplantation, the presence of graft tissue in the recipient brain was assessed by Thy-1 immunohistochemistry. Antibodies specific for neurons, astrocytes, and oligodendrocytes and hematoxylin staining for endothelial cells were used for the characterization of proliferating (BrdU+) cells. The following were the major observations: 1) Of ten transplanted kittens, four had the cavity completely filled with neural tissue that resembled the intact cerebral cortex in its cytoarchitecture, whereas, in four other kittens, the cavity was partially closed. In two kittens, the cavity remained or became larger, which was also the case with all four sham-operated (lesioned, without graft) animals. 2) A substantial part of the remodeled tissue was of host origin. Only a few donor cells survived and dispersed widely in the host parenchyme. 3) In the remodeled region of transplanted animals, the densities of nerve, glial, and endothelial cells were similar to those in intact animals. 4) Cell proliferation increased after transplantation but only within a limited time, because, 2 months after the operation, the number of mitotic cells in the grafted cerebral cortex did not differ from that in intact controls. Our data suggest that the xenograft evokes repair processes in the kitten visual cortex that lead to structural recovery from a mechanical insult. The regeneration seems to rely on a complex interplay of many different mechanisms, including attenuation of necrosis, cell proliferation, and immigration of host cells into the wounded area.

Traumatic lesions and transplants of granule cells in the dentate gyrus alter the distribution of afferent fibers in the molecular layer

The present experiments determined whether traumatic lesions of the dentate gyrus granule cells had a different effect on the afferents in the molecular layer (ML) than nontraumatic lesions. Nontraumatic lesions of the granule cells induced by colchicine, ibotenic acid, x-radiation, and adrenalectomy have been reported to reduce both the acetylcholinesterase (AChE)-positive fibers and entorhinal afferents in the ML. After the nontraumatic granule cell lesions, the laminar distribution of the entorhinal afferents was maintained in the ML, whereas the AChE laminar pattern was lost. In the present study, dentate granule cells were traumatically lesioned by a fluid injection into the infragranular cleavage plane (IGCP) of the dentate gyrus. The traumatic lesion resulted in an altered distribution of the afferents in the ML. The perforant path fibers, shown by injection of wheat germ agglutinin horseradish peroxidase into the entorhinal cortex, occupied a greater proportion of the ML in lesioned animals than in control animals. The normal laminar pattern of AChE-positive afferents was not present after the granule cell lesion. There was an initial increase in AChE-positive fibers in the ML that lasted several weeks but eventually returned to near normal levels. The altered distribution of afferents could in part be due to uneven shrinkage of the molecular layer and/or sprouting of the afferents. Granule cell suspension transplants into the IGCP also traumatically lesioned the host granule cells but immediately replaced the damaged host granule cells with immature granule cells. The distribution of afferents was similar to that found in lesioned-only animals. The traumatic lesion induced MAP2 immunoreactivity in the anisomorphic reactive astrocytes of the ML. At the longer survival times, MAP2 was not seen in either the astrocytes of the ML or in the isomorphic reactive astrocytes in CA3.

Migration of purified embryonic motoneurons grafted into adult mouse CNS

Embryonic motoneurons were fluorescently-labelled with carbocyanine (diI) by means of retrograde transport and then grafted into the adult mouse spinal cord (L2) and brain (striatum) for 2-10 weeks. The motoneurons were grafted either following purification on the fluorescence-activated cell sorter or in the presence of embryonic glial cells and interneurons from the spinal cord. In both conditions of grafting, motoneurons were found to survive and develop in both grey and white matter and were found to migrate long distances in both regions of the central nervous system. Migration of neurons after grafting remains a controversial issue, therefore we have discussed the work of other groups that have described the same phenomenon.

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.

Retinal transplants in congenitally blind mice: patterns of projection and synaptic connectivity

Embryonic retinae were transplanted onto the midbrain of neonatal congenitally anophthalmic mice and neonatal mice from which both eyes had been removed. When donor mice of the AKR strain were used, the detailed patterns of the transplant projections to the host brain were demonstrated with an antibody to Thy-1.1, which specifically stains neural tissue derived from AKR donors. Many of the subcortical visual centers were innervated, and only small differences were encountered between anophthalmic and eye-enucleated mice. The terminal arbors of transplant-derived axons could not be classified as in normal animals, although several distinct arbor types were seen. In the superior colliculus, the laminar arrangements that characterize normal retinal arbors were disrupted. Despite this, the synaptic patterns formed by transplant-derived axons in the superior colliculus of anophthalmic mice compared very closely with those of retinal axons in normal, sighted animals. These observations indicate that the ability of a retinal transplant to innervate the host brain and to form the synaptic arrays characteristic of optic terminals are not dependent on prior innervation, nor do they appear to be influenced by the events that follow eye removal.

Cross-species septohippocampal transplants: ultrastructure of Thy-1.2-labeled donor fibers into the dentate gyrus

A naturally occurring species-specific membrane marker was used to identify unambiguously transplanted septal cells and their fibers which have grown into host tissue. Cell suspensions of the septum/basal forebrain region of C57Bl/6 mouse embryos were transplanted into the dentate gyrus of Sprague-Dawley rats that had received a fornix lesion. The membranes of the mouse contained Thy-1.2, while the membranes of the rat contained Thy-1.1. An antibody to Thy-1.2 clearly identified the donor tissue and did not react with the Thy-1.1 of the host's membranes. The ultrastructure of the immunoreactively labeled tissue confirmed previous biochemical findings on the distribution of Thy-1 and showed Thy-1.2 immunoreactivity on axons and dendrites, microtubules, some mitochondrial membranes, and the surface membranes of cell bodies. Within the transplant, a few glial profiles showed immunoreactive fibrils, but most glial profiles within the transplant and all glial profiles outside the transplant were not immunoreactive. Astrocyte fibers enclosed the outgrowing labeled fibers to form fascicles, but did not penetrate the fascicle. There was no other distinctive association of astrocytic profiles with immunoreactive fibers. Dendrites grew for long distances into the host's molecular layer. Many immunoreactive dendritic profiles formed synapses with unlabeled terminal profiles from the host. The host synapses on the long dendrites of the transplanted neurons may form an important source of input for the initiation of physiological activity in the new circuits established by the transplant. A few labeled (donor) synaptic terminals were observed in the molecular layer, but Thy-1.2-labeled dendritic profiles were much more prominent than labeled axonal profiles.

Increase in acetylcholinesterase in the molecular layer of the dentate gyrus in the absence of septal inputs following selective granule cell lesions

Granule cell lesions cause an increase in acetylcholinesterase (AChE) staining in the molecular layer of the dentate gyrus. The source of this response was examined by combining granule cell lesions with lesions of the fornix-fimbria, thereby removing the cholinergic input from the septum to the hippocampus. The increased AChE staining was present in animals with granule cell lesions regardless of whether the fornix was lesioned or intact. The increase in AChE staining occurred without a corresponding increase in choline acetyltransferase staining. These findings suggest that an AChE-positive, but non-cholinergic, sprouting response occurred within the dentate gyrus following selective lesions of the granule cells. The source of this sprouting may be from AChE-positive hilar interneurons.

Selective lesions of granule cells by fluid injections into the dentate gyrus

Granule cells were selectively lesioned by injections of fluid into the infragranular cleavage plane in the dentate gyrus. The granule cells were axotomized by the cavity created by the fluid and 6 days after the injection there were no granule cells at the injection site. The size of the granule cell loss could be altered by varying the volume and rate of the injection. The loss of granule cells led to a shrinkage of the molecular layer and to a reactive gliosis. The lesion also caused an increase in the density of AChE and Timm staining in the molecular layer above the lesion. Although the increased density of AChE and Timm staining may have been due in part to the shrinkage of the molecular layer, part was due to the growth of inputs in response to the loss of granule cells and/or to the axotomy of the input terminals. The changes seen in the molecular layer above the lesion site ended abruptly at the margins of the lesion and the adjacent molecular and granule cell layers appeared normal.