Fetal Striatal Cells Research Articles

A novel mode of immunoprotection of neural xenotransplants: Masking of donor major histocompatibility complex class I enhances transplant survival in the central nervous system

To determine the role of major histocompatibility complex (MHC) class I in immunological rejection of neural xenotransplants, F(ab')2 fragments of a monoclonal antibody to porcine MHC class I were used to mask this complex on porcine fetal striatal cells transplanted into rat striata previously lesioned with quinolinic acid. Presence of MHC class I on the surface of porcine striatal cells was confirmed by fluorescence-activated cell sorting prior to F(ab')2 treatment. At three to four months post-transplantation, survival of F(ab')2-treated xenografts was assessed by means of donor-specific immunostaining and compared to that of untreated xenografts in non-immunosuppressed rats and in rats immunosuppressed with cyclosporine A. In this study, masking of donor MHC class I by F(ab')2 treatment resulted in enhanced xenografts survival compared to the non-immunosuppressed controls (graft survival rates, 52% and 7%, respectively; P < 0.005) at survival times up to four months. While xenograft survival in F(ab')2-treated animals was not significantly different from that in cyclosporine-treated rats (74% graft survival), mean graft volume in F(ab')2-treated animals was smaller than that in cyclosporine-treated animals (1.07 +/- 0.30 mm3 versus 3.14 +/- 0.51 mm3; P < 0.005). The cytoarchitectonic organization of the xenografts was similar in F(ab')2- and cyclosporine-treated animals, and grafts in both groups exhibited long distance target-directed axonal outgrowth. The pattern of immunoreactivity to porcine MHC class I in the xenografts corresponded to the regional distribution of donor glia. In xenografts undergoing rejection, infiltration with host inflammatory cells was restricted to necrotic graft remnants and spared the nearby host structures. We conclude that MHC class-I-restricted immune mechanisms play an important role in neural xenograft rejection and that masking of this complex on donor cells may provide a useful strategy for immunoprotection of neural xenografts.

Striatal grafts in infarct striatopallidum increase GABA release, reorganize GABA A receptor and improve water-maze learning in the rat

We grafted fetal striatal cells in ischemic rat models, and investigated graft survival/growth, GABA release, GABA A receptor reorganization and functional recovery. One hour intraluminal occlusion of the middle cerebral artery (MCA) induced ischemic infarct in the lateral part of the striatum and adjacent cortex. In ischemic rats, the acquisition of Morris' water-maze learning was significantly slower than that of control rats. In these animals GABA level in the globus pallidus, detected by microdialysis, was about the half of that of controls. However, after the grafts of fetal striatal cells in the Striatopallidum, the acquisition was improved, thus no difference was observed in the time course of learning curves in control and grafted animals. GABA level recovered to almost normal level by the graft. It further increased by the treatment of a GABA uptake blocker (nipecotic acids) in the perfusion. In the grafts, GABA A receptor organization detected by autoradiography using [ 3H] labeled SR95531 was restored for more than 1 year after the graft. Data suggest that fetal striatal cell grafts in infarct striatum may partially reconstruct striatopallidal GABA projection and reorganize GABA A receptor. This might be a basis of improvement of function.

Trophic influences of human and rat amniotic fluid on neural tube-derived rat fetal cells

Normal human (week 17–20) and rat (E16–17) amniotic fluids were used as culture media for primary cultures of rat fetal (E 16) cortical, mesencephalic and striatal cell dissociates, or astroglial subcultures from the same brain regions. Phase-bright and dark cells were identified under phase contrast microscopy and their cell processes were measured utilizing semi-automated procedures. Subcultured astroglia were immuno-reacted against glial fibrillary acidic protein and fibronectin. Rat and human amniotic fluid allowed survival and growth of neuronal and non-neuronal cells. Human amniotic fluid samples were trophic in variable degrees. Cerebral cortex subcultured astroglia usually expressed a radial-like morphotype. Although charcoal-adsorbed human amniotic fluid was trophic for primary cultures, its ability to sustain neuritic growth depended on its degree of trophism before treatment. Growth of cell processes in neuronal- and glial-like cells in primary cultures was inhibited to different degrees by the addition of antisera towards nerve or epidermal growth factors. It is concluded that amniotic fluid constitutes a trophic medium for astroglia and neurons. Both, nerve and epidermal growth factors appear to be necessary for growth of cell processes in neuronal and glial primary cultures in amniotic fluid. Trophic effect of amniotic fluid on subcultured astroglia did not seem to be diminished by nerve growth factor antiserum. The role of amniotic fluid during the early phases of brain organogenesis is discussed.

Improvement of passive avoidance task after grafting of fetal striatal cell suspensions in ischemic striatum in the rat

Behavioral recovery and cell survival/growth after grafting of fetal striatal cell suspensions in the ischemic striatum of rats were investigated. Ischemia was induced by one hour intraluminal occlusion of the right middle cerebral artery under halothane anesthesia. During the ischemia rats usually manifested signs of hemiparesis and sometimes rotations. Behavioral function was measured by a passive avoidance task and radial arm maze test at 1-2 weeks and 6-7 weeks after ischemia. The size of the ischemic lesions depended on each animal, but the ischemic animals showed deficits in both passive avoidance task and radial maze test. Two weeks after ischemia, fetal striatal cells, marked with DiI, were transplanted into the ischemic striatum. The transplantation improved the ischemia-induced deficit in the passive avoidance task but not in radial maze test. Although there were variations in the size of the grafts, many DiI-positive cells with dendritic outgrowth were detected under fluorescent microscopy. Immunohistochemical study revealed that many choline acetyltransferase (ChAT) positive cells and GABA-positive cells survived in the grafts. However, striosome-matrix compartments were not evident inside the grafts. Thus, partial recoveries in both cytoarchitectural and behavioral aspects were obtained by striatal cell grafts, suggesting that neural transplantation could be a useful approach in reconstructing ischemic brain function.

Striatal grafts in the ischemic striatum improve pallidal GABA release and passive avoidance

Fetal Striatal cells were grafted into the ischemic striatum of rats and pallidal GABA release, and behavioral improvement were investigated. Intraluminal occlusion of the middle cerebral artery (MCA) for 1 h induced ischemic infarcts in the lateral Striatum and the adjacent cortex. In ischemic rats, the performance of a passive avoidance task was disturbed, and the pallidal GABA level detected by microdialysis decreased to about a half of control. After the graft, the deficit in the passive avoidance was partially alleviated and the GABA level recovered moderately and increased further by the infusion of an uptake blocker. The data indicate that fetal Striatal cell grafts in the ischemic striatum partially restored both chemical and behavioral deficits.

Reconstruction of GABAergic transmission and behavior by striatal cell grafts in rats with ischemic infarcts in the middle cerebral artery.

Fetal striatal cell suspensions were grafted stereotaxically into the infarcted striatum of rats, and reconstruction of striatopallidal GABA transmission and behavior were investigated. Occlusion of the middle cerebral artery (MCA) for one hour induced ischemic infarcts mainly in the lateral striatum, as detected by magnetic resonance imaging (MRI) and histology. Ischemic rats had deficits in the performance of a passive avoidance task, both acquisition and retention, but no changes in general circadian actograms. In these animals pallidal GABA, detected by microdialysis, decreased to about half of control levels. There were suggestions of an improvement in passive avoidance performance in the grafted animals. Pallidal GABA concentrations recovered almost to control levels, and were increased by infusions of the GABA uptake blocker nipecotic acid. These data indicate that neural transplantation is a promising approach to improve the deficits in chemical transmission and behavior following ischemic infarcts in rat striatum.

Intrastriatal transplantation of cross-species fetal striatal cells reduces abnormal movements in a primate model of Huntington disease.

Huntington disease is a neurological movement disorder involving massive neuronal death in the caudate-putamen region of the brain. Neither preventive nor curative therapy exists for this disease. The implantation of cross-species striatal neural precursor cells into the lesioned striatum of nonhuman primates (baboons) reduced the abnormal movements seen in the disease model. These abnormal movements reappeared after immunological rejection of the implanted striatal cells and were not modified by transplantation with nonstriatal cells. These findings encourage further experimentation toward the use of cell sources other than human fetal cells in a potential clinical application to Huntington disease.

Correlated light and electron microscopic study of dopaminergic neurons and their synaptic junctions with DARPP‐32‐containing cells in three‐dimensional reaggregate tissue culture

An antibody to tyrosine hydroxylase has been used in a correlated light and electron microscopic study to characterize dopaminergic neurons and synaptic junctions in three-dimensional reaggregate cell culture. Dissociated fetal mesencephalic cells containing dopamine neurons were coaggregated with dissociated fetal striatal cells in rotatory culture for 21 days. Sections of the coaggregates were stained by the peroxidase anti-peroxidase technique to reveal tyrosine hydroxylase-immunoreactive structures. Clusters of immunoreactive perikarya as well as dendrites and axons were observed. Immunolabeled perikarya were round or oval and approximately 20 microns in diameter. Boutons immunoreactive for tyrosine hydroxylase formed symmetric synapses, primarily with unlabeled dendritic shafts. Symmetric membrane specializations were also observed between tyrosine hydroxylase-positive boutons and unlabeled dendritic spines as well as with the perikaryon of an unlabeled medium-size neuron possessing a slightly indented nucleus. To characterize the neurochemical nature of the neurons postsynaptic to tyrosine hydroxylase-positive boutons in the reaggregates, an antibody against DARPP-32 (a dopamine and adenosine 3':5'-monophosphate-regulated phosphoprotein) and an antibody against tyrosine hydroxylase were employed to visualize striatal dopaminoceptive neurons and dopaminergic structures, respectively, in the same section. Examination of reaggregate sections at the light microscopic level demonstrated that DARPP-32-immunoreactive cells were distributed into discrete clusters that were associated with patches of tyrosine hydroxylase-positive axonal varicosities. Ultrastructural analysis of tyrosine hydroxylase-positive boutons in such clusters revealed that dopaminergic axons synaptically contacted DARPP-32-immunoreactive neurons as well as unlabeled neuronal structures.

A primate model of Huntington's disease: cross-species implantation of striatal precursor cells to the excitotoxically lesioned baboon caudate-putamen

Ibotenic acid was injected unilaterally into the baboon caudate-putamen (CP) to achieve a neural degeneration model in the primate, with a neuropathology similar to Huntington's disease. Four to six weeks later injections of cell suspensions of striatal precursor cells, obtained by dissection of the fetal rat striatal region (13-15 days gestational age), were made into the excitotoxically lesioned CP of 3 baboons immunosuppressed by Cyclosporin A. Morphological analysis indicated that in one of the baboons, which had the largest lesion of the CP and the shortest survival time (6 weeks after implantation), there was a surviving striatal implant. The implanted neurons grew in high densities in cellular aggregates within the host gliotic CP. These neurons had a neuronal size phenotypical for rat striatum, i.e. on average about a 25% smaller neuronal cell diameter than a similar population in the baboon caudate-putamen. Glial-fibrillary-acid-protein immunoreactivity was present on large astrocytes within the striatal implant, with a distinct border towards the lesion-induced astrogliosis of the host. Neuronal markers for acetylcholinesterase and Leu-enkephalin were distributed in a typical patchy manner in the striatal implants along with fiber staining for tyrosine-hydroxylase-like immunoreactivity (TH) possibly derived from afferent host dopaminergic axons. Some of these fibers in the implants came from intrinsic TH-positive neuronal somata, probably of neocortical fetal origin and transiently expressing the enzyme. In conclusion, the results indicate that neuronal replacement can be achieved by cross-species implantation of fetal striatal precursor cells to the previously neuron depleted primate CP under immunosuppression but that the survival and growth of such implants may be variable and subject to unfavourable trophic conditions.

Neural grafting in a rat model of huntington's disease: Striosomal-like organization of striatal grafts as revealed by acetylcholinesterase histochemistry, immunocytochemistry and receptor autoradiography

Grafts of fetal striatum were implanted in the form of a cell suspension into the brains of rats with prior ibotenic acid lesions of the caudate-putamen. The grafts were placed in three different sites: the lesioned caudate-putamen, or the denervated (but otherwise undamaged) globus pallidus and substantia nigra. After 3–6 months survival the grafts were investigated by means of immunohistochemistry and receptor autoradiography in combination with routine histology and acetylcholinesterase histochemistry. The grafts placed within the lesioned caudate-putamen were at least 10-fold larger larger than those placed in the substantia nigra region, with the grafts placed in the globus pallidus being of intermediate size. In all locations the acetylcholinesterase staining had an uneven, patchy distribution, which was most pronounced in the grafts located within the caudate-putamen. These patches did not bear any obvious relationship to variations in density of the neuronal perikarya within the grafted tissue. Many of the neuropeptide-immunoreactive neuron types present in the normal striatum, such as those containing substance P, [Met]enkephalin, somatostatin, cholecystokinin and neuropeptide Y were also detected in the grafted striatum along with acetylcholinesterase-positive staining. Acetylcholinesterase-positive, [Met]enkephalin-positive, substance P-positive and tyrosine hydroxylase-positive markers all showed uneven, patchy distributions in the grafts. This was also the case for the distribution of dopamine D2 and opiate receptors (as revealed by [ 3H]spiroperidol and [ 3H]diprenorphine autoradiography, respectively), whereas muscarinic receptor binding was even throughout the grafts. As is the case in the so-called striosomal patches (neurochemically defined compartments) in the immature intact striatum during the early postnatal period, patches of high acetylcholinesterase staining in the grafts showed partial correspondence with patches of high [Met]enkephalin fibre staining, and dopamine receptor density, and (although to a lesser degree) also with patches of high opiate receptor density and high substance P-immunoreactivity. This correspondence of patches also occurred between tyrosine hydroxylase fibre staining and acetylcholinesterase staining as revealed by grafts placed into the substantia nigra. These results suggest that the fetal striatal cell suspension grafts will give rise to a fairly normal range of striatal neuron and receptor types and that they develop at least some of the striosomal features characteristic for the normal striatum. These organizational features were most prominently developed in the grafts located within the lesioned host caudate-putamen, but they did occur to some degree also in the grafts placed in the striatal target areas, globus pallidus and substantia nigra.