Cross-species Grafts of Embryonic Rabbit Mesencephalic Tissue Survive and Cause Behavioral Recovery in the Presence of Chronic Immunosuppression

The Influence of Donor Age on the Survival of Solid and Suspension Intraparenchymal Human Embryonic Nigral Grafts

In many species, graft survival and graft-derived behavioral recovery are affected by the embryonic donor age. We compared the ability of solid and suspension grafts of human embryonic mesencephalic dopaminergic (DA) neurons at different embryonic stages to survive intra-parenchymal transplantation into 6-OHDA lesioned immunosuppressed rats. Suspension grafts survived best when donor age was between postconception (PC) days 34 and 56. Transplants displayed numerous healthy tyrosine hydroxylase immunoreactive (TH-IR) neurons which sent extensive neuritic processes into the host striatum. Suspension grafts survived poorly when donor age was greater than 65 days. Solid implants displayed comparable viability of TH-IR neurons when donor age was between 44 and 65 days. No solid grafts contained TH-IR cells when donor tissue was older than 72 days. The suspension and solid methods of transplantation resulted in comparable survival of robust grafts, but solid grafts resulted in more intergraft variability than suspension grafts, particularly among the more marginal implants. Our results demonstrate that the upper limit for survival of human embryonic DA suspension grafts correlates well with the period of development of the human nigrostriatal pathway. The “window” for donor age of solid human embryonic DA grafts appears to be extended by about 9 days in comparison to suspension grafts. These data suggest that the upper age limit for grafting human mesencephalic DA neurons should be PC day 56 for suspension grafts, and PC day 65 for solid implants. Older donors are likely to produce grafts with fewer surviving DA neurons.

Cyclosporine-A increases locomotor activity in rats with 6-hydroxydopamine-induced hemiparkinsonism: relevance to neural transplantation

BACKGROUND

The immunosuppressant cyclosporine-A (CsA) is the primary drug for neural transplantation in Parkinson's disease. However, little is known of its direct effects on movement disorders. Our previous observation of increased locomotor activity in normal rats injected with CsA prompted us to investigate further the effects of CsA on hemiparkinsonian rats.

METHODS

We examined the effects of CsA with 6-hydroxydopamine-induced hemiparkinsonism. The animals were randomly assigned to either intraperitoneal injections of CsA (15 mg/kg) or olive oil (the vehicle used for CsA) for 32 days. All animals were tested using the elevated body swing test, and the spontaneous and the amphetamine-induced rotational tests prior to and following the 32-day drug regimen.

RESULTS

As revealed by the elevated body swing test, CsA-treated rats had significantly higher mean percent contralateral (to the lesion) swings compared to their pretreatment level (p < 0.01) or to vehicle-treated rats at posttreatment (p < 0.005). In the spontaneous rotational test, CsA-treated rats displayed ipsilateral (to the lesion) rotations which were significantly higher than their pretreatment rotational behavior (p < 0.005) or the posttreatment rotational behavior of olive oil-treated rats (p < 0.0001). Similarly, CsA-treated rats displayed significantly more amphetamine-induced ipsilateral rotations compared to their or the olive oil-treated rats pretreatment level (p < 0.05).

CONCLUSION

Our present observations extend our previous findings on motor alterations produced by CsA on normal rats to hemiparkinsonian rats. These results taken together would suggest that CsA may interact with the locomotor effects observed following neural transplantation with adjunctive CsA immunosuppression.

Neural xenotransplantation: reconstruction of neuronal circuitry across species barriers

Selective replacement of degenerated neurons in the adult brain with allogeneic fetal neuroblasts is a promising therapeutic modality for human neurodegenerative diseases, but is confounded with practical and potential ethical problems. To evaluate the potential of xenogeneic donors as a cell source for neural transplantation, we have critically examined the available experimental evidence in animal models pertaining to the survival, integration and function of xenogeneic fetal neuroblasts in the host brain. A statistical meta-analysis across multiple studies revealed that immunologically-related transplantation parameters (immunosuppression and donor-host phylogenetic distance) were the main determinants of neural xenograft survival. The immunological basis for xenograft rejection is reviewed in the context of novel immunoprotection strategies designed to enhance xenograft survival. Furthermore, the evidence for behavioral recovery based on anatomical and functional integration of neural xenografts in the host brain is examined with an awareness of developmental considerations. It is concluded that neural xenotransplantation offers a unique opportunity for effective neuronal replacement with significant potential for clinical use.

Grafts in the treatment of Parkinson's disease: animal models

Long-term treatment of parkinsonian patients with L-DOPA leads to a loss of efficacy over time and the appearance of important side effects such as dyskinesias. Grafts of chromaffin cells of the adrenal medulla or fetal ventral mesencephalic neurons bring behavioral improvement in animal models of Parkinson's disease. These improvements are likely to be related to the secretion of dopamine by the grafted cells and/or to the reinnervation of the host tissue. In addition, a leak in the blood-brain barrier may allow peripheral catecholamines to gain access to the brain. Lack of clear effects of grafts in parkinsonian patients may be due to their poor survival in the human brain. Improvement of grafting techniques as well as the addition of neurotrophic factors to grafts may help increase their survival and improve behavioral effects. Recently, genetic techniques have allowed the creation of genetically modified cell lines which can produce L-DOPA and these cells may be grafted in the brain. Interestingly, these cell lines may be encapsulated in permselective membranes which can protect them from immunological rejection and avoid the uncontrolled cell growth of these mitotically active cells. Grafting techniques seem to be an interesting alternative to treat parkinsonian patients. Improvement of grafting procedures may help increase survival of grafts and thus enhance behavioral improvements. Moreover, genetic modification of well-known tumor cell lines or patient's own cells such as astrocytes may help avoid the low availability as well as ethical and immunological problems linked to the use of fetal human tissue.

Employment of fibroblasts for gene transfer: applications for grafting into the central nervous system

Genetic modification of primary skin fibroblasts offers a new approach to the focal delivery of deficient transmitter-specific enzymes (e.g., TH) or trophic substances (e.g., NGF) to the damaged or diseased CNS. Although fibroblasts are unable to provide anatomical corrections to defective neural connectivity, they can serve as biological pumps for the enzymes and growth factors in vivo. The capability of genetically engineered cells to ameliorate disease phenotypes in animal models of CNS disorders may ultimately results in the restoration of function. At this time, primary skin fibroblasts appear to be a convenient cellular population for the application of gene transfer and intracerebral grafting for the animal model of Parkinson's disease. It is now important for future investigations to provide data concerning the long-term stable expression of the transgene product (e.g., TH) following intracerebral implantation, as well as determining optimal conditions for the survival of primary cells grafted into the nervous system.