by Kyoto University
Credit: Stem Cells Translational Medicine (2024). DOI: 10.1093/stcltm/szae066
Researchers have developed a technique to enhance the effectiveness of cell transplantation therapy for stroke or traumatic brain injury. The team, including Professor Jun Takahashi, Researcher Bumpei Samata, and Graduate Student Keitaro Yamagami from the Department of Clinical Application at CiRA, published their study in the journal Stem Cells Translational Medicine on September 28, 2024.
When the motor cortex of the brain is damaged due to traumatic brain injury or stroke, it can result in long-term motor paralysis and significant motor function impairment. Although treatments such as drug therapy, surgery, and rehabilitation are commonly employed, their effectiveness is limited due to the low regenerative capacity of the central nervous system (CNS), thus necessitating the development of curative therapies.
Cell transplantation therapy using human induced pluripotent stem cell (iPSC)-derived brain organoids has gained attention as a promising new treatment approach to repair damaged neural circuits and promote the recovery of motor functions. However, the success rate remains low due to acute cell death after cell transplantation.
Previous reports have shown that cell transplantations one week after traumatic brain injury lead to better outcomes in terms of cell engraftment and neuronal axonal extension compared to transplants immediately following injury. Based on those observations, the research group hypothesized that brain tissues one week after traumatic brain injury may offer a more favorable environment for cell transplantation than immediately after injury.
Therefore, they sought to identify candidate substances responsible for the more permissive environment at the latter time point. The group found several candidate substances through transcriptome analysis, comparing RNA expression in brain tissues immediately and one week after injury.
Cell toxicity tests were performed using neurons derived from brain organoids to evaluate the ability of these candidate substances to protect against oxidative stress, a common cause of neuronal cell death following strokes and traumatic brain injuries.
The study found that treatment with progranulin (PGRN), a growth factor, reduced apoptosis through Akt phosphorylation and enhanced neuron survival. To validate the therapeutic effects of PGRN-treated human iPSC-derived brain organoids (hiPSC-COs), the researchers transplanted hiPSC-COs treated with recombinant human PGRN (rhPGRN) into mouse brains and performed histological evaluations three months later.
The results showed a significant improvement in the engraftment efficiency of hiPSC-COs, with enhanced axonal extension along the corticospinal tract, in the rhPGRN-treated group compared to the untreated group.
Based on these results, rhPGRN is believed to act as a priming agent to enhance engraftment and axonal extension of iPSC-derived neurons during cell transplantation therapy. Further studies will be necessary to identify optimal administration routes and evaluate safety (e.g., tumor formation) to ensure safer and more effective cell transplantation therapies.
More information: Keitaro Yamagami et al, Progranulin enhances the engraftment of transplanted human iPS cell-derived cerebral neurons, Stem Cells Translational Medicine (2024). DOI: 10.1093/stcltm/szae066
Journal information:Stem Cells Translational Medicine
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