The method for producing a cell aggregate including glial progenitor cells according to the present invention comprises: (1) a step of subjecting pluripotent stem cells to suspension culture in an embryoid-body-forming culture medium containing one or more SMAD signaling inhibitors and one or more Wnt signaling activators in the absence of feeder cells for 5 days to 10 days, to form a cell aggregate; (2) a step of subjecting the cell aggregate obtained in (1) to suspension culture in an embryoid-body-forming culture medium containing retinoic acid; (3) a step of subjecting the cell aggregate obtained in (2) to suspension culture in an embryoid-body-forming culture medium or neuron-and-glia-proliferating culture medium containing retinoic acid and one or more SHH signaling activators; and (4) a step of subjecting the cell aggregate obtained in (3) to suspension culture in a neuron-and-glia-proliferating culture medium containing no retinoic acid and one or more SHH signaling activators.

The method for producing a cell aggregate including glial progenitor cells according to the present invention comprises: (1) a step of subjecting pluripotent stem cells to suspension culture in an embryoid-body-forming culture medium containing one or more SMAD signaling inhibitors and one or more Wnt signaling activators in the absence of feeder cells for 5 days to 10 days, to form a cell aggregate; (2) a step of subjecting the cell aggregate obtained in (1) to suspension culture in an embryoid-body-forming culture medium containing retinoic acid; (3) a step of subjecting the cell aggregate obtained in (2) to suspension culture in an embryoid-body-forming culture medium or neuron-and-glia-proliferating culture medium containing retinoic acid and one or more SHH signaling activators; and (4) a step of subjecting the cell aggregate obtained in (3) to suspension culture in a neuron-and-glia-proliferating culture medium containing no retinoic acid and one or more SHH signaling activators.

A method of obtaining cell derived vesicles comprising an active wild-type p53 is disclosed. The method comprising: (i) isolating cell derived vesicles from a biological sample comprising cells; and (ii) treating the cell derived vesicles with a DNA damaging agent, or the method comprising: (i) treating cells with a DNA damaging agent; and (ii) isolating cell derived vesicles from a biological sample comprising the cells. A proteinaceous preparation comprising cell derived vesicles and a pharmaceutical composition comprising the proteinaceous preparation are also disclosed. Methods of treating a disease, disorder or condition associated with a mutant or a nonfunctional p53 protein and methods of inducing apoptosis of a target cell comprising a mutant or a nonfunctional p53 protein are also disclosed.

A method of obtaining cell derived vesicles comprising an active wild-type p53 is disclosed. The method comprising: (i) isolating cell derived vesicles from a biological sample comprising cells; and (ii) treating the cell derived vesicles with a DNA damaging agent, or the method comprising: (i) treating cells with a DNA damaging agent; and (ii) isolating cell derived vesicles from a biological sample comprising the cells. A proteinaceous preparation comprising cell derived vesicles and a pharmaceutical composition comprising the proteinaceous preparation are also disclosed. Methods of treating a disease, disorder or condition associated with a mutant or a nonfunctional p53 protein and methods of inducing apoptosis of a target cell comprising a mutant or a nonfunctional p53 protein are also disclosed.

The present invention provides a composition for treating ischemic diseases or neuroinflammatory diseases. PSA-NCAM-positive neural progenitor cells used in the present invention promote angiogenesis in injected tissue and inhibit an inflammatory response. The PSA-NCAM-positive neural progenitor cells can be simply isolated by using an anti-PSA-NCAM-antibody, and exhibit excellent angiogenic and anti-inflammatory activities compared with mesenchymal stem cells, and thus can be useful as a composition for effectively treating ischemic diseases caused by a vascular injury and nerve damage diseases caused by inflammation. In addition, a secretome of the neural progenitor cells of the present invention reduces the ischemic injury site and allows a neurological function to recover, and thus can be used as an agent for treating ischemic diseases and degenerative nervous system disorders such as nerve damage diseases caused by inflammation.

The present invention provides a composition for treating ischemic diseases or neuroinflammatory diseases. PSA-NCAM-positive neural progenitor cells used in the present invention promote angiogenesis in injected tissue and inhibit an inflammatory response. The PSA-NCAM-positive neural progenitor cells can be simply isolated by using an anti-PSA-NCAM-antibody, and exhibit excellent angiogenic and anti-inflammatory activities compared with mesenchymal stem cells, and thus can be useful as a composition for effectively treating ischemic diseases caused by a vascular injury and nerve damage diseases caused by inflammation. In addition, a secretome of the neural progenitor cells of the present invention reduces the ischemic injury site and allows a neurological function to recover, and thus can be used as an agent for treating ischemic diseases and degenerative nervous system disorders such as nerve damage diseases caused by inflammation.

Uses of n-butylidenephthalide (BP) in dopaminergic progenitor cell transplantation are provided, wherein the uses include using BP to enhance the therapeutic effect of dopaminergic progenitor cell transplantation, and using a combination of BP and BP-treated dopaminergic progenitor cells in dopaminergic progenitor cell transplantation. The uses especially relate to using BP to enhance the therapeutic effect of dopaminergic progenitor cell transplantation on Parkinson’s disease.

Uses of n-butylidenephthalide (BP) in dopaminergic progenitor cell transplantation are provided, wherein the uses include using BP to enhance the therapeutic effect of dopaminergic progenitor cell transplantation, and using a combination of BP and BP-treated dopaminergic progenitor cells in dopaminergic progenitor cell transplantation. The uses especially relate to using BP to enhance the therapeutic effect of dopaminergic progenitor cell transplantation on Parkinson’s disease.

A genetically modified glial cells, and use of such cells for rejuvenating glial cell population or treating glial cell-related disorders are disclosed. A method of treating a disorder of the brain and/or brain stem in a subject by introducing a population of genetically modified glial progenitor cells into the brain and/or brain stem of the subject, wherein the genetically modified glial progenitor cells have increased expression of one or more genes compared to the same type of glial progenitor cells that have not been genetically modified, wherein said increased expression of the one or more genes in the genetically modified glial progenitor cells confer competitive advantage over native or already resident glial progenitor cells in the subject.

The present invention relates to novel compositions and methods to produce 3D organ equivalents of the brain (i.e. “mini-brains”). The invention also relates to methods of using human induced pluripotent stem cells, a combination of growth and other soluble factors and gyratory shaking. Cells from healthy or diseased donors or animals can be used to allow testing different genetic backgrounds. The model can be further enhanced by using genetically modified cells, adding micro-glia or their precursors or indicator cells (e.g. with reporter genes or tracers) as well as adding endothelial cells to form a blood-brain-barrier.