A gene and cell therapy using a cell fusion technology is proposed. Cells overexpressing hemagglutinin neuraminidase (HN) and fusion (F) proteins have effects of enhancing cell fusion with other cells, restoring cell damage through the cell fusion with damaged cells, and transferring a normal gene. Therefore, when a vector including genes encoding the HN and F proteins of the present invention or a cell transformed with the vector is clinically applied to neurodegenerative diseases, muscular diseases, and the like, an effect of reducing the damage of damaged cells through cell fusion can be expected.

An objective of the present invention is to provide an improved negative-strand RNA viral vector and a use thereof, the negative-strand RNA viral vector exhibiting transient high expression of genes loaded in the vector and enabling the rapid removal of the vector after said expression. It was discovered that by adding a micro-RNA target sequence to the NP, P, or L gene of a negative-strand RNA viral vector, it is possible to control the expression of the vector depending on the micro-RNA expressed by the introduction cell. In particular, when a micro-RNA target sequence was added to the NP or P gene, the expression of the vector decreased depending on the micro-RNA, and the removal of the vector was promoted, while the effect was reversed when a micro-RNA target sequence was added to the L gene. The vector can be applied in cell therapy and regenerative medicine and can be used as a therapeutic vector that targets cancer.

The present invention relates to retroviral vectors, particularly lentiviral vectors, comprising a modified retroviral RNA sequence that is codon-substituted and comprises a reduced number of retroviral open-reading frames, and wherein the retroviral vector is pseudotyped with hemagglutinin-neuraminidase (HN) and fusion (F) proteins from a respiratory paramyxovirus, methods of making the same and uses thereof.

The present invention relates to a medicament for preventing and/or treating cognitive impairment and/or a neurodegenerative disease with accumulation of a prionoid, comprising a Sendai virus envelope as an active ingredient and combined application of the medicament and an immune checkpoint inhibitor.

A genome editing kit includes a viral envelope, a Cas9 protein, a surfactant, and at least one positively charged substance selected from the group consisting of protamine sulfate, polyarginine, polylysine, polyethyleneimine, and hexadimethrine bromide. A genome editing composition includes a viral envelope, a Cas9 protein, a guide RNA, and a positively charged substance. A genome editing method and a method for producing a genome-edited cell or organism include the step of bringing a viral envelope, a Cas9 protein, a guide RNA, and a positively charged substance into contact with a cell or organism. The genome editing kit etc. are capable of editing genomes of cells (e.g., immune cells (strain)) that are conventionally difficult to transfect.

The present invention relates to a Sendai virus or recombinant Sendai virus vector. In particular the present invention provides methods, vectors, formulations, compositions, and kits for a modified Enders strain Sendai viral vector. An immunogenic vector can be used in any in vitro or in vivo system. Moreover, some embodiments include vectors for imaging virus growth, location and transmission.

The present invention relates to nucleic acid cassettes for gene therapy, particularly to nucleic acid cassettes encoding therapeutic proteins in combination with exogenous signal peptides. The invention further relates to viral and non-viral vectors comprising such nucleic acid cassettes, and the use of such nucleic acid cassettes and vectors to increase expression of therapeutic proteins by airway cells.

The present invention relates to gene and cell therapy using a cell fusion technology and more particularly, cells overexpressing hemagglutinin neuraminidase (HN) and fusion (F) proteins have effects of enhancing cell fusion with other cells, restoring cell damage through the cell fusion with damaged cells, and transferring a normal gene. Therefore, when a vector including genes encoding the HN and F proteins of the present invention or a cell transformed with the vector is clinically applied to neurodegenerative diseases, muscular diseases, and the like, an effect of reducing the damage of damaged cells through cell fusion can be expected.

The present disclosure relates to methods for transiently activating temperature-sensitive agents in one or more cells, for example by contacting one or more cells with a temperature-sensitive agent and transiently incubating the cells at a permissive temperature for inducing an activity of the temperature-sensitive agent in the cells. Additionally, the present disclosure relates to methods of contacting one or more cells in a subject with a temperature-sensitive agent and then lowering the subject's core body temperature to a permissive temperature for inducing an activity of the temperature-sensitive agent in the cells. The disclosure also relates to methods of contacting one or more cells in a subject with a temperature-sensitive agent, maintaining the subject's surface body temperature at a permissive temperature for inducing an activity of the temperature-sensitive agent in the cells. Further disclosed are methods of treating a subject with a temperature-sensitive therapeutic agent.

Provided are a storage method and a banking system of cells prepared using somatic cell nuclear transfer (NT) technology with homozygous genotypes of genes of human leukocyte antigen (HLA)-A, HLA-B, HLA-DR, and the like. The banking of NT cell-derived stem cells may be applied to autologous or allogenic patients and can provide transplantable cells and tissue materials for the treatment of various diseases such as diabetes, osteoarthritis, Parkinson's disease, and the like.