The present invention relates to a CRISPR/Cas system having an inversion correction potential, which uses at least one guide RNA targeting a sequence region where two different homologs present on genomic introns are conjugated to each other in an inversion manner, and a Cas protein, and a CRISPR/Cas system of FVIII gene inversion correction potential that uses at least one guide RNA targeting an int22-1/3 homolog or int22-1/2 homolog sequence region present on intron 22 of coagulation factor VIII (F8) gene and a Cas protein. A CRISPR/Cas system according to the present invention comprises a system which employs a small-size Cas9 and a guide RNA fitted thereto, thereby enabling all CRISPR/Cas instruments to be easily packaged in one AAV, which is impossible in conventional large-size Cas9. In addition, the CRISPR/Cas system can induce normal gene expression thanks to the inversion gene correction potential thereof and is excellent as a technology capable of effectively overcoming the difficult intracellular delivery of large-size gene mutation through gene editing. Particularly, the system can induce normal FVIII expression by restoring the inversion of FVIII gene and thus is useful for the treatment of hemophilia A.

The present invention relates to a composition for producing an extracellular matrix from a eukaryotic cell, the composition comprising a polypeptide or compound capable of specifically binding to a microtubule associated serine/threonine kinase family member 4 (MAST4) protein or a fragment thereof or a polynucleotide, polypeptide or compound capable of specifically binding to a nucleic acid coding for the MAST4 protein or a fragment thereof, and a composition for promoting chondrogenesis, comprising the same composition.

Provided herein are methods for preventing or treating diseases, said methods comprising (i) inhibiting entry of bacteriophages and/or component(s) thereof into microbiota, bodily fluid(s) or tissue(s) of the mammals and/or (ii) inactivating or modifying bacteriophages and/or component(s) thereof present in microbiota, bodily fluid(s) or tissues of the mammals and/or (iii) inactivating or modifying bacteriophages and/or component(s) thereof in one or more of food, drinking water, water for washing, water for air humidification, air, or habitat object of the mammals.

The purpose of the present invention is to provide a novel medical application of pluripotent stem cells (muse cells) in regeneration medicine. The present invention provides a cell preparation and a pharmaceutical composition which are for amelioration and treatment of brain disorders resulting from fetal growth retardation, such as abnormal motor quality or abnormal neurological development, and which contain SSEA-3 positive pluripotent stem cells isolated from a mesenchymal tissue from a live body or cultured mesenchymal cells. It is assumed that this cell preparation is based on a mechanism where muse cells that are administered to objects having the disorders are engrafted on an impaired brain tissue, thereby ameliorating or treating the disorders.

An apparatus for unilateral spinal cord compression includes a fixed member and a movable member that moves longitudinally along the fixed member by using a linear actuating mechanism to compress a portion of spinal cord encompassed by the movable member and the fixed member.

This invention provides compositions of active highly phosphorylated lysosomal sulfatase enzymes, their pharmaceutical compositions, methods of producing and purifying such lysosomal sulfatase enzymes and compositions and their use in the diagnosis, prophylaxis, or treatment of diseases and conditions, including particularly lysosomal storage diseases that are caused by, or associated with, a deficiency in the lysosomal sulfatase enzyme.

Provided are a posttraumatic stress disorder (PTSD) animal model in which dopamine receptor subtype 4 (D4R) is damaged or deficient, a method for preparing the same, a method for screening a drug for treating PTSD using the same, and a pharmaceutical composition for treating PTSD comprising a drug detected by the screening method. As it is identified that a specific type of dopamine receptor is associated with a mechanism for fear memory expression induced by long-term depression (LTD), the understanding of pathogenesis of PTSD may be heightened, the animal model exhibiting similar clinical conditions of PTSD and the method for preparing the same may be applied in analyses for stability and effectiveness of a therapeutic agent for PTSD and screening of a therapeutic drug. Further, an agonist of D4R contained in the composition has been approved by the US FDA and clinically used for psychiatric diseases such as schizophrenia, and thus may be immediately used for clinical applications for PTSD symptoms.

This invention relates to a pharmaceutical composition for treatment of a bone disease comprising, as an active ingredient, a protein comprising an extracellular cysteine-rich domain, which is from the Frizzled receptor selected from the group consisting of mammalian animal-derived Frizzled 1, Frizzled 2, and Frizzled 7 and has activity of increasing bone mass, bone density, and/or bone strength, or a mutant of such domain having sequence identity of 85% or higher to the amino acid sequence of the domain and having activity of increasing bone mass, bone density, and/or bone strength, or a vector comprising a nucleic acid encoding the protein.

The present invention has found that chimeric animals suffer from noticeable inflammation after birth, though neither immune response nor inflammation in the fetal period of these animals has been reported hitherto. This is an unexpected finding since chimeric animals in the fetal period were exclusively analyzed in prior studies and thus it is deemed that immunotolerance has been theoretically established therein. The present invention provides a composition for suppressing immune response or inflammation in the fetal period of a born chimeric animal.

Studies of the pathogenic mechanisms underlying human myopathies and muscular dystrophies often require animal models, but models of some human diseases are not yet available. The present invention provides methods to promote the engraftment and development of myogenic cells from individuals with such diseases into mature muscle tissue in mice to treat muscle diseases, muscle injury and reduced muscle function. Immortalized human myogenic precursor cells (hMPCs) form mature human myofibers following implantation into the hindlimbs of immunodeficient mice. The engraftment of the cells and their development into mature muscle myofibers is promoted by intermittent neuromuscular electrical stimulation (iNMES) of the peroneal nerve of the engrafted limb. The human myofibers that form are innervated, their contractile apparatus is fully differentiated, and they are comprised of human myonuclei, with minimal contamination by murine myonuclei.