The present disclosure relates to a JAK3 gene-mutated severe combined immunodeficiency animal model and a method of constructing the same. In the JAK3 gene-mutated severe combined immunodeficiency animal model of the present disclosure, the JAK3 gene is specifically deficient, the expression of cytokines is regulated by controlling the number and activity of macrophages, and the thymus, lymphocytes, and Peyer's patches, which are observed in conventional severe combined immunodeficiency animal models, particularly mini-pigs, are completely lacking. In addition, the animal model of the present disclosure can be used as a treatment model for JAK3 SCID patients, as similar phenotypes are observed in patients with human severe combined immunodeficiency caused by a JAK3 gene mutation, and can be used for artificial blood development or xenotransplantation.

Duchenne muscular dystrophy (DMD), which affects 1 in 5,000 male births, is one of the most common genetic disorders of children. This disease is caused by an absence or deficiency of dystrophin protein in striated muscle. The major DMD deletion hot spots are found between exon 6 to 8, and exons 45 to 53. Here, a humanized mouse model is provided that can be used to test a variety of DMD exon skipping strategies. Among these are, CRISPR/Cas9 oligonucleotides, small molecules or other therapeutic modalities that promote exon skipping or micro dystrophin mini genes or cell based therapies. Methods for restoring the reading frame of exon 44 deletion via CRISPR-mediated exon skipping in the humanized mouse model, in patient-derived iPS cells and ultimately, in patients using various delivery systems are also contemplated. The impact of CRISPR technology on DMD is that gene editing can permanently correct mutations.

The present invention provides fish with promoted growth. The fish according to the present invention has loss of function of a melanocortin-4 receptor (MC4R) gene.

The present invention relates to a human artificial chromosome which is genetically transmissible to the next generation with high efficiency and the method for using the same. More specifically, the present invention relates to: a human artificial chromosome in which an about 3.5 Mb to about 1 Mb region containing an antibody light chain gene derived from human chromosome 22 is bound to a chromosome fragment which is transmissible to a progeny through a germ line of a non-human animal, said chromosome fragment is derived from another human chromosome; a non-human animal carrying the human artificial chromosome and an offspring thereof; a method for producing the non-human animal; a method for producing a human antibody using the nonhuman animal or an offspring thereof; and a human antibody-producing mouse carrying the human artificial chromosome.

Duchenne muscular dystrophy (DMD), which affects 1 in 5,000 male births, is one of the most common genetic disorders of children. This disease is caused by an absence or deficiency of dystrophin protein in striated muscle. The major DMD deletion hot spots are found between exon 6 to 8, and exons 45 to 53. Here, a humanized mouse model is provided that can be used to test a variety of DMD exon skipping strategies. Among these are, CRISPR/Cas9 oligonucleotides, small molecules or other therapeutic modalities that promote exon skipping or micro dystrophin mini genes or cell based therapies. Methods for restoring the reading frame of exon 44 deletion via CRISPR-mediated exon skipping in the humanized mouse model, in patient-derived iPS cells and ultimately, in patients using various delivery systems are also contemplated. The impact of CRISPR technology on DMD is that gene editing can permanently correct mutations.

Genetically modified non-human animals and methods and compositions for making and using the same are provided, wherein the genetic modification comprises a humanization of an endogenous signal-regulatory protein gene, in particular a humanization of a SIRP gene. Genetically modified mice are described, including mice that express a human or humanized SIRP protein from an endogenous SIRP locus.

The present invention relates to: A schizophrenia animal model wherein the model is a mouse in which an anoctamin 1 (ANO1) gene is knocked out in cholinergic neurons of a medial habenula; and a preparation method therefor and the like. The schizophrenia animal model according to the present invention targets the medial habenula which is brain tissue playing a major role in the pathogenesis of schizophrenia, and it has been confirmed that when the ANO1 gene is specifically knocked out in the cholinergic neurons of the medial habenula, positive, negative and cognitive symptoms of schizophrenia are observed, thereby confirming that schizophrenia has been induced. Therefore, the animal model of the present invention is expected to be effectively useful in schizophrenia pathogenesis research and therapeutic agent development and screening.

Provided is a method for developing a secondary organ by using a non-human animal in which organ formation is inhibited, for the purpose of establishing a process for producing a functional cell such as a cell within the body of an animal such as a pig, the method including the step of raising a newborn or a fetus of the non-human animal in which organ formation is inhibited by complementing at least a part of the function of the organ whose formation is inhibited.

Provided herein non-human transgenic animals comprising a genome that: i) under-expresses, or is inducible to under-express, Hu Antigen R (HuR) in at least some neurons of said transgenic animal; ii) does not express HuR, or is inducible to not express HuR, in at least some neurons of said transgenic animal; or iii) does not express functional HuR, or is inducible to not express functional HuR in at least some neurons of said transgenic animal, as well as methods of screening drugs and therapies (e.g., useful in treating ALS) using such animals.

Methods and materials for treating a mammal having a congenital disease (e.g., a congenital heart disease such as congenital long QT syndrome) are provided herein. For example, this document provides methods and materials for generating and using nucleic acids to treat a mammal having a congenital disease, where the nucleic acids can suppress expression of mutant disease-related alleles in the mammal while providing a replacement cDNA that does not contain the disease-related mutation(s).