Provided is a double-gene knockout vector system, a method for preparing porcine fibroblasts with both CD163 gene and CD13 gene being knocked-out, prepared porcine fibroblasts, and a method for preparing a gene-edited pig with both CD163 gene and CD13 gene being knocked-out. The vector system of the present disclosure comprises a CD163 gene knockout vector and a CD13 gene knockout vector. The CD163 gene knockout vector comprises a gene editing vector backbone and a DNA fragment ligated to the gene editing vector backbone, with a nucleotide sequence of the DNA fragment being shown in any one of SEQ ID NOs: 1-3. The CD13 gene knockout vector comprises a gene editing vector backbone and a DNA fragment ligated to the gene editing vector backbone, a nucleotide sequence of the DNA fragment being shown in any one of SEQ ID NOs: 4-6.

The present invention relates to a porcine alpha-S1-casein gene, a porcine alpha-S1-casein gene promoter, an expression comprising the same promoter, and a method for the production of a target protein using the same expression vector. The promoter of the present invention facilitates the mammary gland-specific expression of the target protein. Accordingly, an animal transformed with the promoter secretes the target protein in milk at high concentration, and thus can be advantageously used for the production of useful proteins.

The present invention relates to a transgenic pig comprising a mutated IAPP gene and displaying a phenotype associated with diabetes. The invention also relates to a transgenic blastocyst, embryo, fetus, donor cell and/or cell nucleusderived from said transgenic pig. The invention further relates to use of the transgenic pig as a model system for studying therapy, treatment and/or prevention of diabetes.

Methods and compositions for synchronizing the time of insemination in gilts are provided. More particularly, methods and compositions for synchronizing the time of insemination in gilts using a gonadotropin-releasing hormone and a hormone for synchronizing estrus are provided.

Provided are cells, tissues, organs, and/or animals having one or more modified genes for enhanced xenograft survival and/or tolerance. And methods of producing and using the cells, tissues, organs, and/or animals.

Genetically modified cells, tissues, and organs for treating or preventing diseases are disclosed. Also disclosed are methods of making the genetically modified cells and non-human animals.

A method for non-surgical neutering or castration of a non-human mammal for AAV-mediated delivery of an anti-GnRH polypeptide to a non-human animal is described. More particularly, the animal is administered an adeno-associated virus (AAV) vector having an AAV capsid having packaged therein nucleic acid sequences comprising an AAV 5′ inverted terminal repeat (ITR), a sequence encoding a polypeptide which specifically binds gonadotropin releasing hormone (GnRH) under control of regulatory sequences which direct expression of the polypeptide, and an AAV 3′ ITR. A composition comprising the AAV-anti-GnRH may also be used for inhibiting tumor growth in a mammal with a cancer responsive to gonadal steroid hormones.

Disease model pigs produced by nuclear transplantation, disease model pigs exhibiting stable phenotypes and production methods thereof are provided. Chimeric pigs for producing disease model pigs exhibiting stable phenotypes, genital glands thereof, and germ cells thereof are also provided. A method for producing a genetically modified disease model pig, includes: (a) transplanting a nucleus of a genetically modified cell into cytoplasm of an egg; (b) developing an obtained clonal embryo in a womb of a female pig to obtain an offspring; and mating the obtained offspring or having the offspring undergo sexual reproduction to further obtain the genetically modified offspring as a disease model pig.

There are provided to a Rag-2 (Recombination activating gene 2) gene targeting vector, a method for producing SCID-like miniature pigs introduced with the vector, and a use thereof.

A biological system for generating and preserving a repository of personalized, humanized transplantable cells, tissues, and organs for transplantation, wherein the biological system is biologically active and metabolically active, the biological system having genetically reprogrammed cells, tissues, and organs in a non-human animal for transplantation into a human recipient, wherein the non-human animal does not present one or more surface glycan epitopes and specific sequences from the wild-type swine's SLA is replaced with a synthetic nucleotides based on a human captured reference sequence from a human recipient's HLA.