The present invention provides transgenic animals (e.g., transgenic porcine animals), organs, tissues, and cells derived from the transgenic animals that are particularly useful for xenotransplantation therapies. In particular, the present invention provides transgenic porcine animals, as well as organs, tissues and cells derived from the transgenic porcine animals, which lack any expression of a functional alpha 1,3 galactosyltransferase (GTKO) gene and comprise at least six transgenes under the control of at least three promoters within a single multi-gene expression vector, and further comprise at least four additional genetic modifications. Also provided are methods of making the transgenic animals (e.g., transgenic porcine animals), and methods of using the transgenic animals, organs, tissues, and cells derived from the transgenic animals for xenotransplantation therapies and treating a disease or condition.

The present invention relates to polyclonal antibodies directed against at least one non-human biological pathogen, or against at least one molecule derived from said pathogen, towards a human or a non-human animal organism, wherein the said polyclonal antibodies are devoid of an antigenic determinant selected in a group comprising (i) N-glycolneuraminic acid (Neu5Gc) and/or (ii) a-1,3-galactose, and their use as a medicament.

The present disclosure relates methods and compositions useful for prevention of porcine reproductive and respiratory syndrome virus (PRRSv) in animals, including animals of the species Sus scrofa. The present teachings relate to swine wherein at least one allele of a CD163 gene has been inactivated, and to specific methods and nucleic acid sequences used in gene editing to inactivate the CD163 gene. Swine wherein both alleles of the CD163 gene are inactivated are resistant to porcine reproductive and respiratory syndrome virus (PRRSv). Elite lines comprising homozygous CD163 edited genes retain their superior properties

The present disclosure relates generally to methods for using porcine sex-sorted sperm cells for the efficient dissemination of desirable traits in multi-level swine production systems. The methods include using sex-sorted sperm cells for skewing offspring gender at the commercial farm level, producing porcine herds having improved growth performance traits, producing pathogen-resistant porcine herds, and disseminating desirable traits from a genetic nucleus to commercial farms using low dose artificial insemination techniques. The methods also provide a means for reducing costs at the production level by increasing the ratio of female offspring and improving animal welfare at all levels of production by reducing or eliminating male castration. In addition, the methods of the present technology may be employed to develop production flows for specialized pork products.

The present invention relates to a breeding method for generating gene-edited non-human animals. In particular, the method of the present invention features simultaneous reprograming and gene-editing carried out in somatic cells and subsequent subcloning and genotyping conducted at the in vitro cell stage to obtain precisely gene-edited induced pluripotency stem cells (iPSCs) which are then used in somatic nuclear transfer (SCNT) to generate a precisely gene-edited non-human animal embryo and a resultant gene-edited non-human animal.

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 β 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.

Methods for protecting porcine fetuses from infection with Porcine Reproductive and Respiratory Syndrome Virus (PRRSV). The methods comprise breeding a female porcine animal with a male porcine animal. The female porcine animal comprises modified chromosomal sequences in both alleles of its CD163 gene, wherein the modified chromosomal sequences reduce the susceptibility of the female porcine animal to infection by PRRSV, as compared to the susceptibility to infection by PRRSV of a female porcine animal that does not comprise any modified chromosomal sequences in the alleles of its CD163 gene. The male porcine animal comprises at least one wild-type CD163 allele.

The present invention provides certain donor animals, tissues and cells that are particularly useful for xenotransplantation therapies. In particular, the invention includes porcine animals, as well as tissue and cells derived from these, which lack any expression of functional alpha 1,3 galactosyltransferase (aGT) and express one or more additional transgenes which make these animals suitable donors for xenotransplantation of vascularized xenografts and derivatives thereof. Methods of treatment and using organs, tissues and cells derived from such animals are also provided.

Provided is an SgRNA combination, comprising an SgRNA specifically targeting the GGTA1 gene, an SgRNA specifically targeting the CMAH gene and an SgRNA specifically targeting the β4GalNT2 gene. Also provided is a CRISPR/Cas9 vector combination, comprising a GGTA1-CRISPR/Cas9 vector, a CMAH-CRISPR/Cas9 vector and a β4GalNT2-CRISPR/Cas9 vector. Also provided is an applicaton of the CRISPR/Cas9 vector combination in knocking out the GGTA1 gene, the CMAH gene and the β4GalNT2 gene. The knockout rates of the three genes with the specifically targeted SgRNA sequences are respectively 56%, 63%, and 41%. A three genes knockoutpig can be obtained, wherein the three genes related to immune rejectionare knocked out, and heart valves of said pig can be acquired.

The present disclosure provides compositions and methods for increasing resistance to PCV2 infection in pigs. The increased resistance may be the result of siRNA or genetic modification through CRISPR or a vectored virus targeting SNPs that are resistant to PCV2 infection.