Tissue for use as a transplant, which tissue is allogeneic or xenogeneic and respectively the tissue may express an MHC I molecule that is immunologically incompatible to the transplant recipient and/or may express an MHC II molecule immunologically incompatible to the transplant recipient. The tissue suitable for use as a transplant and the method for its production include a genetic alteration of the tissue that provides for immunologic compatibility of the tissue with a transplant recipient. In the tissue for use as a transplant, which tissue expresses allogeneic or xenogeneic MHC I and/or allogeneic or xenogeneic MHC II molecules, the expression of the allogeneic or xenogeneic MHC I is downregulated by at least 50% to up to 90%, preferably the expression of the allogeneic or xenogeneic MHC I is downregulated by at least 60%.

The present invention provides a kidney production method including a step of tissue-specifically removing a metanephric mesenchyme of a metanephros of a non-human animal; a step of transplanting, into the metanephros, a kidney precursor cell derived from a non-human animal which is allogeneic or xenogeneic to the non-human animal; and a step of advancing development of the metanephros, which is a step in which the transplanted kidney precursor cell is differentiated and matured to form a part of the kidney.

Disclosed herein are nerve xenografts and methods of using such for repairing and/or protecting a nerve tissue in a human patient. The subject matter disclosed herein generally relates to nerve xenografts derived from genetically engineered source animals, and use of such nerve xenografts for repairing and/protecting nerve tissue in a human patient, e.g., for reconstruction of large peripheral nerve gaps, treatment of spinal cord injuries and ailments, and other therapies.

Methods are disclosed herein for producing human hepatocytes from human induced pluripotent stem cells. Also provided are transgenic rats for the expansion of human hepatocytes, such as those produced using the methods disclosed herein.

Described here are methods, compositions, and systems for generating transgenic islet cells suitable for xenotransplantation.

The present invention provides a kidney production method including a step of tissue-specifically removing a metanephric mesenchyme of a metanephros of a non-human animal; a step of transplanting a human kidney precursor cell into the metanephros; and a step of advancing development of the metanephros, which is a step in which the transplanted human kidney precursor cell is differentiated and matured to form a part of the kidney.

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.

Methods of generating functional human organs and tissue in animal bodies suitable for transplantation into human subjects are provided. In particular, the contribution of human donor cells to tissues and organs can be increased in interspecies host embryos by knocking out a growth factor receptor gene such as the insulin-like growth factor 1 receptor or insulin receptor gene. Almost entirely donor-derived functional organs and tissue can be generated by using this method. The methods described herein are useful for generating human organs and tissue in animals and may be helpful for overcoming the current problems with organ shortage for transplantation therapy. Additionally, such organs and tissue can be used in drug discovery, drug screening, and toxicology testing.

Described herein is a method for producing a chimeric non-human animal expressing a human ETV2 gene comprising: a) generating an ETV2 null non-human animal cell, wherein both copies of the non-human ETV2 gene carry a mutation that prevents production of functional ETV2 protein in said non-human animal; b) creating an ETV2 null non-human blastocyst by somatic cell nuclear transfer comprising fusing a nucleus from said ETV2 null non-human animal cell of a) into an enucleated non-human oocyte and activating said oocyte to divide so as to form an ETV2 null non-human blastocyst; c) introducing human stem cells into the ETV2 null non-human blastocyst of b); and d) implanting said blastocyst from c) into a pseudopregnant surrogate non-human animal to generate a chimeric non-human animal expressing human ETV2.

The invention provides double knockout transgenic pigs (GT/CMAH-KO pigs) lacking expression of any functional αGAL and CMAH. Double knockout GT/CMAH-KO transgenic organs, tissues and cells are also provided. Methods of making and using the GT/CMAH-KO pigs and tissue are also provided.