Described herein is a method for producing a chimeric non-human animal expressing a human NKX2-5, HANDII, TBX5 gene or a combination thereof gene comprising: a) generating a NKX2-5, HANDII, TBX5 or combination thereof null non-human animal cell, wherein both copies of the non-human NKX2-5, HANDII, TBX5 gene or combination thereof carry a mutation that prevents production of functional NKX2-5, HANDII, TBX5 protein or combination thereof in said non-human animal; b) creating a NKX2-5, HANDII, TBX5 or combination thereof null non-human blastocyst by somatic cell nuclear transfer comprising fusing a nucleus from said NKX2-5, HANDII, TBX5 or combination thereof null non-human animal cell of a) into an enucleated non-human oocyte and activating said oocyte to divide so as to form an NKX2-5, HANDII, TBX5 or combination thereof null non-human blastocyst; c) introducing human stem cells into the NKX2-5, HANDII, TBX5 or combination 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 NKX2-5, HANDII, TBX5 or combination thereof.

The disclosure in the specification relates to an artificial recombinant chromosome and the use thereof, and more particularly to an artificial recombinant chromosome generated by the recombination of two or more chromosomes and a production of a transgenic animal using a cell including the same. Especially, in the disclosure in the specification, an interchromosomal exchange between the recipient chromosome and the donor chromosome has many merits to produce the artificial recombinant chromosome for producing the transgenic animal.

Described herein is a method for producing a chimeric non-human animal expressing a human a MYF5, MYOD, MRF4 gene or a combination thereof gene comprising: a) generating an MYF5, MYOD, MRF4 or combination thereof null non-human animal cell, wherein both copies of the non-human MYF5, MYOD, MRF4 gene or combination thereof carry a mutation that prevents production of functional MYF5, MYOD, MRF4 protein or combination thereof in said non-human animal; b) creating a MYF5, MYOD, MRF4 or combination thereof null non-human blastocyst by somatic cell nuclear transfer comprising fusing a nucleus from said MYF5, MYOD, MRF4 or combination thereof null non-human animal cell of a) into an enucleated non-human oocyte and activating said oocyte to divide so as to form an MYF5, MYOD, MRF4 or combination thereof null non-human blastocyst; c) introducing human stem cells into the MYF5, MYOD, MRF4 or combination 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 MYF5, MYOD, MRF4 or combination thereof.

Provided are improved compositions and methods for achieving gene therapy in hematopoietic cells and hematopoietic precursor cells, including erythrocytes, erythroid progenitors, and embryonic stem cells. Also provided are improved gene therapy methods for treating hematopoietic-related disorders. Retroviral gene therapy vectors that are optimized for erythroid specific expression and treatment of hemoglobinopathic conditions are disclosed.

Factor IX proteins are described with an increase in the number of glycosylation sites and other modifications to provide Factor IX proteins that have higher specific activity and a longer useful clotting function relative to wild type or non-modified Factor IX protein.

The invention features methods, kits, and compositions for mitochondrial replacement in the treatment of disorders arising from mitochondrial dysfunction. The invention also features methods of diagnosing neuropsychiatric (e.g., bipolar disorder) and neurodegenerative disorders based on mitochondrial structural abnormalities.

The present invention relates to a method for the generation of V.sub.H heavy chain-only antibodies in a transgenic non-human mammal. In particular, the present invention relates to a method for the production of a V.sub.H heavy chain-only antibody in a transgenic non-human mammal comprising the step of expressing more than one heterologous V.sub.H heavy chain locus in that mammal.

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.

Generation of chimeric non-human animals hosting bat donor cells involves chimeric mice having bat cells that may be stably tolerated to provide a new platform technology in the general field of biology, and having application in the field of immunology related to virus-host interaction, cancer biology, autoimmunity, and the development of new drugs.

In one aspect, the invention provides methods of inhibiting the effects of MASP-2-dependent complement activation in a living subject. The methods comprise the step of administering, to a subject in need thereof, an amount of a MASP-2 inhibitory agent effective to inhibit MASP-2-dependent complement activation. In some embodiments, the MASP-2 inhibitory agent inhibits cellular injury associated with MASP-2-mediated alternative complement pathway activation, while leaving the classical (C1q-dependent) pathway component of the immune system intact. In another aspect, the invention provides compositions for inhibiting the effects of lectin-dependent complement activation, comprising a therapeutically effective amount of a MASP-2 inhibitory agent and a pharmaceutically acceptable carrier.