The invention encompasses methods for increasing genetic progress in livestock, and for genetic dissemination, including the use of amniocentesis to obtain fetal amniocytes for use in genomic evaluation and cloning.

The present invention provides manufacturing processes for biological replication of undifferentiated plant and animal cells and tissue in a weightless condition, including those systems used in current stem cell research and development and use of undifferentiated parenchyma in plants. The present invention further provides methods for adapting plants and animals to survive outside their native environments. In particular, undifferentiated cells from plants or animals are replicated under weightless conditions in which cell replication or proliferation is accelerated and sustained. Under such conditions, the undifferentiated cells can be “forced” to express sets of genes useful for survival in particular environmental conditions. In this manner, cells surviving prolonged exposure to specific environmental conditions can be selected for and cultivated to produce an organism adapted to that particular environment in an accelerated manner. Methods of identifying specific genes associated with adaptation of a plant or animal to a specific environment are also disclosed.

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.

The present disclosure relates to a novel murine parvovirus, sequences encoded thereby, and applications therefor. In one embodiment the disclosure provides a method for detecting the presence of a parvovirus in a sample, comprising detecting one or more nucleic acids or polypeptides derived from the parvovirus, or antibodies against the parvovirus, in the sample. Also provided are vectors and host cells comprising sequences encoded by the parvovirus and related sequences. Also provided are animal models of kidney disease associated with infection by the parvovirus.

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 herein is the first viable galactosyltransferase (Gal) knock-out sheep having a deletion or mutation of alpha-1,3-galactosyltransferase (GGTA1) gene and methods of making the same. Also provided are methods of screening a biological implant for stimulation of an antibody-mediated inflammatory response to a Gal antigen by implanting the biological implant into a recipient Gal knock-out animal and detecting signs of antibody-mediated inflammatory response in the recipient Gal knock-out animal. Further provided is a method of implanting a biological implant into a human subject by screening a first biological implant for signs of antibody-mediated inflammatory response in a recipient Gal knock-out animal and, upon detecting minimal or no signs of antibody mediated inflammatory response in the recipient Gal knock-out animal, implanting a second biological implant into the human subject, wherein the second biological implant is comparable to the first biological implant.

The present invention provides methods and compostions to improve the efficiency of somatic cell nuclear transfer (SCNT) and the consequent production of nuclear transfer ESC (ntESC) and transgenic cells and/or non-human animals. More specifically, the present invention relates to the discovery that trimethylation of Histone H3-Lysine 9 (H3K9me3) in reprogramming resistant regions (RRRs) in the nuclear genetic material of donor somatic cells prevents efficient somatic cell nuclear reprogramming or SCNT. The present invention provide methods and compositions to decrease H3K9me3 in methods to improve efficacy of SCNT by exogenous or overexpression of the demethylase Kdm4 family and/or inhibiting methylation of H3K9me3 by inhibiting the histone methyltransferases Suv39h1 and/or Suv39h2.

The present invention provides methods and compostions to improve the efficiency of somatic cell nuclear transfer (SCNT) and the consequent production of nuclear transfer ESC (ntESC) and transgenic cells and/or non-human animals. More specifically, the present invention relates to the discovery that trimethylation of Histone H3-Lysine 9 (H3K9me3) in reprogramming resistant regions (RRRs) in the nuclear genetic material of donor somatic cells prevents efficient somatic cell nuclear reprogramming or SCNT. The present invention provide methods and compositions to decrease H3K9me3 in methods to improve efficacy of SCNT by exogenous or overexpression of the demethylase Kdm4 family and/or inhibiting methylation of H3K9me3 by inhibiting the histone methyltransferases Suv39h1 and/or Suv39h2.

The invention encompasses methods for increasing genetic progress in livestock, and for genetic dissemination, including the use of amniocentesis to obtain fetal amniocytes for use in genomic evaluation and cloning.

Apicomplexan parasites or red blood cells infected with apicomplexan parasites are administered to an animal in combination with a delayed death agent that initially allows parasite replication but subsequently kills the apicomplexan parasites. This allows the elicitation of an immune response by the animal while preventing the parasites producing a serious infection of the animal. The apicomplexan parasites may be malaria or babesia parasites. The delayed death agent may be a tetracycline class antibiotic, a macrolide antibiotic or a lincosamide antibiotic.