Non-human animals suitable for use as animal models for Retinoschisis are provided. In some embodiments, provided non-human animals are characterized by a disruption in a Retinoschisin-1 locus. In some embodiments, provided non-human animals are characterized by a mutant Retinoschisin-1 gene. The non-human animals may be described, in some embodiments, as having a phenotype that includes the development of one or more symptoms or phenotypes associated with Retinoschisis. Methods of identifying therapeutic candidates that may be used to prevent, delay or treat Retinoschisis or eye-related diseases, disorders or conditions are also provided.

The present invention provides ungulate animals, tissue and organs as well as cells and cell lines derived from such animals, tissue and organs, which lack expression of functional endogenous immunoglobulin loci. The present invention also provides ungulate animals, tissue and organs as well as cells and cell lines derived from such animals, tissue and organs, which express xenogenous, such as human, immunoglobulin loci. The present invention further provides ungulate, such as porcine genomic DNA sequence of porcine heavy and light chain immunogobulins. Such animals, tissues, organs and cells can be used in research and medical therapy. In addition, methods are provided to prepare such animals, organs, tissues, and cells.

Genetically modified mice comprising a nucleic acid sequence encoding a human M-CSF protein are provided. Also provided are genetically modified mice comprising a nucleic acid sequence encoding a human M-CSF protein that have been engrafted with human cells such as human hematopoietic cells, and methods for making such engrafted mice. These mice find use in a number of applications, such as in modeling human immune disease and pathogen infection; in in vivo screens for agents that modulate hematopoietic cell development and/or activity, e.g. in a healthy or a diseased state; in in vivo screens for agents that are toxic to hematopoietic cells; in in vivo screens for agents that prevent against, mitigate, or reverse the toxic effects of toxic agents on hematopoietic cells; in in vivo screens of human hematopoietic cells from an individual to predict the responsiveness of an individual to a disease therapy, etc.

The present invention relates to a Pde6b-deficient animal model of retinal degeneration produced by engineered endonucleases, and a method for producing the same. In the animal model of retinal degeneration according to the present invention, only a specific target gene can be removed using engineered endonucleases, so that mutagenesis can be stably achieved. In addition, it is possible to produce a congenital animal model through genetic manipulation at the embryonic stage rather than through acquired factors, which allows for production of an animal model that uniformly exhibits symptoms of the disease in question without being influenced by other factors.

This invention relates to the engineering of animal cells, preferably mammalian, more preferably rat, that are deficient due to the disruption of tumor suppressor gene(s) or gene product(s). In another aspect, the invention relates to genetically modified rats, as well as the descendants and ancestors of such animals, which are animal models of human cancer and methods of their use.

Described herein is the discovery that neither the nuclear localization signal (NLS) nor the prion-like domain (PLD) of TDP-43 is necessary for embryonic stem cell culture and differentiation into motor neurons in vitro. The ability of ES cells to express these TDP-43 mutants and differentiate into motor neurons that exhibit an ALS-like phenotype whereby the TDP-43 mutants redistribute to and aggregate in the cytoplasm and fail to regulate cryptic exon splicing allows these cells to act as a model of TDP-43 proteinopathy for the testing of candidate therapeutic agents that may resolve such proteinopathy. Additionally, these ES cells may be used to successfully generate non-human animals, e.g., mice, that also exhibit hallmark symptoms of ALS and that may be used in testing candidate agents useful in treating TDP-43 proteinopathies.

A genetically modified mouse is provided that comprises a conditional Acvr1 allele that comprises a mutated exon that, upon induction, converts to a mutant exon phenotype, wherein the mutant exon phenotype includes ectopic bone formation. Mice comprising a mutant Acvr1 exon 5 in antisense orientation, flanked by site-specific recombinase recognition sites, are provided, wherein the mice further comprise a site-specific recombinase that recognizes the site-specific recombinase recognitions sites, wherein the recombinase is induced upon exposure of the mouse to tamoxifen. Upon exposure to tamoxifen, the recombinase is expressed and acts on the RRS-flanked mutant exon 5 and places the mutant exon 5 in sense orientation and deletes the wild-type exon.

Provided are a method for constructing a mouse model with conditional knockout of the Tmem30a gene from a pancreatic cell and a use thereof. The construction method includes the steps of: constructing a homozygote mouse with conditional knockout of a Tmem30a gene, where both ends of one or more exons of the Tmem30a gene are inserted into directly arrayed loxp loci; and mating the mouse with a pancreatic cell specific transgenic mouse Ins2-Cre, thereby obtaining the mouse model with conditional knockout of the Tmem30a gene from the pancreatic cell. The mouse with conditional knockout of the Tmem30a gene from the pancreatic cell shows glucose intolerance and poor insulin sensitivity, and can be used as a diabetes research model.

The present invention provides ungulate animals, tissue and organs as well as cells and cell lines derived from such animals, tissue and organs, which lack expression of functional endogenous immunoglobulin loci. The present invention also provides ungulate animals, tissue and organs as well as cells and cell lines derived from such animals, tissue and organs, which express xenogenous, such as human, immunoglobulin loci. The present invention further provides ungulate, such as porcine genomic DNA sequence of porcine heavy and light chain immunogobulins. Such animals, tissues, organs and cells can be used in research and medical therapy. In addition, methods are provided to prepare such animals, organs, tissues, and cells.

The present disclosure provides transgenic nematode systems for assessing function of heterologous genes, their variants and drug discovery. The transgenic nematodes contain a heterologous gene that is inserted via homologous recombination at the native locus replacing and removing the nematode ortholog, wherein expression of the heterologous gene rescues function of the removed nematode ortholog and a transgenic control animal is provided. The heterologous gene may be further modified to provide a variant, such as a human clinical variant, whereby a transgenic test animal is provided. Those transgenic test animals are used in methods to assess function of the heterologous variant and drug screens to find therapeutic candidates reversing deviant activity back to wildtype.