This invention provides a therapeutic method for treatment of EGFR gene mutation-positive lung cancer using the REIC/Dkk-3 gene in combination with the EGFR tyrosine kinase inhibitor, the PD-1/-L1 immune checkpoint pathway inhibitor, and/or the molecular-targeted agent. This invention provides a therapeutic agent comprising, as an active ingredient, the REIC/Dkk-3 gene, which is used in combination with the EGFR tyrosine kinase inhibitor, the PD-1/-L1 immune checkpoint pathway inhibitor, and/or the molecular-targeted agent for treatment of EGFR gene mutation-positive lung cancer.

Genetically modified non-human animals expressing human SIRPα and human IL-15 from the non-human animal genome are provided. Also provided are methods for making non-human animals expressing human SIRPα and human IL-15 from the non-human animal genome, and methods for using non-human animals expressing human SIRPα and human IL-15 from the non-human animal genome. These animals and methods find many uses in the art, including, for example, in modeling human T cell and/or natural killer (NK) cell development and function, in modeling human pathogen infection of human T cells and/or NK cells, and in various in vivo screens.

Disclosed is a novel means which makes it possible to steadily mass-produce knockout individuals even in large animals. The method of the present invention is a method for producing a non-human large mammal or fish (non-human animal) that produces gametes originating in a different individual, and comprises transplanting at least one pluripotent cell derived from a second non-human animal into an embryo derived from a first non-human animal, said embryo being at a cleavage stage and having a genome in which a function of nanos3 gene is inhibited, to prepare a chimeric embryo, and allowing said chimeric embryo to develop into an individual.

Provided is a drug target for vitiligo. The drug target is IFN-γ signaling. It also provides a method for establishing vitiligo animal model, or a vitiligo induction method in an animal, and the established vitiligo animal model. Further, provided is a method for screening candidate drugs for treating vitiligo using the said animal model.

A chimeric non-human mammal disease model, wherein (1) at least 30% of all the glial cells in the corpus callosum of the chimeric non-human mammal are human glial cells, and/or (2) at least 5% of all of the glial cells in the white matter of the brain and/or brain stem of the chimeric non-human mammal are human glial cells, and wherein the human glial cells comprise a combination of a first group of human glial cells tagged with a first label and a second group of human glial cells tagged with a second label that is distinguishable from the first label.

The invention discloses methods for the generation of chimaeric human—non-human antibodies and chimaeric antibody chains, antibodies and antibody chains so produced, and derivatives thereof including fully humanised antibodies; compositions comprising said antibodies, antibody chains and derivatives, as well as cells, non-human mammals and vectors, suitable for use in said methods.

The invention discloses methods for the generation of chimaeric human—non-human antibodies and chimaeric antibody chains, antibodies and antibody chains so produced, and derivatives thereof including fully humanised antibodies; compositions comprising said antibodies, antibody chains and derivatives, as well as cells, non-human mammals and vectors, suitable for use in said methods.

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.

Provided is an epithelial tissue stem cell derived from an adult, which lacks at least one tumor suppressor gene.

A liver lesion-mouse model which is a liver-specific ISX gene expression and p53 gene knockout transgenic mouse, wherein liver lesion develops after the mouse is fed with a high calorie diet.