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.

In order to develop tools and methods useful in a variety of applications, including the research and development of medical treatments which involve the modification of collagen protein and use of the same, the present invention provides a modified collagen protein expressed in a transformed cell and capable of forming collagen fibers outside of the cell, wherein the transformation is performed by introducing, into the cell, polynucleotides coding the modified collagen protein.

The present invention relates to a system for screening personalized anticancer agents, a method for screening personalized anticancer agents using the system, and an apparatus for screening personalized anticancer agents. When the inventive system for screening personalized anticancer agents is used, an anticancer agent showing an optimal anticancer activity against cancer cells collected from a patient can be selected from a variety of anticancer agents, and it is possible to previously examine a therapeutic response that can appear when the selected anticancer agent is administered into the patient. Thus, the risk of trial and error in cancer therapy can be reduced, and the cost and time required for cancer therapy can be reduced.

Residual, refractory or relapsed cancer is treated by immunostimulation in the presence of allogeneic immune effector cells, optimally in combination with radiation therapy. The methods of the disclosure induce a systemic allogeneic anti-tumor immune response that results in tumor regression in untreated sites of disease, i.e. non-injected, non-irradiated, etc.

The present disclosure relates to genetically modified non-human animals expressing human or chimeric (e.g., humanized) Thrombopoietin (THPO), and methods of use thereof.

An objective of the present invention is to provide non-human animal models of cancer pathology, which mimic the hierarchical organization, cancer progression process, or biological property of human cancer tissues, and uses thereof. To achieve the objective described above, first, the present inventors transplanted cells of NOG-established cancer lines into NOG mice and morphologically observed the resulting tissue organization. As a result, the non-human animal models were demonstrated to exhibit pathologies (the hierarchical organization, cancer progression process, or biological properties of the cancer cells) similar to that of human cancer. Specifically, the present inventors succeeded in preparing non-human animal models exhibiting pathologies more similar to a human cancer, and cell culture systems using NOG-established cancer cell lines where the in vitro cell morphology is more similar to that of human cancer.

The invention provides compositions and methods useful for the treatment and prevention of conditions associated with short telomere length.

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.

Embodiments disclosed here are production methods and compositions of engineered immune cells, such as B or T lymphocytes, from limited lineage myeloid progenitor cells, or from pluripotent stem cells, or from multilineage hematopoietic progenitor cells comprising the addition of various cell differentiation transcription factors and inhibiting epigenetic histone methylations in said cells.

Described herein are transgenic mice for testing immunogenicity and protective efficacy of a wide variety of therapeutic agents and vaccines, determining allograft rejection, and developing monoclonal antibodies and generating hybridomas. Methods of generating a transgenic mouse is also described. Described herein are mouse models capable of expressing B cell, a T cell, a monocyte, a macrophage, a dendritic cell, a NK cell, a iNKT cell, an innate lymphoid cell, a microglia cell, a red blood cell, which can develop into a functional human immune system.