Disclosed herein are chimeric blastocysts, such as chimeric blastocysts derived from a host blastocyst from a first mammalian species and having donor pluripotent stem cells from a second mammalian species, wherein the donor pluripotent stem cells have reduced expression or reduced biological activity of one or more proteins in the TLR/NF-kB signaling pathway or the p53 pathway. Methods of preparing chimeric blastocysts and methods of obtaining mammalian organs and tissues are also provided.

The present invention is directed generally to systems for making host cells with artificial endosymbionts. In an embodiment, the systems of the invention comprise a host cell, an artificial endosymbiont, a means for introducing the artificial endosymbiont to the host cell, a means for separating the host cells with artificial endosymbionts from free artificial endosymbionts, and a means for detecting artificial endosymbionts in host cells.

An artificial recombinant chromosome produced by recombination of two or more chromosomes and the production of a transgenic animal using a cell including the same are disclosed. A method for producing a cell including one or more artificial recombinant chromosomes includes preparing a first targeted cell and a second targeted cell, producing one or more microcells using the second targeted cell, producing a fusion cell using the first targeted cell and the one or more microcells, and producing a cell including an artificial recombinant chromosome by treating the fusion cell with site specific recombinase (SSR).

Systems for selecting, generating, and breeding hybrid dairy cattle are described, as are methods for maintaining herds of hybrid cattle.

Systems for selecting, generating, and breeding hybrid dairy cattle are described, as are methods for maintaining herds of hybrid cattle.

This application provides a method for preparing human cell-derived microcells from human cells comprising DNA of interest, comprising: a step of culturing human cells in a medium containing at least one micronucleus inducer selected from the group consisting of microtubule polymerization inhibitors (excepting colcemid), microtubule depolymerization inhibitors, and spindle checkpoint inhibitors, thereby to produce human cell-derived microcells; and a step of collecting human cell-derived microcells comprising the DNA of interest, and a method for preparing human cells comprising DNA of interest by use of the method, which can be also applied to non-human animal cells.

The present invention is directed generally to eukaryotic host cells comprising artificial endosymbionts and methods of introducing artificial endosymbionts into eukaryotic host cells. The invention provides artificial endosymbionts that introduce a phenotype to host cells that is maintained in daughter cells. The invention additionally provides eukaryotic host cells containing magnetotactic bacteria.

The present invention is directed generally to eukaryotic host cells comprising artificial endosymbionts and methods of introducing artificial endosymbionts into eukaryotic host cells. The invention provides artificial endosymbionts that introduce a phenotype to host cells that is maintained in daughter cells. The invention additionally provides eukaryotic host cells containing magnetotactic bacteria.

Disclosure of a mammalian cytoplasmic donor cell line. Disclosure of a patient specific cell line. Methods to obtain a mammalian cytoplasmic donor cell line by fusing a differentiated mammalian cell and a functionally enucleated mammalian embryonic cell line. Methods to obtain a mammalian cytoplasmic donor cell line by fusing a differentiated mammalian cell and a functionally enucleated human cancer cell. Methods to obtain a patient specific cell line of a cell type similar to a mammalian cytoplasmic donor cell line by functionally enucleating the mammalian cytoplasmic donor cell line and fusing the functionally enucleated mammalian cytoplasmic donor cell line with a differentiated cell obtained from the patient. A method of treatment of a human patient by administering the patient-specific cell line to the patient.

The present invention is directed generally to eukaryotic cells comprising single-celled organisms that are introduced into the eukaryotic cell through human intervention and which transfer to daughter cells of the eukaryotic cell through at least five cell divisions, and methods of introducing such single-celled organisms into eukaryotic cells. The invention also provides methods of using such eukaryotic cells. The invention further provides single-celled organisms that introduce a phenotype to eukaryotic cells that is maintained in daughter cells. The invention additionally provides eukaryotic cells containing magnetotactic bacteria.