The present invention relates to the production of avian induced pluripotent stem cells from non-pluripotent somatic cells, including embryonic fibroblasts and adult somatic cells. In this method, avian (including quail or chicken) somatic cells are reprogrammed into a state closely resembling embryonic stem cells including the expression of key stem cell markers alkaline phosphatase, etc. by transfecting/transducing the non-stem cells with genes (preferably using a non-integrating vector as otherwise described herein or alternatively an integrating vector, such a lentiviral vector, retroviral vector or inducible lentiviral vector, among others) which express at least nanog, Lin28 and cMyc. In preferred aspects of the invention, the transfected/transduced vectors express nanog, Lig28, cMyc, Oct 4 (POU5F1 or PouV), SOX2 and KLF4. The induced stem cells which are produced contribute to all 3 germ layers, the trophectoderm and in certain aspects, the gonad in chimeric offspring.

The present invention relates to a composition for inducing direct conversion from a somatic cell into one or more kinds selected from the group consisting of an induced Hepatic stem cell (iHSC), a hepatocyte, and a cholangiocyte, and a method of direct conversion of a somatic cell into one or more kinds selected from the group consisting of an induced Hepatic stem cell, a hepatocyte, and a cholangiocyte.

Methods of expanding peripheral blood lymphocytes (PBLs) from blood of patients with hematological malignancies, including lymphomas and leukemias, genetic modifications of expanded PBLs to incorporate chimeric antigen receptors, genetically modified T cell receptors, and other genetic modifications, and uses of such expanded and/or modified PBLs in the treatment of diseases such as cancers and hematological malignancies are disclosed herein.

The present invention relates to a culture media system that is useful for the isolation and epigenetically stable propagation of normal stem cells in culture which are derived from columnar epithelial tissues and cancer stem cells from epithelial cancers. In certain embodiments, the culture system is a feeder-free system.

Disclosed are findings that: (a) induced pluripotent stem cells derived from aged donors (A-iPSC) show increased genomic instability, a defect in apoptosis, a defect in glucose metabolism, and a blunted DNA damage response are compared to those derived from young donors (Y-iPSC); and (b) inhibition of excessive glutathione-mediated H.sub.2O.sub.2 scavenging activity, found to be associated with A-iPSC and in turn inhibiting DNA damage response and apoptosis, substantially rescues these defects and reduces the oncogenic potential of A-iPSC. Supplementation of pluripotency factor ZSCAN10 (shown to be poorly activated in A-iPSC and to act upstream of glutathione involvement), e.g., by expression as an adjunct to the four Yamanaka iPSC reprogramming factors, led to substantial recovery of genomic stability, DNA damage response, and apoptosis in A-iPSC through enhancing GLUT3 and normalizing homeostasis of glutathione/H.sub.2O.sub.2; GLUT3 (a pluripotent stem cell-specific glucose transporter acting upstream of glutathione and also poorly activated in A-iPSC) has similar effects, indicating that inhibition of glutathione/H.sub.2O.sub.2 notably through delivery of ZSCAN 10 and/or GLUT3 and/or an exosome subunit will be clinically useful, resulting in A-iPSC of improved properties and reduced oncogenic potential.

A method for coordinating the manufacturing of an expanded cell therapy product for a patient may include receiving a cell order request to expand the cell therapy product for the patient; generating a patient-specific identifier or cell order identifier associated with the cell order request; and initiating a process to expand the cell therapy product from at least some of a solid tumor obtained from the patient. If acceptance parameters for the expansion cell therapy product do not meet certain acceptance criteria at a second time point subsequent to a first time point in the expansion process, it is determined whether re-performing the expansion of the cell therapy product using the cell expansion technique is possible from the first time point based on the acceptance parameters at the second time point. If such re-performing the expansion is possible, patient treatment events that use the expanded cell therapy product are rescheduled.

Described herein are methods of transdifferentiating preadipocytes, populations of transdifferentiated preadipocytes, and methods of using the transdifferentiated preadipocytes.

Universal human induced pluripotent stem cells (universal hiPSCs) and a method of forming the same are provided in the disclosure, including the following steps: providing a first cell group including human stem cells; providing a second cell group including human mononuclear cells; in some embodiments, the second cell group further includes human stem cells, in which the human stem cells of the second cell group are allogenic cells from the first cell group; mixing the first cell group and the second cell group to form cell mixture; maintaining the cell mixture at a temperature below 30° C. for at least one day; reprogramming the human stem cells of the cell mixture to obtain universal hiPSCs. The universal hiPSCs includes human leukocyte antigen-1 (HLA class I) gene and human leukocyte antigen-2 (HLA class II) gene, but no HLA class I and HLA class II expressions.

The present disclosure provides a method of generating mature mesenchymal stem cells and the cell culture medium used in such method. Also disclosed herein include a mesenchymal stem cell culture obtained by the method as disclosed herein, and uses thereof.

Methods of enhancing fertility of a female subject by increasing the number of oogonia present in the ovary of the female subject are provided. Aspects of the methods include methods of in vivo expansion of oogonia as well as methods of ex vivo expansion of oogonia.