Proteomic analysis of reporter genes for molecular imaging of transplanted embryonic stem cells

Study of stem cells may reveal promising treatment for diseases. The fate and function of transplanted stem cells remain poorly defined. Recent studies demonstrate that reporter genes can monitor real-time survival of transplanted stem cells in living subjects. We examined the effects of a novel and versatile triple fusion (TF) reporter gene construction on embryonic stem (ES) cell function by proteomic analysis. Murine ES cells were stably transduced with a self-inactivating lentiviral vector containing fluorescence (firefly luciferase; Fluc), bioluminescence (monomeric red fluorescence protein; mRFP), and positron emission tomography (herpes simplex virus type 1 truncated thymidine kinase; tTK) reporter genes. Fluorescence-activated cell sorting (FACS) analysis isolated stably transduced populations. TF reporter gene effects on cellular function were evaluated by quantitative proteomic profiling of control ES cells versus ES cells stably expressing the TF construct (ES-TF). Overall, no significant changes in protein quantity were observed. TF reporter gene expression had no effect on ES cell viability, proliferation, and differentiation capability. Molecular imaging studies tracked ES-TF cell survival and proliferation in living animals. In summary, this is the first proteomic study, demonstrating the unique potential of reporter gene imaging for tracking ES cell transplantation non-invasively, repetitively, and quantitatively.     

利用ES细胞建立可诱导的白血病模型

胚胎干细胞（embryonic stem cells,ESCs）是从囊胚的内细胞团分离出来的多潜能干细胞,具有多向分化的能力。将外源基因导入ES细胞建立转基因动物,对于研究外源基因的功能和调控具有一定的价值。载有外源性基因的病毒在感染ES细胞后,可通过囊胚注射获得具有胚系遗传的该转基因动物,并且这一外源基因可以稳定遗传和表达。该研究主要是利用携带hPML-RARα基因的慢病毒感染小鼠ES细胞系（R1）,获得携带该基因的ES细胞,感染后的ES细胞核型正常。在此基础上,将感染后的ES细胞经囊胚注射,获得了携带有hPML-RARα基因的3只嵌合小鼠,其中,有1只具有遗传特性。对嵌合体小鼠与C57杂交的后代给予强力霉素（doxycycline）处理,3天以后骨髓细胞hPML-RARα基因开始表达,这证明了在小鼠体内该外源基因表达的可诱导性。以上证实,已经成功利用ES细胞建立了可诱导的白血病转基因小鼠模型。     

Differentiation stage-specific analysis of gene function with inducible short hair-pin RNA in differentiating embryonic stem cells

Cell differentiation is regulated by spatial and temporal coordination of gene expressions. Previously, we have established an embryonic stem (ES) cell differentiation system that can trace early cardiovascular developmental process in vitro. Here we show that tetracycline-induced short hair-pin RNA (shRNA) expression in differentiating ES cells successfully suppressed stage-specific genes for differentiation and modified cell fates. We established ES cell lines carrying shRNA gene driven by tRNA(val) promoter with tetracycline operator sequences (tet-ON system). When expression of vascular endothelial growth factor receptor-2 (VEGFR2) gene, a vascular progenitor and mesoderm marker and an essential gene for endothelial cell (EC) differentiation, was suppressed by shRNA in early ES cell differentiation, appearance of VEGFR2(+) mesoderm cells was substantially reduced. Suppression of VEGFR2 expression at mesoderm stage almost completely inhibited EC differentiation from VEGFR2(+) mesoderm cells. This novel experimental system, thus, can selectively determine stage-specific roles of genes in differentiation in vitro.     

Gene delivery to embryonic stem cells

Since the establishment of embryonic stem (ES) cells and the identification of tissue-specific stem cells, researchers have made great strides in the analysis of the natural biology of such stem cells for the development of therapeutic applications. Specifically, ES cells are capable of differentiating into all of the cell types that constitute the whole body. Thus, ES cell research promises new type of treatments and possible cures for a variety of debilitating diseases and injuries. The potential medical benefits obtained from stem cell technology are compelling and stem cell research sees a bright future. Control of the growth and differentiation of stem cells is a critical tool in the fields of regenerative medicine, tissue engineering, drug discovery, and toxicity testing. Toward such a goal, we present here an overview of gene delivery in ES cells, covering the following topics: significance of gene delivery in ES cells, stable versus transient gene delivery, cytotoxicity, suspension versus adherent cells, expertise, time, cost, viral vectors for gene transduction (lentiviruses, adenoviruses, and adeno-associated viruses, chemical methods for gene delivery, and mechanical or physical gene delivery methods (electroporation, nucleofection, microinjection, and nuclear transfer).     

Mesenchymal stem cells originating from ES cells show high telomerase activity and therapeutic benefits

We establish a novel method for the induction and collection of mesenchymal stem cells using a typical cell surface marker, CD105, through adipogenesis from mouse ES cells. ES cells were cultured in a medium for adipogenesis. Mesenchymal stem cells from mouse ES cells were easily identified by the expression of CD105, and were isolated and differentiated into multiple mesenchymal cell types. Mesenchymal stem cells showed remarkable telomerase activity and sustained their growth for a long time with a high potential for differentiation involving skeletal myogenesis in vitro. When mesenchymal stem cells were transplanted into the injured tibialis anterior muscles, they differentiated into skeletal muscle cells in vivo. In addition, they improved the vascular formation, but never formed teratoma for longer than 6 months. Gene expression profiles revealed that mesenchymal stem cells lost pluripotency, while they acquired high potential to differentiate into mesenchymal cell lines. They thus indicate a promising new source of cell-based therapy without teratoma formation.