Differentiation of human embryonic stem cells along a hepatocyte lineage and its application in liver regeneration

Hepatocyte transplantation and bioarUficial liver （BAL） as alternatives to liver transplantation offer the possibility of effective treatment for many inherited and acquired hepatic disorders. Unfortunately, the limited availability of donated livers and the variability of their derived hepatocytes make it difficult to obtain enough viable human hepatocytes for the hepatocyte-based therapies. Embryonic stem cells （ESCs）, which could be isolated directly from the blastocyst inner cell mass, have permanent self-renewal capability and developmental pluripotency and therefore might be an ideal cell source in the treatment of hepatic discords. However, differentiation of hESCs into hepatocytes with significant numbers remains a challenge. This review updates our current understanding of differentiation of ESCs into hepatic lineage cells, their future therapeutic uses and problems in liver regeneration.     

Advances in studies on hepatic stem cells

The question whether hepatic stem cells exist or not has been debated for several decades. Current researches confirm that there are hepatic stem cells in the liver. Oval cells, putative bipotential hepatic stem cells, are probably located within canals of Hering, portal tracts or branches of biliary trees. Bone marrow is a potential source of oval cells, indicating that there exists a close relationship between liver and hematopoiesis in adulthood. Hepatic stem cells are able to proliferate in vitro and can be induced to differentiate into hepatocytes. This will provide a promising approach of cell transplantation, tissue engineering and gene therapy for liver diseases. In this review, the evidence of their presence, origin, identification, proliferation in vitro, differentiation by induction, application prospects of hepatic stem cells and future directions for the field are discussed.     

Electroporation Transfection as an Effective Tool to Trace Transplanted NSCs in Adult Central Nervous System

Neural stem cells, which are clonogenic cells with self-renewal and multilineage differentiation properties, are currently considered as powerful candidates for cell replacement therapy in neurodegenerative disorders such as Parkinson‘s disease. A key issue is whether stem cells can survive, migrate and differentiate following transplantation into the adult central nervous system. This research shows that enhanced green fluorescent protein (EGFP) plasmid electreporation transfected neural stem cells can functionally differentiate in vitro and that most of the EGFP-positive cells can survive and migrate towards the damaged areas when transplanted into the brain of a Parkinson‘s disease model rat. The results suggest an effective and maneuverable tracing tool to detect whether transplanted neural stem and progenitor cells function in the adult brain in vivo.     

Notch signaling stimulates osteogenic differentiation of human bone marrow-derived mesenchymal stem cells

Notch signaling is one of the most important pathways mediating cell determination and differentiation.In this study, the roles of Notch signal in the regulation of osteogenic differentiation of human bone marrow mesenchymal stem cells (hMSCs) were investigated. The expression of Notch1, Jaggedl and DTXI detected by reverse transcrip-tion polymerase chain reaction (RT-PCR) suggested that Notch signal might exhibit a physiological regulatory role in the differentiation of MSCs. Constitutive expression of the intracellular domain of Notchl (ICN), the active form of Notchl protein, can activate Notch signal in cells without ligands‘ binding, hMSCs were isolated, expanded, and infected with retrovirus carrying green fluorescent protein (GFP) gene or ICN. Overexpression of ICN in hMSCs resulted in enhanced osteogenic differentiation induced by dexamethasone (Dex), which was characterized by an increase of cellular alkaline phosphatase (ALP) activity and calcium deposition. These results indicate that Notch stimulates differentiation of MSCs into osteoblasts.     

Ex vivo expansions and transplantations of mouse bone marrow－derived hematopoietic stem／progenitor cells

To examine the effects of co-culture with bone marrow mesenchymal stem cells on expansion of hematopoietic tem/progenitor cells and the capacities of rapid neutrophil engraftment and hematopoietic reconstitution of the expanded ells, we expanded mononuclear cells (MNCs) and CD34^ /c-kit^ cells from mouse bone marrow and transplanted the expanded cells into the irradiated mice. MNCs were isolated from mouse bone marrow and CD34^ /c-kit^ cells were selected from MNCs by using MoFlo Cell Sorter. MNCs and CD34^ /c-kit^ cells were co-cultured with mouse bone marrow-derived mesenchymal stem cells (MSCs) under a two-step expansion. The expanded cells were then transplanted into sublethally irradiated BDF 1 mice. Results showed that the co-culture with MSCs resulted in expansions of median total nucleated cells, CD34^ cells, GM-CFC and HPP-CFC respectively by 10.8-, 4.8-, 65.9- and 38.8-fold for the mononuclear cell culture, and respectively by 76.1-, 2.9-, 71.7- and 51.8-fold for the CD34^ /c-kit^ cell culture. The expanded cells could rapidly engraft in the sublethally irradiated mice and reconstitute their hematopoiesis. Co-cultures with MSCs in conjunction with two-step expansion increased expansions of total nucleated cells, GM-CFC and HPP-CFC, which led us to conclude MSCs may create favorable environment for expansions of hematopoietic stem/progenitor cells. The availability of increased numbers of expanded ceils by the co-culture with MSCs may result in more rapid engraftment ofneutrophils following infusion to transplant recipients.     

Corrosion of magnesium and magnesium –calcium alloy in biologically-simulated environment

A study of biocompatibility and corrosion of both metallic magnesium(Mg) and a magnesium alloy containing 1% calcium(Mg–Ca) were investigated in in vitro culture conditions with and without the presence of bone marrow derived human mesenchymal stem cells(h MSCs).Chemical analysis of the degraded samples was performed using XRD and FEGSEM. The results from the XRD analysis strongly suggested that crystalline phase of magnesium carbonate was present on the surface of both the Mg and Mg–Ca samples. Flame absorption spectrometry was used to analyse the release of magnesium and calcium ions into the cell culture medium. Magnesium concentration was kept consistently at a level ranging from 40 to 80 m M for both Mg and Mg–Ca samples. No cell growth was observed when in direct contact with the metals apart from a few cells observed at the bottom of culture plate containing Mg–Ca alloy. In general, in vitro study of corrosion of Mg–Ca in a biologicallysimulated environment using cell culture medium with the presence of h MSCs demonstrated close resemblances to in vivo corrosion. Although in vitro corrosion of Mg–Ca revealed slow corrosion rate and no immediate cytotoxicity effects to h MSCs, its corrosion rate was still too high to achieve normal stem cell growth when cells and alloys were cultured in vitro in direct contact.     

Inducing dopaminergic differentiation of expanded rat mesencephalic neural stem cells by ascorbic acid in vitro

Ascorbic acid (AA) induced differentiation of neural stem cells (NSCs) into dopaminergic (DAergic) neurons is reported.NSCs derived from rat mesencephalon were maintained and expanded in a defined medium containing mitogens of basic fibroblast growth factor (bFGF) and epidermal growth factor (EGF).Compared with the control, ascorbic acid treatment led to more DAergic neuronal differentiation as indicated by the expression of tyrosine hydroxylase (TH) and dopamine transporter (DAT), which are specific markers of dopamine neurons.AA induction also enhanced expression of Nurr1 and Shh.PD98059, an inhibitor of mitogen-activated protein kinase/extracellular signal-regulated kinase (MAPK/ERK) pathway, could block AA-induced Nurr1, TH and DAT mRNA expression.The results might suggest a new strategy to provide enough dopaminergic cells for the therapy of Parkinson's disease (PD), and Nurr1 and ERK signaling pathway might participate in the AA-induced DAergic differentiation.     

Induction of embryonic stem cells to hematopoietic cellsin vitro

In order to get hematopoietic cells from embryonic stem (ES) cells and to study development mechanisms of hematopoietic cells, the method of inducing embryonic stem cells to hematopoietic cells was explored by differenciating mouse ES cells and human embryonic cells in three stages. The differentiated cells were identified by flow cytometry, immunohistochemistry and Wright’s staining. The results showed that embryoid bodies (EBs) could form when ES cells were cultured in the medium with 2-mercaptoethanol (2-ME). However, cytokines, such as stem cell factor (SCF), thrombopoietin (TPO), interleukin-3 (IL-3), interleukin-6 (IL-6), erythropoietin (EPO) and granular colony stimulating factor (G-CSF), were not helpful for forming EBs. SCF, TPO and embryonic cell conditional medium were useful for the differentiation of mouse EBs to hematopoietic progenitors. Eighty-six percent of these cells were CD34⁺ after 6-d culture. Hematopoietic progenitors differentiated to B lymphocytes when they were cocultured with primary bone marrow stroma cells in the DMEM medium with SCF and IL-6. 14 d later, most of the cells were CD34^－CD38⁺. Wright’s staining and immunohistochemistry showed that 80% of these cells were plasma-like morphologically and immunoglubolin positive. The study of hematopoietic cells from human embryonic cells showed that human embryonic cell differentiation was very similar to that of mouse ES cells. They could form EBs in the first stage and the CD34 positive cells account for about 48.5% in the second stage.     

Effects of STAT3 antisense RNA on IL-6-induced differentiation and growth arrest of Ml leukemia cells

To investigate the biological roles of STAT3 in the regulation of growth and differentiation of leukemia cells, we modified a murine myeloid leukemia cell line Ml with STAT3 antisense RNA. The effects of STAT3 antisense RNA on the growth arrest and terminal differentiation of Ml cells induced by interleukin 6 (IL-6) were determined. It was found that STAT3 antisense RNA blocked the activation of STAT3, and reduced the growth arrest and terminal differentiation of IL-6-induced Ml leukemia cells. These results indicate that STAT3 activation is a necessary process for IL-6-induced growth arrest of Ml cells and for the differentiation of Ml cells into macrophage.     

Advances in tissue engineering

Tissue engineering is a newly developed specialty involved in the construction of tissues and organs either in vitro or in vivo. Tremendous progress has been achieved over the past decade in tisse construction as well as in other related areas, such as bone marrow stromal cells, embryonic stem cells and tissue progenitor cells. In our laboratory, tissues of full-thickness skin, bone, cartilage and tendon have been successfully engineered, and the engineered tissues have repaired full-thickness skin wound, cranial bone defects, articular cartilage defects and tendon defects in animals. In basic research areas, bone marrow stromal cells have been induced and transformed into osteoblasts and chondrocytes in vitro. Mouse embryo stem cell lines we established have differentiated into neuron precursor, cardiac muscle cells and epithelial cells. Genetic modifications of seed cells for promoting cell proliferation, delaying cell aging and inducing immune tolerance have also been investigated.     

Adult neural stem cells-Functional potential and therapeutic applications

The adult brain has been thought traditionally as a structure with a very limited regenerative capacity. It is now evident that neurogenesis in adult mammalian brain is a prevailing phenomenon. Neural stem cells with the ability to self-renew, differentiate into neurons, astrocytes and oligodendrocytes reside in some regions of the adult brain. Adult neurogenesis can be stimulated by many physiological factors including pregnancy. More strikingly, newborn neurons in hippocampus integrally function with local neurons, thus neural stem cells might play important roles in memory and learning function. It seems that neural stem cells could transdifferentiate into other tissues, such as blood cells and muscles. Although there are some impediments in this field, some attempts have been made to employ adult neural stem cells in the cell replacement therapy for traumatic and ischemic brain injuries.     

The molecular mechanism of embryonic stem cell pluripotency maintenance

In vitro cultured embryonic stem （ES） cells are derived from the inner cell mass （ICM） of pre-implantation embryos, and are capable of giving rise to all cell and tissue types of the three germ layers upon being injected back into blastocysts. These ceils are therefore said to possess pluripotency that can be maintained infinitely in culture under optimal conditions. Such pluripotency maintenance is believed to be due to the symmetrical cleavage of the cells in an undifferentiated state. The pluripotency of ES cells is the basis for their various practical and potential applications. ES cells can be used as donor cells to generate knockout or transgenic animals, as in vitro models of mammalian development, and as cell resources for cell therapy in regenerative medicine. The further success in these applications, particularly in the last two, is dependent on the establishment of a culture system with components in the medium clearly defined and the subsequent procedures for controlled differentiation of the cells into specific lineages. In turn, elucidating the molecular mechanism for pluripotency maintenance of ES cells is the prerequisite. This paper summarizes the recent progresses in this area, focusing mainly on the LIF/STAT3, BMPs/Smads, canonical Wnt, TGFβ/activin/nodal, PI3K and FGF signaling pathways and the genes such as oct4, nanog that are crucial in ES cell pluripotency maintenance. The regulatory systems of pluripotency maintenance in both mouse and human ES cells are also discussed. We believe that the cross-talkings between these signaling pathways, as well as the regulatory system underlying pluripotency maintenance will be the main focus in the area of ES cell researches in the future.     

Neural stem cell transplantation in the repair of spinal cord injury

Neural stem cells are a pronising candidate for neural transplantation aimed at neural cell replacement and repair of the damaged host central nervous system (CNS). Recent studies using neural stem cells have shown that implanted neural stem cells can effectively incorporate into the damaged CNS and differentiate into neurons, astrocytes, and oligodendrocytes. The recent explosion in the field of neural stem cell research has provided insight into the inductive factors influencing neural stem cell differentiation and may yield potential therapies for several neurological disorders, including spinal cord injury. In this review, we summarize recent studies involving neural stem cell biology in both rodents and humans. We also discuss unique advantages and possible mechanisms of using neural stem cell trans plantation in the repair of spinal cord injury.     

Regulation of BMP4 on the proliferation and differentiation in SVZa neural stem cells

The neural stem cells in the anterior subventricular zone (SVZa) mainly generate the progenitors that will differentiate into neurons, and along a highly circumscribed migratory access Rostral migratory stream (RMS), they migrate to the olfactory bulbs (OB). To understand the effects of BMPs on SVZa neural stem cells, in this study BMP4 at various concentrations was used to induce SVZa neural stem cells, and the living cell labeling using BMP4 promotor conjugated with red fluorescence protein showed the expression of BMP4 dynamically. The results demonstrated that low BMP4 doses (1-5 ng/mL) promoted while high doses (10-100 ng/mL) inhibited the proliferation of SVZa neural stem cells, and BMP4 promotedneuron differentiation in the early stage (1-3 d), howeverm, it inhibited the neuron commitment after 4 d. Noggin, the antagonist of BMP4, blocked the physiological effects of BMP4. In OB, BMP4 is mainly to accelerate the progenitors to withdraw from the cell cycle and trigger the differentiation, and in RMS, it promotes the proliferation of committed progenitors and not differentiation, further in SVZa, BMP4 enhances astrocyte commitment.     

Construction of cytopathic PK-15 cell model of classical swine fever virus

No cytopathic effect (CPE) can be observed on classical swine fever virus (CSFV) infected cell culture in vitro. This brings an obstacle to the researches on reciprocity between CSFV and host cells. Based on the construction of full-length genomic infectious cDNA clone of Chinese CSFV standard virulent Shimen strain, partial deletion is introduced into genomic cDNA to obtain a 7.5 kb subgenomic cDNA. A new subgenomic CSFV is derived from transfection with the subgenomic cDNA on PK-15 cells pre-infected by CSFV Shimen virus. Typical CPE induced by this subgenomic virus is observed on PK-15 cells. Coexistence of wildtype and subgenomic virus in cytopathic cell culture is demonstrated by RT-PCR detection in cytopathic cells. For conclusion, the construction of cytopathic cell model exploited a new way for researches on the molecular mechanism of CSFV pathogenesis.     

Derivation of androgenetic embryonic stem cells from m-carboxycinnamic acid bishydroxamide (CBHA) treated androgenetic embryos

The androgenetic embyronic stem (aES) cells are useful models in studying the effects of imprinted genes on pluripotency maintaining and embryo development. The expression patterns of imprinted genes are significantly different between uniparental derived aES cells and zygote-derived embryonic stem (ES) cells, therefore, the imprinting related cell pluripotency needs further exploitation. Several approaches have been applied in generation of androgenetic embryos and derivation of aES cell lines. Here, we describe a method to generate androgenetic embryos by injecting two mature sperms into one enucleated oocyte. Then these androgenetic embryos were treated with a histone deacetylase inhibitor: m-carboxycinnamic acid bishydroxamide (CBHA). Further, aES cell lines were successfully derived from these treated androgenetic embryos at blastocyst stage. The CBHA could improve not only the quality of androgenetic embryos, but also the efficiencies of aES (CaES) cells derivation and chimeric mice generation. The imprinted gene expression pattern in the CBHA treated embryo-derived aES (CaES) cells was also highly similar to that of zygote-derived ES cells.     

<Emphasis Type="Italic">In vitro</Emphasis> induced dopaminergic differentiation of expanded rat mesencephalic neural stem cell

Recent progress in stem cell biology and recognition of the unique biological properties of stem cell have made it possible to treat the neurodegenerative diseases includ- ing Parkinson抯 disease (PD) by the approach of cell-re- placement and nutritional support with NSCs. Tissue re-construction based on the stem cells endowed us some unpredicted application and market opportunities. Studies in a variety of systems have highlighted perfect prospects for the application of stem cells in the t…     

Human embryonic stem cells-derived endothelial cell therapy facilitates kidney regeneration by stimulating renal resident stem cell proliferation in acute kidney injury

Endothelial cell therapy has been implicated to enhance tissue regeneration and vascularization in ischemic kidney. However, no published study has yet examined direct effects of endothelial cell treatment in kidney recovery. This study investigated the therapeutic efficacy of endothelial cells in a mouse model with acute kidney injury (AKI). Thus, human embryonic stem cells-derived endothelial cells (hESC-ECs) labeled with a reporter system encoding a double fusion reporter gene for firefly luciferase (Fluc) and green fluorescent protein (GFP) were characterized by Fluc imaging and immunofluoresence staining. Cultured hESC-ECs (1×106) were injected into ischemic kidney shortly after AKI. Survival of the transplanted hESC-ECs was monitored in vivo from day 1 to 14 after endothelial cell transplantation and potential impact of hESC-EC treatment on renal regeneration was assessed by histological analyses. We report that a substantial level of bioluminescence activity was detected 24 h after hESC-EC injection followed by a gradual decline from 1 to 14 d. Human ESC-ECs markedly accelerated kidney cell proliferation in response to ischaemia-induced damage, indicated by an elevated number of BrdU+ cells. Co-expression of Sca-1, a kidney stem cell proliferation marker, and BrdU further suggested that the observed stimulation in renal cell regeneration was, at least in part, due to increased proliferation of renal resident stem cells especially within the medullary cords and arteriole. Differentiation of hESC-ECs to smooth muscle cells was also observed at an early stage of kidney recovery. In summary, our results suggest that endothelial cell therapy facilitates kidney recovery by promoting vascularization, trans-differentiation and endogenous renal stem cell proliferation in AKI.