[Induction of hepatic specification of human adipose-derived stem cells (hADSCs) in vitro].

OBJECTIVE: To induce hepatic differentiation of human adipose-derived stem cells (hADSCs) in vitro. METHODS: hADSCs were isolated from human adipose tissue and treated with improved hepatic medium containing HGF, bFGF and FGF4. After 7 days of culture, OSM was added to the culture media. Cell growth during hepatic differentiation was evaluated by CCK8 assay. Morphology of differentiation was examined under light microscope. Liver specific genes and proteins were detected by RT-PCR analysis and immunohistochemical staining, respectively. And functional characteristics of hepatocytes were also examined. RESULTS: The number of hADSCs cultured in the improved hepatic media was increased significantly in comparison to hADSCs cultured in control media from 5 days to 21 days (t=6.59, 8.69, 15.94 and 24.64, respectively, P<0.05). The hADSCs-derived hepatocyte-like cells exhibited hepatocyte morphology, expressed hepatocyte markers, possessed hepatocyte-specific activities, such as uptake and excretion of indocyanine green, glycogen storage and albumin production. CONCLUSION: hADSCs can be induced into hepatocyte-like cells in this differentiation system. And this differentiation system promoted the growth of hADSCs.

Self-renewal and pluripotency is maintained in human embryonic stem cells by co-culture with human fetal liver stromal cells expressing hypoxia inducible factor 1alpha.

Human embryonic stem (hES) cells are typically maintained on mouse embryonic fibroblast (MEF) feeders or with MEF-conditioned medium. However, these xenosupport systems greatly limit the therapeutic applications of hES cells because of the risk of cross-transfer of animal pathogens. The stem cell niche is a unique tissue microenvironment that regulates the self-renewal and differentiation of stem cells. Recent evidence suggests that stem cells are localized in the microenvironment of low oxygen. We hypothesized that hypoxia could maintain the undifferentiated phenotype of embryonic stem cells. We have co-cultured a human embryonic cell line with human fetal liver stromal cells (hFLSCs) feeder cells stably expressing hypoxia-inducible factor-1 alpha (HIF-1alpha), which is known as the key transcription factor in hypoxia. The results suggested HIF-1alpha was critical for preventing differentiation of hES cells in culture. Consistent with this observation, hypoxia upregulated the expression of Nanog and Oct-4, the key factors expressed in undifferentiated stem cells. We further demonstrated that HIF-1alpha could upregulate the expression of some soluble factors including bFGF and SDF-1alpha, which are released into the microenvironment to maintain the undifferentiated status of hES cells. This suggests that the targets of HIF-1alpha are secreted soluble factors rather than a cell-cell contact mechanism, and defines an important mechanism for the inhibition of hESCs differentiation by hypoxia. Our findings developed a transgene feeder co-culture system and will provide a more reliable alternative for future therapeutic applications of hES cells.

[Repair of swine full-thickness cutaneous deficiency by autogenic BMSCs compounded with collagen membrane].

OBJECTIVE: To supply references to tissue-engineered skin clinical applications with autogenic BMSCs composited collagen membrane to repair swine full-thickness cutaneous deficiency. METHODS: Twenty mL bone marrow were obtained respectively from 4 swine, autogenic BMSCs were cultured and passed to the 3rd passage. The fresh bovine tendon treated by means of chemically cross-linked was made 5 cm diameter collagen I (Col I) membrane. The 2 x 10(7)/mL P3 swine autogenic BMSCs labeled DAPI were planted to sterile Col I membrane for 24 hours incubation, then the tissue-engineered skin was constructed. The five full-thickness skin defect of 5 cm diameter was excised to the muscle from forward to backward on the back midline two sides of swine. The tissue-engineered skin were implanted in the experimental group, while Col I membrane was implanted in control group. After 3 and 8 weeks of implantation, the two swine wound surface healing circumstance was observed and further evaluated with histology analysis and TEM. After 3 weeks of implantation, the experimental group were observed with fluorescence microscopy and staining for glycogen. RESULTS: After 3 weeks of implantation, the wound surface of control group were observed nigrescene, scab and putrescence, and after 8 weeks of implantation, also evident putrescence and scar. The wound surface of experiment group was alive after 3 weeks implantation, appearance was leveled off and flexible without evident scar. The wound surface recovered well after 8 weeks of implantation, wound surface healing rate was significantly difference between the two groups (P < 0.01). After 3 weeks of implantation, control group were observed acestoma hyperplasia and no epidermal coverage by histology analysis. The experimental group was showed integrity epidermis and dermis structure. The basal layer was crimson and continuously positive with glycogen staining. After 8 weeks of implantation, the experimental group and control group were emerged normal skin structure. After 3 weeks of implantation in control group, a lot of neutrophilic granulocytes and fibroblasts were noticed, but no epidermal structure was observed under TEM. In the experimental group, a lot of epidermal cells were observed, dermatome connection among epidermal cells and hemidesmosome connection between basilar membrane cells and basal membrane were observed in epidermis. In the dermis experimental group, blood capillary endothelial cells were noticed. Furthermore, considerable collagen fiber deposit was found in the surrounding tissue of fibroblasts. After 3 weeks of implantation, BMSCs labeled with DAPI were located reconstructed epidermal basement membrane and dermis by fluorescence microscopy. CONCLUSION: Tissue-engineered skin which is composited with autogenic BMSCs as seed cells and collagen membrane were potential prospects in application of repairing swine full-thickness cutaneous deficiency.

Cells extract from fetal liver promotes the hematopoietic differentiation of human embryonic stem cells.

Here, we have now developed a new inducing system to promote the differentiation of human stem cells (hESCs) toward hematopoietic lineages by the treatment with cells extract of human fetal liver tissue (hFLT). The embryoid bodies (EBs) obtained from human H1 embryonic stem cells were exposed to buffer, hFLT cells extract, heated hFLT cell extract, and cell extract of human liver cells lines-LO2. Then, the feature of EBs in different groups was characterized by real-time RT-PCR and colony-forming assays. The results showed the treatment by hFLT cells extract could activate the hematopoietic genes expression and improve the capacity for hematopoietic progenitor development of hEBs. After that, we cocultured hFLT extract treated hEBs on the hFLSCs (human fetal liver stromal cells) feeder to differentiate them into hematopoietic cells. As a control, untreated hEBs were cocultured on hFLSCs feeder with cytokines. The feature of induced cells from hEBs was characterized by flow cytometry, Wright-Giemsa staining, and colony-forming assays. The results demonstrated that hFLT cells extract was capable of inducing hEBs into hematopoietic cells and combing it with hFLSCs feeder could largely promote hematopoietic differentiation of hESCs. This method may supply a new way to substitute the cytokines required in hematopoietic induction of hESCs.

Lineage restriction and differentiation of human embryonic stem cells into hepatic progenitors and zone 1 hepatocytes.

Human embryonic stem (hES) cells can self-renew, which enables them to have considerable expansion potential, and are pluripotent. If their differentiation can be controlled, they can offer promise for clinical programs in cell therapies. A novel strategy has been developed to derive early hepatocytic lineage stages from hES cells using four sequential inducing steps lasting 16 days. First, embryoid bodies (EBs) were generated by growing hES cells in suspension for 2 days; second, EBs were lineage restricted to definitive endoderm with 3 days of treatment with human activin A; third, cells were differentiated further by coculturing for 5 days with human fetal liver stromal cells (hFLSCs) made transgenic to stably release basic fibroblast growth factor (bFGF); fourth, treating them for 6 days with soluble signals comprised of hFLSC-derived bFGF, hepatocyte growth factor, oncostatin M, and dexamethasone. Induced cells displayed morphological, immunohistochemical, and biochemical characteristics of hepatocytic committed progenitors and of early lineage stage hepatocytes found in zone 1 of the liver acinus. They expressed alpha-fetoprotein, albumin, cytokeratin 18, glycogen, a fetal P450 isoform, and CYP1B1, and demonstrated indocyanine green uptake and excretion. In conclusion, we have developed a novel method to lineage restrict hES cells into early lineage stages of hepatocytic fates.

Legume lectin FRIL preserves neural progenitor cells in suspension culture in vitro.

In vitro maintenance of stem cells is crucial for many clinical applications. Stem cell preservation factor FRIL (Flt3 receptor-interacting lectin) is a plant lectin extracted from Dolichos Lablab and has been found preserve hematopoietic stem cells in vitro for a month in our previous studies. To investigate whether FRIL can preserve neural progenitor cells (NPCs), it was supplemented into serum-free suspension culture media. FRIL made NPC grow slowly, induced cell adhesion, and delayed neurospheres formation. However, FRIL did not initiate NPC differentiation according to immunofluorescence and semiquantitive RT-PCR results. In conclusion, FRIL could also preserve neural progenitor cells in vitro by inhibiting both cell proliferation and differentiation.

Overexpression of spindlin1 induces metaphase arrest and chromosomal instability.

Spin/Ssty gene family is high conserved and very abundant transcript involved in gametogenesis, which was repeatedly detected in early embryo. Nevertheless, the biologic roles of the members are still largely unknown. Previously we have identified human gene spindlin1 as a homologue of the family from ovarian cancer cells, and reported that stable overexpression of spindlin1 could transform NIH3T3 cells and induce tumorigenesis in nude mouse. Here, we showed that spindlin1, as a nuclear protein, was relocated during mitosis. A fraction of spindlin1 proteins was dynamic distributed along mitotic spindle tubulin and enriched at midzone following anaphase entering. We also showed that transient overexpression of spindlin1 induced cell cycle delay in metaphase, caused mitotic spindle defects, and resulted in chromosome instability, micronucleus and multinuclear giant cells formation. Moreover, time-lapse microscopy revealed that these cells arrested at metaphase for more than 3 h with chromosome nondisjunction or missegregation. Furthermore, Mad2 up-regulation in these cells suggested that overexpression of spindlin1 may affect the bipolar spindle correctly attachment to chromosomes and activate spindle checkpoint. Taken together, these data demonstrated that excess spindlin1 protein may be detrimental for spindle microtubule organization, chromosomal stability and can potentially contribute to the development of cancer.

NRSF silencing induces neuronal differentiation of human mesenchymal stem cells.

Mesenchymal stem cells (MSCs) are multipotent cells that have the potential to differentiate into the neuronal cell lineage. Here, we describe the highly efficient and specific induction of cells with neuronal characteristics, without glial differentiation, from human bone marrow-derived mesenchymal stem cells by NRSF silencing. Cells that have the characteristics of MSCs were obtained from human bone marrow. Lentiviral vectors were used to deliver small interference NRSF RNA (siNRSF) into MSCs. After being infected with lentivirus containing siNRSF, MSCs were successfully induced to differentiate into neuronal cells, which exhibited neuron-like morphology and formed nissl bodies. These differentiated cells expressed multiple neuron-specific genes including brain-derived neurotrophic factor (BDNF), neurogenin 1 (NGN1), neuron-specific enolase (NSE), synaptophysin (SYP), and neuron-specific growth-associated protein (SCG10), as well as expressing mature neuronal marker proteins, such as beta-tubulin III, NSE, microtubule-associated protein type 2 (MAP-2), and neurofilament-200 (NF-200), yet did not express the glial markers glial fibrillary acidic protein (GFAP) and oligodendrocyte transcription factor 2 (Olig2), as verified by immunofluorescence staining. The whole cell patch-clamp technique recorded TTX-sensitive Na(+) currents and action potential from these differentiated cells. Thus, our results demonstrate that NRSF silencing can activate some neuronal genes and induce neuronal differentiation of mesenchymal stem cells.

Regulatory role of neuron-restrictive silencing factor in the specific expression of cocaine- and amphetamine-regulated transcript gene.

Cocaine- and amphetamine-regulated transcript (CART) peptide is an endogenous peptide which is widely expressed in the CNS and PNS as well as in endocrine cells. Despite the functional knowledge about CART, the mechanisms that regulate CART gene transcription are poorly characterized. Here, we showed that neuron-restrictive silencer factor (NRSF) functions as a negative regulator of CART gene expression in neuroendocrine cells. A putative neuron-restrictive silencer element (NRSE) conserved between the rodent and human CART promoter was identified and demonstrated to bind to NRSF in sequence-specific manner by the electrophoretic mobility shift and chromatin immunoprecipitation assays. Ectopic expression of NRSF in pheochromocytoma cells (PC12) and insulin-secreting cells (INS-1) induced a marked reduction in the level of CART mRNA and the activity of CART promoter or NRSE reporter. The CART promoter showed very low activity in endogenous NRSF-expressing HeLa cells. When expression of NRSF was down-regulated in HeLa cells using a RNA interfering technique, the transcriptional activity of the CART promoter or a NRSE reporter was significantly increased. Taken together, our data suggested that CART gene expression in neuroendocrine cells is strictly controlled by NRSF, via a mechanism dependent upon the CART NRSE.

[Analysis of properties of collagen membranes before and after crosslinked].

OBJECTIVE: To compare the properties of collagen membranes before and after crosslinked and to establish the foundation of application of collagen membranes. METHODS: Fresh bovine tendons were separated and collagen was extracted by washing, smashing and acetic acid dissolving. The collagen protein was determined by ultraviolet spectrophotometer and its characteristics were analyzed by SDS-polyacrylamide gel electrophoresis (SDS-PAGE), wavelength scanning and amino acids detecting. Collagen membranes were produced by lyophilization. And then the biocharacteristics of the membranes before and after glutaraldehyde crosslinked were compared. BMSCs separated from volunteer's bone marrow were seeded on collagen membranes before and after crosslinked by 2 x 10(3) in 100 microL medium, seven days after culture, the absorption spectrum of BMSCs was examined, and BMSCs were observed by scanning electron microscope (SEM). RESULTS: The contents of collagen protein were 2 mg/mL. The maximum absorption wave length appeared at about 230 nm. SDS-PAGE suggested that molecular weight of main bands was more than 66.2 x 10(3), the same as collagen marker from calf skin. There were 21.47% glycine, 12.04% praline and 10.18% hydroxyproline. No tryptophan was found. Before crosslinked, collagen membranes were in shape of white sponges and with big holes and the range of pH value was from 4.5 to 5.0. SEM showed reticular conformation and pore structure of collagen membranes, but the bore diameter was bigger. Their water-absorbing capacity was 61 times as much as their weight. The mechanical strength was 210 g/cm3. The dissolution time of collagenase was 90 minutes. After crossl inked, collagen membranes became thin, colorless, semi-transparent and compact with better tenacity. Under SEM, compact collagen fiber appeared reticular. There was lower water-absorbing capacity and pH value ranged from 6.5 to 7.0. The mechanical strength was 3,400 g/cm3 and the dissolution time of collagenase became longer. BMSCs could grow better either on before-crosslinked collagen membranes or on after-crosslinked ones. CONCLUSION: As biomaterial scaffolds, after crosslinked collagen membranes were better than before-crosslinked ones.

Overexpression of SPINDLIN1 induces cellular senescence, multinucleation and apoptosis.

Human or mouse Spindlin1 is expressed in various tissues and cells, but its biological functions are poorly understood. In this study, we show that human SPINDLIN1 is localized to interphase nucleus and mitotic chromosomes, and its expression in HeLa cells is not regulated in a cell cycle-dependent manner. When SPINDLIN1 is stably overexpressed in HeLa cells, it results in multinucleation of cells, and these multinucleated cells exhibits characteristic features of senescence and apoptosis shown by growth and morphological alterations, beta-galactosidase activity, and Annexin V/7-Aminoactinomycin D staining. Mouse Spindlin1 is highly homologous with human Spindlin1, when overexpressed in NIH3T3 cells, it also induces multinucleation, senescence and apoptosis in murine cells. Our results demonstrate that SPINDLIN1 is an important gene for mammalian mitotic chromosome functions, and disrupted regulation results in abnormal cell division, a mechanism that may be involved in tumorigenesis.

Full-thickness tissue engineered skin constructed with autogenic bone marrow mesenchymal stem cells.

To explore the feasibility of repairing clinical cutaneous deficiency, autogenic bone marrow mesenchymal stem cells (BMSCs) were isolated and differentiated into epidermal cells and fibroblasts in vitro supplemented with different inducing factors and biomaterials to construct functional tissueengineered skin. The results showed that after 72 h induction, BMSCs displayed morphologic changes such as typical epidermal cell arrangement, from spindle shape to round or oval; tonofibrils, melanosomes and keratohyaline granules were observed under a transmission electronic microscope. The differentiated cells expressed epidermal stem cell surface marker CK19 (59.66% +/- 4.2%) and epidermal cells differentiation marker CK10. In addition, the induced epidermal cells acquired the anti-radiation capacity featured by lowered apoptosis following exposure to UVB. On the other hand, the collagen microfibrils deposition was noticed under a transmission electronic microscope after differentiating into dermis fibroblasts; RT-PCR identified collagen type I mRNA expression in differentiated cells; radioimmunoassay detected the secretion of interleukin-6 (IL-6) and interleukin-8 (IL-8) (up to 115.06 pg/mL and 0.84 ng/mL, respectively). Further in vivo implanting BMSCs with scaffold material shortened skin wound repair significantly. In one word, autogenic BMSCs have the potential to differentiate into epidermal cells and fibroblasts in vitro, and show clinical feasibility acting as epidermis-like and dermis-like seed cells in skin engineering.

Structure of human spindlin1. Tandem tudor-like domains for cell cycle regulation.

Spindlin1, a meiotic spindle-binding protein that is highly expressed in ovarian cancer cells, was first identified as a gene involved in gametogenesis. It appeared to be a target for cell cycle-dependent phosphorylation and was demonstrated to disturb the cell cycle. Here we report the crystal structure of human spindlin1 to 2.2A of resolution, representing the first three-dimensional structure from the spin/ssty (Y-linked spermiogenesis-specific transcript) gene family. The refined structure, containing three repeats of five/four anti-parallel beta-strands, exhibits a novel arrangement of tandem Tudor-like domains. Two phosphate ions, chelated by Thr-95 and other residues, appear to stabilize the long loop between domains I and II, which might mediate the cell cycle regulation activity of spindlin1. Flow cytometry experiments indicate that cells expressing spindlin1 display a different cell cycle distribution in mitosis, whereas those expressing a T95A mutant, which had a great decrease in phosphorous content, have little effect on the cell cycle. We further identified associations of spindlin1 with nucleic acid to provide a biochemical basis for its cell cycle regulation and other functions.

[The maintenance of cord blood CD34+ progenitor cells with plant lectin FRIL in vitro and the expression of related cell cycle modulator HTm4 and HTm4S].

Ex vivo maintainance of human stem cells is crucial for many clinical applications. Current culture conditions provide some level support but cytokines induce most quiescent stem cells to proliferate and differentiate. Better control of primitive cells is needed to extend the time and range of manipulation of such cells. A recently identified plant lectin Flt3 receptor-interacting lectin (FRIL) present may a special ability to preserve primitive CB progenitors for extended periods in culture without exogenous cytokines. But the mechanisms of FRIL preserving quiescent primitive cells are still unknown. Recently a novel protein HTm4 and its alternatively spliced variant HTm4S, which serve as hematopoietic cell cycle regulators, have been identified. In this report we studied the effect of FRIL on the in vitro maintenance of quiescent human cord blood stem cells and the expression of the novel hematopoietic cell cycle regulator HTm4 and HTm4S in progenitor cells cultured in FRIL. We analyzed the proliferation and the HPP-CFC proportion of CD34(+) cells treated with FRIL. The human HTm4 and HTm4S mRNA expression was detected by semi-quantitative RT-PCR, and the cell cycle status of CB CD34(+) cells was analyzed by FACS. The results showed that incubation of CD34(+) cells in FRIL resulted in a low proliferation of progenitor cells and fewer cycling cells, but FRIL selectively maintained a higher number of primitive cells with proliferative potential in suspension culture. CB CD34(+) cells cultured in FRIL showed significant diversity in the expression of HTm4 and HTm4S during 0~14 d. On d 0, HTm4 was detected at high level, downregulated on d 1, but upregulated during d 3 to d 14, and reaching the highest level on d 7. But the expression levels of HTm4S changed little in the cells cultured in FRIL except the obviously increased expression on d 7. Exogenous expression showed that HTm4 was localized around the karyon while HTm4S scatted in the cytoplasm, respectively, which may be responsible for their difference in function. Thus, FRIL can preserve quiescent primitive CD34(+), and FRIL's ability to preserve quiescent primitive cells in a reversible manner may significantly expand the time and range of ex vivo manipulations of human stem cells for clinical applications. In other words, HTm4 and HTm4S may play a crucial role in the cell cycle modulation of CD34(+) progenitor cells maintained with FRIL in vitro.

[Migration and differentiation of exogenous rat mesenchymal stem cells engrafted into normal and injured hearts of rats].

OBJECTIVE: To investigate the effects of different microcircumstances on the migration and differentiation of grafted rat mesenchymal stem cells (rMSC) in host myocardium and the feasibility of treatment of myocardial infarction by exogenous adult stem cells. METHODS: rMSC were isolated from the femurs and tibiae of a male Wistar rat and then purified, made into cell suspension, and labeled with DAPI. 35 female Wistar rat were divided randomly into four groups: acute myocardial infarction control group (AMI group, n = 10, the descending anterior branch of left coronary artery was ligated), acute myocardial infarction + rMSC transplantation group (AMI + rMSC group, n = 10, 1 - 3 hours after the ligation DAPI-labeled rMSC were injected into the peri-infarct tissues), normal heart + rMSC transplantation group (normal heart + MSC group, n = 10, DAPI-labeled rMSC were injected into the corresponding myocardium), and mono-nuclear cells transplantation group (AMI + MNCS, n = 5 DAPI-labeled mononuclear cells were injected into he periinfarct tissues). Ten weeks after the implantation, the rats were killed and their hearts were harvested. Immunohistochemistry was used to examine the troponin, GATA-4 and connexin-43. RESULTS: No lymphocyte proliferation and immonologic rejection were seen in the cardiac tissues of the rats implanted with rMSC. DAPI-labeled rMSC with blue nuclei were distributed extensively in the myocardium of the AMI + rMSC group, ovoid in shape and arranged in parallel with the cardiac muscle fibers, and were distributed sporadically like islands in the myocardium of the normal heart + rMSC group, irregular in shape and not arranged in parallel with the cardiac muscle fibers. No blue nucleus was seen in the cardiac tissues of the hearts implanted with DAPI-labeled mononuclear cells. Troponin and GATA4 were positive immunohistochemically in the implanted rMSC with blue nuclei and the host cardiac muscle cells of the AMI group and AMI + rMSC group, however, were negative in the implanted rMSC with blue nuclei and normal cardiac muscle cells of the normal heart + rMSC group. CONCLUSION: Purified rMSC are immunologically tolerable and can be used as donor cells for exogenous cells therapy. Capable of surviving and homing in both in normal and injured hearts, exogenous rMSC migrate and differentiate into cardiac muscle cell-like cells in myocardium with infarction, however, not in normal heart.

[Identification of differentially expressed genes in Lin-CD34- and Lin-CD34+ cells].

OBJECTIVE: To identify genes that differentially expressed in Lin(-)CD(34)(-) and Lin(-)CD(34)(+) cells. METHODS: With Lin(-)CD(34)(-) cells as tester and Lin(-)CD(34)(+) cells as driver, cDNA subtractive library for Lin(-)CD(34)(-) cells was constructed using suppression subtractive hybridization technique. Part of clones in the library were sequenced and the homologue analysis was conducted against the DNA database in GenBank. RESULTS: 593 clones containing an average of 300 - 500 bp insert were identified. Of them, 53 randomly selected ESTs were sequenced. Homologue analysis revealed that 37 ESTs represented 10 known genes, and the other 16 ESTs represented 4 novel sequences. CONCLUSION: Part of specifically expressed genes in Lin(-)CD(34)(-) cells were identified, which maybe related to Lin(-)CD(34)(-) cells' specific characteristics.

Induction of umbilical cord blood mesenchymal stem cells into neuron-like cells in vitro.

Mesenchymal stem cells (MSCs) in human umbilical cord blood are multipotent stem cells that differ from hematopoietic stem cells. They can differentiate in vitro into mesenchymal cells such as osteoblasts and adipocytes. However, differentiation into nonmesenchymal cells has not been demonstrated. Here, we report the isolation, purification, expansion, and differentiation of human umbilical cord blood MSCs into neurocytes in vitro. Cord blood samples were allowed to drain from the end of the cord into glass bottles with 20 U/mL preservative-free heparin. MSCs were isolated from human umbilical cord blood, purified, and expanded in Mesencult medium. Surface antigens of MSCs were analyzed by fluorescence-activated cell sorting (FACS). MSC passages 2,5, and 8 were induced to differentiate into neuron-like cells. Neurofilament (NF) and neuron-specific enolase (NSE) were detected by immunohistochemistry staining. Special Nissl bodies were observed by histochemical analysis. The results showed that 6.6 x 10(5) primary MSCs were expanded for 10 passages to obtain 9.9 x 10(8) MSCs, an increase of approximately 1.5 x 10(3)-fold. FACS results showed that the MSCs did not express antigens CD34, CD11a, and CD11b and expressed CD29 and CD71, an expression pattern identical to that of human bone marrow-derived MSCs. Induction results indicated that approximately 70% of the cells exhibited a typical neuron-like phenotype. Immunohistochemistry staining suggested that induced MSCs of different passages expressed NF and NSE. Special Nissl bodies were obvious in the neuron-like cells. These results suggest that MSCs in human umbilical cord blood are capable of differentiating into neuron-like cells in vitro.

[Development of the human/rat chimera model with neonatal rats].

The purpose of this study was to transplant neonatal rat with human cord blood Lin(-) cells to test the possibility of this xenograft model. The Lin(-) cells were purified from human cord blood (CB) using negative selection strategy based on different lineage-specific antigens. The Lin(-) cells were injected into the liver of neonatal rats using a microinjector at an average of 5 x 10(5) cells for each. Peripheral blood (PB) and spleen were collected at 2,4 and 8 weeks after injection. Flow cytometry was performed to detect human cells in the rat PB, PCR was used to detect human cells in PB as well as spleen. The results showed that a definite proportion of human cells existed in peripheral blood of chimeric rat and the human specific beta2 microglobulin gene fragments were detected in spleen genomic DNA of chimeric rat. It is concluded that human/rat chimera model can be developed with neonatal rats. Human/rat xenograft model may provide a useful and convenient method for human hematopoietic stem cell assay in vivo.

[Migration and differentiation of human bone marrow mesenchymal stem cells in the rat brain].

Bone marrow mesenchymal stem cells (MSCs) are multipotent tissue stem cells that can be induced in vitro to differentiate into a variety of cells such as osteoblasts, chondrocytes and adipocytes. MSCs are useful vehicles for both cell and gene therapy for a variety of diseases. Here, we injected human MSCs with enhanced green fluorescent protein (EGFP) into the striatum of Parkinson disease (PD) rat and examined their survival, migration, differentiation, and the behavior changes in PD rats, which will provide a theoretical foundation and technical method for clinic PD therapy by stem cells. The results showed that human bone marrow MSCs can survive in rat brain for a long time (exceeding 70 d). MSCs were found in multiple areas of the rat brain including the striatum, the corpus callosum, contralateral cortex and even the brain vascular wall. Immunocytochemical staining suggested that implanted cells expressed human neurofilament (NF), neuron-specific enolase (NSE) and glial fibrillary acid protein (GFAP). At the same time, remission in abnormal behavior of the PD rats appeared. Rotation scores decreased gradually from 8.86+/-2.09 r/min pre-transplantation to 4.87+/-2.06 r/min 90 d post-transplantation (statistic result showed P<0.05).

Radioprotective effect of FLT3 ligand expression regulated by Egr-1 regulated element on radiation injury of SCID mice.

OBJECTIVE: Hematopoietic factors have an important effect on the regulation of hematopoiesis by stimulating the proliferation of hematopoietic progenitor cells. Although the cytokines that stimulate hematopoiesis have also often proved to exert radioprotective effects, no definitive correlation has been found between the expression of these cytokines regulated by radio-inducible genes and their radioprotective effects. In the current experiments, we evaluated the radioprotective effects of the hematopoietic growth factors regulated by a radio-inducible promoter on radiation injury. METHODS: The human Flt3 (FL) cDNA and enhanced green fluorescent protein (EGFP) cDNA were linked together with the internal ribosome entry site (IRES) and then inserted into the eukaryotic expression vector pCI-neo with the Egr-1 promoter (Egr-GF), and the vector was transduced into bone marrow stromal cell lines HFCL (HFCL/EGF). The level of green fluorescence in HFCL/EGF cells was detected after radiation with flow cytometry. The expression of FL in irradiated HFCL/EGF cells was confirmed with Northern blot and ELISA. The HFCL/EGF and CD34(+) cells from human umbilical cord blood were sequentially transplanted intravenously into sublethally irradiated severe combined immunodeficient (SCID) mice. The numbers of peripheral white blood cells transplanted into recipient mice were detected. RESULTS: The activity of EGFP in transfected cells was significantly increased after exposure to gamma radiation at 2.0, 2.5, and 5.0 Gy as compared with nontransfected cells. The expression of FL in HFCL/EGF was significantly higher than that of the control groups (HFCL, HFCL/pCI-neo, and HFCL/FG). The level of secreted FL in serum-free supernatants of HFCL/EGF on human CD34(+) cells was higher than that of control groups. In contrast with three control groups (HFCL, HFCL/pCI-neo, and HFCL/GF), HFCL/EGF resulted in a proportional increase in the number of white blood cells at an early stage after radiation. CONCLUSIONS: We show that radiation enhances the ability of expression of FL in HFCL/EGF to stimulate the proliferation of hematopoietic progenitor cells. These results suggest in vivo use of gene therapy of FL regulated by the Egr-1 promoter protects hematopoiesis from irradiation-induced damage.