搜索结果: 'methocult media formulations for human hematopoietic cells serum containing'

The creation of a humanized chimeric mouse nervous system permits the study of human neural development and disease pathogenesis using human cells in vivo. Humanized glial chimeric mice with the brain and spinal cord being colonized by human glial cells have been successfully generated. However,generation of humanized chimeric mouse brains repopulated by human neurons to possess a high degree of chimerism have not been well studied. Here we created humanized neuronal chimeric mouse brains by neonatally engrafting the distinct and highly neurogenic human induced pluripotent stem cell (hiPSC)-derived rosette-type primitive neural progenitors. These neural progenitors predominantly differentiate to neurons,which disperse widely throughout the mouse brain with infiltration of the cerebral cortex and hippocampus at 6 and 13 months after transplantation. Building upon the hiPSC technology,we propose that this potentially unique humanized neuronal chimeric mouse model will provide profound opportunities to define the structure,function,and plasticity of neural networks containing human neurons derived from a broad variety of neurological disorders. View Publication

Zika virus (ZIKV) infection has been associated with severe complications both in the developing and adult nervous system. To investigate the deleterious effects of ZIKV infection,we used human neural progenitor cells (NPC),derived from induced pluripotent stem cells (iPSC). We found that NPC are highly susceptible to ZIKV and the infection results in cell death. ZIKV infection led to a marked reduction in cell proliferation,ultrastructural alterations and induction of autophagy. Induction of apoptosis of Sox2 + cells was demonstrated by activation of caspases 3/7,8 and 9,and by ultrastructural and flow cytometry analyses. ZIKV-induced death of Sox2 + cells was prevented by incubation with the pan-caspase inhibitor,Z-VAD-FMK. By confocal microscopy analysis we found an increased number of cells with supernumerary centrosomes. Live imaging showed a significant increase in mitosis abnormalities,including multipolar spindle,chromosome laggards,micronuclei and death of progeny after cell division. FISH analysis for chromosomes 12 and 17 showed increased frequency of aneuploidy,such as monosomy,trisomy and polyploidy. Our study reinforces the link between ZIKV and abnormalities in the developing human brain,including microcephaly. View Publication

Endothelial cells (ECs) line the luminal surface of blood vessels and have an active role in the recruitment of leukocytes,including immune cell activation. Regulatory T cells (Tregs) are immune suppressor cells that maintain peripheral tolerance and must interact with the endothelium as they traffic into tissue. We hypothesized that human ECs could modulate Tregs and their suppressor function. Cocultures of CD4+ T cells with human umbilical vein ECs (HUVECs) or dermal microvascular ECs (HDMECs) were conducted and analyzed for activation and proliferation after 72 and 120 h using flow cytometry. In monocyte-depleted cultures,human ECs were found to support CD4+ T cell proliferation in the presence of external mitogens phytohemagglutinin or anti-CD3/28 antibodies (aCD3/28). Activation was shown by CD25 expression in these cells that also transiently expressed the Treg transcription factor FOXP3. HUVECs supported the specific concurrent proliferation of both effector T cells and Tregs when cocultured with aCD3/28. Purified Tregs were also functionally activated by prior coculture with EC to suppress effector T (Teff) cell proliferation. Both direct coculture and indirect coculture of EC and Treg showed activation of the Treg suppressive phenotype. However,whereas HUVEC showed enhancement of suppression by both mechanisms,HDMEC only supported Treg suppressive activity via the contact-independent mechanism. In the contact-independent cultures,the soluble mediators IL-6,GM-CSF,or G-CSF released from ECs following interferon-gamma$ activation were not responsible for the enhanced Treg suppressor function. Following direct coculture,Treg expression of inhibitory receptors PD-1 and OX40 was elevated while activated EC expressed the counter ligands programmed death ligand (PD-L)1 and PD-L2. Therefore,human ECs have a role in supporting T cell proliferation and increasing Treg suppressor function. This ability of EC to enhance Treg function could offer novel targets to boost Treg activity during inflammatory disorders. View Publication

Developing an efficient culture system for controlled human pluripotent stem cell (hPSC) differentiation into selected lineages is a major challenge in realizing stem cell-based clinical applications. Here,we report the use of chitin-alginate 3D microfibrous scaffolds,previously developed for hPSC propagation,to support efficient neuronal differentiation and maturation under chemically defined culture conditions. When treated with neural induction medium containing Noggin/retinoic acid,the encapsulated cells expressed much higher levels of neural progenitor markers SOX1 and PAX6 than those in other treatment conditions. Immunocytochemisty analysis confirmed that the majority of the differentiated cells were nestin-positive cells. Subsequently transferring the scaffolds to neuronal differentiation medium efficiently directed these encapsulated neural progenitors into mature neurons,as detected by RT-PCR and positive immunostaining for neuron markers βIII tubulin and MAP2. Furthermore,flow cytometry confirmed that textgreater90% βIII tubulin-positive neurons was achieved for three independent iPSC and hESC lines,a differentiation efficiency much higher than previously reported. Implantation of these terminally differentiated neurons into SCID mice yielded successful neural grafts comprising MAP2 positive neurons,without tumorigenesis,suggesting a potential safe cell source for regenerative medicine. These results bring us one step closer toward realizing large-scale production of stem cell derivatives for clinical and translational applications. View Publication

Magnesium alloys have attracted great interest for medical applications due to their unique biodegradable capability and desirable mechanical properties. When designed for medical applications,these alloys must have suitable degradation properties,i.e.,their degradation rate should not exceed the rate at which the degradation products can be excreted from the body. Cellular responses and tissue integration around the Mg-based implants are critical for clinical success. Four magnesium–zinc–strontium (ZSr41) alloys were developed in this study. The degradation properties of the ZSr41 alloys and their cytocompatibility were studied using an in vitro human embryonic stem cell (hESC) model due to the greater sensitivity of hESCs to known toxicants which allows to potentially detect toxicological effects of new biomaterials at an early stage. Four distinct ZSr41 alloys with 4 wt% zinc and a series of strontium compositions (0.15,0.5,1,and 1.5 wt% Sr) were produced through metallurgical processing. Their degradation was characterized by measuring total mass loss of samples and pH change in the cell culture media. The concentration of Mg ions released from ZSr41 alloy into the cell culture media was analyzed using inductively coupled plasma atomic emission spectroscopy. Surface microstructure and composition before and after culturing with hESCs were characterized using field emission scanning electron microscopy and energy dispersive X-ray spectroscopy. Pure Mg was used as a control during cell culture studies. Results indicated that the Mg–Zn–Sr alloy with 0.15 wt% Sr provided slower degradation and improved cytocompatibility as compared with pure Mg control. View Publication

Organs-on-chips are microengineered in vitro tissue structures that can be used as platforms for physiological and pathological research. They provide tissue-like microenvironments in which different cell types can be co-cultured in a controlled manner to create synthetic organ mimics. Blood vessels are an integral part of all tissues in the human body. Development of vascular structures is therefore an important research topic for advancing the field of organs-on-chips since generated tissues will require a blood or nutrient supply. Here,we have engineered three-dimensional constructs of vascular tissue inside microchannels by injecting a mixture of human umbilical vein endothelial cells,human embryonic stem cell-derived pericytes (the precursors of vascular smooth muscle cells) and rat tail collagen I into a polydimethylsiloxane microfluidic channel with dimensions 500 μm × 120 μm × 1 cm (w × h × l). Over the course of 12 h,the cells organized themselves into a single long tube resembling a blood vessel that followed the contours of the channel. Detailed examination of tube morphology by confocal microscopy revealed a mature endothelial monolayer with complete PECAM-1 staining at cell–cell contacts and pericytes incorporated inside the tubular structures. We also demonstrated that tube formation was disrupted in the presence of a neutralizing antibody against transforming growth factor-beta (TGF-β). The TGF-β signaling pathway is essential for normal vascular development; deletion of any of its components in mouse development results in defective vasculogenesis and angiogenesis and mutations in humans have been linked to multiple vascular genetic diseases. In the engineered microvessels,inhibition of TGF-β signaling resulted in tubes with smaller diameters and higher tortuosity,highly reminiscent of the abnormal vessels observed in patients with one particular vascular disease known as hereditary hemorrhagic telangiectasia (HHT). In summary,we have developed microengineered three-dimensional vascular structures that can be used as a model to test the effects of drugs and study the interaction between different human vascular cell types. In the future,the model may be integrated into larger tissue constructs to advance the development of organs-on-chips. View Publication

Exposure to ionizing radiation was shown to result in an increased risk of breast cancer. There is strong evidence that steroid hormones influence radiosensitivity and breast cancer risk. Tumors may be initiated by a small subpopulation of cancer stem cells (CSCs). In order to assess whether the modulation of radiation-induced breast cancer risk by steroid hormones could involve CSCs,we measured by flow cytometry the proportion of CSCs in irradiated breast cancer cell lines after progesterone and estrogen treatment. Progesterone stimulated the expansion of the CSC compartment both in progesterone receptor (PR)-positive breast cancer cells and in PR-negative normal cells. In MCF10A normal epithelial PR-negative cells,progesterone-treatment and irradiation triggered cancer and stemness-associated microRNA regulations (such as the downregulation of miR-22 and miR-29c expression),which resulted in increased proportions of radiation-resistant tumor-initiating CSCs. View Publication

Plasmacytoid dendritic cells (pDCs) play a vital role in activation of anti-HIV-1 immunity,and suppression of pDCs might mitigate immune responses against HIV-1. HIV-1 gp120 high-mannose has been attributed immunosuppressive roles in human myeloid DCs,but no receptors for high-mannose have so far been reported on human pDCs. Here we show that upon activation with HIV-1 or by a synthetic compound triggering the same receptor in human pDCs as single-stranded RNA,human pDCs upregulate the mannose receptor (MR,CD206). To examine the functional outcome of this upregulation,inactivated intact or viable HIV-1 particles with various degrees of mannosylation were cultured with pDCs. Activation of pDCs was determined by assaying secretion of IFN-alpha,viability,and upregulation of several pDC-activation markers: CD40,CD86,HLA-DR,CCR7,and PD-L1. The level of activation negatively correlated with degree of mannosylation,however,subsequent reduction in the original mannosylation level had no effect on the pDC phenotype. Furthermore,two of the infectious HIV-1 strains induced profound necrosis in pDCs,also in a mannose-independent manner. We therefore conclude that natural mannosylation of HIV-1 is not involved in HIV-1-mediated immune suppression of pDCs. View Publication

Data suggest that clinical applications of human induced pluripotent stem cells (hiPSCs) will be realized. Nonetheless,clinical applications will require hiPSCs that are free of exogenous DNA and that can be manufactured through Good Manufacturing Practice (GMP). Optimally,derivation of hiPSCs should be rapid and efficient in order to minimize manipulations,reduce potential for accumulation of mutations and minimize financial costs. Previous studies reported the use of modified synthetic mRNAs to reprogram fibroblasts to a pluripotent state. Here,we provide an optimized,fully chemically defined and feeder-free protocol for the derivation of hiPSCs using synthetic mRNAs. The protocol results in derivation of fully reprogrammed hiPSC lines from adult dermal fibroblasts in less than two weeks. The hiPSC lines were successfully tested for their identity,purity,stability and safety at a GMP facility and cryopreserved. To our knowledge,as a proof of principle,these are the first integration-free iPSCs lines that were reproducibly generated through synthetic mRNA reprogramming that could be putatively used for clinical purposes. View Publication

The process of X chromosome inactivation (XCI) during reprogramming to produce human induced pluripotent stem cells (iPSCs),as well as during the extensive programming that occurs in human preimplantation development,is not well-understood. Indeed,studies of XCI during reprogramming to iPSCs report cells with two active X chromosomes and/or cells with one inactive X chromosome. Here,we examine expression of the long noncoding RNA,XIST,in single cells of human embryos through the oocyte-to-embryo transition and in new mRNA reprogrammed iPSCs. We show that XIST is first expressed beginning at the 4-cell stage,coincident with the onset of embryonic genome activation in an asynchronous manner. Additionally,we report that mRNA reprogramming produces iPSCs that initially express XIST transcript; however,expression is rapidly lost with culture. Loss of XIST and H3K27me3 enrichment at the inactive X chromosome at late passage results in X chromosome expression changes. Our data may contribute to applications in disease modeling and potential translational applications of female stem cells. View Publication

Mesenchymal stem cells (MSC) are multipotent cells with great potential in therapy,reflected by more than 500 MSC-based clinical trials registered with the NIH. MSC are derived from multiple tissues but require invasive harvesting and imply donor-to-donor variability. Embryonic stem cell-derived MSC (ESC-MSC) may provide an alternative,but how similar they are to ex vivo MSC is unknown. Here we performed an in depth characterization of human ESC-MSC,comparing them to human bone marrow-derived MSC (BM-MSC) as well as human embryonic stem cells (hESC) by transcriptomics (RNA-seq) and quantitative proteomics (nanoLC-MS/MS using SILAC). Data integration highlighted and validated a central role of vesicle-mediated transport and exosomes in MSC biology and also demonstrated,through enrichment analysis,their versatility and broad application potential. Particular emphasis was placed on comparing profiles between ESC-MSC and BM-MSC and assessing their equivalency. Data presented here shows that differences between ESC-MSC and BM-MSC are similar in magnitude to those reported for MSC of different origin and the former may thus represent an alternative source for therapeutic applications. Finally,we report an unprecedented coverage of MSC CD markers,as well as membrane associated proteins which may benefit immunofluorescence-based applications and contribute to a refined molecular description of MSC. View Publication

Coronary arteriogenesis is a central step in cardiogenesis,requiring coordinated generation and integration of endothelial cell and vascular smooth muscle cells. At present,it is unclear whether the cell fate programme of cardiac progenitors to generate complex muscular or vascular structures is entirely cell autonomous. Here we demonstrate the intrinsic ability of vascular progenitors to develop and self-organize into cardiac tissues by clonally isolating and expanding second heart field cardiovascular progenitors using WNT3A and endothelin-1 (EDN1) human recombinant proteins. Progenitor clones undergo long-term expansion and differentiate primarily into endothelial and smooth muscle cell lineages in vitro,and contribute extensively to coronary-like vessels in vivo,forming a functional human-mouse chimeric circulatory system. Our study identifies EDN1 as a key factor towards the generation and clonal derivation of ISL1(+) vascular intermediates,and demonstrates the intrinsic cell-autonomous nature of these progenitors to differentiate and self-organize into functional vasculatures in vivo. View Publication