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

Nuclear RNA foci are molecular hallmarks of myotonic dystrophy type 1 (DM1). However,no designated study has investigated their formation and changes in proliferating cells. Proliferating cells,as stem cells,consist of an important cellular pool in the human body. The revelation of foci changes in these cells might shed light on the effects of the mutation on these specific cells and tissues. In this study,we used human DM1 iPS-cell-derived neural stem cells (NSCs) as cellular models to investigate the formation and dynamic changes of RNA foci in proliferating cells. Human DM1 NSCs derived from human DM1 iPS cells were cultured under proliferation conditions and nonproliferation conditions following mitomycin C treatment. The dynamic changes of foci during the cell cycle were investigated by fluorescence in situ hybridization. We found RNA foci formed and dissociated during the cell cycle. Nuclear RNA foci were most prominent in number and size just prior to entering mitosis (early prophase). During mitosis,most foci disappeared. After entering interphase,RNA foci accumulated again in the nuclei. After stopping cell dividing by treatment of mitomycin C,the number of nuclear RNA foci increased significantly. In summary,DM1 NSC nuclear RNA foci undergo dynamic changes during cell cycle,and mitosis is a mechanism to decrease foci load in the nuclei,which may explain why dividing cells are less affected by the mutation. The dynamic changes need to be considered when using foci as a marker to monitor the effects of therapeutic drugs. View Publication

Protein glycosylation provides proteomic diversity in regulating protein localization,stability,and activity; it remains largely unknown whether the sugar moiety contributes to immunosuppression. In the study of immune receptor glycosylation,we showed that EGF induces programmed death ligand 1 (PD-L1) and receptor programmed cell death protein 1 (PD-1) interaction,requiring beta$-1,3-N-acetylglucosaminyl transferase (B3GNT3) expression in triple-negative breast cancer. Downregulation of B3GNT3 enhances cytotoxic T cell-mediated anti-tumor immunity. A monoclonal antibody targeting glycosylated PD-L1 (gPD-L1) blocks PD-L1/PD-1 interaction and promotes PD-L1 internalization and degradation. In addition to immune reactivation,drug-conjugated gPD-L1 antibody induces a potent cell-killing effect as well as a bystander-killing effect on adjacent cancer cells lacking PD-L1 expression without any detectable toxicity. Our work suggests targeting protein glycosylation as a potential strategy to enhance immune checkpoint therapy. View Publication

BACKGROUND Neonatal hypoxia-ischemia induces massive brain damage during the perinatal period,resulting in long-term consequences to central nervous system structural and functional maturation. Although neural progenitor cells (NPCs) migrate through the parenchyma and home in to injury sites in the rodent brain,the molecular mechanisms are unknown. We examined the role of chemokines in mediating NPC migration after neonatal hypoxic-ischemic brain injury. METHODS Nine-day-old mice were exposed to a 120-minute hypoxia following unilateral carotid occlusion. Chemokine levels were quantified in mouse brain extract. Migration and proliferation assays were performed using embryonic and infant mouse NPCs. RESULTS The neonatal hypoxic-ischemic brain injury resulted in an ipsilateral lesion,which was extended to the cortical and striatal areas. NPCs migrated toward an injured area,where a marked increase of CC chemokines was detected. In vitro studies showed that incubation of NPCs with recombinant mouse CCL11 promoted migration and proliferation. These effects were partly inhibited by a CCR3 antagonist,SB297006. CONCLUSIONS Our data implicate an important effect of CCL11 for mouse NPCs. The effective activation of NPCs may offer a promising strategy for neuroregeneration in neonatal hypoxic-ischemic brain injury. View Publication

Human pluripotent stem (hPS) cells such as human embryonic stem (hES) and induced pluripotent stem (hiPS) cells are vulnerable under single cell conditions,which hampers practical applications; yet,the mechanisms underlying this cell death remain elusive. In this paper,we demonstrate that treatment with a specific inhibitor of non-muscle myosin II (NMII),blebbistatin,enhances the survival of hPS cells under clonal density and suspension conditions,and,in combination with a synthetic matrix,supports a fully defined environment for self-renewal. Consistent with this,genetically engineered mouse embryonic stem cells lacking an isoform of NMII heavy chain (NMHCII),or hES cells expressing a short hairpin RNA to knock down NMHCII,show greater viability than controls. Moreover,NMII inhibition increases the expression of self-renewal regulators Oct3/4 and Nanog,suggesting a mechanistic connection between NMII and self-renewal. These results underscore the importance of the molecular motor,NMII,as a novel target for chemically engineering the survival and self-renewal of hPS cells. View Publication

Recent technological advances in cell reprogramming by generation of induced pluripotent stem cells (iPSC) offer major perspectives in disease modelling and future hopes for providing novel stem cells sources in regenerative medicine. However,research on iPSC still requires refining the criteria of the pluripotency stage of these cells and exploration of their equivalent functionality to human embryonic stem cells (ESC). We report here on the use of infrared microspectroscopy to follow the spectral modification of somatic cells during the reprogramming process. We show that induced pluripotent stem cells (iPSC) adopt a chemical composition leading to a spectral signature indistinguishable from that of embryonic stem cells (ESC) and entirely different from that of the original somatic cells. Similarly,this technique allows a distinction to be made between partially and fully reprogrammed cells. We conclude that infrared microspectroscopy signature is a novel methodology to evaluate induced pluripotency and can be added to the tests currently used for this purpose. View Publication

Cord blood (CB) cells that express CD34 have extensive hematopoietic capacity and rapidly divide ex vivo in the presence of cytokine combinations; however,many of these CB CD34+ cells lose their marrow-repopulating potential. To overcome this decline in function,we treated dividing CB CD34+ cells ex vivo with several histone deacetylase inhibitors (HDACIs). Treatment of CB CD34+ cells with the most active HDACI,valproic acid (VPA),following an initial 16-hour cytokine priming,increased the number of multipotent cells (CD34+CD90+) generated; however,the degree of expansion was substantially greater in the presence of both VPA and cytokines for a full 7 days. Treated CD34+ cells were characterized based on the upregulation of pluripotency genes,increased aldehyde dehydrogenase activity,and enhanced expression of CD90,c-Kit (CD117),integrin α6 (CD49f),and CXCR4 (CD184). Furthermore,siRNA-mediated inhibition of pluripotency gene expression reduced the generation of CD34+CD90+ cells by 89%. Compared with CB CD34+ cells,VPA-treated CD34+ cells produced a greater number of SCID-repopulating cells and established multilineage hematopoiesis in primary and secondary immune-deficient recipient mice. These data indicate that dividing CB CD34+ cells can be epigenetically reprogrammed by treatment with VPA so as to generate greater numbers of functional CB stem cells for use as transplantation grafts. View Publication

Immune checkpoint blockade has revolutionized the field of oncology,inducing durable anti-tumour immunity in solid tumours. In patients with advanced prostate cancer,immunotherapy treatments have largely failed1-5. Androgen deprivation therapy is classically administered in these patients to inhibit tumour cell growth,and we postulated that this therapy also affects tumour-associated T cells. Here we demonstrate that androgen receptor (AR) blockade sensitizes tumour-bearing hosts to effective checkpoint blockade by directly enhancing CD8 T cell function. Inhibition of AR activity in CD8 T cells prevented T cell exhaustion and improved responsiveness to PD-1 targeted therapy via increased IFN$\gamma$ expression. AR bound directly to Ifng and eviction of AR with a small molecule significantly increased cytokine production in CD8 T cells. Together,our findings establish that T cell intrinsic AR activity represses IFN$\gamma$ expression and represents a novel mechanism of immunotherapy resistance. View Publication

Well-differentiated primary human bronchial epithelial (HBE) cell cultures are vital for cystic fibrosis (CF) research,particularly for the development of cystic fibrosis transmembrane conductance regulator (CFTR) modulator drugs. Culturing of epithelial cells with irradiated 3T3 fibroblast feeder cells plus the RhoA kinase inhibitor Y-27632 (Y),termed conditionally reprogrammed cell (CRC) technology,enhances cell growth and lifespan while preserving cell-of-origin functionality. We initially determined the electrophysiological and morphological characteristics of conventional versus CRC-expanded non-CF HBE cells. On the basis of these findings,we then created six CF cell CRC populations,three from sequentially obtained CF lungs and three from F508 del homozygous donors previously obtained and cryopreserved using conventional culture methods. Growth curves were plotted,and cells were subcultured,without irradiated feeders plus Y,into air-liquid interface conditions in nonproprietary and proprietary Ultroser G-containing media and were allowed to differentiate. Ussing chamber studies were performed after treatment of F508 del homozygous CF cells with the CFTR modulator VX-809. Bronchial epithelial cells grew exponentially in feeders plus Y,dramatically surpassing the numbers of conventionally grown cells. Passage 5 and 10 CRC HBE cells formed confluent mucociliary air-liquid interface cultures. There were differences in cell morphology and current magnitude as a function of extended passage,but the effect of VX-809 in increasing CFTR function was significant in CRC-expanded F508 del HBE cells. Thus,CRC technology expands the supply of functional primary CF HBE cells for testing CFTR modulators in Ussing chambers. View Publication

The selection of cells that have acquired a desired gene edit is often done by the introduction of additional genes that confer drug resistance or encode fluorophores. However,such marker genes can have unintended physiological effects and are not compatible with editing of single nucleotides. Here,we present SNIPE,a method that allows the marker-free selection of edited cells based on single nucleotide differences to unedited cells. SNIPE drastically enriches for cells,which have been precisely edited (median 7-fold). We validate the approach for 42 different edits using Cas9 or Cas12a in different cell types and species. We use it to enrich for combinations of substitutions that change missense mutations carried by all people today back to the ancestral state seen in Neandertals and Denisovans. We also show that it can be used to kill cultured tumor cells with aberrant genotypes and to repair heterozygous tumorigenic mutations. Genome editing often requires marker genes for selection of edited cells. Here,the authors present SNIPE,a marker-free method that selects cells based on DNA sequence,enabling precise enrichment of edited cells and applications from evolutionary research to the elimination of cancer cells. View Publication

Prion diseases are irreversible progressive neurodegenerative diseases,leading to severe incapacity and death. They are characterized in the brain by prion amyloid deposits,vacuolisation,astrocytosis,neuronal degeneration,and by cognitive,behavioural and physical impairments. There is no treatment for these disorders and stem cell therapy therefore represents an interesting new approach. Gains could not only result from the cell transplantation,but also from the stimulation of endogenous neural stem cells (NSC) or by the combination of both approaches. However,the development of such strategies requires a detailed knowledge of the pathology,particularly concerning the status of the adult neurogenesis and endogenous NSC during the development of the disease. During the past decade,several studies have consistently shown that NSC reside in the adult mammalian central nervous system (CNS) and that adult neurogenesis occurs throughout the adulthood in the subventricular zone of the lateral ventricle or the Dentate Gyrus of the hippocampus. Adult NSC are believed to constitute a reservoir for neuronal replacement during normal cell turnover or after brain injury. However,the activation of this system does not fully compensate the neuronal loss that occurs during neurodegenerative diseases and could even contribute to the disease progression. We investigated here the status of these cells during the development of prion disorders. We were able to show that NSC accumulate and replicate prions. Importantly,this resulted in the alteration of their neuronal fate which then represents a new pathologic event that might underlie the rapid progression of the disease. View Publication

Somatic cells can be reprogrammed to induced pluripotent stem cells (iPSCs) by expressing four transcription factors: Oct4,Sox2,Klf4,and c-Myc. Here we report that enhancing RA signaling by expressing RA receptors (RARs) or by RA agonists profoundly promoted reprogramming,but inhibiting it using a RAR-α dominant-negative form completely blocked it. Coexpressing Rarg (RAR-γ) and Lrh-1 (liver receptor homologue 1; Nr5a2) with the four factors greatly accelerated reprogramming so that reprogramming of mouse embryonic fibroblast cells to ground-state iPSCs requires only 4 d induction of these six factors. The six-factor combination readily reprogrammed primary human neonatal and adult fibroblast cells to exogenous factor-independent iPSCs,which resembled ground-state mouse ES cells in growth properties,gene expression,and signaling dependency. Our findings demonstrate that signaling through RARs has critical roles in molecular reprogramming and that the synergistic interaction between Rarg and Lrh1 directs reprogramming toward ground-state pluripotency. The human iPSCs described here should facilitate functional analysis of the human genome. View Publication