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

The response to programmed death-1 (PD-1) blockade varies in hepatocellular carcinoma (HCC). We utilize a panel of 16 serum factors to show that a circulating level of serum amyloid A (SAA) > 20.0 mg/L has the highest accuracy in predicting anti-PD-1 resistance in HCC. Further experiments show a correlation between peritumoral SAA expression and circulating SAA levels in patients with progressive disease after PD-1 inhibition. In vitro experiments demonstrate that SAA induces neutrophils to express PD-L1 through glycolytic activation via an LDHA/STAT3 pathway and to release oncostatin M,thereby attenuating cytotoxic T cell function. In vivo,genetic or pharmacological inhibition of STAT3 or SAA eliminates neutrophil-mediated immunosuppression and enhances antitumor efficacy of anti-PD-1 treatment. This study indicates that SAA may be a critical inflammatory cytokine implicated in anti-PD-1 resistance in HCC. Targeting SAA-induced PD-L1+ neutrophils through STAT3 or SAA inhibition may present a potential approach for overcoming anti-PD1 resistance. The reasons for why hepatocellular carcinoma (HCC) is unresponsive to anti-PD-1 inhibition in some patients is not fully understood. Here the authors use human samples and mice tumour models to implicate serum amyloid A and STAT3 signalling involvement in the resistance to anti-PD1 immunotherapy in HCC. View Publication

We have recently shown that more than 90% of long-term culture initiating cells (LTC-IC) mobilized in the peripheral blood (PB) of normal individuals express HLA-DR and CD38 antigens and can sustain hematopoiesis for only 5 weeks. However,10% of LTC-IC in mobilized PB are CD34+ HLA-DR- and CD34+ CD38- and can sustain hematopoiesis for at least 8 weeks. We now examine the ex vivo expansion potential of CD34+ HLA-DR+ cells (rich in mature LTC-IC) and CD34+ HLA-DR- cells (rich in primitive LTC-IC) in granulocyte colony-stimulating factor (G-CSF) mobilized PB progenitor cells (PBPC). Cells were cultured in contact with M2-10B4 cells (contact) or in transwells above M2-10B4 (noncontact) without and with interleukin-3 (IL-3) and macrophage inflammatory protein (MIP-1alpha) for 2 and 5 weeks. Progeny were evaluated for the presence of colony-forming cells (CFC) and LTC-IC. When CD34+ HLA-DR+ PB cells were cultured in contact cultures without cytokines,a threefold expansion of CFC was seen at 2 weeks,but an 80% decrease in CFC was seen at week 5. Further,the recovery of LTC-IC at week 2 was only 17% and 1% at week 5. This confirms our previous observation that although CD34+ HLA-DR+ mobilized PB cells can initiate long-term cultures,they are relatively mature and cannot sustain long-term hematopoiesis. In contrast,when CD34+ HLA-DR- mobilized PB cells were cultured in contact cultures without cytokines,CFC expansion persisted until week 5 and 49% and 11% of LTC-IC were recovered at week 2 and 5,respectively. As we have shown for steady state bone marrow (BM) progenitors,recovery of LTC-IC was threefold higher when CD34+ HLA-DR- PBPC were cultured in noncontact rather than contact cultures,and improved further when IL-3 and MIP-1alpha were added to noncontact cultures (96 +/- 2% maintained at week 5). We conclude that although G-CSF mobilizes a large population of mature" CD34+ HLA-DR+ LTC-IC with a limited proliferative capacity View Publication

BACKGROUND We previously generated induced pluripotent stem cells by reprograming adipose stem cells through the introduction of microRNAs targeting four transcription factors (Oct3/4,Sox2,c-Myc,and Klf4). In this study,we aimed to reprogram cancer cells using microRNAs to explore their therapeutic potential. METHODS Mature microRNAs (mir-302a-d,369-3p and 5p,and mir-200c,as needed) were introduced into colon cancer cells (DLD-1,RKO,and HCT116) using lipofection. RESULTS The transfected cells exhibited an embryonic stem cell-like morphology and expressed the undifferentiated marker genes Nanog,Oct3/4,SOX2,and Klf4,as well as tumor-related antigen-1-60. These cells expressed neurogenic or adipogenic markers,indicating that reprogramming of the cancer cells was partially successful. Moreover,we found that miRNA-expressing DLD-1 cells showed low proliferative activity in vitro and in vivo,accompanied by increased expression of the tumor suppressor genes p16 (ink4a) and p21 (waf1) . miRNA-expressing DLD-1 cells also exhibited enhanced sensitivity to 5-fluorouracil,possibly through the downregulation of multidrug-resistant protein 8. The reprogrammed cells from DLD-1,RKO,and HCT116 cells exhibited reduced c-Myc expression,in contrast to the high c-Myc expression in the induced pluripotent cancer cells that were generated using four transcription factors. CONCLUSIONS Our cancer reprogramming method employing simple lipofection of mature microRNAs is safe and well suited for clinical application,because it avoids integration of exogenous genes into the host genome and allows escape from augmentation of c-Myc gene expression. View Publication

Umbilical cord blood (CB) represents a main source of circulating endothelial progenitor cells (cEPCs). In view of their clinical use,in either the autologous or allogeneic setting,cEPCs should likely be expanded from CB kept frozen in CB banks. In this study,we compared the expansion,functional features,senescence pattern over culture,and in vivo angiogenic potential of cEPCs isolated from fresh or cryopreserved CB (cryoCB). cEPCs could be isolated in only 59% of cryoCB compared to 94% for fresh CB,while CB units were matched in terms of initial volume,nucleated and CD34(+) cell number. Moreover,the number of endothelial colony-forming cells was significantly decreased when using cryoCB. Once cEPCs culture was established,the proliferation,migration,tube formation,and acetylated-LDL uptake potentials were similar in both groups. In addition,cEPCs derived from cryoCB displayed the same senescence status and telomeres length as that of cEPCs derived from fresh CB. Karyotypic aberrations were found in cells obtained from both fresh and cryoCB. In vivo,in a hind limb ischemia murine model,cEPCs from fresh and cryoCB were equally efficient to induce neovascularization. Thus,cEPCs isolated from cryoCB exhibited similar properties to those of fresh CB in vitro and in vivo. However,the low frequency of cEPCs colony formation after cryopreservation shed light on the need for specific freezing conditions adapted to cEPCs in view of their future clinical use. View Publication

Monocyte cytokines (ie,monokines) induce natural killer (NK) cells to produce interferon-gamma (IFN-gamma),which is critical for monocyte clearance of infectious pathogens and tumor surveillance. Human CD56bright NK cells produce far more IFN-gamma in response to monokines than do CD56dim NK cells. The kinases and phosphatases involved in regulating IFN-gamma production by monokine-activated NK cells are not clearly identified. SHIP1 is a 5' inositol phosphatase that dephosphorylates the phosphatidylinositol-3 kinase (PI-3K) product PI3,4,5P3. Here,we show that constitutive expression of SHIP1 is distinctly lower in CD56bright NK cells compared with CD56dim NK cells,suggesting it could be an important negative regulator of IFN-gamma production in monokine-activated NK cells. Indeed,overexpression of SHIP1 in CD56bright NK cells followed by monokine activation substantially lowered IFN-gamma production. This effect was not seen when NK cells were infected with a SHIP1 mutant containing an inactive catalytic domain. Finally,NK cells in SHIP1-/- mice produced more IFN-gamma in response to monokines in vivo than did NK cells from wild-type mice. Collectively,these results demonstrate that SHIP1 negatively regulates monokine-induced NK cell IFN-gamma production in vitro and in vivo and provide the first molecular explanation for an important functional distinction observed between CD56bright and CD56dim human NK subsets. View Publication

The vascularization of tissue-engineered bone is a prerequisite step for the successful repair of bone defects. Hypoxia inducible factor-1$$ (HIF-1$$) plays an essential role in angiogenesis-osteogenesis coupling during bone regeneration and can activate the expression of angiogenic factors in mesenchymal stem cells (MSCs). Dimethyloxaloylglycine (DMOG) is an angiogenic small molecule that can inhibit prolyl hydroxylase (PHD) enzymes and thus regulate the stability of HIF-1$$ in cells at normal oxygen tension. Human induced pluripotent stem cell-derived MSCs (hiPSC-MSCs) are promising alternatives for stem cell therapy. In this study,we evaluated the effect of DMOG on promoting hiPSC-MSCs angiogenesis in tissue-engineered bone and simultaneously explored the underlying mechanisms in vitro. The effectiveness of DMOG in improving the expression of HIF-1$$ and its downstream angiogenic genes in hiPSC-MSCs demonstrated that DMOG significantly enhanced the gene and protein expression profiles of angiogenic-related factors in hiPSC-MSCs by sustaining the expression of HIF-1$$. Further analysis showed that DMOG-stimulated hiPSC-MSCs angiogenesis was associated with the phosphorylation of protein kinase B (Akt) and with an increase in VEGF production. The effects could be blocked by the addition of the phosphatidylinositol 3-kinase (PI3K) inhibitor LY294002. In a critical-sized calvarial defect model in rats,DMOG-treated hiPSC-MSCs showed markedly improved angiogenic capacity in the tissue-engineered bone,leading to bone regeneration. Collectively,the results indicate that DMOG,via activation of the PI3K/Akt pathway,promotes the angiogenesis of hiPSC-MSCs in tissue-engineered bone for bone defect repair and that DMOG-treated hiPSC-MSCs can be exploited as a potential therapeutic tool in bone regeneration. View Publication

UNLABELLED Congenital human cytomegalovirus (HCMV) infection is a major cause of central nervous system structural anomalies and sensory impairments. It is likely that the stage of fetal development,as well as the state of differentiation of susceptible cells at the time of infection,affects the severity of the disease. We used human embryonic stem (ES) cell-derived primitive prerosette neural stem cells (pNSCs) and neural progenitor cells (NPCs) maintained in chemically defined conditions to study HCMV replication in cells at the early stages of neural development. In contrast to what was observed previously using fetus-derived NPCs,infection of ES cell-derived pNSCs with HCMV was nonprogressive. At a low multiplicity of infection,we observed only a small percentage of cells expressing immediate-early genes (IE) and early genes. IE expression was found to be restricted to cells negative for the anterior marker FORSE-1,and treatment of pNSCs with retinoic acid restored IE expression. Differentiation of pNSCs into NPCs restored IE expression but not the transactivation of early genes. Virions produced in NPCs and pNSCs were exclusively cell associated and were mostly non-neural tropic. Finally,we found that viral genomes could persist in pNSC cultures for up to a month after infection despite the absence of detectable IE expression by immunofluorescence,and infectious virus could be produced upon differentiation of pNSCs to neurons. In conclusion,our results highlight the complex array of hurdles that HCMV must overcome in order to infect primitive neural stem cells and suggest that these cells might act as a reservoir for the virus. IMPORTANCE Human cytomegalovirus (HCMV) is a betaherpesvirus that is highly prevalent in the population. HCMV infection is usually asymptomatic but can lead to severe consequences in immunosuppressed individuals. HCMV is also the most important infectious cause of congenital developmental birth defects. Manifestations of fetal HCMV disease range from deafness and learning disabilities to more severe symptoms such as microcephaly. In this study,we have used embryonic stem cells to generate primitive neural stem cells and have used these to model HCMV infection of the fetal central nervous system (CNS) in vitro. Our results reveal that these cells,which are similar to those present in the developing neural tube,do not support viral replication but instead likely constitute a viral reservoir. Future work will define the effect of viral persistence on cellular functions as well as the exogenous signals leading to the reactivation of viral replication in the CNS. View Publication

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Chondrogenesis of mesenchymal stem cells (MSCs) is typically induced when they are condensed into a single aggregate and exposed to transforming growth factor-beta (TGF-beta). Hypoxia,like aggregation and TGF-beta delivery,may be crucial for complete chondrogenesis. However,the pellet dimensions and associated self-induced oxygen gradients of current chondrogenic methods may limit the effectiveness of in vitro differentiation and subsequent therapeutic uses. Here we describe the use of embryoid body-forming technology to produce microscopic aggregates of human bone marrow MSCs (BM-MSCs) for chondrogenesis. The use of micropellets reduces the formation of gradients within the aggregates,resulting in a more homogeneous and controlled microenvironment. These micropellet cultures (approximately 170 cells/micropellet) as well as conventional pellet cultures (approximately 2 x 10(5) cells/pellet) were chondrogenically induced under 20% and 2% oxygen environments for 14 days. Compared to conventional pellets under both environments,micropellets differentiated under 2% O(2) showed significantly increased sulfated glycosaminoglycan (sGAG) production and more homogeneous distribution of proteoglycans and collagen II. Aggrecan and collagen II gene expressions were increased in pellet cultures differentiated under 2% O(2) relative to 20% O(2) pellets but 2% O(2) micropellets showed even greater increases in these genes,as well as increased SOX9. These results suggest a more advanced stage of chondrogenesis in the micropellets accompanied by more homogeneous differentiation. Thus,we present a new method for enhancing MSC chondrogenesis that reveals a unique relationship between oxygen tension and aggregate size. The inherent advantages of chondrogenic micropellets over a single macroscopic aggregate should allow for easy integration with a variety of cartilage engineering strategies. View Publication

Pluripotency,the ability of a cell to differentiate and give rise to all embryonic lineages,defines a small number of mammalian cell types such as embryonic stem (ES) cells. While it has been generally held that pluripotency is the product of a transcriptional regulatory network that activates and maintains the expression of key stem cell genes,accumulating evidence is pointing to a critical role for epigenetic processes in establishing and safeguarding the pluripotency of ES cells,as well as maintaining the identity of differentiated cell types. In order to better understand the role of epigenetic mechanisms in pluripotency,we have examined the dynamics of chromatin modifications genome-wide in human ES cells (hESCs) undergoing differentiation into a mesendodermal lineage. We found that chromatin modifications at promoters remain largely invariant during differentiation,except at a small number of promoters where a dynamic switch between acetylation and methylation at H3K27 marks the transition between activation and silencing of gene expression,suggesting a hierarchy in cell fate commitment over most differentially expressed genes. We also mapped over 50 000 potential enhancers,and observed much greater dynamics in chromatin modifications,especially H3K4me1 and H3K27ac,which correlate with expression of their potential target genes. Further analysis of these enhancers revealed potentially key transcriptional regulators of pluripotency and a chromatin signature indicative of a poised state that may confer developmental competence in hESCs. Our results provide new evidence supporting the role of chromatin modifications in defining enhancers and pluripotency. View Publication