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

Epigenetic modifications refer to a number of biological processes which alter the structure of chromatin and its transcriptional activity such as DNA methylation and histone post-translational processing. Studies have tried to elucidate how the viral genome and its products are affected by epigenetic modifications imposed by cell machinery and how it affects the ability of the virus to either,replicate and produce a viable progeny or be driven to latency. The purpose of this study was to evaluate epigenetic modifications in PBMCs and CD4+ cells after HIV-1 infection analyzing three approaches: (i) global DNA- methylation; (ii) qPCR array and (iii) western blot. HIV-1 infection led to methylation increases in the cellular DNA regardless the activation status of PBMCs. The analysis of H3K9me3 and H3K27me3 suggested a trend towards transcriptional repression in activated cells after HIV-1 infection. Using a qPCR array,we detected genes related to epigenetic processes highly modulated in activated HIV-1 infected cells. SETDB2 and RSK2 transcripts showed highest up-regulation levels. SETDB2 signaling is related to transcriptional silencing while RSK2 is related to either silencing or activation of gene expression depending on the signaling pathway triggered down-stream. In addition,activated cells infected by HIV-1 showed lower CD69 expression and a decrease of IL-2,IFN-γ and metabolism-related factors transcripts indicating a possible functional consequence towards global transcriptional repression found in HIV-1 infected cells. Conversely,based on epigenetic markers studied here,non-stimulated cells infected by HIV-1,showed signs of global transcriptional activation. Our results suggest that HIV-1 infection exerts epigenetic modulations in activated cells that may lead these cells to transcriptional repression with important functional consequences. Moreover,non-stimulated cells seem to increase gene transcription after HIV-1 infection. Based on these observations,it is possible to speculate that the outcome of viral infections may be influenced by the cellular activation status at the moment of infection. View Publication

Areas of a junction between two types of epithelia are known to be cancer-prone in many organ systems. However,mechanisms for preferential malignant transformation at the junction areas remain insufficiently elucidated. Here we report that inactivation of tumor suppressor genes Trp53 and Rb1 in the gastric squamous-columnar junction (SCJ) epithelium results in preferential formation of metastatic poorly differentiated neoplasms,which are similar to human gastroesophageal carcinoma. Unlike transformation-resistant antral cells,SCJ cells contain a highly proliferative pool of immature Lgr5-CD44+ cells,which are prone to transformation in organoid assays,comprise early dysplastic lesions,and constitute up to 30{\%} of all neoplastic cells. CD44 ligand osteopontin (OPN) is preferentially expressed in and promotes organoid formation ability and transformation of the SCJ glandular epithelium. OPN and CD44 overexpression correlate with the worst prognosis of human gastroesophageal carcinoma. Thus,detection and selective targeting of the active OPN-CD44 pathway may have direct clinical relevance. View Publication

Autoimmune uveitis is a leading cause of severe vision loss,and animal models provide unique opportunities for studying its pathogenesis and therapeutic strategies. Here we employ scRNA-seq,RNA-seq and various molecular and cellular approaches to characterize mouse models of classical experimental autoimmune uveitis (EAU),revealing that EAU causes broad retinal neuron degeneration and marker downregulation,and that Müller glia may act as antigen-presenting cells. Moreover,EAU immune response is primarily driven by Th1 cells,and results in dramatic upregulation of CC chemokines,especially CCL5,in the EAU retina. Accordingly,overexpression of CCR5,a CCL5 receptor,in mesenchymal stem cells (MSCs) enhances their homing capacity and improves their immunomodulatory outcomes in preventing EAU,by reducing infiltrating T cells and activated microglia and suppressing Nlrp3 inflammasome activation. Taken together,our data not only provide valuable insights into the molecular characteristics of EAU but also open an avenue for innovative MSC-based therapy.Supplementary InformationThe online version contains supplementary material available at 10.1186/s12974-024-03134-3. View Publication

The persistence of HIV-1 latency reservoirs in CD4+ T cells is a significant obstacle for curing HIV-1. Shock-and-kill strategies,which aim to reactivate latent HIV-1 followed by cytotoxic clearance,have shown limited success in vivo due to insufficient efficacy of latency reversal agents (LRAs) and off-target effects. Natural killer (NK) cells,with their ability to mediate cytotoxicity independent of antigen specificity,offer a promising avenue for enhancing the shock-and-kill approach. Previously,we observed that pan-caspase inhibitors induce NK cells to secrete an LRA in vitro. Here,we aimed to identify this LRA using a targeted proteomic approach. We identified lymphotoxin-α (LTα) as the key LRA secreted by NK cells following pan-caspase inhibitor treatment. LTα was shown to significantly induce HIV-1 LTR promoter activity,a hallmark of viral reactivation. Neutralization of LTα effectively abolished the observed LRA activity,confirming its central role. Moreover,cytokine-primed but not resting human primary NK cells exhibited LRA activity that could be neutralized with LTα neutralizing antibodies. Finally,pan-caspase inhibitor treatment did not decrease the ability of the cytokine-primed NK cells to kill target cells. These findings demonstrate that cytokine-primed NK cells,through LTα secretion,can effectively reactivate latent HIV-1 following pan-caspase inhibitor treatment,without compromising NK cell cytotoxicity. This highlights a potential enhancement strategy utilizing NK cells for shock-and-kill approaches in HIV-1 cure research. View Publication

BackgroundLevels of the human cationic antimicrobial host defence peptide LL-37 are enhanced in the lungs during neutrophilic airway inflammation. LL-37 drives Th17 differentiation,and Th17 cells produce IL-17A and IL-17F which form the biologically active heterodimer IL-17A/F. While IL-17 is a critical mediator of neutrophilic airway inflammation,LL-37 exhibits contradictory functions; LL-37 can both promote and mitigate neutrophil recruitment depending on the inflammatory milieu. The impact of LL-37 on IL-17-induced responses in the context of airway inflammation remains largely unknown. Therefore,we examined signaling intermediates and downstream responses mediated by the interplay of IL-17A/F and LL-37 in human bronchial epithelial cells (HBEC). As LL-37 can become citrullinated during airway inflammation,we also examined LL-37-mediated downstream responses compared to that with citrullinated LL-37 (citLL-37) in HBEC.ResultsUsing an aptamer-based proteomics approach,we identified proteins that are altered in response to IL-17A/F in HBEC. Proteins enhanced in response to IL-17A/F were primarily neutrophil chemoattractants,including chemokines and proteins associated with neutrophil migration such as lipocalin-2 (LCN-2). We showed that selective depletion of LCN-2 mitigates neutrophil migration,functionally demonstrating LCN-2 as a critical neutrophil chemoattractant. We further demonstrated that LL-37 and citLL-37 selectively suppress IL-17A/F-induced LCN-2 abundance in HBEC. Mechanistic studies revealed that LL-37 and citLL-37 suppresses IL-17 A/F-mediated enhancement of C/EBPβ,a transcription factor required for LCN-2 production. In contrast,LL-37 and citLL-37 enhance the abundance of ribonuclease Regnase-1,which is a negative regulator of IL-17 and LCN-2 in HBEC. In an animal model of allergen-challenged airway inflammation with elevated IL-17A/F and neutrophil elastase in the lungs,we demonstrated that CRAMP (mouse orthologue of LL-37) negatively correlates with LCN-2.ConclusionsOverall,our findings showed that LL-37 and citLL-37 can selectively suppress the abundance of IL-17A/F-mediated LCN-2,a protein that is critical for neutrophil migration in HBEC. These results suggest that LL-37,and its modified citrullinated form,have the potential to negatively regulate IL-17-mediated neutrophil migration during airway inflammation. To our knowledge,this is the first study to report that the immunomodulatory function of LL-37 enhances the RNA binding protein Regnase-1,suggesting that a post-transcriptional mechanism of action is mediated by the peptide.Supplementary InformationThe online version contains supplementary material available at 10.1186/s12950-025-00446-w. View Publication

Transplantation of engineered B cells has demonstrated efficacy in HIV disease models. B cell engineering may also be utilized for the treatment of cancer. Recent studies have highlighted that B cell activity is associated with favorable clinical outcomes in oncology. In mice,polyclonal B cells have been shown to elicit anti-cancer responses. As a potential novel cell therapy,we demonstrate that engineering B cells to target a tumor-associated antigen enhances polyclonal anti-tumor responses. We observe that engineered B cells expressing an anti-HPV B cell receptor internalize the antigen,enabling subsequent activation of oncoantigen-specific T cells. Secreted antibodies from engineered B cells form immune complexes,which are taken up by antigen-presenting cells to further promote T cell activation. Engineered B cells hold promise as novel,multi-modal cell therapies and open new avenues in solid tumor targeting. View Publication

Understanding metabolic pathways that regulate Th17 development is important to broaden therapeutic options for Th17-mediated autoimmunity. Here,we report a pivotal role of mitochondrial oxidative phosphorylation (OXPHOS) for lineage specification toward pathogenic Th17 differentiation. Th17 cells rapidly increase mitochondrial respiration during development,and this is necessary for metabolic reprogramming following T cell activation. Surprisingly,specific inhibition of mitochondrial ATP synthase ablates Th17 pathogenicity in a mouse model of autoimmunity by preventing Th17 pathogenic signature gene expression. Notably,cells activated under OXPHOS-inhibited Th17 conditions preferentially express Foxp3,rather than Th17 genes,and become suppressive Treg cells. Mechanistically,OXPHOS promotes the Th17 pioneer transcription factor,BATF,and facilitates T cell receptor (TCR) and mTOR signaling. Correspondingly,overexpression of BATF rescues Th17 development when ATP synthase activity is restricted. Together,our data reveal a regulatory role of mitochondrial OXPHOS in dictating the fate decision between Th17 and Treg cells by supporting early molecular events necessary for Th17 commitment. View Publication

Type III interferon (interferon lambda [IFN-$\lambda$]) is known to be a potential immune modulator,but the mechanisms behind its immune-modulatory functions and its impact on plasmablast differentiation in humans remain unknown. Human B cells and their subtypes directly respond to IFN-$\lambda$. Using B cell transcriptome profiling,we investigate the immune-modulatory role of IFN-$\lambda$ in B cells. We find that IFN-$\lambda$-induced gene expression in B cells is steady,prolonged,and importantly,cell type specific. Furthermore,IFN-$\lambda$ enhances the mTORC1 (mammalian/mechanistic target of rapamycin complex 1) pathway in B cells activated by the B cell receptor (BCR/anti-IgM). Engagement of mTORC1 by BCR and IFN-$\lambda$ induces cell-cycle progress in B cells. Subsequently,IFN-$\lambda$ boosts the differentiation of naive B cells into plasmablasts upon activation,and the cells gain effector functions such as cytokine release (IL-6 and IL-10) and antibody production. Our study shows how IFN-$\lambda$ systematically boosts the differentiation of naive B cells into plasmablasts by enhancing the mTORC1 pathway and cell-cycle progression in activated B cells. View Publication

Recessive dystrophic epidermolysis bullosa (RDEB) is a severe inherited skin disorder caused by mutations in COL7A1. Patient-derived induced pluripotent stem cells (iPSCs) enable the personalized study of RDEB pathogenesis and potential therapies. However,current skin cell differentiation protocols via 2D culture perform suboptimally when applied to engineered 3D skin constructs (ESC). Here,we present an approach to source fibroblasts (iFBs) and keratinocytes (iKCs) from iPSC-derived skin organoids using an optimized differentiation protocol,and utilize them to engineer ESCs modeling wild-type and RDEB phenotypes. The resulting iPSC-derived skin cells display marker expression consistent with primary counterparts and produce ESCs exhibiting significant extracellular matrix remodeling,protein deposition,and epidermal differentiation. RDEB constructs recapitulated hallmark disease features,including absence of collagen VII and reduced iFB proliferation. This work establishes a robust and scalable strategy for generating physiologically-relevant,iPSC-derived skin constructs,offering a powerful model for studying RDEB mechanisms and advancing personalized regenerative medicine. View Publication

Adult human mesenchymal stem cells are primary,multipotent cells capable of differentiating to osteocytic,chondrocytic,and adipocytic lineages when stimulated under appropriate conditions. To characterize the molecular mechanisms that regulate osteogenic differentiation,we examined the contribution of mitogen-activated protein kinase family members,ERK,JNK,and p38. Treatment of these stem cells with osteogenic supplements resulted in a sustained phase of ERK activation from day 7 to day 11 that coincided with differentiation,before decreasing to basal levels. Activation of JNK occurred much later (day 13 to day 17) in the osteogenic differentiation process. This JNK activation was associated with extracellular matrix synthesis and increased calcium deposition,the two hallmarks of bone formation. Inhibition of ERK activation by PD98059,a specific inhibitor of the ERK signaling pathway,blocked the osteogenic differentiation in a dose-dependent manner,as did transfection with a dominant negative form of MAP kinase kinase (MEK-1). Significantly,the blockage of osteogenic differentiation resulted in the adipogenic differentiation of the stem cells and the expression of adipose-specific mRNAs peroxisome proliferator-activated receptor gamma2,aP2,and lipoprotein lipase. These observations provide a potential mechanism involving MAP kinase activation in osteogenic differentiation of adult stem cells and suggest that commitment of hMSCs into osteogenic or adipogenic lineages is governed by activation or inhibition of ERK,respectively. View Publication

Surface marker expression forms the basis for characterization and isolation of human embryonic stem cells (hESCs). Currently,there are few well-defined protein epitopes that definitively mark hESCs. Here we combine immunotranscriptional profiling of hESC lines with membrane-polysome translation state array analysis (TSAA) to determine the full set of genes encoding potential hESC surface marker proteins. Three independently isolated hESC lines (HES2,H9,and MEL1) grown under feeder and feeder-free conditions were sorted into subpopulations by fluorescence-activated cell sorting based on coimmunoreactivity to the hESC surface markers GCTM-2 and CD9. Colony-forming assays confirmed that cells displaying high coimmunoreactivity to GCTM-2 and CD9 constitute an enriched subpopulation displaying multiple stem cell properties. Following microarray profiling,820 genes were identified that were common to the GCTM-2(high)/CD9(high) stem cell-like subpopulation. Membrane-polysome TSAA analysis of hESCs identified 1,492 mRNAs encoding actively translated plasma membrane and secreted proteins. Combining these data sets,88 genes encode proteins that mark the pluripotent subpopulation,of which only four had been previously reported. Cell surface immunoreactivity was confirmed for two of these markers: TACSTD1/EPCAM and CDH3/P-Cadherin,with antibodies for EPCAM able to enrich for pluripotent hESCs. This comprehensive listing of both hESCs and spontaneous differentiation-associated transcripts and survey of translated membrane-bound and secreted proteins provides a valuable resource for future study into the role of the extracellular environment in both the maintenance of pluripotency and directed differentiation. View Publication