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

Mitomycin C (MMC) is the prototype bioreductive DNA alkylating agent. To exploit its unique properties and maximize patient responses,different therapeutic approaches have been investigated. Recently,the focus has concentrated on monitoring the levels of the proteins metabolizing the drug and relating these to activity in a regimen referred to as enzyme-directed bioreductive drug development. To be successful,it is important to understand the enzymology of metabolic activation not only in cell lines but also in solid tumour models. A general mechanism of action for MMC has now emerged that is activated regardless of the source of reducing equivalents,comprising three competing pathways that give rise to unique reactive intermediates and different DNA adducts. Partitioning into the pathways is dictated by chemical considerations such as pH and drug concentration. DT-diaphorase stands out in this mechanism,since it is much less effective at metabolizing MMC at neutral pH. At least five different enzymes can catalyse MMC bioreduction in vitro,and as many activities may be present in solid tumours,including a series of novel mitochondrial reductases such as a cytochrome P450 reductase. Competition between reductases for MMC appears to be based solely on protein levels rather than enzyme kinetics. Consequentially,DT-diaphorase can occupy a central role in MMC metabolic activation since it is often highly overexpressed in cancer cells. Although a good correlation has been observed in cell lines between DT-diaphorase expression and aerobic cytotoxicity,this does not hold consistently in vivo for any single bioreductive enzyme,suggesting revision of the enzyme-directed hypothesis as originally formulated. View Publication

CD4+ T cells recognize antigens through their T cell receptors (TCRs); however,additional signals involving costimulatory receptors,for example,CD28,are required for proper T cell activation. Alternative costimulatory receptors have been proposed,including members of the Toll-like receptor (TLR) family,such as TLR5 and TLR2. To understand the molecular mechanism underlying a potential costimulatory role for TLR5,we generated detailed molecular maps and logical models for the TCR and TLR5 signaling pathways and a merged model for cross-interactions between the two pathways. Furthermore,we validated the resulting model by analyzing how T cells responded to the activation of these pathways alone or in combination,in terms of the activation of the transcriptional regulators CREB,AP-1 (c-Jun),and NF-kappaB (p65). Our merged model accurately predicted the experimental results,showing that the activation of TLR5 can play a similar role to that of CD28 activation with respect to AP-1,CREB,and NF-kappaB activation,thereby providing insights regarding the cross-regulation of these pathways in CD4+ T cells. View Publication

Molecular- and cellular-based therapies have the potential to reduce obesity-associated disease. In response to cold,beige adipocytes form in subcutaneous white adipose tissue and convert energy stored in metabolic substrates to heat,making them an attractive therapeutic target. We developed a robust method to generate a renewable source of human beige adipocytes from induced pluripotent stem cells (iPSCs). Developmentally,these cells are derived from FOXF1+ mesoderm and progress through an expandable mural-like mesenchymal stem cell (MSC) to form mature beige adipocytes that display a thermogenically active profile. This includes expression of uncoupling protein 1 (UCP1) concomitant with increased uncoupled respiration. With this method,dysfunctional adipogenic precursors can be reprogrammed and differentiated into beige adipocytes with increased thermogenic function and anti-diabetic secretion potential. This resource can be used to (1) elucidate mechanisms that underlie the control of beige adipogenesis and (2) generate material for cellular-based therapies that target metabolic syndrome in humans. View Publication

Background: Effective molecular diagnosis of congenital diseases hinges on comprehensive genomic analysis,traditionally reliant on various methodologies specific to each variant type-whole exome or genome sequencing for single nucleotide variants (SNVs),array CGH for copy-number variants (CNVs),and microscopy for structural variants (SVs). Methods: We introduce a novel,integrative approach combining exome sequencing with chromosome conformation capture,termed Exo-C. This method enables the concurrent identification of SNVs in clinically relevant genes and SVs across the genome and allows analysis of heterozygous and mosaic carriers. Enhanced with targeted long-read sequencing,Exo-C evolves into a cost-efficient solution capable of resolving complex SVs at base-pair accuracy. Results: Applied to 66 human samples Exo-C achieved 100% recall and 73% precision in detecting chromosomal translocations and SNVs. We further benchmarked its performance for inversions and CNVs and demonstrated its utility in detecting mosaic SVs and resolving diagnostically challenging cases. Conclusions: Through several case studies,we demonstrate how Exo-C's multifaceted application can effectively uncover diverse causative variants and elucidate disease mechanisms in patients with rare disorders. View Publication

STAT3 is constitutively activated in many cancer types,including lung cancer,and can induce cancer cell proliferation and cancer stem cell (CSC) maintenance. STAT3 is activated by tyrosine kinases,such as JAK and SRC,but the mechanism by which STAT3 maintains its activated state in cancer cells remains unclear. Here,we show that PRMT5 directly methylates STAT3 and enhances its activated tyrosine phosphorylation in non-small cell lung cancer (NSCLC) cells. PRMT5 expression is also induced by STAT3,suggesting the presence of a positive feedback loop in cancer cells. Furthermore,methylation of STAT3 at arginine 609 by PRMT5 is important for its transcriptional activity and support of tumour growth and CSC maintenance. Indeed,NSCLC cells expressing the STAT3 mutant which R609 was replaced to alanine (R609K) show significantly impaired tumour growth in nude mice. Overall,our study reveals a mechanism by which STAT3 remains activated in NSCLC and provides a new target for cancer therapeutic approaches. Subject terms: Oncogenes,Non-small-cell lung cancer,Growth factor signalling View Publication

Hematologic adverse events are common dose-limiting toxicities in drug development. Classical animal models for preclinical safety assessment of immunotherapies are often limited due to insufficient cross-reactivity with non-human homologous proteins,immune system differences,and ethical considerations. Therefore,we evaluate a human bone marrow (BM) microphysiological system (MPS) for its ability to predict expected hematopoietic liabilities of immunotherapeutics. The BM-MPS consists of a closed microfluidic circuit containing a ceramic scaffold covered with human mesenchymal stromal cells and populated with human BM-derived CD34+ cells in chemically defined growth factor-enriched media. The model supports on-chip differentiation of erythroid,myeloid and NK cells from CD34+ cells over 31 days. The hematopoietic lineage balance and output is responsive to pro-inflammatory factors and cytokines. Treatment with a transferrin receptor-targeting IgG1 antibody results in inhibition of on-chip erythropoiesis. The immunocompetence of the chip is established by the addition of peripheral blood T cells in a fully autologous setup. Treatment with T cell bispecific antibodies induces T cell activation and target cell killing consistent with expected on-target off-tumor toxicities. In conclusion,this study provides a proof-of-concept that this BM-MPS is applicable for in vitro hematopoietic safety profiling of immunotherapeutics. Subject terms: Biologics,Haematopoiesis,Lab-on-a-chip,Drug safety View Publication

Secondary and tertiary lymphoid structures are a critical target of suppression in many autoimmune disorders,protein replacement therapies,and in transplantation. Although antigen-specific regulatory T cells (Tregs),such as chimeric antigen receptor (CAR) Tregs,generally persist longer and localize to target tissues more effectively than polyclonal Tregs in animal models,their numbers still progressively decline over time. A potential approach to maximize Treg activity in vivo is the expression of chemokine receptors such as CXCR5,which would enable localization of a greater number of engineered cells at sites of antigen presentation. Indeed,CXCR5 expression on follicular T helper cells and follicular Tregs enables migration toward lymph nodes,B cell zones,and tertiary lymphoid structures that appear in chronically inflamed non-lymphoid tissues. In this study,we generated human and murine CXCR5 co-expressing engineered receptor Tregs and tested them in preclinical mouse models of allo-immunity and hemophilia A,respectively. Additionally,we engineered a murine CXCR5 co-expressing clotting factor VIII (FVIII) specific T cell receptor fusion construct epsilon (FVIII TRuCe CXCR5) Treg to suppress anti-drug antibody development in a model of FVIII protein replacement therapy for hemophilia A. In vitro,anti-HLA-A2 CXCR5+ CAR-Tregs showed enhanced migratory and antigen-specific suppressive capacities compared to untransduced Tregs. When injected into an NSG mouse model of HLA-A2+ pancreatic islet transplantation,anti-HLA-A2 CXCR5+ CAR-Tregs maintained a good safety profile allowing for long-term graft survival in contrast to anti-HLA-A2 CXCR5+ conventional CAR-T (Tconv) cells that eliminated the graft. Similarly,FVIII TRuCe CXCR5 Treg demonstrated increased in vivo persistence and suppressive capacity in a murine model of hemophilia A. Collectively,our findings indicate that CXCR5 co-expression is safe and enhances in vivo localization and persistence in target tissues. This strategy can potentially promote targeted tolerance without the risk of off-target effects in multiple disease models. View Publication

Epstein-Barr virus (EBV) causes infectious mononucleosis and contributes to neurodegenerative disorders and malignancies,particularly in immune-compromised hosts. Transplant patients face high risk of post-transplant lymphoproliferative disease,a life-threatening EBV-driven lymphoma. There are no EBV-specific vaccines or treatments; however,neutralizing antibodies against EBV glycoproteins may offer utility as therapeutic agents. EBV entry into B cells involves gp350,which binds complement receptors,and gp42,which engages HLA class II to trigger fusion. Most existing monoclonal antibodies (mAbs) against these antigens are non-human,limiting clinical use. Using a transgenic mouse model,we generate two gp350 and eight gp42 genetically human neutralizing mAbs that block receptor binding. Structural analyses reveal extended sites of vulnerability relevant to vaccine development. Delivery of a gp42 mAb protects humanized mice from EBV challenge,while a gp350 mAb provides partial protection. These mAbs highlight the utility of transgenic mice to produce therapeutic mAbs for preventing EBV-driven disease. Graphical abstract Highlights•Transgenic mice were used to make genetically human EBV mAbs against gp350 and gp42•mAbs potently neutralize EBV infection by blocking receptor-ligand interactions•mAbs prevent EBV infection following EBV challenge in humanized mice Epstein-Barr virus (EBV) can cause serious illness,including cancer,especially in immunocompromised patients. There are no EBV-specific treatments. Chhan et al. leverage a transgenic mouse model to develop human monoclonal antibodies that block EBV entry. These antibodies prevent EBV infection in a murine challenge model offering hope for new therapies. View Publication

During pregnancy the uterine decidua is populated by large numbers of natural killer (NK) cells with a phenotype CD56(superbright)CD16(-)CD9(+)KIR(+) distinct from both subsets of peripheral blood NK cells. Culture of highly purified CD16(+)CD9(-) peripheral blood NK cells in medium containing TGFbeta1 resulted in a transition to CD16(-)CD9(+) NK cells resembling decidual NK cells. Decidual stromal cells,when isolated and cultured in vitro,were found to produce TGFbeta1. Incubation of peripheral blood NK cells with conditioned medium from decidual stromal cells mirrored the effects of TGFbeta1. Similar changes may occur upon NK cell entry into the decidua or other tissues expressing substantial TGFbeta. In addition,Lin(-)CD34(+)CD45(+) hematopoietic stem/progenitor cells could be isolated from decidual tissue. These progenitors also produced NK cells when cultured in conditioned medium from decidual stromal cells supplemented with IL-15 and stem cell factor. View Publication

Monomeric clustered regularly interspaced short palindromic repeats (CRISPR)-CRISPR associated 9 (Cas9) nucleases have been widely adopted for simple and robust targeted genome editing but also have the potential to induce high-frequency off-target mutations. In principle,two orthogonal strategies for reducing off-target cleavage,truncated guide RNAs (tru-gRNAs) and dimerization-dependent RNA-guided FokI-dCas9 nucleases (RFNs),could be combined as tru-RFNs to further improve genome editing specificity. Here we identify a robust tru-RFN architecture that shows high activity in human cancer cell lines and embryonic stem cells. Additionally,we demonstrate that tru-gRNAs reduce the undesirable mutagenic effects of monomeric FokI-dCas9. Tru-RFNs combine the advantages of two orthogonal strategies for improving the specificity of CRISPR-Cas nucleases and therefore provide a highly specific platform for performing genome editing. View Publication