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

In mammals,the continuous production of hematopoietic cells (HCs) is sustained by a small number of hematopoietic stem cells (HSCs) residing in the bone marrow. Early HSC activity arises in the aorta-gonad mesonephros region,within cells localized to the ventral floor of the major blood vessels,suggesting that the first HSCs may be derived from cells capable of giving rise to the hematopoietic system and to the endothelial cells of the vasculature. TIE1 (TIE) and TIE2 (TEK) are related receptor tyrosine kinases with an embryonic expression pattern in endothelial cells,their precursors,and HCs,suggestive of a role in the divergence and function of both lineages. Indeed,gene targeting approaches have shown that TIE1,TIE2,and ligands for TIE2,the angiopoietins,are essential for vascular development and maintenance. To explore possible roles for these receptors in HCs,we have examined the ability of embryonic cells lacking both TIE1 and TIE2 to contribute to developmental and adult hematopoiesis by generating chimeric animals between normal embryonic cells and cells lacking these receptors. We show here that TIE receptors are not required for differentiation and proliferation of definitive hematopoietic lineages in the embryo and fetus; surprisingly,however,these receptors are specifically required during postnatal bone marrow hematopoiesis. View Publication

Interleukin-15 (IL-15) is essential for natural killer (NK) cell differentiation. In this study,we assessed whether the receptor tyrosine kinase Axl and its ligand,Gas6,are involved in IL-15-mediated human NK differentiation from CD34(+) hematopoietic progenitor cells (HPCs). Blocking the Axl-Gas6 interaction with a soluble Axl fusion protein (Axl-Fc) or the vitamin K inhibitor warfarin significantly diminished the absolute number and percentage of CD3(-)CD56(+) NK cells derived from human CD34(+) HPCs cultured in the presence of IL-15,probably resulting in part from reduced phosphorylation of STAT5. In addition,CD3(-)CD56(+) NK cells derived from culture of CD34(+) HPCs with IL-15 and Axl-Fc had a significantly diminished capacity to express interferon-gamma or its master regulator,T-BET. Culture of CD34(+) HPCs in the presence of c-Kit ligand and Axl-Fc resulted in a significant decrease in the frequency of NK precursor cells responding to IL-15,probably the result of reduced c-Kit phosphorylation. Collectively,our data suggest that the Axl/Gas6 pathway contributes to normal human NK-cell development,at least in part via its regulatory effects on both the IL-15 and c-Kit signaling pathways in CD34(+) HPCs,and to functional NK-cell maturation via an effect on the master regulatory transcription factor T-BET. View Publication

There is an enormous gap between the antiproliferative and in vivo antitumor efficacy of gemcitabine in cell line-based models and its clinical efficacy. This may be due to insensitiveness of the precursor,cancer stem cell (CSC) compartment to cytotoxic agents. The hedgehog pathway is associated with CSC signaling and control. We used a direct xenograft model of pancreatic cancer and a two-stage approach was used to test the hypotheses that targeting CSC could increase the efficacy of gemcitabine. Tumors from a gemcitabine-sensitive xenograft were treated with gemcitabine first,and randomized,after tumor regression to continuing treatment with gemcitabine,a hedgehog inhibitor alone or in combination with gemcitabine. We tested markers described as associated with CSC such as CD24,CD44,ALDH,nestin,and the hedgehog pathway. After induction with gemcitabine,treated tumor showed an enrichment in CSC markers such as ALDH and CD24. Subsequently,a release from gemcitabine prompted a repopulation of proliferating cells and a decrease in such markers to equilibrate from pretreatment levels. Combined treatment with gemcitabine and cyclopamine induced tumor regression and decrease in CSC markers and hedgehog signaling. Cytoplasmic CD24 and ALDH were inversely and strongly associated with growth and were expressed in a minority of cells that we propose constitute the CSC compartment. Hedgehog inhibitors as part of a dual compartment therapeutic approach were able to further reduce tumor growth and decreased both static and dynamic markers of CSC. Direct tumor xenografts are a valid platform to test multicompartment therapeutic approaches in pancreatic cancer. View Publication

PURPOSE: To evaluate the expression of stem cell-related markers at the cellular level in human breast tumors of different subtypes and histologic stage. EXPERIMENTAL DESIGN: We performed immunohistochemical analyses of 12 proteins [CD44,CD24,ALDH1,vimentin,osteonectin,EPCR,caveolin 1,connexin 43,cytokeratin 18 (CK18),MUC1,claudin 7,and GATA3] selected based on their differential expression in breast cancer cells with more differentiated and stem cell-like characteristics in 47 cases of invasive ductal carcinoma (IDC) only,135 cases of IDC with ductal carcinoma in situ (DCIS),35 cases of DCIS with microinvasion,and 58 cases of pure DCIS. We also analyzed 73 IDCs with adjacent DCIS to determine the differences in the expression of markers by histology within individual tumors. CD44+/CD24- and CD24-/CD24+ cells were detected using double immunohistochemistry. RESULTS: CD44 and EPCR expression was different among the four histologic groups and was lower in invasive compared with in situ tumors,especially in luminal A subtype. The expression of vimentin,osteonectin,connexin 43,ALDH1,CK18,GATA3,and MUC1 differed by tumor subtype in some histologic groups. ALDH1-positive cells were more frequent in basal-like and HER2+ than in luminal tumors. CD44+/CD24- cells were detected in 69% of all tumors with 100% of the basal-like and 52% of HER2+ tumors having some of these cells. CONCLUSIONS: Our findings suggest that in breast cancer,the frequency of tumor cells positive for stem cell-like and more differentiated cell markers varies according to tumor subtype and histologic stage. View Publication

Raman spectra often contain undesirable,randomly positioned,intense,narrow-bandwidth,positive,unidirectional spectral features generated when cosmic rays strike charge-coupled device cameras. These must be removed prior to analysis,but doing so manually is not feasible for large data sets. We developed a quick,simple,effective,semi-automated procedure to remove cosmic ray spikes from spectral data sets that contain large numbers of relatively homogenous spectra. Although some inhomogeneous spectral data sets can be accommodated—it requires replacing excessively modified spectra with the originals and removing their spikes with a median filter instead—caution is advised when processing such data sets. In addition,the technique is suitable for interpolating missing spectra or replacing aberrant spectra with good spectral estimates. The method is applied to baseline-flattened spectra and relies on fitting a third-order (or higher) polynomial through all the spectra at every wavenumber. Pixel intensities in excess of a threshold of 3× the noise standard deviation above the fit are reduced to the threshold level. Because only two parameters (with readily specified default values) might require further adjustment,the method is easily implemented for semi-automated processing of large spectral sets. View Publication

The neurodegenerative disease spinocerebellar ataxia type 3 (SCA3) is caused by a CAG-repeat expansion in the ATXN3 gene. In this study,induced pluripotent stem cell (iPSC) lines were established from two SCA3 patients. Dermal fibroblasts were reprogrammed using an integration-free method and the resulting SCA3 iPSCs were differentiated into neurons. These neuronal lines harbored the disease causing mutation,expressed comparable levels of several neuronal markers and responded to the neurotransmitters,glutamate/glycine,GABA and acetylcholine. Additionally,all neuronal cultures formed networks displaying synchronized spontaneous calcium oscillations within 28days of maturation,and expressed the mature neuronal markers NeuN and Synapsin 1 implying a relatively advanced state of maturity,although not comparable to that of the adult human brain. Interestingly,we were not able to recapitulate the glutamate-induced ataxin-3 aggregation shown in a previously published iPSC-derived SCA3 model. In conclusion,we have generated a panel of SCA3 patient iPSCs and a robust protocol to derive neurons of relatively advanced maturity,which could potentially be valuable for the study of SCA3 disease mechanisms. View Publication

Thiazolidinedione derivatives are antidiabetic agents that increase the insulin sensitivity of target tissues in animal models of non-insulin-dependent diabetes mellitus. In vitro,thiazolidinediones promote adipocyte differentiation of preadipocyte and mesenchymal stem cell lines; however,the molecular basis for this adipogenic effect has remained unclear. Here,we report that thiazolidinediones are potent and selective activators of peroxisome proliferator-activated receptor gamma (PPAR gamma),a member of the nuclear receptor superfamily recently shown to function in adipogenesis. The most potent of these agents,BRL49653,binds to PPAR gamma with a Kd of approximately 40 nM. Treatment of pluripotent C3H10T1/2 stem cells with BRL49653 results in efficient differentiation to adipocytes. These data are the first demonstration of a high affinity PPAR ligand and provide strong evidence that PPAR gamma is a molecular target for the adipogenic effects of thiazolidinediones. Furthermore,these data raise the intriguing possibility that PPAR gamma is a target for the therapeutic actions of this class of compounds. View Publication

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

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

SummaryCryosectioning remains the gold standard for antibody and transcriptomic/in situ hybridization tissue analysis. However,tissue processing is time-consuming and costly,limiting routine and diagnostic use. Currently,no commercially available protocols or products exist for multiplexing this process. Here,we introduce multiplexed tissue molds (MTMs) that enable high-throughput cryoprocessing—cutting costs and workload by up to 96% while permitting the processing of tissues of various sizes and origins. We demonstrate compatibility with heterogeneous tissues by processing 19 different adult mouse tissues in parallel. Furthermore,we process up to ?110 neural organoids of different ages and sizes simultaneously and assess their neural differentiation marker expression. MTMs allow sectioning-based tissue analysis when labor,time,and cost are limiting factors. MTMs could be used to compare high specimen numbers in histopathological settings,organism-wide antigen and antibody targeting studies,high-throughput tissue screens,and defined tissue section positioning for,e.g.,spatial transcriptomics experiments. Graphical abstract Highlights•Multiplexed tissue molds (MTMs) drastically upscale cryosectioning procedures•MTMs can simultaneously accommodate up to 19 mouse organs and ?110 cerebral organoids•MTMs reduce analysis costs and processing times of tissues by up to 96%•MTMs could be used to reduce diagnostic costs and for spatial transcriptomics MotivationEfficient cryosectioning remains a critical yet labor- and cost-intensive step for immunohistochemistry and in situ hybridization,limiting routine diagnostic and research applications. The increasing demand for high-throughput tissue analysis—driven by advances in organoid and three-dimensional (3D) culture systems and tissue analysis for diagnostics—necessitates methods capable of processing numerous heterogeneous samples simultaneously. Current protocols lack multiplexing capabilities,leading to variability and extended processing times. Our work introduces multiplexed tissue molds (MTMs),a scalable solution that drastically reduces costs and labor by up to 96% while maintaining tissue integrity and consistency,thereby enabling large-scale (>100 tissues) comparative analyses and enhanced experimental reproducibility as well as access to tissue analysis,where cost is a restrictive factor. Reumann et al. develop multiplexed tissue molds (MTMs),which allow upscaling of tissue processing (up to 19 mouse organs or ?110 cerebral organoids simultaneously) while reducing workload and associated analysis costs by up to 96%. MTMs allow cryosection-based tissue analysis when labor,time,and cost are limiting factors and could be used for patient sample analysis as well as spatial transcriptomics approaches. View Publication

SummaryA strong interest in drugs targeting the tumor microenvironment (TME) necessitates new experimental systems that incorporate key TME components. Compared to traditional 2D cell lines,3D ex vivo spheroids from patient-derived xenograft (PDX) materials may better capture patient tumor characteristics. We developed and validated a 3D tumor spheroid model from non-small cell lung cancer (NSCLC) PDXs to enable T cell infiltration. Histologic and transcriptomic analysis suggested that tumor spheroids closely recapitulate the source PDX tumor tissues. Consistent T cell infiltration into tumor spheroids was achieved using a well-established magnetic nanoparticle technology,which maintained T cell function and tumor-killing activity. Drug treatment studies with immunotherapy agents also demonstrated the potential scalability of 3D tumor-T cell spheroids in assessing drug activity,including tumor viability and cytokine secretion. This platform provides a useful tool for evaluating drug candidates that can be translated to patient tumor responses related to both tumor intrinsic and TME factors. Graphical abstract Highlights•We developed a 3D tumor spheroid model from lung cancer patient-derived xenografts•The model enabled robust T cell infiltration and preserved T cell cytotoxic functions•Histology and RNA-seq showed that tumor spheroids closely resembled source tumors•Proof-of-concept experiments showed this platform’s utility in preclinical drug testing Biological sciences; Biotechnology; Natural sciences; Tissue Engineering View Publication