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

HUCB (human umbilical cord blood) has been frequently used in clinical allogeneic HSC (haemopoietic stem cell) transplant. However,HUCB is poorly recognized as a rich source of MSC (mesenchymal stem cell). The aim of this study has been to establish a new method for isolating large number of MSC from HUCB to recognize it as a good source of MSC. HUCB samples were collected from women following their elective caesarean section. The new method (Clot Spot method) was carried out by explanting HUCB samples in mesencult complete medium and maintained in 37°C,in a 5% CO2 and air incubator. MSC presence was established by quantitative and qualitative immunophenotyping of cells and using FITC attached to MSC phenotypic markers (CD29,CD73,CD44 and CD105). Haematopoietic antibodies (CD34 and CD45) were used as negative control. MSC differentiation was examined in neurogenic and adipogenic media. Immunocytochemistry was carried out for the embryonic markers: SOX2 (sex determining region Y-box 2),OLIG-4 (oligodendrocyte-4) and FABP-4 (fatty acid binding protein-4). The new method was compared with the conventional Rosset Sep method. MSC cultures using the Clot Spot method showed 3-fold increase in proliferation rate compared with conventional method. Also,the cells showed high expression of MSC markers CD29,CD73,CD44 and CD105,but lacked the expression of specific HSC markers (CD34 and CD45). The isolated MSC showed some differentiation by expressing the neurogenic (SOX2 and Olig4) and adipogenic (FABP-4) markers respectively. In conclusion,HUCB is a good source of MSC using this new technique. View Publication

The fabrication of high-density polymer microarray is described,allowing the simultaneous and efficient evaluation of more than 7000 different polymers in a single-cellular-based screen. These high-density polymer arrays are applied in the search for synthetic substrates for hESCs culture. Up-scaling of the identified hit polymers enables long-term cellular cultivation and promoted successful stem-cell maintenance. View Publication

Amyotrophic lateral sclerosis (ALS) is a fatal and incurable neurodegenerative disease caused by the selective and progressive death of motor neurons (MNs). Understanding the genetic and molecular factors influencing ALS survival is crucial for disease management and therapeutics. In this study,we introduce a deep learning-powered genetic analysis framework to link rare noncoding genetic variants to ALS survival. Using data from human induced pluripotent stem cell (iPSC)-derived MNs,this method prioritizes functional noncoding variants using deep learning,links cis-regulatory elements (CREs) to target genes using epigenomics data,and integrates these data through gene-level burden tests to identify survival-modifying variants,CREs,and genes. We apply this approach to analyze 6,715 ALS genomes,and pinpoint four novel rare noncoding variants associated with survival,including chr7:76,009,472:C>T linked to CCDC146. CRISPR-Cas9 editing of this variant increases CCDC146 expression in iPSC-derived MNs and exacerbates ALS-specific phenotypes,including TDP-43 mislocalization. Suppressing CCDC146 with an antisense oligonucleotide (ASO),showing no toxicity,completely rescues ALS-associated survival defects in neurons derived from sporadic ALS patients and from carriers of the ALS-associated G4C2-repeat expansion within C9ORF72. ASO targeting of CCDC146 may be a broadly effective therapeutic approach for ALS. Our framework provides a generic and powerful approach for studying noncoding genetics of complex human diseases. View Publication

Understanding the multicellular organization of stem cells is vital for determining the mechanisms that coordinate cell fate decision-making during differentiation; these mechanisms range from neighbor-to-neighbor communication to tissue-level biochemical gradients. Current methods for quantifying multicellular patterning tend to capture the spatial properties of cell colonies at a fixed scale and typically rely on human annotation. We present a computational pipeline that utilizes topological data analysis to generate quantitative,multiscale descriptors which capture the shape of data extracted from 2D multichannel microscopy images. By applying our pipeline to certain stem cell colonies,we detected subtle differences in patterning that reflect distinct spatial organization associated with loss of pluripotency. These results yield insight into putative directed cellular organization and morphogen-mediated,neighbor-to-neighbor signaling. Because of its broad applicability to immunofluorescence microscopy images,our pipeline is well-positioned to serve as a general-purpose tool for the quantitative study of multicellular pattern formation. View Publication

The primed epiblast acts as a transitional stage between the relatively homogeneous naïve epiblast and the gastrulating embryo. Its formation entails coordinated changes in regulatory circuits driven by transcription factors and epigenetic modifications. Using a multi-omic approach in human embryonic stem cell models across the spectrum of peri-implantation development,we demonstrate that the transcription factors ZIC2 and ZIC3 have overlapping but essential roles in opening primed-specific enhancers. Together,they are essential to facilitate progression to and maintain primed pluripotency. ZIC2/3 accomplish this by recruiting SWI/SNF to chromatin and loss of ZIC2/3 or degradation of SWI/SNF both prevent enhancer activation. Loss of ZIC2/3 also results in transcriptome changes consistent with perturbed Polycomb activity and a shift towards the expression of genes linked to differentiation towards the mesendoderm. Additionally,we find an intriguing dependency on the transcriptional machinery for sustained recruitment of ZIC2/3 over a subset of primed-hESC specific enhancers. Taken together,ZIC2 and ZIC3 regulate highly dynamic lineage-specific enhancers and collectively act as key regulators of human primed pluripotency. Here the authors identify ZIC2 and ZIC3 as key regulators of human primed pluripotency which recruit BRG1 to open primed hESC-specific enhancers. View Publication

Taybi-Linder syndrome (TALS) is a rare autosomal recessive disorder characterized by severe microcephaly with abnormal gyral pattern,severe growth retardation and bone abnormalities. It is caused by pathogenic variants in the RNU4ATAC gene. Its transcript,the small nuclear RNA U4atac,is involved in the excision of ~850 minor introns. Here,we report a patient presenting with TALS features but no pathogenic variants were found in RNU4ATAC,instead the homozygous RTTN c.2953A>G variant was detected by whole-exome sequencing. After deciphering the impact of the variant on the RTTN protein function at centrosome in engineered RTTN-depleted RPE1 cells and patient fibroblasts,we analysed neural stem cells (NSC) derived from CRISPR/Cas9-edited induced pluripotent stem cells and revealed major cell cycle and mitotic abnormalities,leading to aneuploidy,cell cycle arrest and cell death. In cortical organoids,we discovered an additional function of RTTN in the self-organisation of NSC into neural rosettes,by observing delayed apico-basal polarization of NSC. Altogether,these defects contributed to a marked delay of rosette formation in RTTN-mutated organoids,thus impeding their overall growth and shedding light on mechanisms leading to microcephaly. Author summaryPrimary microcephaly is defined as a severe reduction of the brain size that occurs prenatally. Variants in about 50 genes have been associated to primary microcephaly,and most of them encode proteins that regulate cell cycle,notably by participating to centrosome biogenesis. Intriguingly,some other genes involved in the process of minor splicing,such as RNU4ATAC,are also related to primary microcephaly without clear understanding of the underlying pathophysiological mechanisms. In our previous work,we discovered that alterations of minor splicing result into dysfunction of the centrosome/cilium complex. Here,we further feed this link between minor splicing and centrosome/primary cilium by reporting the particular case of a patient who presents with all features of the rare RNU4ATAC-associated syndrome,called the Taybi-Linder syndrome,and yet,is homozygous for the only recurrent pathogenic variant in the centrosomal RTTN gene. Hence,to decipher the underlying cellular mechanisms,we generated unique human neuronal cellular models–iPSC-derived neural stem cells (NSC) and cortical organoids–and unveiled the combination of events that contribute to the depletion of the NSC pool and explain RTTN-associated microcephaly. Our work gives thus precious hints for the understanding of the Taybi-Linder syndrome physiopathology. View Publication

This study describes novel interactors of the retinal Crumbs complex and reveals homo- and heterotypic interactions of CRB1 and CRB2 that are not significantly affected by patient-associated mutations. Crumbs homolog 1 (CRB1) is one of the key genes linked to retinitis pigmentosa and Leber congenital amaurosis,which are characterized by a high clinical heterogeneity. The Crumbs family member CRB2 has a similar protein structure to CRB1,and in zebrafish,Crb2 has been shown to interact through the extracellular domain. Here,we show that CRB1 and CRB2 co-localize in the human retina and human iPSC-derived retinal organoids. In retina-specific pull-downs,CRB1 was enriched in CRB2 samples,supporting a CRB1–CRB2 interaction. Furthermore,novel interactors of the crumbs complex were identified,representing a retina-derived protein interaction network. Using co-immunoprecipitation,we further demonstrate that human canonical CRB1 interacts with CRB1 and CRB2,but not with CRB3,which lacks an extracellular domain. Next,we explored how missense mutations in the extracellular domain affect CRB1–CRB2 interactions. We observed no or a mild loss of CRB1–CRB2 interaction,when interrogating various CRB1 or CRB2 missense mutants in vitro. Taken together,our results show a stable interaction of human canonical CRB2 and CRB1 in the retina. View Publication

Johnson,Ogishi,and Domingo-Vila et al. describe two siblings with inherited PD-L1 deficiency. Human PD-L1 deficiency underlies early-onset T1D,like PD-1 deficiency,but does not lead to fatal autoimmunity with extensive leukocytic dysregulation,unlike PD-1 deficiency. View Publication

The cerebellum plays a critical role in all vertebrates,and many neurological disorders are associated with cerebellum dysfunction. A major limitation in cerebellar research has been the lack of adequate disease models. As an alternative to animal models,cerebellar neurons differentiated from pluripotent stem cells have been used. However,previous studies only produced limited amounts of Purkinje cells. Moreover,in vitro generation of Purkinje cells required co-culture systems,which may introduce unknown components to the system. Here we describe a novel differentiation strategy that uses defined medium to generate Purkinje cells,granule cells,interneurons,and deep cerebellar nuclei projection neurons,that self-formed and differentiated into electrically active cells. Using a defined basal medium optimized for neuronal cell culture,we successfully promoted the differentiation of cerebellar precursors without the need for co-culturing. We anticipate that our findings may help developing better models for the study of cerebellar dysfunctions,while providing an advance toward the development of autologous replacement strategies for treating cerebellar degenerative diseases. View Publication

Cis-regulatory elements (CREs) are noncoding DNA regions regulating cell-type-specific gene expression programs by interacting with distal gene promoters. Here,we aim to decode the function and spatial organization of CRE-promoter interactions in human cardiomyocytes. We analyzed the epigenome and chromatin interactions of human male atrial,ventricular,and failing cardiomyocytes. Atrial and ventricular cardiomyocytes harbored chamber-specific CRE-promoter interactions modulating gene expression as confirmed by functional epigenetic silencing. These CRE-promoter interactions explain the distinct contribution of non-coding genetic variants to atrial and ventricular diseases,such as dilated cardiomyopathy and arrhythmias. We dissected the prototypic KCNJ2 locus,encoding a potassium channel associated with ventricular arrhythmia susceptibility. Functional epigenetic silencing confirmed that CREs,harboring QT-duration-associated genetic risk factors,modulate KCNJ2 gene expression levels,alter KCNJ2-dependent channel currents,and affect cardiomyocyte repolarization. The presented human CM-specific chromatin interaction analysis provides key insights into regulatory mechanisms and aids in interpreting genetic risk factors. Here the authors functionally test and resolve the spatial genome organization of cis-regulatory elements and genetic variants in atrial,ventricular,and failing human cardiomyocytes and linked them to heart disease traits,including QT syndrome. View Publication

The molecular and cellular requirements for the development of different populations of human dendritic cells (DC) were studied. Conditions were defined that support DC production from lymphoid progenitors but that fail to induce DC formation from peripheral monocytes. The production of these lymphoid-related DC was severely blocked when hematopoietic progenitors overexpressed Ik7,a mutant dominant-negative Ikaros protein. In contrast,Ik7 did not block the formation of DC in conditions supporting the development of monocyte-derived DC. Furthermore,Ik7 did not block the formation of monocyte/macrophages and enhanced granulopoiesis. One of the molecular mechanisms mediated by Ik7 appears to be down-regulation of the flt3-receptor mRNA. Thus,distinct signals control the formation of DC demonstrating that some aspects of DC diversity are determined in part by distinct molecular cues at the hematopoietic level. (Blood. 2000;95:128-137) View Publication

Despite progress in the development of drugs that efficiently target cancer cells,treatments for metastatic tumours are often ineffective. The now well-established dependency of cancer cells on their microenvironment suggests that targeting the non-cancer-cell component of the tumour might form a basis for the development of novel therapeutic approaches. However,the as-yet poorly characterized contribution of host responses during tumour growth and metastatic progression represents a limitation to exploiting this approach. Here we identify neutrophils as the main component and driver of metastatic establishment within the (pre-)metastatic lung microenvironment in mouse breast cancer models. Neutrophils have a fundamental role in inflammatory responses and their contribution to tumorigenesis is still controversial. Using various strategies to block neutrophil recruitment to the pre-metastatic site,we demonstrate that neutrophils specifically support metastatic initiation. Importantly,we find that neutrophil-derived leukotrienes aid the colonization of distant tissues by selectively expanding the sub-pool of cancer cells that retain high tumorigenic potential. Genetic or pharmacological inhibition of the leukotriene-generating enzyme arachidonate 5-lipoxygenase (Alox5) abrogates neutrophil pro-metastatic activity and consequently reduces metastasis. Our results reveal the efficacy of using targeted therapy against a specific tumour microenvironment component and indicate that neutrophil Alox5 inhibition may limit metastatic progression. View Publication