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

Wiskott-Aldrich syndrome (WAS) is a severe X-linked primary immunodeficiency resulting from a diversity of mutations distributed across all 12 exons of the WAS gene. WAS encodes a hematopoietic-specific and developmentally regulated cytoplasmic protein (WASp). The objective of this study was to develop a gene correction strategy potentially applicable to most WAS patients by employing nuclease-mediated,site-specific integration of a corrective WAS gene sequence into the endogenous WAS chromosomal locus. In this study,we demonstrate the ability to target the integration of WAS 2-12 -containing constructs into intron 1 of the endogenous WAS gene of primary CD34 + hematopoietic stem and progenitor cells (HSPCs),as well as WASp-deficient B cell lines and WASp-deficient primary T cells. This intron 1 targeted integration (TI) approach proved to be quite efficient and restored WASp expression in treated cells. Furthermore,TI restored WASp-dependent function to WAS patient T cells. Edited CD34 + HSPCs exhibited the capacity for multipotent differentiation to various hematopoietic lineages in vitro and in transplanted immunodeficient mice. This methodology offers a potential editing approach for treatment of WAS using patient’s CD34 + cells. View Publication

Autophagy-based targeted degradation offers a powerful complement to proteasomal degradation leveraging the capacity and versatility of lysosomes to degrade complex cargo. However,it remains unclear which components of the autophagy-lysosomal pathway are most effective for targeted degradation. Here,we describe two orthogonal induced-proximity strategies to identify autophagy effectors capable of degrading organelles and soluble targets. Recruitment of autophagy cargo receptors,ATG8-like proteins,or the kinases ULK1 and TBK1 is sufficient to trigger mitophagy,while only autophagy cargo receptors capable of self-oligomerization degrade soluble cytosolic proteins. We further report a single-domain antibody against p62 and its use as a heterobifunctional degrader to clear mitochondria. Fusing the p62 single-domain antibody to PINK1 enables selective targeting of damaged mitochondria. Our study highlights the importance of avidity for targeted autophagy and suggests that autophagy cargo receptors are attractive entry points for the development of heterobifunctional degraders for organelles or protein aggregates. Using proximity-based screening,protein engineering,and structural analysis,this study describes the development of a p62-based biodegrader for the clearance of organelles and aggregated proteins by autophagy-targeted degradation. View Publication

Botulinum neurotoxins (BoNTs) inhibit cholinergic synaptic transmission by specifically cleaving proteins that are crucial for neurotransmitter exocytosis. Due to the lethality of these toxins,there are elevated concerns regarding their possible use as bioterrorism agents. Moreover,their widespread use for cosmetic purposes,and as medical treatments,has increased the potential risk of accidental overdosing and environmental exposure. Hence,there is an urgent need to develop novel modalities to counter BoNT intoxication. Mammalian motoneurons are the main target of BoNTs; however,due to the difficulty and poor efficiency of the procedures required to isolate the cells,they are not suitable for high-throughput drug screening assays. Here,we explored the suitability of embryonic stem (ES) cell-derived motoneurons as a renewable,reproducible,and physiologically relevant system for BoNT studies. We found that the sensitivity of ES-derived motoneurons to BoNT/A intoxication is comparable to that of primary mouse spinal motoneurons. Additionally,we demonstrated that several BoNT/A inhibitors protected SNAP-25,the BoNT/A substrate,in the ES-derived motoneuron system. Furthermore,this system is compatible with immunofluorescence-based high-throughput studies. These data suggest that ES-derived motoneurons provide a highly sensitive system that is amenable to large-scale screenings to rapidly identify and evaluate the biological efficacies of novel therapeutics. View Publication

Throughout its history,chronic myeloid leukemia (CML) has set precedents for cancer research and therapy. These range from the identification of the first specific chromosomal abnormality associated with cancer to the development of imatinib as a specific,targeted therapy for the disease. The successful development of imatinib as a therapeutic agent for CML can be attributed directly to decades of scientific discoveries. These discoveries determined that the BCR-ABL tyrosine kinase is the critical pathogenetic event in CML and an ideal target for therapy. This was confirmed in clinical trials of imatinib,with imatinib significantly improving the long-term survival of patients with CML. Continuing in this tradition of scientific discoveries leading to improved therapies,the understanding of resistance to imatinib has rapidly led to strategies to circumvent resistance. Continued studies of hematologic malignancies will allow this paradigm of targeting molecular pathogenetic events to be applied to many additional hematologic cancers. View Publication

More recently,reprogramming of somatic cells to an embryonic stem cell-like state presents a milestone in the realm of stem cells,making it possible to derive all cell types from any patients bearing specific genetic mutations. With the development of induced pluripotent stem (iPS) cells,we are now able to use the derivatives of iPS cells to study the mechanisms of disease and to perform drug screening and toxicology testing. In addition,differentiated iPS cells are now close to be used in clinical practice. Here we review the progress of iPS technique and the possible application in the area of Parkinson's disease treatment. View Publication

Human amnion epithelial cells (hAECs) are a heterologous population positive for stem cell markers; they display multilineage differentiation potential,differentiating into cells of the endoderm (liver,lung epithelium),mesoderm (bone,fat),and ectoderm (neural cells). They have a low immunogenic profile and possess potent immunosuppressive properties. Hence,hAECs may be a valuable source of cells for cell therapy. This unit describes an efficient and effective method of hAEC isolation,culture,and cryopreservation that is animal product-free and in accordance with current guidelines on preparation of cells for clinical use. Cells isolated using this method were characterized after 5 passages by analysis of karyotype,cell cycle distribution,and changes in telomere length. The differentiation potential of hAECs isolated using this animal product-free method was demonstrated by differentiation into lineages of the three primary germ layers and expression of lineage-specific markers analyzed by PCR,immunocytochemistry,and histology. View Publication

This protocol describes a strategy for the generation of 3D prostate organoid cultures from healthy mouse and human prostate cells (either bulk or FACS-sorted single luminal and basal cells),metastatic prostate cancer lesions and circulating tumor cells. Organoids derived from healthy material contain the differentiated luminal and basal cell types,whereas organoids derived from prostate cancer tissue mimic the histology of the tumor. We explain how to establish these cultures in the fully defined serum-free conditioned medium that is required to sustain organoid growth. Starting with the plating of digested tissue material,full-grown organoids can usually be obtained in ∼2 weeks. The culture protocol we describe here is currently the only one that allows the growth of both the luminal and basal prostatic epithelial lineages,as well as the growth of advanced prostate cancers. Organoids established using this protocol can be used to study many different aspects of prostate biology,including homeostasis,tumorigenesis and drug discovery. View Publication

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