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

Intestinal tuft cells are one of 4 secretory cell linages in the small intestine and the source of IL-25,a critical initiator of the type 2 immune response to parasite infection. When Raptor,a critical scaffold protein for mammalian target of rapamycin complex 1 (mTORC1),was acutely deleted in intestinal epithelium via Tamoxifen injection in Tritrichomonas muris (Tm) infected mice,tuft cells,IL-25 in epithelium and IL-13 in the mesenchyme were significantly reduced,but Tm burden was not affected. When Tm infected mice were treated with rapamycin,DCLK1 and IL-25 expression in enterocytes and IL-13 expression in mesenchyme were diminished. After massive small bowel resection,tuft cells and Tm were diminished due to the diet used postoperatively. The elimination of Tm and subsequent re-infection of mice with Tm led to type 2 immune response only in WT,but Tm colonization in both WT and Raptor deficient mice. When intestinal organoids were stimulated with IL-4,tuft cells and IL-25 were induced in both WT and Raptor deficient organoids. In summary,our study reveals that enterocyte specific Raptor is required for initiating a type 2 immune response which appears to function through the regulation of mTORC1 activity. View Publication

The activating receptor NKG2D,expressed by natural killer (NK) cells and CD8(+) T cells,has a role in the specific killing of transformed cells. We examined NKG2D expression in patients with glioblastoma multiforme and found that NKG2D was downregulated on NK cells and CD8(+) T cells. Expression of NKG2D on lymphocytes significantly increased following tumor resection and correlated with an increased ability to kill NKG2D ligand-positive tumor targets. Despite the presence of soluble NKG2D ligands in the sera of glioblastoma patients,NKG2D downregulation was primarily caused by tumor-derived tumor growth factor-beta,suggesting that blocking of this cytokine may have therapeutic benefit. View Publication

Cells demonstrate plasticity following injury,but the extent of this phenomenon and the cellular mechanisms involved remain underexplored. Using single-cell RNA sequencing (scRNA-seq) and lineage tracing,we uncover that myoepithelial cells (MECs) of the submucosal glands (SMGs) proliferate and migrate to repopulate the airway surface epithelium (SE) in multiple injury models. Specifically,SMG-derived cells display multipotency and contribute to basal and luminal cell types of the SMGs and SE. Ex vivo expanded MECs have the potential to repopulate and differentiate into SE cells when grafted onto denuded airway scaffolds. Significantly,we find that SMG-like cells appear on the SE of both extra- and intra-lobular airways of large animal lungs following severe injury. We find that the transcription factor SOX9 is necessary for MEC plasticity in airway regeneration. Because SMGs are abundant and present deep within airways,they may serve as a reserve cell source for enhancing human airway regeneration. View Publication

A proposed strategy to cure HIV uses latency-reversing agents (LRAs) to reactivate latent proviruses for purging HIV reservoirs. A variety of LRAs have been identified,but none has yet proven effective in reducing the reservoir size in vivo. Nanocarriers could address some major challenges by improving drug solubility and safety,providing sustained drug release,and simultaneously delivering multiple drugs to target tissues and cells. Here,we formulated hybrid nanocarriers that incorporate physicochemically diverse LRAs and target lymphatic CD4+ T cells. We identified one LRA combination that displayed synergistic latency reversal and low cytotoxicity in a cell model of HIV and in CD4+ T cells from virologically suppressed patients. Furthermore,our targeted nanocarriers selectively activated CD4+ T cells in nonhuman primate peripheral blood mononuclear cells as well as in murine lymph nodes,and substantially reduced local toxicity. This nanocarrier platform may enable new solutions for delivering anti-HIV agents for an HIV cure. View Publication

BACKGROUND It is clinically important to maintain high viability and potency of umbilical cord blood units (CBUs) for transplantation during thawing. In the absence of a standard thawing protocol,this study was designed to develop one based on the consensus practice of transplant centers and address the shortage of dextran 40 thawing solution. STUDY DESIGN AND METHODS Frozen CBU aliquots were thawed using dextran 40 thawing solution while manipulating temperature and volume of diluent and mode of dilution. The effects of these on CD45+ and CD34+ cell viability were measured through annexin V and SYTOX green staining. The developed protocol was then used to compare dextran 40 and PLASMA-LYTE A thawing solutions and finally tested on whole CBUs. RESULTS Step-by-step investigations resulted in the development of a protocol that thaws and dilutes CBUs with room temperature diluent to five times the original volume using two sequential dilutions separated by equilibration times. PLASMA-LYTE A diluent provided superior viability of CD45+ and CD34+ cells than dextran 40 and recovered more colony-forming units. However,both diluents were equally effective in maintaining stability of the thawed CBU for 4 hours. Moreover,the stem cell-enriched CD34+CD38- subpopulations appeared more resistant to cryoinjuries than their CD34+CD38+ counterpart. CONCLUSION The developed thawing protocol recovers viable CD45+ and CD34+ cells above the standard thresholds and maintains CBU potency. PLASMA-LYTE A for thawing solution proved to be an efficient alternative to dextran 40. Finally,greater dilution should be avoided to maintain the viability of CD45+ cells and maximize graft cell dose. View Publication

Myeloid Derived Suppressor Cells (MDSCs) play important roles in constituting the immune suppressive environment promoting cancer development and progression. They are consisted of a heterogeneous population of immature myeloid cells including polymorphonuclear MDSC (PMN-MDSC) and monocytes MDSC (M-MDSC) that are found in both the systemic circulation and in the tumor microenvironment (TME). While previous studies had shown that all-trans retinoic acid (ATRA) could induce MDSC differentiation and maturation,the very poor solubility and fast metabolism of the drug limited its applications as an immune-modulator for cancer immunotherapy. We aimed in this study to develop a drug encapsulated liposome formulation L-ATRA with sustained release properties and examined the immuno-modulation effects. We showed that the actively loaded L-ATRA achieved stable encapsulation and enabled controlled drug release and accumulation in the tumor tissues. In vivo administration of L-ATRA promoted the remodeling of the systemic immune homeostasis as well as the tumor microenvironment. They were found to promote MDSCs maturation into DCs and facilitate immune responses against cancer cells. When used as a single agent treatment,L-ATRA deterred tumor growth,but only in immune-competent mice. In mice with impaired immune functions,L-ATRA at the same dose was not effective. When combined with checkpoint inhibitory agents,L-ATRA resulted in greater anti-cancer activities. Thus,L-ATRA may present a new IO strategy targeting the MDSCs that needs be further explored for improving the immunotherapy efficacy in cancer. View Publication

Rationale: IgA can induce activation of neutrophils which are the most abundant cell type in blood,but the development of IgA as therapeutic has been confounded by its short half-life and a weak ability to recruit NK cells as effector cells. Therefore,we generated an X-shaped antibody (X-body) based on the principle of molecular self-assembly that combines the activities of both IgG and IgA,which can effectively recruit and activate NK cells,macrophages,and neutrophils to kill tumor cells. Methods: X-body was generated by using a self-assembly strategy. The affinity of the X-body with the antigen and Fc receptors was tested by surface plasmon resonance. The shape of X-body was examined using negative staining transmission electron microscopy. The tumor cell killing activity of X-body was assessed in vitro and in multiple syngeneic mouse models. To explore the mechanism of X-body,tumor-infiltrating immune cells were analyzed by single-cell RNA-seq and flow cytometry. The dependence of neutrophil,macrophage,and NK cells for the X-body efficacy was confirmed by in vivo depletion of immune cell subsets. Results: The X-body versions of rituximab and trastuzumab combined the full spectrum activity of IgG and IgA and recruited NK cells,macrophages,and neutrophils as effector cells for eradication of tumor cells. Treatment with anti-hCD20 and anti-hHER2 X-bodies leads to a greater reduction in tumor burden in tumor-bearing mice compared with the IgA or IgG counterpart,and no obvious adverse effect is observed upon X-body treatment. Moreover,the X-body has a serum half-life and drug stability comparable to IgG. Conclusions: The X-body,as a myeloid-cell-centered therapeutic strategy,holds promise for the development of more effective cancer-targeting therapies than the current state of the art. View Publication

The application of genome-wide expression analysis to a large-scale,multicentered program in critically ill patients poses a number of theoretical and technical challenges. We describe here an analytical and organizational approach to a systematic evaluation of the variance associated with genome-wide expression analysis specifically tailored to study human disease. We analyzed sources of variance in genome-wide expression analyses performed with commercial oligonucleotide arrays. In addition,variance in gene expression in human blood leukocytes caused by repeated sampling in the same subject,among different healthy subjects,among different leukocyte subpopulations,and the effect of traumatic injury,were also explored. We report that analytical variance caused by sample processing was acceptably small. Blood leukocyte gene expression in the same individual over a 24-h period was remarkably constant. In contrast,genome-wide expression varied significantly among different subjects and leukocyte subpopulations. Expectedly,traumatic injury induced dramatic changes in apparent gene expression that were greater in magnitude than the analytical noise and interindividual variance. We demonstrate that the development of a nation-wide program for gene expression analysis with careful attention to analytical details can reduce the variance in the clinical setting to a level where patterns of gene expression are informative among different healthy human subjects,and can be studied with confidence in human disease. View Publication

BAFF plays a central role in B-lineage cell biology; however,the regulation of BAFF-binding receptor (BBR) expression during B cell activation and differentiation is not completely understood. In this study,we provide a comprehensive ex vivo analysis of BBRs in human B-lineage cells at various stages of maturation,as well as describe the events that drive and regulate receptor expression. Our data reveal that B-lineage cells ranging from naive to plasma cells (PCs),excluding bone marrow PCs,express BAFF-R uniformly. In contrast,only tonsillar memory B cells (MB) and PCs,from both tonsil and bone marrow tissues,express BCMA. Furthermore,we show that TACI is expressed by MB cells and PCs,as well as a subpopulation of activated CD27(neg) B cells. In this regard,we demonstrate that TACI is inducible early upon B cell activation and this is independent of B cell turnover. In addition,we found that TACI expression requires activation of the ERK1/2 pathway,since its expression was blocked by ERK1/2-specific inhibitors. Expression of BAFF-R and B cell maturation Ag (BCMA) is also highly regulated and we demonstrate that BCMA expression is only acquired in MB cells and in a manner accompanied by loss of BAFF-R expression. This inverse expression coincides with MB cell differentiation into Ig-secreting cells (ISC),since blocking differentiation inhibited both induction of BCMA expression and loss of BAFF-R. Collectively,our data suggest that the BBR profile may serve as a footprint of the activation history and stage of differentiation of normal human B cells. View Publication

Gastric diseases,including peptic ulcer disease and gastric cancer,affect 10% of the world's population and are largely due to chronic Helicobacter pylori infection. Species differences in embryonic development and architecture of the adult stomach make animal models suboptimal for studying human stomach organogenesis and pathogenesis,and there is no experimental model of normal human gastric mucosa. Here we report the de novo generation of three-dimensional human gastric tissue in vitro through the directed differentiation of human pluripotent stem cells. We show that temporal manipulation of the FGF,WNT,BMP,retinoic acid and EGF signalling pathways and three-dimensional growth are sufficient to generate human gastric organoids (hGOs). Developing hGOs progressed through molecular and morphogenetic stages that were nearly identical to the developing antrum of the mouse stomach. Organoids formed primitive gastric gland- and pit-like domains,proliferative zones containing LGR5-expressing cells,surface and antral mucous cells,and a diversity of gastric endocrine cells. We used hGO cultures to identify novel signalling mechanisms that regulate early endoderm patterning and gastric endocrine cell differentiation upstream of the transcription factor NEUROG3. Using hGOs to model pathogenesis of human disease,we found that H. pylori infection resulted in rapid association of the virulence factor CagA with the c-Met receptor,activation of signalling and induction of epithelial proliferation. Together,these studies describe a new and robust in vitro system for elucidating the mechanisms underlying human stomach development and disease. View Publication

Since the first report of derivation of human embryonic stem cell (hESC) lines in 1998,many progresses have been achieved to reliably and efficiently derive,maintain,and differentiate this therapeutically promising cell type. This chapter introduces some basic and widely recognized methods that we use in our hESC core laboratory. Specifically,it includes methods for (1) deriving hESC lines without using enzyme and antibody to isolate the inner cell mass; (2) sustaining hESC self-renewal under feeder-dependent,feeder-conditioned,and defined conditions as well as pluripotency validation and quality control assays; and (3) inducing hESC differentiation to trophoblast with BMP4. View Publication