技术资料

Increasing evidence supports the importance of cell extrinsic regulation in stem cell fate control. Hematopoietic stem cells (HSC) are responsive to local signals from their niche and to systemic feedback from progenitors and mature cells. The Notch ligand Delta-1 (DL1),a key component of the stem cell niche,regulates human hematopoietic lineage development in a dose-dependent manner and has been used clinically for primitive progenitor expansion. How DL1 acts to regulate HSC fate and whether these actions are related to its lineage skewing effects are poorly understood. Here we demonstrate that,although DL1 activates signal transducer and activator of transcription 3 signaling similarly to the gp130-activating cytokine interleukin-6 (IL-6),it has opposite effects on myeloid cell production. Mechanistically,these different outcomes are attributable to a DL1-mediated reduction in membrane (m)-bound IL-6 receptor (R) expression,converting progenitor cells from being directly IL-6 responsive to requiring both IL-6 and soluble (s) IL-6R for activation. Concomitant reduction of both mIL-6R (by DL1 supplementation) and sIL-6R (using dynamically fed cultures) reduced myeloid cell production and led to enhanced outputs of human HSCs. This work describes a new mode of cytokine action in which DL1 changes cytokine receptor distributions on hematopoietic cells,altering feedback networks and their impact on stem cell fate. View Publication

Experiments were conducted to isolate and characterize the gene and gene product of a human hematopoietic colony-stimulating factor with pluripotent biological activities. This factor has the ability to induce differentiation of a murine myelomonocytic leukemia cell line WEHI-3B(D+) and cells from patients with newly diagnosed acute nonlymphocytic leukemia (ANLL). A complementary DNA copy of the gene encoding a pluripotent human granulocyte colony-stimulating factor (hG-CSF) was cloned and expressed in Escherichia coli. The recombinant form of hG-CSF is capable of supporting neutrophil proliferation in a CFU-GM assay. In addition,recombinant hG-CSF can support early erythroid colonies and mixed colony formation. Competitive binding studies done with 125I-labeled hG-CSF and cell samples from two patients with newly diagnosed human leukemias as well as WEHI-3B(D+) cells showed that one of the human leukemias (ANLL,classified as M4) and the WEHI-3B(D+) cells have receptors for hG-CSF. Furthermore,the murine WEHI-3B(D+) cells and human leukemic cells classified as M2,M3,and M4 were induced by recombinant hG-CSF to undergo terminal differentiation to macrophages and granulocytes. The secreted form of the protein produced by the bladder carcinoma cell line 5637 was found to be O-glycosylated and to have a molecular weight of 19,600. View Publication

Elotuzumab is a monoclonal antibody in development for multiple myeloma (MM) that targets CS1,a cell surface glycoprotein expressed on MM cells. In preclinical models,elotuzumab exerts anti-MM efficacy via natural killer (NK)-cell-mediated antibody-dependent cellular cytotoxicity (ADCC). CS1 is also expressed at lower levels on NK cells where it acts as an activating receptor. We hypothesized that elotuzumab may have additional mechanisms of action via ligation of CS1 on NK cells that complement ADCC activity. Herein,we show that elotuzumab appears to induce activation of NK cells by binding to NK cell CS1 which promotes cytotoxicity against CS1(+) MM cells but not against autologous CS1(+) NK cells. Elotuzumab may also promote CS1-CS1 interactions between NK cells and CS1(+) target cells to enhance cytotoxicity in a manner independent of ADCC. NK cell activation appears dependent on differential expression of the signaling intermediary EAT-2 which is present in NK cells but absent in primary,human MM cells. Taken together,these data suggest elotuzumab may enhance NK cell function directly and confer anti-MM efficacy by means beyond ADCC alone. View Publication

Two monoclonal antibodies,BA16 and BA17,have been developed using a detergent-insoluble extract of human mammary epithelial organoids as immunogen. Indirect immunofluorescent staining of cultured cells showed that the component reacting with the antibodies was filamentous and the intensity of staining was stronger in mitotic cells. Immunoblotting of cell extracts showed that both antibodies react with only one band of 40 X 10(3) molecular weight,which was present in keratin-enriched extracts of cells or organoids. Furthermore,the tissue distribution of the component reacting with the antibodies was that predicted for human keratin 19. The antibodies showed differences in the intensity of staining of cells or tissue sections fixed and prepared in different ways indicating that they reacted with different epitopes. The pattern of expression of the 40 X 10(3) Mr keratin by normal mammary epithelial cells was investigated by immunoperoxidase staining of tissue sections,cultured milk cells,and organoids of different sizes cultured in collagen gels. It was found that basal or myoepithelial cells did not express this keratin. Some heterogeneity of expression of this component was seen in luminal epithelial cells,found almost exclusively in the smaller structures. These cells did,however,express other keratins characteristic of luminal cells. The distribution in the mammary tree of the luminal cells that did not express the 40 X 10(3) Mr keratin appears to be similar to that expected for cells with the proliferative potential to produce new terminal ductal lobular units or an increase in branching of existing terminal ductal lobular units. It is shown that these cells have considerable proliferative potential by the fact that they form large colonies in milk cell cultures. View Publication

A prerequisite for the realization of human pluripotent stem cell (hPSC) therapies is the development of bioprocesses for generating clinically relevant quantities of undifferentiated hPSCs and their derivatives under xeno-free conditions. Microcarrier stirred-suspension bioreactors are an appealing modality for the scalable expansion and directed differentiation of hPSCs. Comparative analyses of commercially available microcarriers clearly show the need for developing synthetic substrates supporting the adhesion and growth of hPSCs in three-dimensional cultures under agitation-induced shear. Moreover,the low seeding efficiencies during microcarrier loading with hPSC clusters poses a significant process bottleneck. To that end,a novel protocol was developed increasing hPSC seeding efficiency from 30% to over 80% and substantially shortening the duration of microcarrier loading. Importantly,this method was combined with the engineering of polystyrene microcarriers by surface conjugation of a vitronectin-derived peptide,which was previously shown to support the growth of human embryonic stem cells. Cells proliferated on peptide-conjugated beads in static culture but widespread detachment was observed after exposure to stirring. This prompted additional treatment of the microcarriers with a synthetic polymer commonly used to enhance cell adhesion. hPSCs were successfully cultivated on these microcarriers in stirred suspension vessels for multiple consecutive passages with attachment efficiencies close to 40%. Cultured cells exhibited on average a 24-fold increase in concentration per 6-day passage,over 85% viability,and maintained a normal karyotype and the expression of pluripotency markers such as Nanog,Oct4,and SSEA4. When subjected to spontaneous differentiation in embryoid body cultures or directed differentiation to the three embryonic germ layers,the cells adopted respective fates displaying relevant markers. Lastly,engineered microcarriers were successfully utilized for the expansion and differentiation of hPSCs to mesoderm progeny in stirred suspension vessels. Hence,we demonstrate a strategy for the facile engineering of xeno-free microcarriers for stirred-suspension cultivation of hPSCs. Our findings support the use of microcarrier bioreactors for the scalable,xeno-free propagation and differentiation of human stem cells intended for therapies. View Publication

A growth factor that is mitogenic for vascular endothelial cells,with an ED50 of approximately 1 ng/ml,has been purified 170,000-fold to apparent homogeneity from tissue culture medium conditioned by a rat glioma-derived cell line. The pure protein is a 46-kDa dimer composed of two subunits of equivalent mass as established by comparison of migration in SDS/polyacrylamide gels with and without prior reduction. This glioma-derived growth factor is a glycoprotein and is not mitogenic for BALB/c 3T3 fibroblasts,properties that further distinguish it from other well-characterized vascular endothelial cell mitogens. In contrast to acidic and basic fibroblast growth factors and to platelet-derived endothelial cell growth factor,which have no secretory leader sequences and might only be released by leakage from damaged cells,the glycoprotein nature of this mitogen implies that it is processed through the glycosylating secretory pathway. This secretable growth factor could,therefore,be readily available in the extracellular space under normal physiological conditions in vivo to promote vascular endothelial cell proliferation associated with blood-vessel growth and maintenance. View Publication

BACKGROUND Central to appropriate thrombin formation at sites of vascular injury is the concerted assembly of plasma- and/or platelet-derived factor (F) Va and FXa on the activated platelet surface. While the plasma-derived procofactor,FV,must be proteolytically activated by α-thrombin to FVa to function in prothrombinase,the platelet molecule is released from α-granules in a partially activated state,obviating the need for proteolytic activation. OBJECTIVES The current study was performed to test the hypothesis that subsequent to its endocytosis by megakaryocytes,plasma-derived FV is proteolytically processed to form the platelet-derived pool. METHODS & RESULTS Subsequent to FV endocytosis,a time-dependent increase in FV proteolytic products was observed in megakaryocyte lysates by SDS-PAGE followed by phosphorimaging or western blotting. This cleavage was specific and resulted in the formation of products similar in size to FV/Va present in a platelet lysate as well as to the α-thrombin-activated FVa heavy chain and light chain,and their respective precursors. Other proteolytic products were unique to endocytosed FV. The product/precursor relationships of these fragments were defined using anti-FV heavy and light chain antibodies with defined epitopes. Activity measurements indicated that megakaryocyte-derived FV fragments exhibited substantial FVa cofactor activity that was comparable to platelet-derived FV/Va. CONCLUSIONS Taken together,these observations suggest that prior to its packaging in α-granules endocytosed FV undergoes proteolysis by one or more specific megakaryocyte protease(s) to form the partially activated platelet-derived pool. View Publication

Growth factor signaling pathways are tightly regulated by phosphorylation and include many important kinase targets of interest for drug discovery. Small molecule inhibitors of the bone morphogenetic protein (BMP) receptor kinase ALK2 (ACVR1) are needed urgently to treat the progressively debilitating musculoskeletal disease fibrodysplasia ossificans progressiva (FOP). Dorsomorphin analogues,first identified in zebrafish,remain the only BMP inhibitor chemotype reported to date. By screening an assay panel of 250 recombinant human kinases we identified a highly selective 2-aminopyridine-based inhibitor K02288 with in vitro activity against ALK2 at low nanomolar concentrations similar to the current lead compound LDN-193189. K02288 specifically inhibited the BMP-induced Smad pathway without affecting TGF-β signaling and induced dorsalization of zebrafish embryos. Comparison of the crystal structures of ALK2 with K02288 and LDN-193189 revealed additional contacts in the K02288 complex affording improved shape complementarity and identified the exposed phenol group for further optimization of pharmacokinetics. The discovery of a new chemical series provides an independent pharmacological tool to investigate BMP signaling and offers multiple opportunities for pre-clinical development. View Publication

Developing novel therapies that suppress self-renewal of leukemia stem cells may reduce the likelihood of relapses and extend long-term survival of patients with acute myelogenous leukemia (AML). AML1-ETO (AE) is an oncogene that plays an important role in inducing self-renewal of hematopoietic stem/progenitor cells (HSPCs),leading to the development of leukemia stem cells. Previously,using a zebrafish model of AE and a whole-organism chemical suppressor screen,we have discovered that AE induces specific hematopoietic phenotypes in embryonic zebrafish through a cyclooxygenase (COX)-2 and β-catenin-dependent pathway. Here,we show that AE also induces expression of the Cox-2 gene and activates β-catenin in mouse bone marrow cells. Inhibition of COX suppresses β-catenin activation and serial replating of AE(+) mouse HSPCs. Genetic knockdown of β-catenin also abrogates the clonogenic growth of AE(+) mouse HSPCs and human leukemia cells. In addition,treatment with nimesulide,a COX-2 selective inhibitor,dramatically suppresses xenograft tumor formation and inhibits in vivo progression of human leukemia cells. In summary,our data indicate an important role of a COX/β-catenin-dependent signaling pathway in tumor initiation,growth,and self-renewal,and in providing the rationale for testing potential benefits from common COX inhibitors as a part of AML treatments. View Publication

Bone remodeling,a physiological process characterized by bone formation by osteoblasts (OBs) and resorption of preexisting bone matrix by osteoclasts (OCs),is vital for the maintenance of healthy bone tissue in adult humans. Imbalances in this vital process result in pathological conditions including osteoporosis. Owing to its initial asymptomatic nature,osteoporosis is often detected only after the patient has sustained significant bone loss or a fracture. Hence,anabolic therapeutics that stimulate bone accrual is in high clinical demand. Here we identify Ca²�?�/calmodulin (CaM)-dependent protein kinase kinase 2 (CaMKK2) as a potential target for such therapeutics because its inhibition enhances OB differentiation and bone growth and suppresses OC differentiation. Mice null for CaMKK2 possess higher trabecular bone mass in their long bones,along with significantly more OBs and fewer multinuclear OCs. In vitro,although Camkk2�?�/�?� mesenchymal stem cells (MSCs) yield significantly higher numbers of OBs,bone marrow cells from Camkk2�?�/�?� mice produce fewer multinuclear OCs. Acute inhibition of CaMKK2 by its selective,cell-permeable pharmacological inhibitor STO-609 also results in increased OB and diminished OC formation. Further,we find phospho-protein kinase A (PKA) and Ser¹³³ phosphorylated form of cyclic adenosine monophosphate (cAMP) response element binding protein (pCREB) to be markedly elevated in OB progenitors deficient in CaMKK2. On the other hand,genetic ablation of CaMKK2 or its pharmacological inhibition in OC progenitors results in reduced pCREB as well as significantly reduced levels of its transcriptional target,nuclear factor of activated T cells,cytoplasmic (NFATc1). Moreover,in vivo administration of STO-609 results in increased OBs and diminished OCs,conferring significant protection from ovariectomy (OVX)-induced osteoporosis in adult mice. Overall,our findings reveal a novel function for CaMKK2 in bone remodeling and highlight the potential for its therapeutic inhibition as a valuable bone anabolic strategy that also inhibits OC differentiation in the treatment of osteoporosis. View Publication