技术资料

Epithelial tissues sheath organs and electro-mechanically regulate ion and water transport to regulate development,homeostasis,and hydrostatic organ pressure. Here,we demonstrate how external electrical stimulation allows us to control these processes in living tissues. Specifically,we electrically stimulate hollow,3D kidneyoids and gut organoids and find that physiological-strength electrical stimulation of ? 5 - 10 V/cm powerfully inflates hollow tissues; a process we call electro-inflation. Electro-inflation is mediated by increased ion flux through ion channels/transporters and triggers subsequent osmotic water flow into the lumen,generating hydrostatic pressure that competes against cytoskeletal tension. Our computational studies suggest that electro-inflation is strongly driven by field-induced ion crowding on the outer surface of the tissue. Electrically stimulated tissues also break symmetry in 3D resulting from electrotaxis and affecting tissue shape. The ability of electrical cues to regulate tissue size and shape emphasizes the role and importance of the electrical micro-environment for living tissues. Electrical stimulation of hollow,3D kidney tissues causes these tissues to inflate and change shape. The authors call this process electro-inflation and connect it to electricity driving ions into the center of the tissues,causing water to follow by osmosis. View Publication

Mitochondrial dysfunction has been demonstrated to result in premature aging due to its effects on stem cells. Nevertheless,a full understanding of the role of mitochondrial bioenergetics through differentiation is still lacking. Here we show the bioenergetics profile of human stem cells of embryonic origin differentiating along the hepatic lineage. Our study reveals especially the transition between hepatic specification and hepatic maturation as dependent on mitochondrial respiration and demonstrates that even though differentiating cells are primarily dependent on glycolysis until induction of hepatocyte maturation,oxidative phosphorylation is essential at all stages of differentiation. View Publication

Primary systemic amyloidosis (AL) is a rare monoclonal plasma cell (PC) disorder characterized by the deposition of misfolded immunoglobulin (Ig) light chains (LC) in vital organs throughout the body. To our knowledge,no cell lines have ever been established from AL patients. Here we describe the establishment of the ALMC-1 and ALMC-2 cell lines from an AL patient. Both cell lines exhibit a PC phenotype and display cytokine-dependent growth. Using a comprehensive genetic approach,we established the genetic relationship between the cell lines and the primary patient cells,and we were also able to identify new genetic changes accompanying tumor progression that may explain the natural history of this patient's disease. Importantly,we demonstrate that free lambda LC secreted by both cell lines contained a beta structure and formed amyloid fibrils. Despite absolute Ig LC variable gene sequence identity,the proteins show differences in amyloid formation kinetics that are abolished by the presence of Na(2)SO(4). The formation of amyloid fibrils from these naturally secreting human LC cell lines is unprecedented. Moreover,these cell lines will provide an invaluable tool to better understand AL,from the combined perspectives of amyloidogenic protein structure and amyloid formation,genetics,and cell biology. View Publication

AIMS Pifithrin α (PFTα),an inhibitor of the p53 protein,is regarded as a lead compound for cancer and neurodegenerative disease therapy. There is some evidence that this compound activates the aryl hydrocarbon receptor (AhR) in a complete independent way of the p53 inhibition and that it is easily converted to its condensation product pifithrin β (PFTβ). The aim of this study was to explore the ability of PFTα and of PFTβ to induce a variety of AhR mediated processes. MAIN METHODS Computational analysis using quantum chemical calculations and chemical analysis have been used to study the conformation of the compounds as well as the cyclization reaction. The AhR mediated processes of these compounds have been studied in a rainbow trout cell line (RTG-2) and in a rat hepatoma cell line (H4IIE). KEY FINDINGS PFTα molecule could not take a planar conformation required for AhR activation whereas PFTβ showed a conformation similar to those of the prototypical AhR ligand β-naphthoflavone. In both cell lines,PFTα and PFTβ provoked different responses related with AhR activation. However,when cyclization of PFTα to PFTβ was hampered by acetylation of the exocyclic nitrogen,all these responses were not observed. These results lead to the conclusion that the activation of the AhR is probably caused by PFTβ instead of PFTα. SIGNIFICANCE Since PFTα is a promising compound for the development of new pharmaceuticals inhibiting p53,the chemical instability of this compound as well as the capacity of its transformation product should be taken into account. View Publication

PURPOSE: The Ras-Raf-mitogen-activated protein kinase kinase (MEK) pathway is overactive in many human cancers and is thus a target for novel therapeutics. We have developed a highly potent and selective inhibitor of MEK1/2. The purpose of these studies has been to show the biological efficacy of ARRY-142886 (AZD6244) in enzymatic,cellular,and animal models. EXPERIMENTAL DESIGN: The ability of ARRY-142886 to inhibit purified MEK1 as well as other kinases was evaluated. Its effects on extracellular signal-regulated kinase (ERK) phosphorylation and proliferation in several cell lines were also determined. Finally,the inhibitor was tested in HT-29 (colorectal) and BxPC3 (pancreatic) xenograft tumor models. RESULTS: The IC(50) of ARRY-142886 was determined to be 14 nmol/L against purified MEK1. This activity is not competitive with ATP,which is consistent with the high specificity of compound for MEK1/2. Basal and epidermal growth factor-induced ERK1/2 phosphorylation was inhibited in several cell lines as well as 12-O-tetradecanoylphorbol-13-acetate-induced ERK1/2 phosphorylation in isolated peripheral blood mononuclear cells. Treatment with ARRY-142886 resulted in the growth inhibition of several cell lines containing B-Raf and Ras mutations but had no effect on a normal fibroblast cell line. When dosed orally,ARRY-142886 was capable of inhibiting both ERK1/2 phosphorylation and growth of HT-29 xenograft tumors in nude mice. Tumor regressions were also seen in a BxPC3 xenograft model. In addition,tumors remained responsive to growth inhibition after a 7-day dosing holiday. CONCLUSIONS: ARRY-142886 is a potent and selective MEK1/2 inhibitor that is highly active in both in vitro and in vivo tumor models. This compound is currently being investigated in clinical studies. View Publication

The phosphatidylinositide 3-kinase pathway is frequently deregulated in human cancers and inhibitors offer considerable therapeutic potential. We previously described the promising tricyclic pyridofuropyrimidine lead and chemical tool compound PI-103. We now report the properties of the pharmaceutically optimized bicyclic thienopyrimidine derivatives PI-540 and PI-620 and the resulting clinical development candidate GDC-0941. All four compounds inhibited phosphatidylinositide 3-kinase p110alpha with IC(50) textless or = 10 nmol/L. Despite some differences in isoform selectivity,these agents exhibited similar in vitro antiproliferative properties to PI-103 in a panel of human cancer cell lines,with submicromolar potency in PTEN-negative U87MG human glioblastoma cells and comparable phosphatidylinositide 3-kinase pathway modulation. PI-540 and PI-620 exhibited improvements in solubility and metabolism with high tissue distribution in mice. Both compounds gave improved antitumor efficacy over PI-103,following i.p. dosing in U87MG glioblastoma tumor xenografts in athymic mice,with treated/control values of 34% (66% inhibition) and 27% (73% inhibition) for PI-540 (50 mg/kg b.i.d.) and PI-620 (25 mg/kg b.i.d.),respectively. GDC-0941 showed comparable in vitro antitumor activity to PI-103,PI-540,and PI-620 and exhibited 78% oral bioavailability in mice,with tumor exposure above 50% antiproliferative concentrations for textgreater8 hours following 150 mg/kg p.o. and sustained phosphatidylinositide 3-kinase pathway inhibition. These properties led to excellent dose-dependent oral antitumor activity,with daily p.o. dosing at 150 mg/kg achieving 98% and 80% growth inhibition of U87MG glioblastoma and IGROV-1 ovarian cancer xenografts,respectively. Together,these data support the development of GDC-0941 as a potent,orally bioavailable inhibitor of phosphatidylinositide 3-kinase. GDC-0941 has recently entered phase I clinical trials. View Publication

IL-3,IL-5,and GM-CSF are related hematopoietic cytoines that are important for allergic inflammation. The receptors for human IL-5,IL-3,and GM-CSF are members of the hematopoietin receptor superfamily and are comprised of a cytokine-specific alpha chain and the common beta chain that is shared among these cytokines for signaling. Each of these cytokines contributes to the differentiation and function of leukocyte subpopulations and have clinical importance in protective immunity and in the pathophysiology of a spectrum of immunologic diseases that are as diverse as allergy and asthma,pulmonary alveolar proteinosis,neurodegenerative diseases,and malignancies. Delineating the biology of these cytokines is enabling the development of new strategies for diagnosing and treating these diseases and modulating immune responses. View Publication

Myocardial infarction is a leading cause of mortality and morbidity worldwide,and current treatments fail to address the underlying scarring and cell loss,which is a major cause of heart failure after infarction. The novel strategy,therapeutic angiogenesis and/or vasculogenesis with endothelial progenitor cells transplantation holds great promise to increase blood flow in ischemic areas,thus rebuild the injured heart and reverse the heart failure. Given the potential of self-renewal and differentiation into virtually all cell types,human embryonic stem cells (hESCs) may provide an alternate source of therapeutic cells by allowing the derivation of large numbers of endothelial cells for therapeutic angiogenesis and/or vasculogenesis of ischemic heart diseases. Moreover,to fully understand the fate of implanted hESCs or hESC derivatives,investigators need to monitor the motility of cells in living animals over time. In this chapter,we describe the application of bioluminescence reporter gene imaging to track the transplanted hESC-derived endothelial cells for treatment of myocardial infarction. The technology of inducing endothelial cells from hESCs will also be discussed. View Publication

Human embryonic stem (hES) cells have a potential use for the repair and regeneration of injured tissues. However,teratoma formation can be a major obstacle for hES-mediated cell therapy. Therefore,tracking the fate and function of transplanted hES cells with noninvasive imaging could be valuable for a better understanding of the biology and physiology of teratoma formation. In this study,hES cells were stably transduced with a double fusion reporter gene consisting of firefly luciferase and enhanced green fluorescent protein. Following bioluminescence imaging and histology,we demonstrated that engraftment of hES cells was followed by dramatically increasing signaling and led to teratoma formation confirmed by histology. Studies of the angiogenic processes within teratomas revealed that their vasculatures were derived from both differentiated hES cells and host. Moreover,FACS analysis showed that teratoma cells derived from hES cells expressed high levels of CD56 and SSEA-4,and the subcultured SSEA-4(+) cells showed a similar cell surface marker expression pattern when compared to undifferentiated hES cells. We report here for the first time that SSEA-4(+) cells derived from teratoma exhibited multipotency,retained their differentiation ability in vivo as confirmed by their differentiation into representative three germ layers. View Publication

Extracellular vesicles (EVs) derived from human organoids are phospholipid bilayer-bound nanoparticles that carry therapeutic cargo. However,the low yield of EVs remains a critical bottleneck for clinical translation. Vertical-Wheel bioreactors (VWBRs),with unique design features,facilitate the scalable production of EVs secreted by human blood vessel organoids (BVOs) under controlled shear stress,using aggregate- and microcarrier-based culture systems. Human induced pluripotent stem cell-derived BVOs cultured as aggregates or on Synthemax II microcarriers within VWBRs (40 and 80 rpm) were compared to static controls. The organoids were characterized by metabolite profiling,flow cytometry,and gene expression of EV biogenesis markers. EVs were characterized by nanoparticle tracking analysis,electron microscopy,and Western blotting. Lipidomics provided insights into EV lipid composition,while functional assays assessed the impact of EVs in a D-galactose-induced senescence model. VWBR cultures showed more aerobic metabolism and higher expression of EV biogenesis genes compared to the static control. EVs from different conditions were comparable in size,but the yields were significantly higher for microcarrier and dynamic cultures than static aggregates. Lipidomic profiling revealed minimal variation (< 0.36%) in total lipid content; however,distinct differences were identified in lipid chain lengths and saturation levels,affecting key pathways such as sphingolipid and neurotrophin signaling. Human BVO EVs demonstrated the abilities of reducing oxidative stress and increasing cell proliferation in vitro. Human BVOs differentiated in VWBRs (in particular 40 rpm) produce 2–3 fold higher yield of EVs (per mL) than static control. The bio manufactured EVs from VWBRs have exosomal characteristics and therapeutic cargo,showing functional properties in in vitro assays. This innovative approach establishes VWBRs as a scalable platform for producing functional EVs with defined lipid profiles and therapeutic potential,paving the way for future in vivo studies. The online version contains supplementary material available at 10.1186/s13287-025-04317-2. View Publication

PURPOSE We aimed to assess the biologic activity of PF-03084014 in breast xenograft models. The biomarkers for mechanism and patient stratification were also explored. EXPERIMENTAL DESIGN The in vitro and in vivo properties of PF-03084014 were investigated. The mRNA expressions of 40 key Notch pathway genes at baseline or after treatment were analyzed to link with the antitumor efficacy of PF-03084014 in a panel of breast cancer xenograft models. RESULTS In vitro,PF-03084014 exhibited activity against tumor cell migration,endothelial cell tube formation,and mammosphere formation. In vivo,we observed apoptosis,antiproliferation,reduced tumor cell self-renewal ability,impaired tumor vasculature,and decreased metastasis activity after the treatment of PF-03084014. PF-03084014 treatment displayed significant antitumor activity in 10 of the 18 breast xenograft models. However,the antitumor efficacy in most models did not correlate with the in vitro antiproliferation results in the corresponding cell lines,suggesting the critical involvement of tumor microenvironment during Notch activation. In the tested breast xenograft models,the baseline expressions of the Notch receptors,ligands,and the cleaved Notch1 failed to predict the antitumor response to PF-03084014,whereas several Notch pathway target genes,including HEY2,HES4,and HES3,strongly corresponded with the response with a P value less than 0.01. Many of the best molecular predictors of response were also significantly modulated following PF-03084014 treatment. CONCLUSIONS PF-03084014 showed antitumor and antimetastatic properties via pleiotropic mechanisms. The Notch pathway downstream genes may be used to predict the antitumor activity of PF-03084014 and enrich for responders among breast cancer patients. View Publication

Behçet's disease (BD) is a chronic inflammatory and multisystemic autoimmune disease of unknown etiology. Due to the lack of a specific test for BD,its diagnosis is very difficult and therapeutic options are limited. Induced pluripotent stem cell (iPSC) technology,which provides inaccessible disease-relevant cell types,opens a new era for disease treatment. In this study,we generated BD iPSCs from patient somatic cells and differentiated them into hematopoietic precursor cells (BD iPSC-HPCs) as BD model cells. Based on comparative transcriptome analysis using our BD model cells,we identified eight novel BD-specific genes,AGTR2,CA9,CD44,CXCL1,HTN3,IL-2,PTGER4,and TSLP,which were differentially expressed in BD patients compared with healthy controls or patients with other immune diseases. The use of CXCL1 as a BD biomarker was further validated at the protein level using both a BD iPSC-HPC-based assay system and BD patient serum samples. Furthermore,we show that our BD iPSC-HPC-based drug screening system is highly effective for testing CXCL1 BD biomarkers,as determined by monitoring the efficacy of existing anti-inflammatory drugs. Our results shed new light on the usefulness of patient-specific iPSC technology in the development of a benchmarking platform for disease-specific biomarkers,phenotype- or target-driven drug discovery,and patient-tailored therapies. View Publication