技术资料

Three-dimensional (3D) culture systems have been developed that can re-capitulate organ level responses,simulate compound diffusion through complex structures,and assess cellular heterogeneity of tissues,making them attractive models for advanced in vitro research and discovery. Organoids are a unique subtype of 3D cell culture that are grown from stem cells,are self-organizing,and closely replicate in vivo pathophysiology. Organoids have been used to understand tissue development,model diseases,test drug sensitivity and toxicity,and advance regenerative medicine. However,traditional organoid culture methods are inadequate because they are low throughput and ill-suited for single organoid imaging,phenotypic assessment,and isolation from heterogenous organoid populations. To address these bottlenecks,we have adapted our tissue culture consumable and instrumentation to enable automated imaging,identification,and isolation of individual organoids. Organoids grown on the 3D CytoSort? Array can be reliably tracked,imaged,and phenotypically analyzed using brightfield and fluorescent microscopy as they grow over time,then released and transferred fully intact for use in downstream applications. Using mouse hepatic and pancreatic organoids,we have demonstrated the use of this technology for single-organoid imaging,clonal organoid generation,parent organoid subcloning,and single-organoid RNA extraction for downstream gene expression or transcriptomic analysis. The results validate the ability of the CellRaft AIR? System to facilitate efficient,user-friendly,and automated workflows broadly applicable to organoid research by overcoming several pain points: 1) single organoid time-course imaging and phenotypic assessment,2) establishment of single cell-derived organoids,and 3) isolation and retrieval of single organoids for downstream applications. View Publication

Microtubule-associated protein (MAP) 2 has been perceived as a static cytoskeletal protein enriched in neuronal dendritic shafts. Emerging evidence indicates dynamic functions for various MAPs in activity-dependent synaptic plasticity. However,it is unclear how MAP2 is associated with synaptic plasticity mechanisms. Here,we demonstrate that specific silencing of high-molecular-weight MAP2 in vivo abolished induction of long-term potentiation (LTP) in the Schaffer collateral pathway of CA1 pyramidal neurons and in vitro blocked LTP-induced surface delivery of AMPA receptors and spine enlargement. In mature hippocampal neurons,we observed rapid translocation of a subpopulation of MAP2,present in dendritic shafts,to spines following LTP stimulation. Time-lapse confocal imaging showed that spine translocation of MAP2 was coupled with LTP-induced spine enlargement. Consistently,immunogold electron microscopy revealed that LTP stimulation of the Schaffer collateral pathway promoted MAP2 labeling in spine heads of CA1 neurons. This translocation depended on NMDA receptor activation and Ras-MAPK signaling. Furthermore,LTP stimulation led to an increase in surface-expressed AMPA receptors specifically in the neurons with MAP2 spine translocation. Altogether,this study indicates a novel role for MAP2 in LTP mechanisms and suggests that MAP2 participates in activity-dependent synaptic plasticity in mature hippocampal networks. View Publication

Gene-of-interest knockout organoids present a powerful and versatile research tool to study a gene's effects on many biological and pathological processes. Here,we present a straightforward and broadly applicable protocol to generate gene knockouts in mouse organoids using CRISPR-Cas9 technology. We describe the processes of transient transfecting organoids with pre-assembled CRISPR-Cas9 ribonucleoprotein complexes,organoid cell sorting,and establishing clonal organoid culture pairs. We then detail how to confirm the knockout via Western blot analysis. View Publication

Age-related gastrointestinal decline contributes to whole-organism frailty and mortality. Genistein is known to have beneficial effects on age-related diseases,but its precise role in homeostasis of the aging gut remains to be elucidated. Here,wild-type aging mice and Zmpste24-/- progeroid mice were used to investigate the role of genistein in lifespan and homeostasis of the aging gut in mammals. A series of longitudinal,clinically relevant measurements were performed to evaluate the effect of genistein on healthspan. It was found that dietary genistein promoted a healthier and longer life and was associated with a decrease in the levels of systemic inflammatory cytokines in aging mice. Furthermore,dietary genistein ameliorated gut dysfunctions,such as intestinal inflammation,leaky gut,and impaired epithelial regeneration. A distinct genistein-mediated alteration in gut microbiota was observed by increasing Lachnospira abundance and short-chain fatty acid (SCFA) production. Further fecal microbiota transplantation and dirty cage sharing experiments indicated that the gut microbiota from genistein-fed mice rejuvenated the aging gut and extended the lifespan of progeroid mice. It was demonstrated that genistein-associated SCFAs alleviated tumor necrosis factor alpha-induced intestinal organoid damage. Moreover,genistein-associated propionate promoted regulatory T cell-derived interleukin 10 production,which alleviated macrophage-derived inflammation. This study provided the first data,to the authors' knowledge,indicating that dietary genistein modulates homeostasis in the aging gut and extends the healthspan and lifespan of aging mammals. Moreover,the existence of a link between genistein and the gut microbiota provides a rationale for dietary interventions against age-associated frailty. View Publication

The intestinal epithelial regeneration is driven by intestinal stem cells under homeostatic conditions. Differentiated intestinal epithelial cells,such as Paneth cells,are capable of acquiring multipotency and contributing to regeneration upon the loss of intestinal stem cells. Paneth cells also support intestinal stem cell survival and regeneration. We report here that depletion of an RNA-binding protein named polypyrimidine tract binding protein 1 (PTBP1) in mouse intestinal epithelial cells causes intestinal stem cell death and epithelial regeneration failure. Mechanistically,we show that PTBP1 inhibits neuronal-like splicing programs in intestinal crypt cells,which is critical for maintaining intestinal stem cell stemness. This function is achieved at least in part through promoting the non-productive splicing of its paralog PTBP2. Moreover,PTBP1 inhibits the expression of an AKT inhibitor PHLDA3 in Paneth cells and permits AKT activation,which presumably maintains Paneth cell plasticity and function in supporting intestinal stem cell niche. We show that PTBP1 directly binds to a CU-rich region in the 3' UTR of Phlda3,which we demonstrate to be critical for downregulating the mRNA and protein levels of Phlda3. Our results thus reveal the multifaceted in vivo regulation of intestinal epithelial regeneration by PTBP1 at the post-transcriptional level. View Publication

While readily achieved in cell lines,the application of CRISPR-Cas9 gene editing in human-derived organoids suffers from limited efficacy and complex protocols. Here,we describe a multi-guide RNA CRISPR-Cas9 gene-editing protocol which efficiently achieves complete gene knockout in adult human colonic organoids. This protocol also describes crucial steps including how to harvest patient tissue to maximize gene-editing efficacy and a technique to validate gene knockout following editing with immunofluorescent staining of the organoids against the target protein. View Publication

In cancer microenvironment,aberrant glycosylation events of ECM proteins and cell surface receptors occur. We developed a protocol to generate 3D bioprinted models of colorectal cancer (CRC) crosslinking hyaluronic acid and gelatin functionalized with three signalling glycans characterized in CRC,3'-Sialylgalactose,6'-Sialylgalactose and 2'-Fucosylgalactose. The crosslinking,performed exploiting azide functionalized gelatin and hyaluronic acid and 4arm-PEG-dibenzocyclooctyne,resulted in biocompatible hydrogels that were 3D bioprinted with commercial CRC cells HT-29 and patient derived CRC tumoroids. The glycosylated hydrogels showed good 3D printability,biocompatibility and stability over the time. SEM and synchrotron radiation SAXS/WAXS analysis revealed the influence of glycosylation in the construct morphology,whereas MALDI-MS imaging showed that protein profiles of tumoroid cells vary with glycosylation,indicating that sialylation and fucosylation of ECM proteins induce diverse alterations to the proteome of the tumoroid and surrounding cells. View Publication

Rapamycin analogs,temsirolimus and everolimus,are approved for the treatment of advance renal cell carcinoma (RCC). Currently approved agents inhibit mechanistic target of rapamycin (mTOR) complex 1 (mTORC1). However,the mTOR kinase exists in two distinct multiprotein complexes,mTORC1 and mTORC2,and both complexes may be critical regulators of cell metabolism,growth and proliferation. Furthermore,it has been proposed that drug resistance develops due to compensatory activation of mTORC2 signaling during treatment with temsirolimus or everolimus. We evaluated Ku0063794,which is a small molecule that inhibits both mTOR complexes. Ku0063794 was compared to temsirolimus in preclinical models for renal cell carcinoma. Ku0063794 was effective in inhibiting the phosphorylation of signaling proteins downstream of both mTORC1 and mTORC2,including p70 S6K,4E-BP1 and Akt. Ku0063794 was more effective than temsirolimus in decreasing the viability and growth of RCC cell lines,Caki-1 and 786-O,in vitro by inducing cell cycle arrest and autophagy,but not apoptosis. However,in a xenograft model there was no difference in the inhibition of tumor growth by Ku0063794 or temsirolimus. A potential explanation is that temsirolimus has additional effects on the tumor microenvironment. Consistent with this possibility,temsirolimus,but not Ku0063794,decreased tumor angiogenesis in vivo,and decreased the viability of HUVEC (Human Umbilical Vein Endothelial Cells) cells in vitro at pharmacologically relevant concentrations. Furthermore,expression levels of VEGF and PDGF were lower in Caki-1 and 786-O cells treated with temsirolimus than cells treated with Ku0063794. View Publication

Human neural stem cells hold great promise for research and therapy in neural disease. We describe the generation of integration-free and expandable human neural progenitor cells (NPCs). We combined an episomal system to deliver reprogramming factors with a chemically defined culture medium to reprogram epithelial-like cells from human urine into NPCs (hUiNPCs). These transgene-free hUiNPCs can self-renew and can differentiate into multiple functional neuronal subtypes and glial cells in vitro. Although functional in vivo analysis is still needed,we report that the cells survive and differentiate upon transplant into newborn rat brain. View Publication

UNLABELLED A noninvasive technology that indiscriminately detects tumor tissue in the brain could substantially enhance the management of primary or metastatic brain tumors. Although the documented molecular heterogeneity of diseases that initiate or eventually deposit in the brain may preclude identifying a single smoking-gun molecular biomarker,many classes of brain tumors are generally avid for transferrin. Therefore,we reasoned that applying a radiolabeled derivative of transferrin ((89)Zr-labeled transferrin) may be an effective strategy to more thoroughly identify tumor tissue in the brain,regardless of the tumor's genetic background. METHODS Transferrin was radiolabeled with (89)Zr,and its properties with respect to human models of glioblastoma multiforme were studied in vivo. RESULTS In this report,we show proof of concept that (89)Zr-labeled transferrin ((89)Zr-transferrin) localizes to genetically diverse models of glioblastoma multiforme in vivo. Moreover,we demonstrate that (89)Zr-transferrin can detect an orthotopic lesion with exceptional contrast. Finally,the tumor-to-brain contrast conferred by (89)Zr-transferrin vastly exceeded that observed with (18)F-FDG,currently the most widely used radiotracer to assess tumor burden in the brain. CONCLUSION The results from this study suggest that (89)Zr-transferrin could be a broadly applicable tool for identifying and monitoring tumors in the brain,with realistic potential for near-term clinical translation. View Publication

The specificities of nine approved tyrosine kinase inhibitors (imatinib,dasatinib,nilotinib,gefitinib,erlotinib,lapatinib,sorafenib,sunitinib,and pazopanib) were determined by activity-based kinase profiling using a large panel of human recombinant active kinases. This panel consisted of 79 tyrosine kinases,199 serine/threonine kinases,three lipid kinases,and 29 disease-relevant mutant kinases. Many potential targets of each inhibitor were identified by kinase profiling at the K(m) for ATP. In addition,profiling at a physiological ATP concentration (1 mm) was carried out,and the IC(50) values of the inhibitors against each kinase were compared with the estimated plasma-free concentration (calculated from published pharmacokinetic parameters of plasma C(trough) and C(max) values). This analysis revealed that the approved kinase inhibitors were well optimized for their target kinases. This profiling also implicates activity at particular off-target kinases in drug side effects. Thus,large-scale kinase profiling at both K(m) and physiological ATP concentrations could be useful in characterizing the targets and off-targets of kinase inhibitors. View Publication

The use of human pluripotent stem cells (hPSCs) in cell therapy is hindered by the tumorigenic risk from residual undifferentiated cells. Here we performed a high-throughput screen of over 52,000 small molecules and identified 15 pluripotent cell-specific inhibitors (PluriSIns),nine of which share a common structural moiety. The PluriSIns selectively eliminated hPSCs while sparing a large array of progenitor and differentiated cells. Cellular and molecular analyses demonstrated that the most selective compound,PluriSIn 1,induces ER stress,protein synthesis attenuation,and apoptosis in hPSCs. Close examination identified this molecule as an inhibitor of stearoyl-coA desaturase (SCD1),the key enzyme in oleic acid biosynthesis,revealing a unique role for lipid metabolism in hPSCs. PluriSIn 1 was also cytotoxic to mouse blastocysts,indicating that the dependence on oleate is inherent to the pluripotent state. Finally,application of PluriSIn 1 prevented teratoma formation from tumorigenic undifferentiated cells. These findings should increase the safety of hPSC-based treatments. ?? 2013 Elsevier Inc. View Publication