技术资料

Induced pluripotent stem cells (iPSC) and their differentiated derivatives offer a unique source of human primary cells for toxicity screens. Here,we report on the comparative cytotoxicity of 80 compounds (neurotoxicants,developmental neurotoxicants,and environmental compounds) in iPSC as well as isogenic iPSC-derived neural stem cells (NSC),neurons,and astrocytes. All compounds were tested over a 24-h period at 10 and 100$\$,in duplicate,with cytotoxicity measured using the MTT assay. Of the 80 compounds tested,50 induced significant cytotoxicity in at least one cell type; per cell type,32,38,46,and 41 induced significant cytotoxicity in iPSC,NSC,neurons,and astrocytes,respectively. Four compounds (valinomycin,3,3',5,5'-tetrabromobisphenol,deltamethrin,and triphenyl phosphate) were cytotoxic in all four cell types. Retesting these compounds at 1,10,and 100$\$ using the same exposure protocol yielded consistent results as compared with the primary screen. Using rotenone,we extended the testing to seven additional iPSC lines of both genders; no substantial difference in the extent of cytotoxicity was detected among the cell lines. Finally,the cytotoxicity assay was simplified by measuring luciferase activity using lineage-specific luciferase reporter iPSC lines which were generated from the parental iPSC line. This article is part of a Special Issue entitled SI: PSC and the brain. View Publication

Neuronal conversion from human fibroblasts can be induced by lineage-specific transcription factors; however,the introduction of ectopic genes limits the therapeutic applications of such induced neurons (iNs). Here,we report that human fibroblasts can be directly converted into neuronal cells by a chemical cocktail of seven small molecules,bypassing a neural progenitor stage. These human chemical-induced neuronal cells (hciNs) resembled hiPSC-derived neurons and human iNs (hiNs) with respect to morphology,gene expression profiles,and electrophysiological properties. This approach was further applied to generate hciNs from familial Alzheimer's disease patients. Taken together,our transgene-free and chemical-only approach for direct reprogramming of human fibroblasts into neurons provides an alternative strategy for modeling neurological diseases and for regenerative medicine. View Publication

Recently,direct reprogramming between divergent lineages has been achieved by the introduction of regulatory transcription factors. This approach may provide alternative cell resources for drug discovery and regenerative medicine,but applications could be limited by the genetic manipulation involved. Here,we show that mouse fibroblasts can be directly converted into neuronal cells using only a cocktail of small molecules,with a yield of up to textgreater90% being TUJ1-positive after 16 days of induction. After a further maturation stage,these chemically induced neurons (CiNs) possessed neuron-specific expression patterns,generated action potentials,and formed functional synapses. Mechanistically,we found that a BET family bromodomain inhibitor,I-BET151,disrupted the fibroblast-specific program,while the neurogenesis inducer ISX9 was necessary to activate neuron-specific genes. Overall,our findings provide a proof of principle" for chemically induced direct reprogramming of somatic cell fates across germ layers without genetic manipulation� View Publication

In an attempt to bring pluripotent stem cell biology closer to reaching its full potential,many groups have focused on improving reprogramming protocols over the past several years. The episomal modified Sendai virus-based vector has emerged as one of the most practical ones. Here we describe reprogramming of mesenchymal stromal/stem cells (MSC) derived from umbilical cord Wharton's Jelly into induced pluripotent stem cells (iPSC) using genome non-integrating Sendai virus-based vectors. The detailed protocols of iPSC colony cryopreservation (vitrification) and adaption to feeder-free culture conditions are also included. View Publication

Human pluripotent stem cells (hPSCs) are sensitive to DNA damage and undergo rapid apoptosis compared to their differentiated progeny cells. Here,we explore the underlying mechanisms for the increased apoptotic sensitivity of hPSCs that helps to determine pluripotent stem cell fate. Apoptosis was induced by exposure to actinomycin D,etoposide,or tunicamycin,with each agent triggering a distinct apoptotic pathway. We show that hPSCs are more sensitive to all three types of apoptosis induction than are lineage-non-specific,retinoic-acid-differentiated hPSCs. Also,Bax activation and pro-apoptotic mitochondrial intermembrane space protein release,which are required to initiate the mitochondria-mediated apoptosis pathway,are more rapid in hPSCs than in retinoic-acid-differentiated hPSCs. Surprisingly,Bak and not Bax is essential for actinomycin-D-induced apoptosis in human embryonic stem cells. Finally,P53 is degraded rapidly in an ubiquitin-proteasome-dependent pathway in hPSCs at steady state but quickly accumulates and induces apoptosis when Mdm2 function is impaired. Rapid degradation of P53 ensures the survival of healthy hPSCs but avails these cells for immediate apoptosis upon cellular damage by P53 stabilization. Altogether,we provide an underlying,interconnected molecular mechanism that primes hPSCs for quick clearance by apoptosis to eliminate hPSCs with unrepaired genome alterations and preserves organismal genomic integrity during the early critical stages of human embryonic development. View Publication

Induced pluripotent stem cells (iPSCs) are an essential tool for modeling how causal genetic variants impact cellular function in disease,as well as an emerging source of tissue for regenerative medicine. The preparation of somatic cells,their reprogramming and the subsequent verification of iPSC pluripotency are laborious,manual processes limiting the scale and reproducibility of this technology. Here we describe a modular,robotic platform for iPSC reprogramming enabling automated,high-throughput conversion of skin biopsies into iPSCs and differentiated cells with minimal manual intervention. We demonstrate that automated reprogramming and the pooled selection of polyclonal pluripotent cells results in high-quality,stable iPSCs. These lines display less line-to-line variation than either manually produced lines or lines produced through automation followed by single-colony subcloning. The robotic platform we describe will enable the application of iPSCs to population-scale biomedical problems including the study of complex genetic diseases and the development of personalized medicines. View Publication

The derivation of three-dimensional (3D) stratified neural retina from pluripotent stem cells has permitted investigations of human photoreceptors. We have generated a H9 human embryonic stem cell subclone that carries a green fluorescent protein (GFP) reporter under the control of the promoter of cone-rod homeobox (CRX),an established marker of postmitotic photoreceptor precursors. The CRXp-GFP reporter replicates endogenous CRX expression in vitro when the H9 subclone is induced to form self-organizing 3D retina-like tissue. At day 37,CRX+ photoreceptors appear in the basal or middle part of neural retina and migrate to apical side by day 67. Temporal and spatial patterns of retinal cell type markers recapitulate the predicted sequence of development. Cone gene expression is concomitant with CRX,whereas rod differentiation factor neural retina leucine zipper protein (NRL) is first observed at day 67. At day 90,robust expression of NRL and its target nuclear receptor NR2E3 is evident in many CRX+ cells,while minimal S-opsin and no rhodopsin or L/M-opsin is present. The transcriptome profile,by RNA-seq,of developing human photoreceptors is remarkably concordant with mRNA and immunohistochemistry data available for human fetal retina although many targets of CRX,including phototransduction genes,exhibit a significant delay in expression. We report on temporal changes in gene signatures,including expression of cell surface markers and transcription factors; these expression changes should assist in isolation of photoreceptors at distinct stages of differentiation and in delineating coexpression networks. Our studies establish the first global expression database of developing human photoreceptors,providing a reference map for functional studies in retinal cultures. View Publication

Substrate composition significantly impacts human pluripotent stem cell (hPSC) self-renewal and differentiation,but relatively little is known about the role of endogenously produced extracellular matrix (ECM) components in regulating hPSC fates. Here we identify $\$-5 laminin as a signature ECM component endogenously synthesized by undifferentiated hPSCs cultured on defined substrates. Inducible shRNA knockdown and Cas9-mediated disruption of the LAMA5 gene dramatically reduced hPSC self-renewal and increased apoptosis without affecting the expression of pluripotency markers. Increased self-renewal and survival was restored to wild-type levels by culturing the LAMA5-deficient cells on exogenous laminin-521. Furthermore,treatment of LAMA5-deficient cells with blebbistatin or a ROCK inhibitor partially restored self-renewal and diminished apoptosis. These results demonstrate that endogenous $\$-5 laminin promotes hPSC self-renewal in an autocrine and paracrine manner. This finding has implications for understanding how stem cells dynamically regulate their microenvironment to promote self-renewal and provides guidance for efforts to design substrates for stem cell bioprocessing. View Publication

During differentiation,human embryonic stem cells (hESCs) shut down the regulatory network conferring pluripotency in a process we designated pluripotent state dissolution (PSD). In a high-throughput RNAi screen using an inclusive set of differentiation conditions,we identify centrally important and context-dependent processes regulating PSD in hESCs,including histone acetylation,chromatin remodeling,RNA splicing,and signaling pathways. Strikingly,we detected a strong and specific enrichment of cell-cycle genes involved in DNA replication and G2 phase progression. Genetic and chemical perturbation studies demonstrate that the S and G2 phases attenuate PSD because they possess an intrinsic propensity toward the pluripotent state that is independent of G1 phase. Our data therefore functionally establish that pluripotency control is hardwired to the cell-cycle machinery,where S and G2 phase-specific pathways deterministically restrict PSD,whereas the absence of such pathways in G1 phase potentially permits the initiation of differentiation. View Publication

UNLABELLED: Human bocavirus 1 (HBoV1) is a single-stranded DNA parvovirus that causes lower respiratory tract infections in young children worldwide. In this study,we identified novel splice acceptor and donor sites,namely,A1' and D1',in the large nonstructural protein (NS1)-encoding region of the HBoV1 precursor mRNA. The novel small NS proteins (NS2,NS3,and NS4) were confirmed to be expressed following transfection of an HBoV1 infectious proviral plasmid and viral infection of polarized human airway epithelium cultured at an air-liquid interface (HAE-ALI). We constructed mutant pIHBoV1 infectious plasmids which harbor silent mutations (sm) smA1' and smD1' at the A1' and D1' splice sites,respectively. The mutant infectious plasmids maintained production of HBoV1 progeny virions at levels less than five times lower than that of the wild-type plasmid. Importantly,the smA1' mutant virus that does not express NS3 and NS4 replicated in HAE-ALI as effectively as the wild-type virus; however,the smD1' mutant virus that does not express NS2 and NS4 underwent an abortive infection in HAE-ALI. Thus,our study identified three novel NS proteins,NS2,NS3,and NS4,and suggests an important function of the NS2 protein in HBoV1 replication in HAE-ALI. IMPORTANCE: Human bocavirus 1 infection causes respiratory diseases,including acute wheezing in infants,of which life-threatening cases have been reported. In vitro,human bocavirus 1 infects polarized human bronchial airway epithelium cultured at an air-liquid interface that mimics the environment of human lower respiratory airways. Viral nonstructural proteins are often important for virus replication and pathogenesis in infected tissues or cells. In this report,we identified three new nonstructural proteins of human bocavirus 1 that are expressed during infection of polarized human bronchial airway epithelium. Among them,we proved that one nonstructural protein is critical to the replication of the virus in polarized human bronchial airway epithelium. The creation of nonreplicating infectious HBoV1 mutants may have particular utility in vaccine development for this virus. View Publication

T-cell genome engineering holds great promise for cell-based therapies for cancer,HIV,primary immune deficiencies,and autoimmune diseases,but genetic manipulation of human T cells has been challenging. Improved tools are needed to efficiently knock out" genes and "knock in" targeted genome modifications to modulate T-cell function and correct disease-associated mutations. CRISPR/Cas9 technology is facilitating genome engineering in many cell types� View Publication

The transforming growth factor-$\$(TGF-$\$) family member activin A exerts multiple neurotrophic and protective effects in the brain. Activin also modulates cognitive functions and affective behavior and is a presumed target of antidepressant therapy. Despite its important role in the injured and intact brain,the mechanisms underlying activin effects in the CNS are still largely unknown. Our goal was to identify the first target genes of activin signaling in the hippocampus in vivo. Electroconvulsive seizures,a rodent model of electroconvulsive therapy in humans,were applied to C57BL/6J mice to elicit a strong increase in activin A signaling. Chromatin immunoprecipitation experiments with hippocampal lysates subsequently revealed that binding of SMAD2/3,the intracellular effectors of activin signaling,was significantly enriched at the Pmepa1 gene,which encodes a negative feedback regulator of TGF-$\$ in cancer cells,and at the Kdm6b gene,which encodes an epigenetic regulator promoting transcriptional plasticity. Underlining the significance of these findings,activin treatment also induced PMEPA1 and KDM6B expression in human forebrain neurons generated from embryonic stem cells suggesting interspecies conservation of activin effects in mammalian neurons. Importantly,physiological stimuli such as provided by environmental enrichment proved already sufficient to engender a rapid and significant induction of activin signaling concomitant with an upregulation of Pmepa1 and Kdm6b expression. Taken together,our study identified the first target genes of activin signaling in the brain. With the induction of Kdm6b expression,activin is likely to gain impact on a presumed epigenetic regulator of activity-dependent neuronal plasticity. View Publication