Scientific Resources

The establishment of protocols to differentiate human pluripotent stem cells (hPSCs) including embryonic (ESC) and induced pluripotent (iPSC) stem cells into functional hepatocyte-like cells (HLCs) creates new opportunities to study liver metabolism,genetic diseases and infection of hepatotropic viruses (hepatitis B and C viruses) in the context of specific genetic background. While supporting efficient differentiation to HLCs,the published protocols are limited in terms of differentiation into fully mature hepatocytes and in a smaller-well format. This limitation handicaps the application of these cells to high-throughput assays. Here we describe a protocol allowing efficient and consistent hepatic differentiation of hPSCs in 384-well plates into functional hepatocyte-like cells,which remain differentiated for more than 3 weeks. This protocol affords the unique opportunity to miniaturize the hPSC-based differentiation technology and facilitates screening for molecules in modulating liver differentiation,metabolism,genetic network,and response to infection or other external stimuli. View Publication

Modeling tissues and organs using conventional 2D cell cultures is problematic as the cells rapidly lose their in vivo phenotype. In microfluidic bioreactors the cells reside in microstructures that are continuously perfused with cell culture medium to provide a dynamic environment mimicking the cells natural habitat. These micro scale bioreactors are sometimes referred to as organs-on-chips and are developed in order to improve and extend cell culture experiments. Here,we describe the two manufacturing techniques photolithography and soft lithography that are used in order to easily produce microfluidic bioreactors. The use of these bioreactors is exemplified by a toxicity assessment on 3D clustered human pluripotent stem cells (hPSC)-derived cardiomyocytes by beating frequency imaging. View Publication

Hyperfunction of the mTORC1 pathway has been associated with idiopathic and syndromic forms of autism spectrum disorder (ASD),including tuberous sclerosis,caused by loss of either TSC1 or TSC2. It remains largely unknown how developmental processes and biochemical signaling affected by mTORC1 dysregulation contribute to human neuronal dysfunction. Here,we have characterized multiple stages of neurogenesis and synapse formation in human neurons derived from TSC2-deleted pluripotent stem cells. Homozygous TSC2 deletion causes severe developmental abnormalities that recapitulate pathological hallmarks of cortical malformations in patients. Both TSC2(+/-) and TSC2(-/-) neurons display altered synaptic transmission paralleled by molecular changes in pathways associated with autism,suggesting the convergence of pathological mechanisms in ASD. Pharmacological inhibition of mTORC1 corrects developmental abnormalities and synaptic dysfunction during independent developmental stages. Our results uncouple stage-specific roles of mTORC1 in human neuronal development and contribute to a better understanding of the onset of neuronal pathophysiology in tuberous sclerosis. View Publication

Human embryonic stem cells (ESCs) readily commit to the trophoblast lineage after exposure to bone morphogenetic protein-4 (BMP-4) and two small compounds,an activin A signaling inhibitor and a FGF2 signaling inhibitor (BMP4/A83-01/PD173074; BAP treatment). During differentiation,areas emerge within the colonies with the biochemical and morphological features of syncytiotrophoblast (STB). Relatively pure fractions of mononucleated cytotrophoblast (CTB) and larger syncytial sheets displaying the expected markers of STB can be obtained by differential filtration of dispersed colonies through nylon strainers. RNA-seq analysis of these fractions has allowed them to be compared with cytotrophoblasts isolated from term placentas before and after such cells had formed syncytia. Although it is clear from extensive gene marker analysis that both ESC- and placenta-derived syncytial cells are trophoblast,each with the potential to transport a wide range of solutes and synthesize placental hormones,their transcriptome profiles are sufficiently dissimilar to suggest that the two cell types have distinct pedigrees and represent functionally different kinds of STB. We propose that the STB generated from human ESCs represents the primitive syncytium encountered in early pregnancy soon after the human trophoblast invades into the uterine wall. View Publication

Summary Human pluripotent stem cells (hPSCs) are uniquely dependent on aerobic glycolysis to generate ATP. However,the importance of oxidative phosphorylation (OXPHOS) has not been elucidated. Detailed amino acid profiling has revealed that glutamine is indispensable for the survival of hPSCs. Under glucose- and glutamine-depleted conditions,hPSCs quickly died due to the loss of ATP. Metabolome analyses showed that hPSCs oxidized pyruvate poorly and that glutamine was the main energy source for OXPHOS. hPSCs were unable to utilize pyruvate-derived citrate due to negligible expression of aconitase 2 (ACO2) and isocitrate dehydrogenase 2/3 (IDH2/3) and high expression of ATP-citrate lyase. Cardiomyocytes with mature mitochondria were not able to survive without glucose and glutamine,although they were able to use lactate to synthesize pyruvate and glutamate. This distinguishing feature of hPSC metabolism allows preparation of clinical-grade cell sources free of undifferentiated hPSCs,which prevents tumor formation during stem cell therapy. View Publication

Altering chromatin structure through histone posttranslational modifications has emerged as a key driver of transcriptional responses in cells. Modulation of these transcriptional responses by pharmacological inhibition of class I histone deacetylases (HDACs),a group of chromatin remodeling enzymes,has been successful in blocking the growth of some cancer cell types. These inhibitors also attenuate the pathogenesis of pathological cardiac remodeling by blunting and even reversing pathological hypertrophy. The mechanistic target of rapamycin (mTOR) is a critical sensor and regulator of cell growth that,as part of mTOR complex 1 (mTORC1),drives changes in protein synthesis and metabolism in both pathological and physiological hypertrophy. We demonstrated through pharmacological and genetic methods that inhibition of class I HDACs suppressed pathological cardiac hypertrophy through inhibition of mTOR activity. Mice genetically silenced for HDAC1 and HDAC2 had a reduced hypertrophic response to thoracic aortic constriction (TAC) and showed reduced mTOR activity. We determined that the abundance of tuberous sclerosis complex 2 (TSC2),an mTOR inhibitor,was increased through a transcriptional mechanism in cardiomyocytes when class I HDACs were inhibited. In neonatal rat cardiomyocytes,loss of TSC2 abolished HDAC-dependent inhibition of mTOR activity,and increased expression of TSC2 was sufficient to reduce hypertrophy in response to phenylephrine. These findings point to mTOR and TSC2-dependent control of mTOR as critical components of the mechanism by which HDAC inhibitors blunt pathological cardiac growth. These results also suggest a strategy to modulate mTOR activity and facilitate the translational exploitation of HDAC inhibitors in heart disease. View Publication

BACKGROUND Many groups have generated insulin-secreting cells from hESCs/iPSCs in multiple differentiation stages by mimicking the developmental processes. However,these cells do not always secrete glucose responsive insulin,one of the most important characteristics of pancreatic $$ cells. We focused on the importance of endodermal differentiation from human iPSCs in order to obtain functional pancreatic $$ cells. METHODS We established a 6-stage protocol for the differentiation process from hiPSCs to pancreatic $$ cells using defined culture media without feeders or serum. We examined the effect of CHIR99021,the selective inhibitor of GSK-3$$,in the presence of Activin,FGF2,and BMP4 during definitive endodermal induction by immunostaining for SOX17 and FOXA2. We also compared the insulin secretion at the last stage between monolayer culture and spheroid culture conditions. Cultured cells were transplanted under the kidney capsules of STZ-induced diabetic NOD-SCID mice,and blood glucose levels were measured. Immunohistochemical analysis was performed 4 weeks and 12 weeks after transplantation. RESULTS Addition of CHIR99021 in the presence of Activin,FGF2,and BMP4 for 2 days improved the viability of the endodermal cells,keeping the high positive rate of SOX17. Spheroid formation after the endocrine progenitor stage showed more efficient insulin secretion than monolayer culture did. After cell transplantation,diabetic mice showed lowered blood glucose levels,and we detected islet-like structures in vivo. CONCLUSION We generated functional pancreatic $$ cells from human iPS cells. Induction of definitive endoderm and spheroid formation might be key steps for producing them. View Publication

We demonstrate a highly efficient method for gene delivery into clinically relevant human cell types,such as induced pluripotent stem cells (iPSCs) and fibroblasts,reducing the protocol time by one full day. To preserve cell physiology during gene transfer,we designed a microfluidic strategy,which facilitates significant gene delivery in a short transfection time (textless1 min) for several human cell types. This fast,optimized and generally applicable cell transfection method can be used for rapid screening of different delivery systems and has significant potential for high-throughput cell therapy applications. View Publication

Efficient cryopreservation of human pluripotent stem cells (hPSCs) in chemically defined,xeno-free conditions is highly desirable for medical research and clinical applications such as cell-based therapies. Here we present a simple and effective slow freezing-rapid thawing protocol for the cryopreservation of feeder-free,single hPSCs. This cryopreservation protocol involves the supplementation of 10 % dimethyl sulfoxide (DMSO) and 10 $$M Rho-associated kinase inhibitor Y-27632 into two types of xeno-free,defined media supplements (Knockout Serum Replacement and TeSR2). High post-thaw cell recovery (˜90 %) and cell expansion (˜70 %) can be achieved using this protocol. The cryopreserved single cells retain the morphological characteristics of hPSCs and differentiation capabilities of pluripotent stem cells. View Publication

Myoclonus epilepsy associated with ragged-red fibers (MERRF) is a mitochondrial disorder characterized by myoclonus epilepsy,generalized seizures,ataxia and myopathy. MERRF syndrome is primarily due to an A to G mutation at mtDNA 8344 that disrupts the mitochondrial gene for tRNA(Lys). However,the detailed mechanism by which this tRNA(Lys) mutation causes mitochondrial dysfunction in cardiomyocytes or neurons remains unclear. In this study,we generated human induced pluripotent stem cells (hiPSCs) that carry the A8344G genetic mutation from patients with MERRF syndrome. Compared with mutation-free isogenic hiPSCs,MERRF-specific hiPSCs (MERRF-hiPSCs) exhibited reduced oxygen consumption,elevated reactive oxygen species (ROS) production,reduced growth,and fragmented mitochondrial morphology. We sought to investigate the induction ability and mitochondrial function of cardiomyocyte-like cells differentiated from MERRF-hiPSCs. Our data demonstrate that that cardiomyocyte-like cells (MERRF-CMs) or neural progenitor cells (MERRF-NPCs) differentiated from MERRF-iPSCs also exhibited increased ROS levels and altered antioxidant gene expression. Furthermore,MERRF-CMs or -NPCs contained fragmented mitochondria,as evidenced by MitoTracker Red staining and transmission electron microscopy. Taken together,these findings showed that MERRF-hiPSCs and MERRF-CM or -NPC harboring the A8344G genetic mutation displayed contained mitochondria with an abnormal ultrastructure,produced increased ROS levels,and expressed upregulated antioxidant genes. View Publication

Under defined differentiation conditions,human embryonic stem cells (hESCs) can be directed toward a mesendoderm (ME) or neuroectoderm (NE) fate,the first decision during hESC differentiation. Coupled with lineage-specific G1 lengthening,a divergent ciliation pattern emerged within the first 24 hr of induced lineage specification,and these changes heralded a neuroectoderm decision before any neural precursor markers were expressed. By day 2,increased ciliation in NE precursors induced autophagy that resulted in the inactivation of Nrf2 and thereby relieved transcriptional activation of OCT4 and NANOG. Nrf2 binds directly to upstream regions of these pluripotency genes to promote their expression and repress NE derivation. Nrf2 suppression was sufficient to rescue poorly neurogenic iPSC lines. Only after these events had been initiated did neural precursor markers get expressed at day 4. Thus,we have identified a primary cilium-autophagy-Nrf2 (PAN) control axis coupled to cell-cycle progression that directs hESCs toward NE. View Publication

mTOR inhibition is beneficial in neurodegenerative disease models and its effects are often attributable to the modulation of autophagy and anti-apoptosis. Here,we report a neglected but important bioenergetic effect of mTOR inhibition in neurons. mTOR inhibition by rapamycin significantly preserves neuronal ATP levels,particularly when oxidative phosphorylation is impaired,such as in neurons treated with mitochondrial inhibitors,or in neurons derived from maternally inherited Leigh syndrome (MILS) patient iPS cells with ATP synthase deficiency. Rapamycin treatment significantly improves the resistance of MILS neurons to glutamate toxicity. Surprisingly,in mitochondrially defective neurons,but not neuroprogenitor cells,ribosomal S6 and S6 kinase phosphorylation increased over time,despite activation of AMPK,which is often linked to mTOR inhibition. A rapamycin-induced decrease in protein synthesis,a major energy-consuming process,may account for its ATP-saving effect. We propose that a mild reduction in protein synthesis may have the potential to treat mitochondria-related neurodegeneration. View Publication