Scientific Resources

Induced pluripotent stem cells (iPSCs) hold promise for the treatment of motoneuron diseases because of their distinct features including pluripotency,self-derivation and potential ability to differentiate into motoneurons. However,it is still unknown whether human iPSC-derived motoneurons can functionally innervate target muscles in vivo,which is the definitive sign of successful cell therapy for motoneuron diseases. In the present study,we demonstrated that human iPSCs derived from mesenchymal cells of the umbilical cord possessed a high yield in neural differentiation. Using a chemically-defined in vitro system,human iPSCs efficiently differentiated into motoneurons which displayed typical morphology,expressed specific molecules,and generated repetitive trains of action potentials. When transplanted into the injured musculocutaneous nerve of rats,they survived robustly,extended axons along the nerve,and formed functional connections with the target muscle (biceps brachii),thereby protecting the muscle from atrophy. Our study provides evidence for the first time that human iPSC-derived motoneurons are truly functional not only in vitro but also in vivo,and they have potential for stem cell-based therapies for motoneuron diseases. textcopyright 2013 Elsevier B.V. View Publication

Huntington's disease is caused by expanded CAG repeats in HTT,conferring toxic gain of function on mutant HTT (mHTT) protein. Reducing mHTT amounts is postulated as a strategy for therapeutic intervention. We conducted genome-wide RNA interference screens for genes modifying mHTT abundance and identified 13 hits. We tested 10 in vivo in a Drosophila melanogaster Huntington's disease model,and 6 exhibited activity consistent with the in vitro screening results. Among these,negative regulator of ubiquitin-like protein 1 (NUB1) overexpression lowered mHTT in neuronal models and rescued mHTT-induced death. NUB1 reduces mHTT amounts by enhancing polyubiquitination and proteasomal degradation of mHTT protein. The process requires CUL3 and the ubiquitin-like protein NEDD8 necessary for CUL3 activation. As a potential approach to modulating NUB1 for treatment,interferon-β lowered mHTT and rescued neuronal toxicity through induction of NUB1. Thus,we have identified genes modifying endogenous mHTT using high-throughput screening and demonstrate NUB1 as an exemplar entry point for therapeutic intervention of Huntington's disease. View Publication

In congenital mitochondrial DNA (mtDNA) disorders,a mixture of normal and mutated mtDNA (termed heteroplasmy) exists at varying levels in different tissues,which determines the severity and phenotypic expression of disease. Pearson marrow pancreas syndrome (PS) is a congenital bone marrow failure disorder caused by heteroplasmic deletions in mtDNA. The cause of the hematopoietic failure in PS is unknown,and adequate cellular and animal models are lacking. Induced pluripotent stem (iPS) cells are particularly amenable for studying mtDNA disorders,as cytoplasmic genetic material is retained during direct reprogramming. Here,we derive and characterize iPS cells from a patient with PS. Taking advantage of the tendency for heteroplasmy to change with cell passage,we isolated isogenic PS-iPS cells without detectable levels of deleted mtDNA. We found that PS-iPS cells carrying a high burden of deleted mtDNA displayed differences in growth,mitochondrial function,and hematopoietic phenotype when differentiated in vitro,compared to isogenic iPS cells without deleted mtDNA. Our results demonstrate that reprogramming somatic cells from patients with mtDNA disorders can yield pluripotent stem cells with varying burdens of heteroplasmy that might be useful in the study and treatment of mitochondrial diseases. STEM CELLS2013;31:1287–1297 View Publication

Most neurodegenerative diseases are linked to aberrant accumulation of aggregation-prone proteins. Among them,Huntington's disease (HD) is caused by an expanded polyglutamine repeat stretch in the N terminus of the mutant huntingtin protein (mHTT),which gets cleaved and aggregates in the brain. Recently established human induced pluripotent stem cell-derived HD neurons exhibit some disease-relevant phenotypes and provide tools for HD research. However,they have limitations such as genetic heterogeneity and an absence of mHTT aggregates and lack a robust neurodegeneration phenotype. In addition,the relationship between the phenotype and mHTT levels has not been elucidated. Herein,we present a human embryonic stem cell (hESC)-derived HD neuronal model expressing HTTexon1 fragments,which addresses the deficiencies enumerated above. The wild-type and HD lines are derived from an isogenic background and exhibit insoluble mHTT aggregates and neurodegeneration. We also demonstrate a quantitative relationship between neurodegeneration and soluble monomeric (but not oligomeric or aggregated) mHTT levels. Reduction of ∼10% of mHTT is sufficient to prevent toxicity,whereas ∼90% reduction of wild-type HTT is safe and well-tolerated in these cells. A known HD toxicity modifier (Rhes) showed expected rescue of neurodegeneration. Therefore,the hESC-derived neuronal models complement existing induced pluripotent stem cell-derived neuronal models and provide valuable tools for HD research.—Lu,B.,Palacino,J. A novel human embryonic stem cell-derived Huntington's disease neuronal model exhibits mutant huntingtin (mHTT) aggregates and soluble mHTT-dependent neurodegeneration. View Publication

Stochastic processes and imprinting,along with genetic factors,lead to monoallelic or allele-biased gene expression. Stochastic monoallelic expression fine-tunes information processing in immune cells and the olfactory system,and imprinting plays an important role in development. Recent studies suggest that both stochastic events and imprinting may be more widespread than previously considered. We are interested in allele-biased gene expression occurring in the brain because parent-of-origin effects suggestive of imprinting appear to play a role in the transmission of schizophrenia (SZ) and autism spectrum disorders (ASD) in some families. In addition,allele-biased expression could help explain monozygotic (MZ) twin discordance and reduced penetrance. The ability to study allele-biased expression in human neurons has been transformed with the advent of induced pluripotent stem cell (iPSC) technology and next generation sequencing. Using transcriptome sequencing (RNA-Seq) we identified 801 genes in differentiating neurons that were expressed in an allele-biased manner. These included a number of putative SZ and ASD candidates,such as A2BP1 (RBFOX1),ERBB4,NLGN4X,NRG1,NRG3,NRXN1,and NLGN1. Overall,there was a modest enrichment for SZ and ASD candidate genes among those that showed evidence for allele-biased expression (chi-square,p = 0.02). In addition to helping explain MZ twin discordance and reduced penetrance,the capacity to group many candidate genes affecting a variety of molecular and cellular pathways under a common regulatory process - allele-biased expression - could have therapeutic implications. View Publication

Efficient derivation of neural cells from human embryonic stem cells (hESCs) remains an unmet need for the treatment of neurological disorders. The limiting factors for current methods include being labor-intensive,time-consuming and expensive. In this study,we hypothesize that the substrate topography,with optimal geometry and dimension,can modulate the neural fate of hESCs and enhance the efficiency of differentiation. A multi-architectural chip (MARC) containing fields of topographies varying in geometry and dimension was developed to facilitate high-throughput analysis of topography-induced neural differentiation in vitro. The hESCs were subjected to direct differentiation"� View Publication

Considerable progress has been made in identifying signaling pathways that direct the differentiation of human pluripotent stem cells (hPSCs) into specialized cell types,including neurons. However,differentiation of hPSCs with extrinsic factors is a slow,step-wise process,mimicking the protracted timing of human development. Using a small-molecule screen,we identified a combination of five small-molecule pathway inhibitors that yield hPSC-derived neurons at textgreater75% efficiency within 10 d of differentiation. The resulting neurons express canonical markers and functional properties of human nociceptors,including tetrodotoxin (TTX)-resistant,SCN10A-dependent sodium currents and response to nociceptive stimuli such as ATP and capsaicin. Neuronal fate acquisition occurs about threefold faster than during in vivo development,suggesting that use of small-molecule pathway inhibitors could become a general strategy for accelerating developmental timing in vitro. The quick and high-efficiency derivation of nociceptors offers unprecedented access to this medically relevant cell type for studies of human pain. View Publication

Cockayne syndrome (CS) is a human premature aging disorder associated with neurological and developmental abnormalities,caused by mutations mainly in the CS group B gene (ERCC6). At the molecular level,CS is characterized by a deficiency in the transcription-couple DNA repair pathway. To understand the role of this molecular pathway in a pluripotent cell and the impact of CSB mutation during human cellular development,we generated induced pluripotent stem cells (iPSCs) from CSB skin fibroblasts (CSB-iPSC). Here,we showed that the lack of functional CSB does not represent a barrier to genetic reprogramming. However,iPSCs derived from CSB patient's fibroblasts exhibited elevated cell death rate and higher reactive oxygen species (ROS) production. Moreover,these cellular phenotypes were accompanied by an up-regulation of TXNIP and TP53 transcriptional expression. Our findings suggest that CSB modulates cell viability in pluripotent stem cells,regulating the expression of TP53 and TXNIP and ROS production. View Publication

Transactive response DNA-binding (TDP-43) protein is the dominant disease protein in amyotrophic lateral sclerosis (ALS) and a subgroup of frontotemporal lobar degeneration (FTLD-TDP). Identification of mutations in the gene encoding TDP-43 (TARDBP) in familial ALS confirms a mechanistic link between misaccumulation of TDP-43 and neurodegeneration and provides an opportunity to study TDP-43 proteinopathies in human neurons generated from patient fibroblasts by using induced pluripotent stem cells (iPSCs). Here,we report the generation of iPSCs that carry the TDP-43 M337V mutation and their differentiation into neurons and functional motor neurons. Mutant neurons had elevated levels of soluble and detergent-resistant TDP-43 protein,decreased survival in longitudinal studies,and increased vulnerability to antagonism of the PI3K pathway. We conclude that expression of physiological levels of TDP-43 in human neurons is sufficient to reveal a mutation-specific cell-autonomous phenotype and strongly supports this approach for the study of disease mechanisms and for drug screening. View Publication

Schizophrenia has been defined as a neurodevelopmental disease that causes changes in the process of thoughts,perceptions,and emotions,usually leading to a mental deterioration and affective blunting. Studies have shown altered cell respiration and oxidative stress response in schizophrenia; however,most of the knowledge has been acquired from postmortem brain analyses or from nonneural cells. Here we describe that neural cells,derived from induced pluripotent stem cells generated from skin fibroblasts of a schizophrenic patient,presented a twofold increase in extramitochondrial oxygen consumption as well as elevated levels of reactive oxygen species (ROS),when compared to controls. This difference in ROS levels was reverted by the mood stabilizer valproic acid. Our model shows evidence that metabolic changes occurring during neurogenesis are associated with schizophrenia,contributing to a better understanding of the development of the disease and highlighting potential targets for treatment and drug screening. View Publication

Rett syndrome (RTT) is a progressive neurologic disorder representing one of the most common causes of mental retardation in females. To date mutations in three genes have been associated with this condition. Classic RTT is caused by mutations in the MECP2 gene,whereas variants can be due to mutations in either MECP2 or FOXG1 or CDKL5. Mutations in CDKL5 have been identified both in females with the early onset seizure variant of RTT and in males with X-linked epileptic encephalopathy. CDKL5 is a kinase protein highly expressed in neurons,but its exact function inside the cell is unknown. To address this issue we established a human cellular model for CDKL5-related disease using the recently developed technology of induced pluripotent stem cells (iPSCs). iPSCs can be expanded indefinitely and differentiated in vitro into many different cell types,including neurons. These features make them the ideal tool to study disease mechanisms directly on the primarily affected neuronal cells. We derived iPSCs from fibroblasts of one female with p.Q347X and one male with p.T288I mutation,affected by early onset seizure variant and X-linked epileptic encephalopathy,respectively. We demonstrated that female CDKL5-mutated iPSCs maintain X-chromosome inactivation and clones express either the mutant CDKL5 allele or the wild-type allele that serve as an ideal experimental control. Array CGH indicates normal isogenic molecular karyotypes without detection of de novo CNVs in the CDKL5-mutated iPSCs. Furthermore,the iPS cells can be differentiated into neurons and are thus suitable to model disease pathogenesis in vitro. View Publication

Amyotrophic lateral sclerosis (ALS) is an incurable neuromuscular disease that leads to a profound loss of life quality and premature death. Around 10% of the cases are inherited and ALS8 is an autosomal dominant form of familial ALS caused by mutations in the vamp-associated protein B/C (VAPB) gene. The VAPB protein is involved in many cellular processes and it likely contributes to the pathogenesis of other forms of ALS besides ALS8. A number of successful drug tests in ALS animal models could not be translated to humans underscoring the need for novel approaches. The induced pluripotent stem cells (iPSC) technology brings new hope,since it can be used to model and investigate diseases in vitro. Here we present an additional tool to study ALS based on ALS8-iPSC. Fibroblasts from ALS8 patients and their non-carrier siblings were successfully reprogrammed to a pluripotent state and differentiated into motor neurons. We show for the first time that VAPB protein levels are reduced in ALS8-derived motor neurons but,in contrast to over-expression systems,cytoplasmic aggregates could not be identified. Our results suggest that optimal levels of VAPB may play a central role in the pathogenesis of ALS8,in agreement with the observed reduction of VAPB in sporadic ALS. View Publication