Project description:We developed a novel somite-based step-wise strategy for the efficient derivation of functional human myocytes, suggesting that past failures were due to incomplete specification. Treatment with two small molecules inhibiting glycogen synthase kinase 3β (GSK-3β) and the Notch signaling pathway in undifferentiated hPSCs results in the formation of somite-like cells by Day 4 and, subsequently contractile myotubes in vitro around Day 25 with the ability to engraft and actively participate in muscle repair in vivo. Antibody-based purification can enrich homogenous myocyte populations exhibiting genuine myogenic molecular and cellular characteristics, including extraocular muscle-like features. Furthermore, hPSCs derived from patients with multiple neuromuscular diseases successfully give rise to patient-specific skeletal muscle cells bearing signature phenotypes. Human embryonic stem cell were differentiated to skeletal muscle and compared to non-differentiated cells in triplicate biological replicates. For the confirmation of differentiated cell's characteristics and the global mRNA profiles, We used microarrays to detail the global programme of gene expression underlying cellularisation and identified distinct classes of up-regulated genes during this process. Further more, we used microarrys for the comparing control and disease gene expression profiles, again in triplicate.

Project description:Human pluripotent stem cells (hPSCs) are a promising source of cells for applications in regenerative medicine. Directed differentiation of hPSCs into specialized cells such as spinal motoneurons or midbrain dopamine (DA) neurons has been achieved. However the effective use of hPSCs for cell therapy has lagged far behind. While mouse PSC-derived DA neurons have shown efficacy in models of Parkinson’s disease, DA neurons derived from human PSCs generally display poor in vivo performance. There are also considerable safety concerns for hPSCs related to their potential for teratoma formation or neural overgrowth. Here we present a novel floor plate-based strategy for the derivation of human DA neurons that efficiently engraft, suggesting that past failures were due to incomplete specification rather than a specific vulnerability of the cells. Midbrain floor plate precursors are derived from hPSCs in days following exposure to small molecule activators of sonic hedgehog (SHH) and canonical WNT signaling. Engraftable midbrain DA neurons are obtained by day 25 and can be maintained in vitro for several months. Extensive in vitro molecular profiling, biochemical and electrophysiological data define developmental progression and confirm identity of hPSC-derived midbrain DA neurons. In vivo survival and function is demonstrated in PD animal models in three host species. Long-term engraftment in 6-OHDA-lesioned mouse and rats demonstrates robust survival of midbrain DA neurons, complete restoration of amphetamine-induced rotation behavior and improvements in tests of forelimb use and akinesia. Finally, scalability is demonstrated by transplantation into Parkinsonian monkeys. Excellent DA neuron survival, function and lack of neural overgrowth in the three animal models tested indicate considerable promise for the development of cell based therapies in PD. Differentiated hESC with three conditions (LSB, LSB/S/F8, LSB/S/F8/CHIR) were subjected to RNA extraction in specific timepoint (day 0, 1, 3, 5, 7, 11, 13, 25) and hybridization on Illumina microarrays. Each sample has 3 or 4 biological repeats. Based on previous study* of dual SMAD inhibition neural induction, we developed new midbrain dopamine neuron protocol. It depends on time specific treatment of below factors (LSB/S/F8/CHIR): L (LDN193189 (BMP inhibitor) , day 0-11), SB (SB431542 (TGF-b signal inhibitor), day 0-5), S (SHH + Purmorphamine (Smo agonist), day 1-7), F8 (FGF8, day 1-7) and CHIR (CHIR99021 (GSK3b inhibitor), day 3-13) LSB and LSB/S/F8 are limited control conditions of dual SMAD only (LSB) or traditional patterning with Sonic and FGF (LSB/S/F8) *Chambers,S.M. et al. Highly efficient neural conversion of human ES and iPS cells by dual inhibition of SMAD signaling. Nat. Biotechnol. 27, 275-280 (2009).

Project description:Duchenne muscular dystrophy (DMD) causes severe disability of children and death of young men, with an incidence of approximately 1/5,000 male births. Symptoms appear in early childhood, with a diagnosis made around 4, a time where the amount of muscle damage is already significant, preventing early therapeutic interventions that could be more efficient at halting disease progression. In the meantime, the precise moment at which disease phenotypes arise – even asymptomatically – is still unknown. Thus, there is a critical need to better define DMD onset as well as its first manifestations, which could help identify early disease biomarkers and novel therapeutic targets. In this study, we have used human induced pluripotent stem cells (hiPSCs) from DMD patients to model skeletal myogenesis, and compared their differentiation dynamics to healthy control cells by a comprehensive multi-omics analysis. Transcriptome and miRnome comparisons combined with protein analyses at 7 time points demonstrate that hiPSC differentiation 1) mimics described DMD phenotypes at the differentiation endpoint; and 2) homogeneously and robustly recapitulates key developmental steps - mesoderm, somite, skeletal muscle - which offers the possibility to explore dystrophin functions and find earlier disease biomarkers. Starting at the somite stage, mitochondrial gene dysregulations escalate during differentiation. We also describe fibrosis as an intrinsic feature of skeletal muscle cells that starts early during myogenesis. In sum, our data strongly argue for an early developmental manifestation of DMD whose onset is triggered before the entry into the skeletal muscle compartment, data leading to a necessary reconsideration of dystrophin functions during muscle development.

Project description:Determination of gene expression changes in extraocular and hindlimb (gastrocnemius/soleus) of mdx (dystrophin-deficient) mice at postnatal day 56. 5 independent replicates/muscle group/strain. Keywords: parallel sample

Project description:Human pluripotent stem cells (hPSCs) are a promising source of cells for applications in regenerative medicine. Directed differentiation of hPSCs into specialized cells such as spinal motoneurons or midbrain dopamine (DA) neurons has been achieved. However the effective use of hPSCs for cell therapy has lagged far behind. While mouse PSC-derived DA neurons have shown efficacy in models of Parkinson’s disease, DA neurons derived from human PSCs generally display poor in vivo performance. There are also considerable safety concerns for hPSCs related to their potential for teratoma formation or neural overgrowth. Here we present a novel floor plate-based strategy for the derivation of human DA neurons that efficiently engraft, suggesting that past failures were due to incomplete specification rather than a specific vulnerability of the cells. Midbrain floor plate precursors are derived from hPSCs in days following exposure to small molecule activators of sonic hedgehog (SHH) and canonical WNT signaling. Engraftable midbrain DA neurons are obtained by day 25 and can be maintained in vitro for several months. Extensive in vitro molecular profiling, biochemical and electrophysiological data define developmental progression and confirm identity of hPSC-derived midbrain DA neurons. In vivo survival and function is demonstrated in PD animal models in three host species. Long-term engraftment in 6-OHDA-lesioned mouse and rats demonstrates robust survival of midbrain DA neurons, complete restoration of amphetamine-induced rotation behavior and improvements in tests of forelimb use and akinesia. Finally, scalability is demonstrated by transplantation into Parkinsonian monkeys. Excellent DA neuron survival, function and lack of neural overgrowth in the three animal models tested indicate considerable promise for the development of cell based therapies in PD.

Project description:Conserved and muscle group-specific gene expression patterns shape postnatal development of the novel extraocular muscle phenotype. Comparison of postnatal development of extraocular and hindlimb muscle between birth and P45. Keywords: parallel sample

Project description:Determination of gene expression changes in extraocular and hindlimb (gastrocnemius/soleus) of mdx (dystrophin-deficient) mice at postnatal day 56. 5 independent replicates/muscle group/strain.

Project description:Conserved and muscle group-specific gene expression patterns shape postnatal development of the novel extraocular muscle phenotype. Comparison of postnatal development of extraocular and hindlimb muscle between birth and P45.

Project description:Muscle, normal extraocular, profile

Project description:Mutations in the RYR1 gene are the most common cause of human congenital myopathies and patients with recessive mutations are severely affected and characteristically display ptosis and/or ophthalmoplegia. In order to gain insight into the mechanism leading to extraocular muscle involvement, we investigated the biochemical, structural and physiological properties of eye muscles from mouse models we created knocked-in for RYR1 mutations. Ex vivo force production in extraocular muscles from compound heterozygous RyR1p.Q1970fsX16+p.A4329D mutant mice was significantly reduced compared to that observed in WT. The decrease in muscle force was also accompanied by approximately a 40% reduction in RyR1 protein content, a decrease in electrically evoked calcium transients, disorganization of the muscle ultrastructure and a decrease in the number of calcium release units. Unexpectedly, the superfast and ocular-muscle specific myosin heavy chain-EO isoform was almost undetectable in RyR1p.Q1970fsX16+p.A4329D mutant mice. The results of this study show for the first time that the extraocular muscle phenotype caused by compound heterozygous RYR1 mutations is due to reduced content of ryanodine and dihydropyridine receptors, the presence of fewer calcium release units and associated mitochondria as well as disorganization of myofiber structure. Additionally, the presence of the two mutations leads to the almost complete absence of the extraocular muscle-specific isoform of myosin heavy chain.