Project description:The differentiation of patient-specific induced pluripotent stem cells (iPSCs) into specific neuronal subtypes has been exploited as an approach to modeling a variety of neurological disorders. However, achieving a highly pure population of neurons is challenging when using directed differentiation methods, especially for neuronal subtypes generated by complex and protracted protocols. In this study, we efficiently produced highly pure populations of regionally specified CNS neurons by using a modified NGN2-Puromycin direct conversion protocol. The protocol is amenable across a range of iPSC lines, with an efficiency above 97% by day 21, and above 95% of neurons positive for MAP2. This NGN2-Puromycin conversion resulted in a significant number of peripheral neurons, but by incorporating a short CNS patterning step, we eliminated these peripheral neurons. Furthermore, we used the patterning step to control the rostral-caudal identity. This approach to sequential patterning and NGN2-Puromycin conversion, when patterned with SMAD inhibitors, produced pure populations of forebrain neurons; when SMAD inhibitors and WNT agonists were applied, the approach produced anterior hindbrain excitatory neurons, resulting in a neuronal population containing VSX2/SHOX2 V2a interneurons. Overall, this sequential patterning and conversion protocol can be used for the production of a variety of CNS excitatory neurons from patient-derived iPSCs, which is a highly versatile system for investigating early disease events for a range of neurological disorders including Alzheimer's disease, motor neurons disease and spinal cord injury.

Project description:Human pluripotent stem cells (hPSCs) require precise control of post-transcriptional RNA networks to maintain proliferation and survival. Using a recently developed enhanced UV crosslinking and immunoprecipitation (eCLIP) approach, we identify RNA targets of the IMP/IGF2BP family of RNA-binding proteins in hPSCs. At the broad region- and binding site-level IMP1 and IMP2 show reproducible binding to a large and overlapping set of 3'UTR-enriched targets. RNA Bind-N-Seq applied to recombinant full-length IMP1 and IMP2 reveals CA-rich motifs that are enriched in eCLIP-defined binding sites. We observe that IMP1 loss in hPSCs recapitulates IMP1 phenotypes, including a reduction in cell adhesion and an increase in cell death. For cell adhesion, in hPSCs we find IMP1 maintains levels of integrin mRNA, specifically regulating RNA stability of ITGB5. Additionally, we show IMP1 can be linked to hPSC survival via direct target BCL2. Thus, transcriptome-wide binding profiles identify hPSC targets modulating well-characterized IMP1 roles. eCLIP-seq was performed in biological replicate for IGF2BP1/IMP1 and IGF2BP2/IMP2, as well as one replicate each for IGF2BP3/IMP3, RBFOX2, and an IgG control. Each sample has a size-matched input control for analysis

Project description:Human pluripotent stem cells (hPSCs) require precise control of post-transcriptional RNA networks to maintain proliferation and survival. Using a recently developed enhanced UV crosslinking and immunoprecipitation (eCLIP) approach, we identify RNA targets of the IMP/IGF2BP family of RNA-binding proteins in hPSCs. At the broad region- and binding site-level IMP1 and IMP2 show reproducible binding to a large and overlapping set of 3'UTR-enriched targets. RNA Bind-N-Seq applied to recombinant full-length IMP1 and IMP2 reveals CA-rich motifs that are enriched in eCLIP-defined binding sites. We observe that IMP1 loss in hPSCs recapitulates IMP1 phenotypes, including a reduction in cell adhesion and an increase in cell death. For cell adhesion, in hPSCs we find IMP1 maintains levels of integrin mRNA, specifically regulating RNA stability of ITGB5. Additionally, we show IMP1 can be linked to hPSC survival via direct target BCL2. Thus, transcriptome-wide binding profiles identify hPSC targets modulating well-characterized IMP1 roles. eCLIP-seq was performed in biological replicate for IGF2BP1/IMP1 and IGF2BP2/IMP2, as well as one replicate each for IGF2BP3/IMP3, RBFOX2, and an IgG control. Each sample has a size-matched input control for analysis

Project description:Spinal motor neurons (MNs) integrate sensory stimuli and brain commands to generate movements. In vertebrates, the molecular identities of the cardinal MN types such as those innervating limb versus trunk muscles have been well elucidated. Yet the identities of finer subtypes within these cell populations that innervate individual muscle groups remain enigmatic. Using single-cell transcriptomics, we have investigated heterogeneity in mouse MNs and discovered many unreported MN subtypes. Among limb-innervating MNs, we reveal a surprisingly diverse neuropeptide code for delineating putative motor pool identities. Additionally, we have uncovered that axial MNs are subdivided into three molecularly distinct subtypes, defined by mediolaterally-biased Satb2, Nr2f2 or Bcl11b expression patterns with different axon guidance signatures. These three subtypes are present in chicken and human embryos, suggesting a conserved axial MN expression pattern across higher vertebrates. Overall, our study provides a comprehensive molecular resource of spinal MN types and paves the way towards deciphering how neuronal subtypes evolved to accommodate vertebrate motor behaviors associated with different lifestyles.

Project description:During early embryogenesis the fertilized zygote proceeds through an intricate developmental program, accompanyed by DNA and chromatin remodelling. However, the mechanisms governing this reconfiguring are poorly understood. Parts of the embryogenesis developmental program can be captured in vitro in the form of two types of human pluripotent stem cells (hPSC): naïve and primed hPSCs. Naïve hPSCs resemble the inner cell mass of the blastocyst, whilst primed hPSCs resemble the post-implantation embryo. The nucleus is made of DNA wrapped around chromatin, and the nuclear matrix, a proteinaceous gel that provides structure. Here, we show that disruptions in the nuclear matrix caused primed hPSCs to spontaneously convert to the naïve, earlier embryonic state.

Project description:During early embryogenesis the fertilized zygote proceeds through an intricate developmental program, accompanyed by DNA and chromatin remodelling. However, the mechanisms governing this reconfiguring are poorly understood. Parts of the embryogenesis developmental program can be captured in vitro in the form of two types of human pluripotent stem cells (hPSC): naïve and primed hPSCs. Naïve hPSCs resemble the inner cell mass of the blastocyst, whilst primed hPSCs resemble the post-implantation embryo. The nucleus is made of DNA wrapped around chromatin, and the nuclear matrix, a proteinaceous gel that provides structure. Here, we show that disruptions in the nuclear matrix caused primed hPSCs to spontaneously convert to the naïve, earlier embryonic state.

Project description:During early embryogenesis the fertilized zygote proceeds through an intricate developmental program, accompanyed by DNA and chromatin remodelling. However, the mechanisms governing this reconfiguring are poorly understood. Parts of the embryogenesis developmental program can be captured in vitro in the form of two types of human pluripotent stem cells (hPSC): naïve and primed hPSCs. Naïve hPSCs resemble the inner cell mass of the blastocyst, whilst primed hPSCs resemble the post-implantation embryo. The nucleus is made of DNA wrapped around chromatin, and the nuclear matrix, a proteinaceous gel that provides structure. Here, we show that disruptions in the nuclear matrix caused primed hPSCs to spontaneously convert to the naïve, earlier embryonic state.

Project description:During early embryogenesis the fertilized zygote proceeds through an intricate developmental program, accompanyed by DNA and chromatin remodelling. However, the mechanisms governing this reconfiguring are poorly understood. Parts of the embryogenesis developmental program can be captured in vitro in the form of two types of human pluripotent stem cells (hPSC): naïve and primed hPSCs. Naïve hPSCs resemble the inner cell mass of the blastocyst, whilst primed hPSCs resemble the post-implantation embryo. The nucleus is made of DNA wrapped around chromatin, and the nuclear matrix, a proteinaceous gel that provides structure. Here, we show that disruptions in the nuclear matrix caused primed hPSCs to spontaneously convert to the naïve, earlier embryonic state.

Project description:During early embryogenesis the fertilized zygote proceeds through an intricate developmental program, accompanyed by DNA and chromatin remodelling. However, the mechanisms governing this reconfiguring are poorly understood. Parts of the embryogenesis developmental program can be captured in vitro in the form of two types of human pluripotent stem cells (hPSC): naïve and primed hPSCs. Naïve hPSCs resemble the inner cell mass of the blastocyst, whilst primed hPSCs resemble the post-implantation embryo. The nucleus is made of DNA wrapped around chromatin, and the nuclear matrix, a proteinaceous gel that provides structure. Here, we show that disruptions in the nuclear matrix caused primed hPSCs to spontaneously convert to the naïve, earlier embryonic state.

Project description:During early embryogenesis the fertilized zygote proceeds through an intricate developmental program, accompanyed by DNA and chromatin remodelling. However, the mechanisms governing this reconfiguring are poorly understood. Parts of the embryogenesis developmental program can be captured in vitro in the form of two types of human pluripotent stem cells (hPSC): naïve and primed hPSCs. Naïve hPSCs resemble the inner cell mass of the blastocyst, whilst primed hPSCs resemble the post-implantation embryo. The nucleus is made of DNA wrapped around chromatin, and the nuclear matrix, a proteinaceous gel that provides structure. Here, we show that disruptions in the nuclear matrix caused primed hPSCs to spontaneously convert to the naïve, earlier embryonic state.