Project description:The ability to generate microglia from human induced pluripotent stem cells (iPSCs) provides new tools and avenues for investigating the role of microglia in health and disease. Furthermore, iPSC-derived microglia can be maintained in co-culture with iPSC-derived cortical neurons, which enable investigations of microglia-neuron interactions that are hypothesized to be dysregulated in a number of neuropsychiatric disorders. Human iPSCs were differentiated to generate microglia using an adapted version of a protocol developed by the Fossati group, and the iPSC-derived microglia were validated with marker analysis and real-time PCR. Human microglia generated using this protocol were positive for the markers CD11C, IBA1, P2RY12, and TMEM119, and expressed the microglial-related genes AIF1, CX3CR1, ITGAM, ITGAX, P2RY12, and TMEM119. Human iPSC-derived cortical neurons that had been differentiated for 30 days were plated with microglia and maintained in co-culture until day 60, when experiments were undertaken. The density of dendritic spines in cortical neurons in co-culture with microglia was quantified under baseline conditions and in the presence of pro-inflammatory cytokines. In order to examine how microglia modulate neuronal function, calcium imaging experiments of the cortical neurons were undertaken using the calcium indicator Fluo-4 AM. Live calcium activity of cortical neurons was obtained using a confocal microscope, and fluorescence intensity was quantified using ImageJ. This report describes how co-culturing human iPSC-derived microglia and cortical neurons provide new approaches to interrogate the effects of microglia on cortical neurons.

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:UTX is a histone H3 lysine 27 demethylase required for development. However, the mechanisms underlying developmental gene regulation by UTX are unclear. Here, we discovered a molecular interaction between UTX and 53BP1 that regulates gene expression in a human neurogenesis model. Human 53BP1 contains a UTX-binding site that diverges from its mouse homolog by 41%, and our data suggest that the UTX-53BP1 interaction is conserved in primates but not rodents. ChIP-Seq revealed that the genome-wide targets of UTX and 53BP1 overlap by 84%. We used CRISPR-Cas9 to generate mutations of 53BP1 and UTX in human embryonic stem cells, and found that both 53BP1 and UTX are required to promote the expression of hundreds of neurogenic genes during neural differentiation. Further, 53BP1 is required for human neural progenitor differentiation into neurons. Our findings suggest that the UTX-53BP1 interaction controls gene expression important for neural differentiation in humans.

Project description:UTX is a histone H3 lysine 27 demethylase required for development. However, the mechanisms underlying developmental gene regulation by UTX are unclear. Here, we discovered a molecular interaction between UTX and 53BP1 that regulates gene expression in a human neurogenesis model. Human 53BP1 contains a UTX-binding site that diverges from its mouse homolog by 41%, and our data suggest that the UTX-53BP1 interaction is conserved in primates but not rodents. ChIP-Seq revealed that the genome-wide targets of UTX and 53BP1 overlap by 84%. We used CRISPR-Cas9 to generate mutations of 53BP1 and UTX in human embryonic stem cells, and found that both 53BP1 and UTX are required to promote the expression of hundreds of neurogenic genes during neural differentiation. Further, 53BP1 is required for human neural progenitor differentiation into neurons. Our findings suggest that the UTX-53BP1 interaction controls gene expression important for neural differentiation in humans.

Project description:UTX is a histone H3 lysine 27 demethylase required for development. However, the mechanisms underlying developmental gene regulation by UTX are unclear. Here, we discovered a molecular interaction between UTX and 53BP1 that regulates gene expression in a human neurogenesis model. Human 53BP1 contains a UTX-binding site that diverges from its mouse homolog by 41%, and our data suggest that the UTX-53BP1 interaction is conserved in primates but not rodents. ChIP-Seq revealed that the genome-wide targets of UTX and 53BP1 overlap by 84%. We used CRISPR-Cas9 to generate mutations of 53BP1 and UTX in human embryonic stem cells, and found that both 53BP1 and UTX are required to promote the expression of hundreds of neurogenic genes during neural differentiation. Further, 53BP1 is required for human neural progenitor differentiation into neurons. Our findings suggest that the UTX-53BP1 interaction controls gene expression important for neural differentiation in humans.

Project description:Hypothermia is potently neuroprotective but poor mechanistic understanding has restricted its clinical use. Rodent studies indicate that hypothermia can elicit preconditioning, wherein a subtoxic cellular stress confers resistance to an otherwise lethal injury. The molecular basis of this preconditioning remains obscure. Here we explore molecular effects of cooling using functional cortical neurons differentiated from human pluripotent stem cells (hCNs). Mild-to-moderate hypothermia (28-32 °C) induces cold-shock protein expression and mild endoplasmic reticulum (ER) stress in hCNs, with full activation of the unfolded protein response (UPR). Chemical block of a principal UPR pathway mitigates the protective effect of cooling against oxidative stress, whilst pre-cooling neurons abrogates the toxic injury produced by the ER stressor tunicamycin. Cold-stress thus preconditions neurons by upregulating adaptive chaperone-driven pathways of the UPR in a manner that precipitates ER-hormesis. Our findings establish a novel arm of neurocryobiology that could reveal multiple therapeutic targets for acute and chronic neuronal injury.

Project description:53BP1 is a well-established DNA damage repair factor that has recently been shown to regulate gene expression and critically influence tumor suppression and neural development. For gene regulation, how 53BP1 is regulated remains unclear. Here, we showed that 53BP1-serine 25 phosphorylation by ATM is required for neural progenitor cell proliferation and neuronal differentiation in cortical organoids. 53BP1-serine 25 phosphorylation dynamics controls 53BP1 target genes for neuronal differentiation and function, cellular response to stress, and apoptosis. Beyond 53BP1, ATM is required for phosphorylation of factors in neuronal differentiation, cytoskeleton, p53 regulation, and ATM, BNDF, and WNT signaling pathways for cortical organoid differentiation. Overall, our data suggest that 53BP1 and ATM control key genetic programs required for human cortical development.

Project description:Human induced pluripotent stem cells (iPSCs) can give rise to multiple cell types and hold great promise in regenerative medicine and disease-modeling applications. We have developed a reliable two-step protocol to generate human mammary-like organoids from iPSCs. Non-neural ectoderm-cell-containing spheres, referred to as mEBs, were first differentiated and enriched from iPSCs using MammoCult medium. Gene expression profile analysis suggested that mammary gland function-associated signaling pathways were hallmarks of 10-day differentiated mEBs. We then generated mammary-like organoids from 10-day mEBs using 3D floating mixed gel culture and a three-stage differentiation procedure. These organoids expressed common breast tissue, luminal, and basal markers, including estrogen receptor, and could be induced to produce milk protein. These results demonstrate that human iPSCs can be directed in vitro toward mammary lineage differentiation. Our findings provide an iPSC-based model for studying regulation of normal mammary cell fate and function as well as breast disease development.

Project description:The recapitulation of human developmental processes and pathological manifestations requires access to specific cell types and precursor stages during embryogenesis and disease. Here, we describe a scalable in vitro differentiation protocol to guide human pluripotent stem cells stepwise into pancreatic duct-like organoids. The protocol mimics pancreatic duct development and was successfully used to model the onset and progression of pancreatic ductal adenocarcinoma; the approach is suitable for multiple downstream applications. However, the protocol is cost- and time-intensive. For complete details on the use and execution of this protocol, please refer to Breunig et al. (2021).

Project description:BACKGROUND:UTX/KDM6A is known to interact and influence multiple different chromatin modifiers to promote an open chromatin environment to facilitate gene activation, but its molecular activities in developmental gene regulation remain unclear. RESULTS:We report that in human neural stem cells, UTX binding correlates with both promotion and suppression of gene expression. These activities enable UTX to modulate neural stem cell self-renewal, promote neurogenesis, and suppress gliogenesis. In neural stem cells, UTX has a less influence over histone H3 lysine 27 and lysine 4 methylation but more predominantly affects histone H3 lysine 27 acetylation and chromatin accessibility. Furthermore, UTX suppresses components of AP-1 and, in turn, a gliogenesis program. CONCLUSIONS:Our findings revealed that UTX coordinates dualistic gene regulation to govern neural stem cell properties and neurogenesis-gliogenesis switch.