Project description:Glial progenitor cells (GPCs), the primary source of oligodendrocytes and astrocytes in the human CNS, emerge during the 2nd trimester of human development and subsequently colonize the brain, where a pool remains throughout adulthood. While fetal GPCs are highly migratory and proliferative, there is evidence that their capacities diminish throughout aging or as a result of demyelination-induced exhaustion, thus compromising their ability to mobilize, remyelinate, and self-renew. To investigate this mechanism, we first utilized bulk and scRNA-Sequencing to characterize the human fetal GPC pool and leveraged these data to elucidate transcriptional discrepancies in adult human GPCs. This revealed age-induced transcriptional shifts towards loss of proliferative competency and the potential onset of senescence. Further, we inferred adult networks of direct repressive transcription factor activity that may drive functional decline during GPC aging. Finally, we coupled these data with miRNA profiling of both populations to establish both upstream and parallel arms of repression that may stifle the functional aptitude of aged GPCs. These identified upstream regulators may be ideal therapeutic targets toward rejuvenating GPCs crippled by mitotic exhaustion or aging.

Project description:Glial progenitor cells (GPCs), the primary source of oligodendrocytes and astrocytes in the human CNS, emerge during the 2nd trimester of human development and subsequently colonize the brain, where a pool remains throughout adulthood. While fetal GPCs are highly migratory and proliferative, there is evidence that their capacities diminish throughout aging or as a result of demyelination-induced exhaustion, thus compromising their ability to mobilize, remyelinate, and self-renew. To investigate this mechanism, we first utilized bulk and scRNA-Sequencing to characterize the human fetal GPC pool and leveraged these data to elucidate transcriptional discrepancies in adult human GPCs. This revealed age-induced transcriptional shifts towards loss of proliferative competency and the potential onset of senescence. Further, we inferred adult networks of direct repressive transcription factor activity that may drive functional decline during GPC aging. Finally, we coupled these data with miRNA profiling of both populations to establish both upstream and parallel arms of repression that may stifle the functional aptitude of aged GPCs. These identified upstream regulators may be ideal therapeutic targets toward rejuvenating GPCs crippled by mitotic exhaustion or aging.

Project description:Glial progenitor cells comprise the most abundant population of progenitor cells in the adult human brain. They are responsible for CNS remyelination, and likely contribute to the astrogliotic response to brain injury and degeneration as well. Adult human GPCs are biased to differentiate as oligodendrocytes and elaborate new myelin, and yet they retain multilineage plasticity, and can give rise to neurons as well as astrocytes and oligodendrocytes once removed from the adult parenchymal environment. GPCs retain strong mechanisms for cell-autonomous self-renewal, and yet both their phenotype and fate may be dictated by their microenvironment. Using the transcriptional profiles of acutely isolated GPCs, we have begun to understand the operative ligand-receptor interactions involved in these processes, and have identified several key signaling pathways by which adult human GPCs may be reliably instructed to either oligodendrocytic or astrocytic fate. In addition, we have noted significant differences between the expressed genes and dominant signaling pathways of fetal and adult human GPCs, as well as between rodent and human GPCs. The latter data in particular call into question therapeutic strategies predicated solely upon data obtained using rodents, while perhaps highlighting the extent to which evolution has been attended by the phylogenetic modification of glial phenotype and function. Human adult brain dissociates were sorted for one of three markers, either GLT1 (astrocyte, n =3), CD11b (microglia, n=4) or A2B5 (glial progenitor cell, n=7). In addition to positively selected, the negative fraction and unsorted dissociates were collected as matched controls for each sort.

Project description:Huntington’s disease (HD) is characterized by hypomyelination as well as by neuronal loss. To assess the basis for white matter involution in HD, we generated bipotential glial progenitor cells (GPCs) from human embryonic stem cells (hESCs), derived from either huntingtin (mHTT)-mutant embryos or normal controls, and performed RNA sequence analysis to assess mHTT-dependent changes in gene expression. In hGPCs derived from 3 distinct mHTT-expressing hESC lines, a set of transcription factors associated with glial differentiation and myelin synthesis was sharply down-regulated, relative to normal hESC GPCs. In particular, NKX2.2, OLIG2, SOX10 and MYRF were all suppressed, with the consequent diminution of myelinogenesis-associated transcription. Accordingly, when mHTT-expressing hGPCs were transplanted into hypomyelinated shiverer mice, the resultant mHTT glial chimeras were hypomyelinated. The mHTT hGPCs also manifested impaired astrocytic differentiation, and developed abnormal fiber domain architecture. These data suggest that white matter involution in HD is a product of a cell-autonomous mHTT-dependent suppression of both astrocytic and oligodendrocytic differentiation by affected GPCs.

Project description:The molecular basis of astrocyte differentiation and maturation is poorly understood. As microRNAs have important roles in cell fate transitions, we set out to study their function during the glial progenitor cell (GPC) to astrocyte transition. Inducible deletion of all canonical microRNAs in GPCs in vitro led to a block in the differentiation to astrocytes. In an unbiased screen, the reintroduction of let-7 and miR-125 families of microRNAs rescued differentiation. Let-7 and miR-125 shared many targets and functioned in parallel to JAK-STAT signaling, a known regulator of astrogliogenesis. While individual knockdown of shared targets did not rescue the differentiation phenotype in microRNA-deficient GPCs, overexpression of these targets in wild-type GPCs blocked differentiation. This finding supports the idea that microRNAs simultaneously suppress multiple mRNAs that inhibit differentiation. The microRNA-regulated targets were enriched for genes downregulated during in vivo astrocyte differentiation and upregulated in glioblastomas, consistent with validity of using the in vitro model to study in vivo events. These findings provide insight into the microRNAs and the genes they regulate in this important cell fate transition. Small RNA profiling of 2 replicates of GPCs and astrocytes

Project description:Glial progenitor cells comprise the most abundant population of progenitor cells in the adult human brain. They are responsible for CNS remyelination, and likely contribute to the astrogliotic response to brain injury and degeneration as well. Adult human GPCs are biased to differentiate as oligodendrocytes and elaborate new myelin, and yet they retain multilineage plasticity, and can give rise to neurons as well as astrocytes and oligodendrocytes once removed from the adult parenchymal environment. GPCs retain strong mechanisms for cell-autonomous self-renewal, and yet both their phenotype and fate may be dictated by their microenvironment. Using the transcriptional profiles of acutely isolated GPCs, we have begun to understand the operative ligand-receptor interactions involved in these processes, and have identified several key signaling pathways by which adult human GPCs may be reliably instructed to either oligodendrocytic or astrocytic fate. In addition, we have noted significant differences between the expressed genes and dominant signaling pathways of fetal and adult human GPCs, as well as between rodent and human GPCs. The latter data in particular call into question therapeutic strategies predicated solely upon data obtained using rodents, while perhaps highlighting the extent to which evolution has been attended by the phylogenetic modification of glial phenotype and function.

Project description:The molecular basis of astrocyte differentiation and maturation is poorly understood. As microRNAs have important roles in cell fate transitions, we set out to study their function during the glial progenitor cell (GPC) to astrocyte transition. Inducible deletion of all canonical microRNAs in GPCs in vitro led to a block in the differentiation to astrocytes. In an unbiased screen, the reintroduction of let-7 and miR-125 families of microRNAs rescued differentiation. Let-7 and miR-125 shared many targets and functioned in parallel to JAK-STAT signaling, a known regulator of astrogliogenesis. While individual knockdown of shared targets did not rescue the differentiation phenotype in microRNA-deficient GPCs, overexpression of these targets in wild-type GPCs blocked differentiation. This finding supports the idea that microRNAs simultaneously suppress multiple mRNAs that inhibit differentiation. The microRNA-regulated targets were enriched for genes downregulated during in vivo astrocyte differentiation and upregulated in glioblastomas, consistent with validity of using the in vitro model to study in vivo events. These findings provide insight into the microRNAs and the genes they regulate in this important cell fate transition.

Project description:Huntington’s disease (HD) and juvenile-onset schizophrenia (SCZ) have long been regarded as distinct disorders. However, both manifest cell-intrinsic abnormalities in glial differentiation, with resultant astrocytic dysfunction and hypomyelination. To assess whether a common mechanism might underlie the similar glial pathology of these otherwise disparate conditions, we utilized comparative correlation network approaches to analyze RNA-seq data from human glial progenitor cells (hGPCs) produced from disease-derived pluripotent stem cells. We identified gene sets preserved between HD and SCZ hGPCs yet distinct from normal controls, that included 174 highly-connected genes in the shared disease-associated network, focused on genes involved in synaptic signaling. These synaptic genes were largely suppressed in both SCZ and HD hGPCs, and gene regulatory network analysis identified a core set of upstream regulators of this network, of which OLIG2 and TCF7L2 were prominent. Among their downstream targets, ADGRL3, a modulator of glutamatergic synapses, was notably suppressed in both SCZ and HD hGPCs. ChIP-seq confirmed that OLIG2 and TCF7L2 each bound to the regulatory region of ADGRL3, whose expression was then rescued by lentiviral overexpression of these transcription factors. These data suggest that the disease-associated suppression of OLIG2 and TCF7L2-dependent transcription of glutamate signaling regulators may impair glial receptivity to neuronal glutamate. The consequent loss of activity-dependent mobilization of hGPCs may yield deficient oligodendrocyte production, and hence the hypomyelination noted in these disorders, as well as the disrupted astrocytic differentiation and attendant synaptic dysfunction associated with each. Together, these data highlight the importance of convergent glial molecular pathology in both the pathogenesis and phenotypic similarities of two otherwise unrelated disorders, HD and SCZ.

Project description:Huntington’s disease (HD) and juvenile-onset schizophrenia (SCZ) have long been regarded as distinct disorders. However, both manifest cell-intrinsic abnormalities in glial differentiation, with resultant astrocytic dysfunction and hypomyelination. To assess whether a common mechanism might underlie the similar glial pathology of these otherwise disparate conditions, we utilized comparative correlation network approaches to analyze RNA-seq data from human glial progenitor cells (hGPCs) produced from disease-derived pluripotent stem cells. We identified gene sets preserved between HD and SCZ hGPCs yet distinct from normal controls, that included 174 highly-connected genes in the shared disease-associated network, focused on genes involved in synaptic signaling. These synaptic genes were largely suppressed in both SCZ and HD hGPCs, and gene regulatory network analysis identified a core set of upstream regulators of this network, of which OLIG2 and TCF7L2 were prominent. Among their downstream targets, ADGRL3, a modulator of glutamatergic synapses, was notably suppressed in both SCZ and HD hGPCs. ChIP-seq confirmed that OLIG2 and TCF7L2 each bound to the regulatory region of ADGRL3, whose expression was then rescued by lentiviral overexpression of these transcription factors. These data suggest that the disease-associated suppression of OLIG2 and TCF7L2-dependent transcription of glutamate signaling regulators may impair glial receptivity to neuronal glutamate. The consequent loss of activity-dependent mobilization of hGPCs may yield deficient oligodendrocyte production, and hence the hypomyelination noted in these disorders, as well as the disrupted astrocytic differentiation and attendant synaptic dysfunction associated with each. Together, these data highlight the importance of convergent glial molecular pathology in both the pathogenesis and phenotypic similarities of two otherwise unrelated disorders, HD and SCZ.

Project description:Huntington’s disease (HD) and juvenile-onset schizophrenia (SCZ) have long been regarded as distinct disorders. However, both manifest cell-intrinsic abnormalities in glial differentiation, with resultant astrocytic dysfunction and hypomyelination. To assess whether a common mechanism might underlie the similar glial pathology of these otherwise disparate conditions, we utilized comparative correlation network approaches to analyze RNA-seq data from human glial progenitor cells (hGPCs) produced from disease-derived pluripotent stem cells. We identified gene sets preserved between HD and SCZ hGPCs yet distinct from normal controls, that included 174 highly-connected genes in the shared disease-associated network, focused on genes involved in synaptic signaling. These synaptic genes were largely suppressed in both SCZ and HD hGPCs, and gene regulatory network analysis identified a core set of upstream regulators of this network, of which OLIG2 and TCF7L2 were prominent. Among their downstream targets, ADGRL3, a modulator of glutamatergic synapses, was notably suppressed in both SCZ and HD hGPCs. ChIP-seq confirmed that OLIG2 and TCF7L2 each bound to the regulatory region of ADGRL3, whose expression was then rescued by lentiviral overexpression of these transcription factors. These data suggest that the disease-associated suppression of OLIG2 and TCF7L2-dependent transcription of glutamate signaling regulators may impair glial receptivity to neuronal glutamate. The consequent loss of activity-dependent mobilization of hGPCs may yield deficient oligodendrocyte production, and hence the hypomyelination noted in these disorders, as well as the disrupted astrocytic differentiation and attendant synaptic dysfunction associated with each. Together, these data highlight the importance of convergent glial molecular pathology in both the pathogenesis and phenotypic similarities of two otherwise unrelated disorders, HD and SCZ.