Project description:The neural stem cell decision to self-renew or differentiate is tightly regulated by its microenvironment. Here, we have asked about this microenvironment, focusing on growth factors in the embryonic cortex at a time when it is largely comprised of neural precursor cells (NPCs) and newborn neurons. We show that cortical NPCs secrete factors that promote their maintenance while cortical neurons secrete factors that promote differentiation. To define factors important for these activities, we used transcriptome profiling to identify ligands produced by NPCs and neurons, cell surface mass spectrometry to identify receptors on these cells, and computational modeling to integrate these data. The resultant model predicts a complex growth factor environment with multiple autocrine and paracrine interactions. We tested this communication model, focusing on neurogenesis, and identified IFNγ, Nrtn and glial-derived neurotrophic factor (GDNF) as ligands with unexpected roles in promoting neurogenic differentiation of NPCs in vivo. We prepared E16 cortical neuron, E13 cortical precursor and co-cultured E16 cortical neuron and E13 cortical precursor cultures from three independent biological replicates.

Project description:The developing mammalian brain generates a variety of Neural Progenitor Cells (NPCs). Primary NPCs throughout the neuraxis are derived from the ventricular zone. Intermediate progenitor cells (IPCs) are produced uniquely in the telencephalon and contribute extensively to the neurons that comprise the cerebral cortex and basal ganglia. It is known that the fate of the diverse NPC populations is determined by the interplay of transcription factors and regulation by regional humoral cues. However, despite our recent appreciation that nutrient-regulated intracellular metabolic milieu (pO2, energy, and redox state) significantly influence cell fate, an unexplored area is whether NPCs have intrinsic metabolic identity, and if so, the mechanism by which molecular metabolism contributes to brain development.Little is known however, if intrinsic differences in cellular metabolism of regional NPCs make certain NPCs susceptible while others resistant to genetic and environmental insults. We conjectured that regional (fore-and hindbrain) NPCs are metabolically distinct.

Project description:Cell-based models of many neurological and psychiatric diseases, established by reprogramming patient somatic cells into human induced pluripotent stem cells (hiPSCs), have now been reported. While numerous reports have demonstrated that neuronal cells differentiated from hiPSCs are electrophysiologically active mature neurons, the “age” of these cells relative to cells in the human brain remains unresolved. Comparisons of gene expression profiles of hiPSC-derived neural progenitor cells (NPCs) and neurons to the Allen BrainSpan Atlas indicate that hiPSC neural cells most resemble first trimester neural tissue. Consequently, we posit that hiPSC-derived neural cells may most accurately be used to model the early developmental defects that contribute to disease predisposition rather than the late features of the disease. Though the characteristic symptoms of schizophrenia (SCZD) generally appear late in adolescence, it is now thought to be a neurodevelopmental condition, often predated by a prodromal period that can appear in early childhood. Postmortem studies of SCZD brain tissue typically describe defects in mature neurons, such as reduced neuronal size and spine density in the prefrontal cortex and hippocampus, but abnormalities of neuronal organization, particularly in the cortex, have also been reported. We postulated that defects in cortical organization in SCZD might result from abnormal migration of neural cells. To test this hypothesis, we directly reprogrammed fibroblasts from SCZD patients into hiPSCs and subsequently differentiated these disorder-specific hiPSCs into NPCs. SCZD hiPSC differentiated into forebrain NPCs have altered expression of a number of cellular adhesion genes, reduced WNT signaling and aberrant cellular migration. 3 independent differentiations (biological replicates) for each of four control and four schizophrenic patients were analyzed.

Project description:Cell-based models of many neurological and psychiatric diseases, established by reprogramming patient somatic cells into human induced pluripotent stem cells (hiPSCs), have now been reported. While numerous reports have demonstrated that neuronal cells differentiated from hiPSCs are electrophysiologically active mature neurons, the “age” of these cells relative to cells in the human brain remains unresolved. Comparisons of gene expression profiles of hiPSC-derived neural progenitor cells (NPCs) and neurons to the Allen BrainSpan Atlas indicate that hiPSC neural cells most resemble first trimester neural tissue. Consequently, we posit that hiPSC-derived neural cells may most accurately be used to model the early developmental defects that contribute to disease predisposition rather than the late features of the disease. Though the characteristic symptoms of schizophrenia SZ generally appear late in adolescence, it is now thought to be a neurodevelopmental condition, often predated by a prodromal period that can appear in early childhood. Postmortem studies of SZ brain tissue typically describe defects in mature neurons, such as reduced neuronal size and spine density in the prefrontal cortex and hippocampus, but abnormalities of neuronal organization, particularly in the cortex, have also been reported. We postulated that defects in cortical organization in SZ might result from abnormal migration of neural cells. To test this hypothesis, we directly reprogrammed fibroblasts from SZ patients into hiPSCs and subsequently differentiated these disorder-specific hiPSCs into NPCs. SZ hiPSC differentiated into forebrain NPCs have altered expression of a number of cellular adhesion genes and WNT signaling. Methods: We compared global transcription of forebrain NPCs from six control and four SZ patients by RNAseq. Results: Multi-dimensional scaling (MDS) resolved most SZ and control hiPSC NPC samples; 848 genes were significantly differentially expressed (FDR<0.01) Conclusions: The WNT signaling pathway was enriched 2-fold (fisher exact test p-value = 0.031). 1-2 independent differentiations (biological replicates) for each of four control and four schizophrenia patients were analyzed; samples were generated in parallel to neuron RNAseq data.

Project description:Tau is encoded by MAPT and abnormal aggregates of tau are a hallmark of a group of neurodegenerative diseases called tauopathies. MAPT is lowly expressed in neural progenitor cells (NPCs), but it is more highly expressed in oligodendrocytes, astrocytes, and neurons that derive from NPCs. This expression switch at differentiation suggests that MAPT expression is controlled by transcription factors and cis-regulatory elements specific to these differentiated cell types, including neurons.

Project description:Tau is encoded by MAPT and abnormal aggregates of tau are a hallmark of a group of neurodegenerative diseases called tauopathies. MAPT is lowly expressed in neural progenitor cells (NPCs), but it is more highly expressed in oligodendrocytes, astrocytes, and neurons that derive from NPCs. This expression switch at differentiation suggests that MAPT expression is controlled by transcription factors and cis-regulatory elements specific to these differentiated cell types, including neurons.

Project description:Tau is encoded by MAPT and abnormal aggregates of tau are a hallmark of a group of neurodegenerative diseases called tauopathies. MAPT is lowly expressed in neural progenitor cells (NPCs), but it is more highly expressed in oligodendrocytes, astrocytes, and neurons that derive from NPCs. This expression switch at differentiation suggests that MAPT expression is controlled by transcription factors and cis-regulatory elements specific to these differentiated cell types, including neurons.

Project description:Tau is encoded by MAPT and abnormal aggregates of tau are a hallmark of a group of neurodegenerative diseases called tauopathies. MAPT is lowly expressed in neural progenitor cells (NPCs), but it is more highly expressed in oligodendrocytes, astrocytes, and neurons that derive from NPCs. This expression switch at differentiation suggests that MAPT expression is controlled by transcription factors and cis-regulatory elements specific to these differentiated cell types, including neurons.

Project description:Tau is encoded by MAPT and abnormal aggregates of tau are a hallmark of a group of neurodegenerative diseases called tauopathies. MAPT is lowly expressed in neural progenitor cells (NPCs), but it is more highly expressed in oligodendrocytes, astrocytes, and neurons that derive from NPCs. This expression switch at differentiation suggests that MAPT expression is controlled by transcription factors and cis-regulatory elements specific to these differentiated cell types, including neurons.

Project description:Tau is encoded by MAPT and abnormal aggregates of tau are a hallmark of a group of neurodegenerative diseases called tauopathies. MAPT is lowly expressed in neural progenitor cells (NPCs), but it is more highly expressed in oligodendrocytes, astrocytes, and neurons that derive from NPCs. This expression switch at differentiation suggests that MAPT expression is controlled by transcription factors and cis-regulatory elements specific to these differentiated cell types, including neurons.