Project description:Neurons of the CNS must maintain their distinct identity over an entire lifespan. Apart from instructive information provided by transcription factors driving neuron specific genes, other gene programs need to be permanently silenced. The mechanisms governing enduring gene-silencing in neurons are largely unknown, as are the consequences if they fail. Here we show that loss of the Polycomb repressive complex 2 (PRC2) obligate unit Eed in differentiated murine midbrain dopamine (mDA) neurons resulted in progressive loss of the H3K27me3 histone modification followed by upregulation of PRC2 targets, also highly enriched for the constitutive heterochromatin H3K9me3 modification. This was followed by reduced expression of mDA neuron-identity genes, particularly evident in the Substantia nigra pars compacta. Consequently, mDA-neuronal function was severely disrupted, causing parkinsonian-like motor skill deficits. Deletion of Eed in differentiated serotonergic (5HT) neurons resulted in a similar upregulation of PRC2-targets and reduced expression of genes defining 5HT neurons, which promoted loss of serotonergic identity followed by loss of function and altered behaviour. Overall, our results reveal that PRC2 inactivation leads to a selective and progressive loss of mDA or 5HT neuronal identity and function, but not to any loss of cells. Thus, our study shows that PRC2-dependent maintenance of neuronal identity is essential and safeguards against expression of other non-relevant gene programs and loss of neuronal function.

Project description:Neurons of the CNS must maintain their distinct identity over an entire lifespan. Apart from instructive information provided by transcription factors driving neuron specific genes, other gene programs need to be permanently silenced. The mechanisms governing enduring gene-silencing in neurons are largely unknown, as are the consequences if they fail. Here we show that loss of the Polycomb repressive complex 2 (PRC2) obligate unit Eed in differentiated murine midbrain dopamine (mDA) neurons resulted in progressive loss of the H3K27me3 histone modification followed by upregulation of PRC2 targets, also highly enriched for the constitutive heterochromatin H3K9me3 modification. This was followed by reduced expression of mDA neuron-identity genes, particularly evident in the Substantia nigra pars compacta. Consequently, mDA-neuronal function was severely disrupted, causing parkinsonian-like motor skill deficits. Deletion of Eed in differentiated serotonergic (5HT) neurons resulted in a similar upregulation of PRC2-targets and reduced expression of genes defining 5HT neurons, which promoted loss of serotonergic identity followed by loss of function and altered behaviour. Overall, our results reveal that PRC2 inactivation leads to a selective and progressive loss of mDA or 5HT neuronal identity and function, but not to any loss of cells. Thus, our study shows that PRC2-dependent maintenance of neuronal identity is essential and safeguards against expression of other non-relevant gene programs and loss of neuronal function.

Project description:The 5HT system is organized into rostral and caudal populations with discrete anatomical locations and opposite axonal trajectories in the developing hindbrain. 5HT neuron cell bodies in the rostral subdivision migrate to the midbrain and pons and extend ascending projections throughout the forebrain. 5HT cell bodies in the caudal subdivision migrate to the ventral medulla and caudal half of the pons and provide descending projections to the brainstem and spinal cord. Experiment Overall Design: We used microarrays to determine genes expressed by both rostral and caudal 5HT neurons as well as genes that are differentially expressed between rostral and caudal 5HT neurons at E12.5 when axon pathfinding and cell migration are underway. E12.5 neural tubes were isolated from ePet-EYFP embryos and dissected into a rostral domain (mesecephalic flexure to pontine flexure) and a caudal domain (pontine flexure to spinal cord). After cell dissociation (details under growth protocol), cells were subjected to fluorescent activated cell sorting (FACS) to obtain 4 cell populations. R+ = rostral ePetEYFP positive 5HT neurons; R- = YFP negative non-serotonergic cells in the rostral neural tube; C+ = caudal ePetEYFP positive 5HT neurons; C- = YFP negative non-serotonergic cells in the caudal neural tube. 200,000 cells for each of the 4 cell types (R+, R-, C+, C-) were collected for RNA extraction and hybridization to Affymetrix Mouse 430 2.0 arrays.

Project description:The histone methyltransferase complex PRC2 is a crucial chromatin modifier and controls key steps in developmental transitions and cell fate choices. Mutations in PRC2 core subunits are found in Weaver syndrome with craniofacial defects, intellectual disabilities, and often macrocephaly, but its pathogenicity and molecular mechanism are unknown. Here, we examined the role of PRC2/Eed in neural stem/progenitor cells (NSPCs) during cortical neurogenesis We found that Eed is highly expressed in embryonic cerebral cortex and specific deletion of Eed in forebrain reduced the number of upper layer neurons but not deeper layer neurons and ultimately contributed to abnormal cortical development. In addition, our results revealed that PRC2/Eed regulated Hedgehog signaling pathway through activation of Gli3 not dependent on H3K27me3 but H3K27ac. What?s more, Increased Gli3 in NSPCs could reduce Gli1 expression and contribute to the defects of cortical neurogenesis caused by Eed deletion. Finally, Hedgehog signaling activation with small molecule SAG or genetic inactivation of Ptch1 could partially rescue the cortical neurogenesis defects in vivo after Eed depletion. In general, we identified a novel PRC2/Eed-Gli3-Gli1 regulatory axis that is critical for normal cortical neurogenesis. Our findings define a critical function for PRC2/Eed in cortical development and shed light on the genetic basis of intellectual disabilities of neural developmental disorders caused by PRC2/Eed mutation.

Project description:The histone methyltransferase complex PRC2 is a crucial chromatin modifier and controls key steps in developmental transitions and cell fate choices. Mutations in PRC2 core subunits are found in Weaver syndrome with craniofacial defects, intellectual disabilities, and often macrocephaly, but its pathogenicity and molecular mechanism are unknown. Here, we examined the role of PRC2/Eed in neural stem/progenitor cells (NSPCs) during cortical neurogenesis We found that Eed is highly expressed in embryonic cerebral cortex and specific deletion of Eed in forebrain reduced the number of upper layer neurons but not deeper layer neurons and ultimately contributed to abnormal cortical development. In addition, our results revealed that PRC2/Eed regulated Hedgehog signaling pathway through activation of Gli3 not dependent on H3K27me3 but H3K27ac. What?s more, Increased Gli3 in NSPCs could reduce Gli1 expression and contribute to the defects of cortical neurogenesis caused by Eed deletion. Finally, Hedgehog signaling activation with small molecule SAG or genetic inactivation of Ptch1 could partially rescue the cortical neurogenesis defects in vivo after Eed depletion. In general, we identified a novel PRC2/Eed-Gli3-Gli1 regulatory axis that is critical for normal cortical neurogenesis. Our findings define a critical function for PRC2/Eed in cortical development and shed light on the genetic basis of intellectual disabilities of neural developmental disorders caused by PRC2/Eed mutation.

Project description:The Polycomb Repressive Complex 2 (PRC2) regulates corticogenesis, yet how PRC2 influences cell identity in the mature brain is poorly defined. Using a mouse model in which the PRC2 gene Eed is conditionally deleted from the developing mouse dorsal telencephalon, we performed single nuclei RNA sequencing on the cortical plate of adult heterozygote and homozygote Eed knockout mice compared to controls.

Project description:Mutations in the SNCA gene cause autosomal dominant Parkinson’s disease (PD), with progressive loss of dopaminergic neurons in the substantia nigra, and accumulation of aggregates of α-synuclein. However, the sequence of molecular events that proceed from the SNCA mutation during development, to its end stage pathology is unknown. Utilising human induced pluripotent stem cells (hiPSCs) with SNCA mutations, we resolved the temporal sequence of pathophysiological events that occur during neuronal differentiation in order to discover the early, and likely causative, events in synucleinopathies. We adapted a small molecule-based protocol that generates highly enriched midbrain dopaminergic (mDA) neurons (>80%). We characterised their molecular identity using single-cell RNA sequencing and their functional identity through the synthesis and secretion of dopamine, the ability to generate action potentials, and form functional synapses and networks. RNA velocity analyses confirmed the developmental transcriptomic trajectory of midbrain neural precursors into different mDA neuronal clusters. To characterise the synucleinopathy, we adopted super-resolution methods to determine the number, size, and structure of aggregates in SNCA-mutant mDA neurons. By day 27 of differentiation, prior to maturation to mDA neurons of molecular and functional identity, we demonstrate the formation of small aggregates; specifically, β-sheet rich oligomeric aggregates, in SNCA-mutant midbrain immature neurons. The aggregation progresses over time to accumulate phosphorylated and fibrillar aggregates. When the midbrain neurons were functional, we observed impaired intracellular calcium signalling, evidenced with an increased basal calcium level and impairments in both cytosolic and mitochondrial calcium rearrangements. Once midbrain identity fully developed, SNCA-mutant neurons exhibited mitochondrial dysfunction, oxidative stress, lysosomal swelling as well as an upregulation of mitophagy and autophagy. In addition, SNCA-mutant neurons displayed pathophysiological excitability, revealed as a depolarised resting membrane potential, an increased input resistance, and impaired firing properties. Ultimately these multiple cellular stresses lead to an increase in cell death by day 62 post-differentiation. Our differentiation paradigm generates an efficient model for studying disease mechanisms in PD, and highlights that protein misfolding to generate intraneuronal oligomers is one of the earliest critical events driving disease in human neurons, rather than a late-stage hallmark of the disease.

Project description:Analysis of changes in gene expression in skin epidermis upon conditional knockout of the essential Polycomb repressive complex 2 (PRC2) subunit Eed. Loss of Eed in skin epithelium leads to de-repression of key Merkel-differentiation genes, which are known PRC2 targets, and results in ectopic formation of Merkel cells that are associated with all hair types. Gene expression analysis: To determine the changes in gene expression in skin epidermis upon conditional knockout of Eed, total RNA was isolated from skin epidermis in four biologic replicates from cells in different conditions and hybridized to SurePrint G3 Mouse GE 8X60K microarrays (Agilent).

Project description:To date, it remains largely unclear to what extent chromatin machinery contributes to the susceptibility and progression of complex diseases. Here, we combine deep epigenome mapping with single cell transcriptomics to mine for evidence of chromatin dysregulation in type-2 diabetes. We find two chromatin-state signatures that track β-cell dysfunction in mice and humans: ectopic activation of bivalent Polycomb-silenced domains and loss of expression at an epigenomically unique class of lineage-defining genes. β-cell specific Polycomb (Eed/PRC2) loss of function in mice triggers diabetes-mimicking transcriptional signatures and highly penetrant, hyperglycemia-independent, dedifferentiation, indicating that PRC2 dysregulation contributes to disease. The work provides novel resources for exploring β-cell transcriptional regulation and identifies PRC2 as necessary for long-term maintenance of β-cell identity. Importantly, the data suggest a two-hit (chromatin and hyperglycemia) model for loss of β-cell identity in diabetes.

Project description:Analysis of changes in gene expression in skin epidermis upon conditional knockout of the essential Polycomb repressive complex 2 (PRC2) subunit Eed. Loss of Eed in skin epithelium leads to de-repression of key Merkel-differentiation genes, which are known PRC2 targets, and results in ectopic formation of Merkel cells that are associated with all hair types.