Integrative multi-omics analyses reveal multi-modal FOXG1 functions acting on epigenetic processes and in concert with NEUROD1 to regulate synaptogenesis in the mouse hippocampus

Background: FOXG1 has important functions for neuronal differentiation and balances excitatory/inhibitory network activity. Mutations in the human FOXG1 gene cause a rare neurodevelopmental disorder, FOXG1-syndrome, which manifests differing phenotypes, including severe cognitive dysfunction, microencephaly, social withdrawal, and communication and memory deficits. Changes at the molecular level underlying these functional abnormalities upon FOXG1 haploinsufficiency are largely unexplored, in human patients as well as in animals modelling the debilitating disease. Methods: We present multi-omics data and explore comprehensively how FOXG1 impacts neuronal maturation at the chromatin level in the adult mouse hippocampus. We used RNA-, ATAC- and ChIP-sequencing of primary hippocampal neurons and co-immunoprecipitation to explore various levels of epigenetic changes and transcription factor networks acting to alter neuronal differentiation upon reduction of FOXG1. Results: We provide the first comprehensive multi-omics data set exploring FOXG1 presence at the chromatin and identifying the consequences of reduced FOXG1 expression in primary hippocampal neurons. Analyzing the multi-omics data, our study reveals that FOXG1 uses various different ways to regulate transcription at the chromatin level. On a genome-wide level, FOXG1 (i) both represses and activates transcription, (ii) binds mainly to enhancer regions, and (iii) bidirectionally alters the epigenetic landscape in regard to levels of H3K27ac, H3K4me3, and chromatin accessibility. Genes affected by the chromatin alterations upon FOXG1 reduction impact synaptogenesis and axonogenesis. This finding emphasizes the importance of FOXG1 to integrate and coordinate transcription of genes necessary for proper neuronal function by acting on a genome-wide level. Interestingly, FOXG1 acts through histone deacetylases (HDACs) and inhibition of HDACs partly rescued transcriptional alterations observed upon FOXG1 reduction. On a more detailed level of analysis, we show that FOXG1 (iv) operates synergistically with NEUROD1. Interestingly, we could not detect a clear hierarchy of these two key transcription factors, but instead provide first evidence that they act in highly concerted and orchestrated manner to control neuronal differentiation. Conclusions: This integrative and multi-omics view of changes upon FOXG1 reduction reveals an unprecedented multimodality ofFOXG1 functions converging on neuronal maturation, fueling novel therapeutic options based on epigenetic drugs to alleviate, at least in part, neuronal dysfunctions.

Astrocytic cell adhesion genes linked to schizophrenia promote synaptic programs in neurons

Recent genetic discoveries in schizophrenia have highlighted neuronal genes with functions in the synapse. Although emblematic of neurons, the development of synapses and neuronal maturation relies on interactions with glial cells including astrocytes. To study the role of glia-neuron interactions in schizophrenia, we generated RNA sequence data from human pluripotent stem cell (hPSC) derived neurons that were cocultured with glial cells. We found that expression of genes characteristic of astrocytes induced the expression of post-synaptic genetic programs in neurons, consistent with advanced neuronal maturation. We further found that the astrocyte-induced genes in neurons were associated with risk for schizophrenia. To understand how glial cells promoted neuronal maturation, we studied the association of transcript abundances in glial cells to gene expression in neurons. We found that expression of synaptic cell adhesion molecules in glial cells corresponded to induced synaptic transcripts in neurons and were associated with genetic risk for schizophrenia. These included 11 genes in significant GWAS loci and three with direct genetic evidence for the disorder (MAGI2, NRXN1, LRRC4B, and MSI2). Our results suggest that astrocyte-expressed genes with functions in the synapse are associated with schizophrenia and promote synaptic genetic programs in neurons, and further highlight the potential role for astrocyte-neuron interactions in schizophrenia.

Lower circulating neuron-specific enolase concentrations in adults and adolescents with severe mental illness

Background Both neurodegenerative and neurodevelopmental abnormalities have been suggested to be part of the etiopathology of severe mental illness (SMI). Neuron-specific enolase (NSE), mainly located in the neuronal cytoplasm, may indicate the process as it is upregulated after neuronal injury while a switch from non-neuronal enolase to NSE occurs during neuronal maturation. Methods We included 1132 adult patients with SMI [schizophrenia (SZ) or bipolar spectrum disorders], 903 adult healthy controls (HC), 32 adolescent patients with SMI and 67 adolescent HC. Plasma NSE concentrations were measured by enzyme immunoassay. For 842 adults and 85 adolescents, we used total grey matter volume (TGMV) based on T1-weighted magnetic resonance images processed in FreeSurfer v6.0. We explored NSE case-control differences in adults and adolescents separately. To investigate whether putative case-control differences in NSE were TGMV-dependent we controlled for TGMV. Results We found significantly lower NSE concentrations in both adult (p < 0.001) and adolescent patients with SMI (p = 0.007) compared to HC. The results remained significant after controlling for TGMV. Among adults, both patients with SZ spectrum (p < 0.001) and bipolar spectrum disorders (p = 0.005) had lower NSE than HC. In both patient subgroups, lower NSE levels were associated with increased symptom severity. Among adults (p < 0.001) and adolescents (p = 0.040), females had lower NSE concentrations than males. Conclusion We found lower NSE concentrations in adult and adolescent patients with SMI compared to HC. The results suggest the lack of progressive neuronal injury, and may reflect abnormal neuronal maturation. This provides further support of a neurodevelopmental rather than a neurodegenerative mechanism in SMI.

Alterations in Dendritic Spine Maturation and Neurite Development Mediated by FAM19A1

Neurogenesis and functional brain activity require complex associations of inherently programmed secretory elements that are regulated precisely and temporally. Family with sequence similarity 19 A1 (FAM19A1) is a secreted protein primarily expressed in subsets of terminally differentiated neuronal precursor cells and fully mature neurons in specific brain substructures. Several recent studies have demonstrated the importance of FAM19A1 in brain physiology; however, additional information is needed to support its role in neuronal maturation and function. In this study, dendritic spine morphology in Fam19a1-ablated mice and neurite development during in vitro neurogenesis were examined to understand the putative role of FAM19A1 in neural integrity. Adult Fam19a1-deficient mice showed low dendritic spine density and maturity with reduced dendrite complexity compared to wild-type (WT) littermates. To further explore the effect of FAM19A1 on neuronal maturation, the neurite outgrowth pattern in primary neurons was analyzed in vitro with and without FAM19A1. In response to FAM19A1, WT primary neurons showed reduced neurite complexity, whereas Fam19a1-decifient primary neurons exhibited increased neurite arborization, which was reversed by supplementation with recombinant FAM19A1. Together, these findings suggest that FAM19A1 participates in dendritic spine development and neurite arborization.