Epigenetic mechanisms such as DNA methylation are essential regulators of the function and information storage capacity of neurons. DNA methylation is highly dynamic in the developing and adult brain, and is actively regulated by neuronal activity and behavioural experiences. However, it is presently unclear how methylation status at individual genes is targeted for modification. Here, we report that extra-coding RNAs (ecRNAs) interact with DNA methyltransferases and regulate neuronal DNA methylation. Expression of ecRNA species is associated with gene promoter hypomethylation, is altered by neuronal activity, and is overrepresented at genes involved in neuronal function. Knockdown of the Fos ecRNA locus results in gene hypermethylation and mRNA silencing, and hippocampal expression of Fos ecRNA is required for long-term fear memory formation in rats. These results suggest that ecRNAs are fundamental regulators of DNA methylation patterns in neuronal systems, and reveal a promising avenue for therapeutic targeting in neuropsychiatric disease states.
Genomic enhancer elements regulate gene expression programs important for neuronal fate and function and are implicated in brain disease states. Enhancers undergo bidirectional transcription to generate non-coding enhancer RNAs (eRNAs). However, eRNA function remains controversial. Here, we combined Assay for Transposase-Accessible Chromatin using Sequencing (ATAC-Seq) and RNA-Seq datasets from three distinct neuronal culture systems in two activity states, enabling genome-wide enhancer identification and prediction of putative enhancer–gene pairs based on correlation of transcriptional output. Notably, stimulus-dependent enhancer transcription preceded mRNA induction, and CRISPR-based activation of eRNA synthesis increased mRNA at paired genes, functionally validating enhancer–gene predictions. Focusing on enhancers surrounding the Fos gene, we report that targeted eRNA manipulation bidirectionally modulates Fos mRNA, and that Fos eRNAs directly interact with the histone acetyltransferase domain of the enhancer-linked transcriptional co-activator CREB-binding protein (CBP). Together, these results highlight the unique role of eRNAs in neuronal gene regulation and demonstrate that eRNAs can be used to identify putative target genes.
As the primary source of norepinephrine (NE) in the brain, the locus coeruleus (LC) regulates both arousal and stress responses. However, how local neuromodulatory inputs contribute to LC function remains unresolved. Here we identify a network of transcriptionally and functionally diverse GABAergic neurons in the LC dendritic field that integrate distant inputs and modulate modes of LC firing to control arousal. We define peri-LC anatomy using viral tracing and combine single-cell RNA sequencing and spatial transcriptomics to molecularly define both LC and peri-LC cell types. We identify several cell types which underlie peri-LC functional diversity using a series of complementary approaches in behaving mice. Our findings indicate that LC and peri-LC neurons comprise transcriptionally and functionally heterogenous neuronal populations, alongside anatomically segregated features which coordinate specific influences on behavioral arousal and avoidance states. Defining the molecular, cellular and functional diversity in the LC provides a road map for understanding the neurobiological basis of arousal alongside hyperarousal-related neuropsychiatric phenotypes.
Learning to predict rewards is essential for the survival of animals. Contemporary views suggest that such learning is driven by a reward prediction error-the difference between received and predicted rewards. Here we show using two-photon calcium imaging and optogenetics in mice that a different class of reward learning signals exists within the orbitofrontal cortex (OFC). Specifically, the reward responses of many OFC neurons exhibit plasticity consistent with filtering out rewards that are less salient for learning (such as predicted rewards, or, unpredicted rewards available in a context containing highly salient aversive stimuli). We show using quasi-simultaneous imaging and optogenetics that this reward response plasticity is sculpted by medial thalamic inputs to OFC. These results provide a biological substrate for emerging theoretical views of meta-reinforcement learning in prefrontal cortex.
Enhancer elements in DNA regulate gene expression programs important for neuronal fate and function, and are increasingly implicated in brain disease states. Enhancers undergo bidirectional transcription to generate non-coding enhancer RNAs (eRNAs), but the function of eRNAs in neuronal systems remains controversial. Here, we performed genome-wide characterization of transcribed enhancers from rat cortical neurons, revealing elevated sequence conservation, enriched localization near genes involved in neuronal or synaptic function, and correlated activity-dependent regulation of putative eRNA-mRNA pairs. Functional validation using a CRISPR-dCas9 fusion system to drive eRNA synthesis from enhancers produced corresponding increases in mRNA at linked genes. Focusing on eRNAs arising from enhancers at the Fos gene locus, we report that eRNA and mRNA correlate on a single-cell level, that CRISPR-targeted eRNA delivery to an enhancer is sufficient for mRNA induction, and that eRNA knockdown decreases mRNA and alters neuronal physiology. These results suggest that eRNAs regulate gene expression and neuronal function.Correspondence to Jeremy Day (jjday@uab.edu | day-lab.org | @DayLabUAB)
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