Project description:Bipolar disorder is a complex polygenetic disorder that is characterized by recurrent episodes of depression and mania, the heterogeneity of which is likely complicated by epigenetic modifications that remain to be elucidated. Here, we performed transcriptomic analysis of peripheral blood RNA from monozygotic twins discordant for bipolar disorder and identified a bipolar disorder-associated upregulated long non-coding RNA (lncRNA), AP1AR-DT. We observed that overexpression of AP1AR-DT in the mouse medial prefrontal cortex (mPFC) resulted in a reduction of both the total spine density and the spontaneous excitatory postsynaptic current (sEPSC) frequency of mPFC neurons, as well as depressive and anxiety-like behaviors. A combination of the results of brain transcriptome analysis of AP1AR-DT overexpressing mice brains with the known genes associated with bipolar disorder revealed that NEGR1, which encodes neuronal growth regulator 1, is one of the AP1AR-DT targets and is reduced in vivo upon gain of AP1AR-DT in mice. The results of the present study demonstrated that overexpression of recombinant Negr1 in the mPFC neurons of AP1AR-DTOE mice ameliorates depressive and anxiety-like behaviors and normalizes the reduced excitatory synaptic transmission induced by the gain of AP1AR-DT. Furthermore, the study provides evidence that AP1AR-DT reduces NEGR1 expression by competing for the transcriptional activator NRF1 in the overlapping binding site of the NEGR1 promoter region. The epigenetic and pathophysiological mechanism linking AP1AR-DT to the modulation of excitatory synaptic function provides etiological implications for bipolar disorder.

Project description:Hormonal fluctuations throughout the ovarian cycle contribute to femalesâ?? higher vulnerability to anxiety disorders when compared to males. Notably, such sex differences are controlled by regulation of genes in the medial prefrontal cortex (mPFC) including the transcription factor early growth response 1 (Egr1) in rats, which highlights a control of anxiety-like behaviors by sexually-biased gene expression. We therefore undertook a large-scale characterization of sex differences and their interaction with the estrous cycle in the adult mPFC transcriptome and report that proestrus and diestrus females (with high and low ovarian hormones levels, respectively) exhibited a partly-opposed sexually-biased transcriptome. Surprisingly, the extent of regulations within females vastly exceeded sex differences, and support a multi-level reorganization of synaptic function across the estrous cycle. Furthermore, genome-wide analysis of Egr1 binding highlighted its role in controlling the synapse-related genes varying within females, and the sex- and estrous cycle-dependent transcriptomic reorganization in the rat mPFC. Early growth response 1 (Egr1) binding profiling in the adult rat medial prefrontal cortex of males, proestrus females, and diestrus females. A total of 9 animals were used, corresponding to 3 Males, 2 proestrus females, and 4 diestrus females.

Project description:Hormonal fluctuations throughout the ovarian cycle contribute to females’ higher vulnerability to anxiety disorders when compared to males. Notably, such sex differences are controlled by regulation of genes in the medial prefrontal cortex (mPFC) including the transcription factor early growth response 1 (Egr1) in rats, which highlights a control of anxiety-like behaviors by sexually-biased gene expression. We therefore undertook a large-scale characterization of sex differences and their interaction with the estrous cycle in the adult mPFC transcriptome and report that proestrus and diestrus females (with high and low ovarian hormones levels, respectively) exhibited a partly-opposed sexually-biased transcriptome. Surprisingly, the extent of regulations within females vastly exceeded sex differences, and support a multi-level reorganization of synaptic function across the estrous cycle. Furthermore, genome-wide analysis of Egr1 binding highlighted its role in controlling the synapse-related genes varying within females, and the sex- and estrous cycle-dependent transcriptomic reorganization in the rat mPFC. mRNA profiling of 2-3 month-old males and females Sprague-Dawley rats in either Proestrus or Diestrus. A total of 11 samples were analyzed, corresponding to 4 males, 3 proestrus females, and 4 diestrus females.

Project description:Stressful life events increase risk for depression, yet the molecular mechanisms by which stress is encoded in the brain to induce maladaptive behaviors are not well understood. Emerging evidence has shown that stress dysregulates gene expression in the brain, yet the cellular origin of these gene expression alterations has yet to be determined. To address this question, we used a chronic unpredictable stress (CUS) paradigm that drives depressive- and anxiety-like behaviors in male and female mice and single-nucleus transcriptomics to identify cell type-specific gene expression changes in the cortex. We find that neocortical excitatory neurons are particularly vulnerable to chronic stress exposure, and that CUS reprograms these cells to decrease transcription of synaptic genes involved in glutamatergic neurotransmission. We identify the ubiquitously expressed factor, Yin Yang 1 (YY1), as a key driver of the transcriptional reprogramming observed in excitatory neurons isolated from CUS mice. Selective depletion of YY1 in excitatory neurons of the prefrontal cortex (PFC) increases the stress sensitivity of mice, inducing depressive- and anxiety-related behaviors following an abbreviated stress exposure and deregulating expression of key stress-related genes in the PFC. Importantly, we find that YY1 functions in both males and females to facilitate stress coping. This work establishes a novel mechanism underlying chronic stress-induced behavior, in which epigenetic responses to stress in PFC excitatory neurons are mediated by stress-dependent YY1 activity. Our findings demonstrate how post-mitotic neurons adapt to stress experience and identify a novel molecular target that is generalizable to males and females for therapeutic treatment of stress-related neuropsychiatric disorders.

Project description:Major depressive disorder (MDD) is a prevalent and life-threatening illness in modern society. The susceptibility to MDD is profoundly influenced by environmental factors, such as stressful lifestyle or traumatic events, which could impose maladaptive transcriptional program through epigenetic regulation. However, the underlying molecular mechanisms remain elusive. Here we report that stress-susceptible rodents exhibit lower levels of histone crotonylation in the medial prefrontal cortex (mPFC), concurrent with regional upregulation of chromodomain Y-like (CDYL), a crotonyl-CoA hydratase and histone methyllysine reader. Overexpression of CDYL in the prelimbic cortex (PL), a sub-region of mPFC, increases microdefeat-induced social avoidance behaviors and anhedonia in mice. Conversely, knockdown of CDYL in PL prevents chronic social defeat stress-induced depression-like behaviors. Mechanistically, we show that CDYL inhibits structural synaptic plasticity mainly by transcriptional repression of neuropeptide VGF, and this activity is dependent on its dual effect on regional histone crotonylation and H3K27 tri-methylation on the VGF promoter. Together, our data indicate CDYL plays a critical role in regulating stress-induced depression-like behaviors, providing a potential therapeutic target for MDD.

Project description:Inhibitory control is a core cognitive function preventing the expression of maladaptive behaviors. This function is overridden in mental illnesses including bipolar disorder, autism spectrum disorders and schizophrenia, causing maladaptive psychomotor agitation. We developed intersectional CRISPR/Cas9 targeting approaches in adult mice to identify receptor/circuit selective mechanisms responsible for inactivation of inhibitory control in two models of amphetamine-induced psychomotor agitation. Inactivation of dopamine D2-receptors in the medial-prefrontal cortex (mPFC) abolished amphetamine-induced: psychomotor agitation, motor sensitization, and cAMP-associated transcriptome changes in the striatum. Further characterization using intersectional projection preparations indicate that these deficits implicate D2-receptors expressed on projection neurons innervating cholinergic interneurons of the dorsomedial striatum (DMS). Trans-synaptic targeting of acetylcholine production in DMS neurons receiving these projections restored psychomotor agitation in mice lacking mPFC D2- receptor expression. These findings identify a circuit by which activation of cortical D2-receptor circumvent an acetylcholine-mediated inhibition of DMS functions by the mPFC to promote psychomotor activation.

Project description:Hormonal fluctuations throughout the ovarian cycle contribute to females’ higher vulnerability to anxiety disorders when compared to males. Notably, such sex differences are controlled by regulation of genes in the medial prefrontal cortex (mPFC) including the transcription factor early growth response 1 (Egr1) in rats, which highlights a control of anxiety-like behaviors by sexually-biased gene expression. We therefore undertook a large-scale characterization of sex differences and their interaction with the estrous cycle in the adult mPFC transcriptome and report that proestrus and diestrus females (with high and low ovarian hormones levels, respectively) exhibited a partly-opposed sexually-biased transcriptome. Surprisingly, the extent of regulations within females vastly exceeded sex differences, and support a multi-level reorganization of synaptic function across the estrous cycle. Furthermore, genome-wide analysis of Egr1 binding highlighted its role in controlling the synapse-related genes varying within females, and the sex- and estrous cycle-dependent transcriptomic reorganization in the rat mPFC.

Project description:Hormonal fluctuations throughout the ovarian cycle contribute to females’ higher vulnerability to anxiety disorders when compared to males. Notably, such sex differences are controlled by regulation of genes in the medial prefrontal cortex (mPFC) including the transcription factor early growth response 1 (Egr1) in rats, which highlights a control of anxiety-like behaviors by sexually-biased gene expression. We therefore undertook a large-scale characterization of sex differences and their interaction with the estrous cycle in the adult mPFC transcriptome and report that proestrus and diestrus females (with high and low ovarian hormones levels, respectively) exhibited a partly-opposed sexually-biased transcriptome. Surprisingly, the extent of regulations within females vastly exceeded sex differences, and support a multi-level reorganization of synaptic function across the estrous cycle. Furthermore, genome-wide analysis of Egr1 binding highlighted its role in controlling the synapse-related genes varying within females, and the sex- and estrous cycle-dependent transcriptomic reorganization in the rat mPFC.

Project description:RBFOX3 mutations are linked to epilepsy and cognitive impairments, but the underlying pathophysiology of these disorders is poorly understood. Here we report replication of human symptoms in a mouse model with disrupted Rbfox3. Rbfox3 knockout mice displayed increased seizure susceptibility and decreased anxiety-related behaviors. Focusing on hippocampal phenotypes, we found Rbfox3 knockout mice showed increased expression of plasticity genes Egr4 and Arc, and the synaptic transmission and plasticity were defective in the mutant perforant pathway. The mutant dentate granules cells exhibited an increased frequency, but normal amplitude, of excitatory synaptic events, and this change was associated with an increase in the neurotransmitter release probability and dendritic spine density. Together, our results demonstrate anatomical and functional abnormality in Rbfox3 knockout mice, and may provide mechanistic insights for RBFOX3-related human brain disorders. Two samples (one is from wild-type and the other is from Rbfox3 homozygous knockout mice)

Project description:Impairment in social communication skills is a hallmark feature of autism spectrum disorder (ASD). The role of G-protein coupled receptor 158 (GPR158) in ASD remains largely unexplored. In this study, we observed both constitutive and cell/tissue-specific knockouts of Gpr158 in pyramidal neurons or medial prefrontal cortex (mPFC) result in impaired novelty preference, while sociability remains unaffected in male mice. Notably, loss of GPR158 leads to a significant decline in excitatory synaptic transmission, characterized by the reduction in glutamate vesicles, as well as the expression and phosphorylation of GluN2B in the mPFC. We successfully rescue the phenotype of social novelty deficits either by reintroducing GPR158 in the mPFC of Gpr158 deficient mice or by chemogenetic activation of pyramidal neurons where Gpr158 is specifically ablated. Our findings indicate that GPR158 in pyramidal neurons plays a specific role in modulating social novelty, and may represent a potential target for treating social disorder.