Project description:Corticosterone drives behavioral inflexibility via plasticity-related gene expression in the dorsal striatum

Project description:We report age-differential synaptic plasticity deficits associated with cognitive inflexibility and CaMKIIa hyperactivity in Adnp-mutant mice. These mice show impaired and inflexible contextual learning and memory along with social and anxiety-related deficits in adults, long after the juvenile-stage decrease of ADNP protein levels to ~10% of the newborn level. Adnp-mutant mice show abnormally enhanced long-term potentiation in adults but not in juveniles. This is accompanied by CaMKIIa hyperactivity involving increased baseline autophosphorylation and altered phosphorylation of CaMKIIa substrates, as revealed by unbiased proteomic analyses.

Project description:The proteome of glutamatergic synapses is diverse across the mammalian brain and involved in neurodevelopmental disorders (NDDs). Among those is Fragile X syndrome (FXS), an NDD caused by the dysfunctional RNA binding protein FMRP. Here we demonstrate how the brain region-specific composition of post-synaptic density (PSD) contributes to FXS. The FXS mouse model shows, in the striatum, an altered association of the PSD with the actin cytoskeleton, reflecting immature dendritic spine morphology and reduced synaptic actin dynamics. Enhancing actin turnover with constitutively active RAC1 ameliorates these deficits. At the behavioral level, the FXS model displays striatal-driven inflexibility, a typical feature of FXS individuals, that is rescued by exogenous RAC1. Striatal ablation of Fmr1 is sufficient to recapitulate behavioral impairments observed in the FXS model. These results indicate that dysregulation of synaptic actin dynamics in the striatum, a region largely unexplored in FXS, contributes to the manifestation of FXS behavioral phenotypes.

Project description:ADNP syndrome, involving the ADNP transcription factor in the SWI/SNF chromatin-remodeling complex, is characterized by developmental delay, intellectual disability, and autism spectrum disorders (ASD). In ASD, ADNP is a highly penetrant risk gene, accounting for ~0.17% cases. Although Adnp-haploinsufficient mice display various phenotypic deficits, the underlying synaptic mechanisms are poorly understood. Here we report age-differential synaptic plasticity deficits associated with cognitive inflexibility and CaMKIIα hyperactivity in Adnp-mutant mice. These mice show impaired and inflexible contextual learning and memory additional to social and anxiety-related deficits in adults long after a marked decrease in ADNP protein levels to ~10% of newborn levels in juveniles. In addition, Adnp-mutant adults show abnormally enhanced long-term potentiation in adults but not in juveniles. This accompanies CaMKIIα hyperactivity involving increased baseline autophosphorylation, as revealed by unbiased proteomic analyses. Therefore, ADNP haploinsufficiency in mice leads to cognitive inflexibility involving altered synaptic plasticity and signaling in adults long after a marked decrease in Adnp expression in juveniles.

Project description:We report age-differential synaptic plasticity deficits associated with cognitive inflexibility and CaMKIIa hyperactivity in Adnp-mutant mice. These mice show impaired and inflexible contextual learning and memory additional to social and anxiety-related deficits in adults long after a marked decrease in ADNP protein levels to ~10% of newborn levels in juveniles. In addition, Adnp-mutant adults show abnormally enhanced long-term potentiation in adults but not in juveniles. This accompanies CaMKIIa hyperactivity involving increased baseline autophosphorylation, as revealed by unbiased proteomic analyses.

Project description:The human striatum can be subdivided into the caudate, putamen, and nucleus accumbens (NAc). In mice, this roughly corresponds to the dorsal medial striatum (DMS), dorsal lateral striatum (DLS), and ventral striatum (NAc). Each of these structures have some overlapping and distinct functions related to motor control, cognitive processing, motivation, and reward. Previously, we used a “time-of-death” approach to identify diurnal rhythms in RNA transcripts in these three human striatal subregions. Here, we identify molecular rhythms across similar striatal subregions collected from C57BL/6J mice across 6 times of day and compare results to the human striatum. Pathway analysis indicates a large degree of overlap between species in rhythmic transcripts involved in processes like cellular stress, energy metabolism, and translation. Notably, a striking finding in humans is that small nucleolar RNAs (snoRNAs) and long non-coding RNAs (lncRNAs) are among the most highly rhythmic transcripts in the NAc and this is not conserved in mice, suggesting the rhythmicity of RNA processing in this region could be uniquely human. Furthermore, the peak timing of overlapping rhythmic genes is altered between species, but not consistently in one direction. Taken together, these studies reveal conserved as well as distinct transcriptome rhythms across the human and mouse striatum and are an important step in understanding the normal function of diurnal rhythms in humans and model organisms in these regions and how disruption could lead to pathology.

Project description:Chronic stress is a major triggering factor for neuropsychiatric disorders including obsessive-compulsive disorder (OCD), a mental health condition characterized by motor stereotypies and striatal overactivation. However, the mechanisms at the cell- and microcircuit-level through which stress triggers motor symptoms is currently unknown. Here, we report that chronic stress (CS) in mice alters dorsomedial striatum (DMS) function, by affecting GABAergic interneuron populations and somatostatin-positive (SOM) interneurons in particular. Specifically, we show that CS impairs communication between SOM interneurons and medium spiny neurons, promoting striatal overactivation / disinhibition and increased motor output. Using probabilistic machine learning for analyzing animal behavior we further demonstrate that in vivo chemogenetic manipulation of SOM interneurons in DMS modulates motor phenotypes in stressed mice. Altogether, we propose a causal link between dysfunction of striatal SOM interneurons and motor symptoms in stress-related neuropsychiatric disorders.

Project description:Corticosterone (CORT)-mediated adaptive plasticity improves animal fitness in stressful environments. Although it brings ecological benefits, the cost potentially constrains its expression and evolution. Revealing the factors affecting plasticity costs is of great ecological and evolutionary significance. Evidence indicates that both CORT and background colour can induce metabolic changes in animals, which in turn determine phenotypic plasticity. However, whether and/or how CORT and background colour jointly act on plastic responses has not been studied. Here, this question has been investigated in amphibian tadpoles (Microhyla fissipes) exposed to CORT at different background colours (white or black) using integrated morphological, histological, and transcriptomic analyses. The results showed that CORT exposure increased relative tail length, immune function, and metabolic maintenance (i.e., transcription of substrate catabolism and oxidative phosphorylation) at the expense of reduction in growth rate and skin melanin level. The black background also increased relative tail length and metabolic maintenance (i.e., transcription of oxidative phosphorylation) at the cost of reduction in growth rate, but increased skin melanin level. The expression of critical pigmentation genes indicated that black background activated a distinct and opposite pigmentation regulating route to CORT. Although there was no interactive effect of background colour and CORT on phenotypic and metabolic variations, their additive effects further impact the trade-off between somatic growth, metabolic maintenance, and pigmentation in terms of resource allocation. In conclusion, the individual and additive effects of background colour and CORT exposure on tadpole plasticity were revealed. These results likely provide new insights into the environmental adaptation of animals.

Project description:The ventromedial prefrontal cortex (vmPFC) is a part of the limbic system engaged in higher-order functions ranging from behavioral flexibility to social cognition characteristically impaired in schizophrenia and autism. Intrinsically photosensitive retinal ganglion cells (ipRGCs) are a major source of indirect input to this area by way of the recently discovered perihabenular nucleus (PHb). Here, we demonstrate that the integrity of the vmPFC is dependent on ipRGC input: Its loss in mice causes dendritic degeneration, dysregulation of genes involved in synaptic plasticity, and depressed neuronal activity in the vmPFC. These alterations are reflected in a profound inability to suppress emotional interference in behavior.

Project description:Transcriptional study to investigate differences in prefrontal cortex and striatum of mice that consumed ethanol despite negative consequences, which resembles the compulsive aspect of alcohol addiction. The transcriptional analysis performed in the striatum and prefrontal cortex revealed genes and biological pathways differentially regulated specifically in animals of the group Inflexible Drinkers that could be involved with the loss of control over voluntary ethanol consumption (da Silva E Silva et al., 2016; de Paiva Lima et al., 2017).