Project description:Social plasticity is a pervasive feature of animal behavior. Animals adjust the expression of their social behavior to the daily changes in social life and to transitions between life-history stages, and the ability to change in these ways impacts their Darwinian fitness. This behavioral plasticity may be achieved either by rewiring or by biochemically switching nodes of the neural network underlying the social behavior in response to perceived social information. Independent of the proximate mechanisms, at the neuromolecular level social plasticity relies on the regulation of gene expression, such that different neurogenomic states emerge in response to different social stimuli and the switches between states are orchestrated by signaling pathways that interface the social environment and the genotype. Here, we test this hypothesis by characterizing the changes in the brain profile of gene expression in response to social odors in the Mozambique Tilapia, Oreochromis mossambicus. This species has a rich repertoire of social behaviors during which both visual and chemical information are conveyed to conspecifics. Specifically, dominant males increase their urination frequency during agonist encounters and during courtship to convey chemical information reflecting their dominance status. We recorded electro-olfactograms to test the extent to which the olfactory epithelium can discriminate between olfactory information from dominant and subordinate males as well as from pre- and post-spawning females. We then performed a genome-scale gene expression analysis of the olfactory bulb and the olfactory cortex homolog in order to identify the neuromolecular systems involved in processing these social stimuli. Our results show that different olfactory stimuli from conspecifics’ have a major impact in the brain transcriptome, with different chemical social cues eliciting specific patterns of gene expression in the brain. These results confirm the role of rapid changes in gene expression in the brain as a genomic mechanism underlying behavioural plasticity and reinforce the idea of an extensive transcriptional plasticity of cichlid genomes, especially in response to rapid changes in their social environment.

Project description:Social plasticity is a pervasive feature of animal behavior. Animals adjust the expression of their social behavior to the daily changes in social life and to transitions between life-history stages, and the ability to change in these ways impacts their Darwinian fitness. This behavioral plasticity may be achieved either by rewiring or by biochemically switching nodes of the neural network underlying the social behavior in response to perceived social information. Independent of the proximate mechanisms, at the neuromolecular level social plasticity relies on the regulation of gene expression, such that different neurogenomic states emerge in response to different social stimuli and the switches between states are orchestrated by signaling pathways that interface the social environment and the genotype. Here, we test this hypothesis by characterizing the changes in the brain profile of gene expression in response to social odors in the Mozambique Tilapia, Oreochromis mossambicus. This species has a rich repertoire of social behaviors during which both visual and chemical information are conveyed to conspecifics. Specifically, dominant males increase their urination frequency during agonist encounters and during courtship to convey chemical information reflecting their dominance status. We recorded electro-olfactograms to test the extent to which the olfactory epithelium can discriminate between olfactory information from dominant and subordinate males as well as from pre- and post-spawning females. We then performed a genome-scale gene expression analysis of the olfactory bulb and the olfactory cortex homolog in order to identify the neuromolecular systems involved in processing these social stimuli. Our results show that different olfactory stimuli from conspecificsM-bM-^@M-^Y have a major impact in the brain transcriptome, with different chemical social cues eliciting specific patterns of gene expression in the brain. These results confirm the role of rapid changes in gene expression in the brain as a genomic mechanism underlying behavioural plasticity and reinforce the idea of an extensive transcriptional plasticity of cichlid genomes, especially in response to rapid changes in their social environment. Brain samples from 40 African cichlid males, Oreochromis mossambicus were collected after stimulation with different social olfactory stimuli. Samples were collected from 2 brain areas: BO and Dp after males were exposed to dominant (DOM) and subordinate (SUB) male urine and pre- (PRE) and post-ovulatory (POST) female scent. In OB 5 replicates were collected from males exposed to DOM and 6 to the other stimuli. For Dp 5 replicates were collected from males exposed to DOM and POST, 4 to SUB and 6 to PRE.

Project description:Genetic disruptions of the forkhead box transcription factor FOXP2 in humans cause an autosomal-dominant speech and language disorder. While FOXP2 expression pattern are highly conserved, its role in specific brain areas for mammalian social behaviors remains largely unknown. Here we studied mice carrying a homozygous cortical Foxp2 deletion. The postnatal development and gross morphological architecture of mutant mice was indistinguishable from wildtype (WT) littermates. Unbiased behavioral profiling of adult mice revealed abnormalities in approach behavior towards conspecifics as well as in the reciprocal responses of WT interaction partners. Furthermore mutant mice showed alterations in acoustical parameters of ultrasonic vocalizations (USV), which also differed in function of the social context. Cell type-specific gene expression profiling of cortical pyramidal neurons revealed aberrant regulation of genes involved in social behavior. In particular Foxp2 mutants showed the downregulation of Mint2 (Apba2), a gene involved in approach behavior in mice and autism spectrum disorder in humans. Taken together these data demonstrate that cortical Foxp2 is required for normal social behaviors in mice.

Project description:The lateral habenula (LHb) is an essential hub brain region modulating the monoamine system such as dopamine, serotonin. Hyperactivity of LHb has implications for psychiatric disorders such as depression, anxiety, and schizophrenia, which are commonly associated with social dysfunction. However, the role of LHb in social behavior has remained elusive. Here, we find that experiencing acute social isolation affects synaptic function in LHb and social behavior. After acute social isolation, long-term depression (LTD) in LHb is impaired and rescued by activating the 5-HT4 receptor (5-HT4R). Indeed, Htr4 expression in LHb is up-regulated following acute social isolation. Finally, acute social isolation enhances the social preference for familiars such as housing-mates to stranger conspecifics. Consistent with electrophysiological results, pharmacological activation of 5-HT4R in LHb restored innate social preference. These results suggest that acute social isolation influences social decisions with 5-HT4R-dependent synaptic modification in LHb.

Project description:Two Alexandrium fundyense (former tamarense) genotypes with different lytic capacties were analyzed with respect to their response towards co-occuring protistan grazers (Polykrikos) grazing on conspecifics. One Alexandrium genotype was able to lyse the grazer whereas the other genotype completely lacks this ability. The difference in their genotypes resulted in the creation of different niches and in difference in their gene expression response.

Project description:EGR4 (early growth response 4), a transcription factor, was previously shown to be up-regulated in lung cancer bone metastasis, compared with its expression in metastasis in other organs, using a multiorgan metastasis model of human small-cell lung cancer cells (SBC-5) in NK cell-depleted SCID mice (Kakiuchi S et al. Mol Cancer Res 2003). Here we show that EGR4 was essential for survival cancer cells, and migration ability. Next, in searching of downstream genes regulated by EGR4, we analyzed the changes in transcriptomes of SBC-5 cells at different time-points (24, 48 and 72 hr) when knockdown of EGR4 by siRNA. Lots of genes were identified either up-regulated or down-regulated in siEGR4 samples compared with control siRNA. Among these genes, there were genes with roles in metastasis or bone biology. The fact that EGR4 knockdown led to up-regulation or suppression of these genes also indicated dual roles of EGR4 in transcriptional regulation, which is consistent with previous reports: EGR4 may repress its own promoter (Zipfel PF et al. Biochim Biophys Acta. 1997) or activate certain inflammatory genes (Decker EL et al. Nucleic Acids Res. 2003; Wieland GD et al. J Cell Sci. 2005).

Project description:EGR4 (early growth response 4), a transcription factor, was previously shown to be up-regulated in lung cancer bone metastasis, compared with its expression in metastasis in other organs, using a multiorgan metastasis model of human small-cell lung cancer cells (SBC-5) in NK cell-depleted SCID mice (Kakiuchi S et al. Mol Cancer Res 2003). Here we show that EGR4 was essential for survival cancer cells, and migration ability. Next, in searching of downstream genes regulated by EGR4, we analyzed the changes in transcriptomes of SBC-5 cells at different time-points (24, 48 and 72 hr) when knockdown of EGR4 by siRNA. Lots of genes were identified either up-regulated or down-regulated in siEGR4 samples compared with control siRNA. Among these genes, there were genes with roles in metastasis or bone biology. The fact that EGR4 knockdown led to up-regulation or suppression of these genes also indicated dual roles of EGR4 in transcriptional regulation, which is consistent with previous reports: EGR4 may repress its own promoter (Zipfel PF et al. Biochim Biophys Acta. 1997) or activate certain inflammatory genes (Decker EL et al. Nucleic Acids Res. 2003; Wieland GD et al. J Cell Sci. 2005). SBC-5 cells were cultured at 1x10^6 cells/2 ml in 3.5 cm plate. After seeding 24 hours, cells were transfected either siEGR4 or siEGFP (for control), using Lipofectamin. At 24, 48 and 72 hours after starting of siRNA, we extracted RNA from these cells, and subjected these RNAs to microarray analysis. The labeling, amplification, hybridization and microarray data analysis were described previously (Dat LT et al. Int J Oncol, 40: 1455-1469 2012).

Project description:Innate social behaviors, such as mating and fighting, are fundamental to animal reproduction and survival. However, social engagements are associated with risks for the individual, such as pathogenic infection and physical injury. Little is known about the neural mechanism that allows for appropriate risk assessment and the suppression of hazardous social interactions. We have identified the posteromedial nucleus of the cortical amygdala (COApm) as a locus required for the suppression of mating with an unhealthy female and aggressive behaviors towards a dominant male intruder. Using anatomical tracing, functional imaging, and circuit-level epistatic analyses, we show that suppression of social engagements is mediated by the COApm projections onto the glutamatergic population of the medial amygdalar nucleus (MEA). We further show that this projection that governs social engagements is demarcated by expression of both the neuromodulator thyrotropin-releasing hormone (TRH) in the COApm and the TRH-receptor (TRHR) in the postsynaptic MEA glutamatergic neurons. Modulating TRH-expressing neurons as well as infusing TRHR ligand into the MEA phenocopy functional manipulation of the COApm-MEA circuit. We have, therefore, uncovered a novel neural mechanism that endows animals with the ability to modulate innate reproductive and aggressive social interactions according to the health and threat status of reciprocating individuals. Deficits in such a mechanism may lead to the spread of disease, while uncontrolled engagement may lead to pathological conditions, such as social withdrawal and depression.

Project description:Social play is a frequently studied behavior and it is the most characteristic form of social interaction observed in adolescent rats. Social play is necessary for adolescents to develop proper cognitive, emotional, and social competency. Deficits in social play have been observed in several neurodegenerative disorders such as autism, schizophrenia, and attention deficit hyperactivity disorder. However, the information available on neural substrates and the mechanism involved in social play is still limited. This study characterized social play by proteomic and transcriptional profiling studies. Social play was performed on male Sprague Dawley rats on postnatal day 38 and protein and gene expression in the amygdala was determined following behavioral testing. The proteomic analysis led to the identification of 170 differentially expressed proteins (p≤0.05) with 67 upregulated and 103 downregulated proteins. The transcriptomic analysis led to the identification of 188 genes (adjusted p≤0.05) with 55 upregulated and 133 downregulated genes. Based on both protein and gene expression data, DAVID analysis revealed that social play altered neurotransmitter signaling including GABAergic and glutamatergic signaling and G-protein coupled receptor (GPCR) signaling. These data suggest that the synaptic levels of GABA and glutamate increased during play. Ingenuity Pathway Analysis (IPA) confirmed these alterations. IPA also revealed that differentially expressed genes/proteins in our data had significant over representation of additional neurotransmitter signaling systems, including the opioid, serotonin, and dopamine systems, suggesting that play alters the systems involved in the regulation of reward. In addition, corticotropin-releasing hormone signaling was altered indicating that an increased level of stress occurs during play. Our data suggest that increased inhibitory GPCR signaling in these neurotransmitter pathways occurs following social play as a physiological response to regulate the induced level of reward and stress and to maintain the excitatory-inhibitory balance in the neurotransmitter systems.

Project description:Human male germline homeostasis depends on a balance between differentiation and maintenance of spermatogonial stem cells. To unveil the molecular regulation of this balance we compared human testicular tissues with severely perturbed germ cell differentiation with the normal situation. By performing single cell RNA sequencing of close to 30.000 cells and histomorphometric analysis we demonstrate that the proportion of spermatogonia remains remarkably stable despite the dwindling numbers of differentiated germ cells. In spite of this, these samples displayed altered stem cell dynamics with a push of reserve stem cells towards differentiation. This shift in dynamics was associated with the activation of gene networks regulated by four main gatekeeping transcription factors: ASCL2, EGR4, HOXC9, and DLX5. We provide invaluable information on the pathways regulating human germline stem cell dynamics along with evidence for a striking depletion of the reserve stem cell pool when these are disturbed.