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Project description:Sexual dimorphisms in the brain give rise to sex differences in physiology and behavior, yet we have limited understanding of the transcriptomic changes underlying their development. We evaluated developmental transcriptome dynamics for one of the most extreme neuroanatomical sexual dimorphisms in vertebrates - the songbird robust nucleus of the arcopallium (RA). RA is the telencephalic motor output nucleus of the song system. It grows monomorphically for the first few weeks posthatch, then continues growing in males but regresses in females, becoming 5-7 times larger in males. We quantified RA gene expression from monomorphic and dimorphic stages of development in both sexes. Mirroring the morphology, male and female transcriptomes initially resembled one other, then diverged markedly. Thousands of genes showed developmental regulation, corresponding to highly sex-specific biological processes. Males showed enrichments for neuronal growth and morphogenesis, synapse organization, metabolism, and voltage-gated ion channels. Females showed enrichments for cell polarity and differentiation, chemotaxis inhibition, gene silencing, and hormone and immune signaling. Notably, the majority of sex-biased genes in monomorphic RA were sex chromosome Z genes. These findings reveal a profound, sex-specific reorganization of RA’s transcriptome, providing novel insights into potential targets and drivers of sexually dimorphic neurodevelopment.

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Project description:To identify genes that are downstream of gonadal hormones and that control dimorphic behaviors, we used a MEEBO array platform to profile gene expression of adult male and female hypothalamus against a whole brain reference sample. The experimental design allowed us to identify genes that are upreguated in the hypothalamus compared to the whole brain and are dimorphically expressed between the two sexes. In situ hybridization of candiate genes were carried out to validate the dimorphic expression of these genes in the hypothalamus. Array results were used to create a list of genes to screen by in situ hybridization. For each normalization method, a list of genes that were upregulated in the male or the female was created, and a gene had to be on a set number of these individual normalization lists in order to be considered for screening. A similar method was used to create a list of hypothalamic upregulated genes. The final screening list was comprised of genes that were upregulated in the male or female as well as in the hypothalamus. If in situ hybridization proved that the gene was upregulated in the male or female brain, we concluded that that transcript was differentially expressed. No one normalization method was weighted over another, and the array results were used to create a screening list for in situ hybridizations. Hypothalami from 4 adult animals of each sex were microdissected and pooled for each experimental sample and the whole brain plus pituitary from one male and one female were pooled to provide the reference sample. Each set of samples (male and female) was hybridized to two arrays to provide two technical replicates for each set of samples taken. A total of three sets of samples were taken (three biological replicates). For the "_amp" Samples, source (hypothalamus and whole brain) mRNA was amplified using T7 based method. For this set, data were not normalized, rather the raw intensities were used to calculate ratios. Candidate genes from this study was also included in final list in situ screening.

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Project description: Not available