Project description:Here, we set out to understand the extent and nature of epigenomic changes associated with sexual differentiation in the brown alga Ectocarpus, which has a well described UV system. Five histone modifications, H3K4me3, H3K27Ac, H3K9Ac, H3K36me3, H4K20me3, were quantified in near-isogenic male and female lines, leading to the identification of 13 different chromatin states across the Ectocarpus genome that showed different patterns of enrichment at transcribed, silent, housekeeping or narrowly-expressed genes. Chromatin states were strongly correlated with levels of gene expression indicating a relationship between the assayed marks and gene transcription. The relative proportion of each chromatin state across the genome remained stable in males and females, but a subset of genes exhibited different chromatin states in the two sexes. In particular, males and females displayed distinct patterns of histone modifications at sex-biased genes, indicating that chromatin state transitions occur preferentially at genes involved in sex-specific pathways. Finally, our results reveal the unique chromatin landscape of the U and V sex chromosomes compared to autosomes. Taken together, our observations reveal a role for histone modifications in sex determination and sexual differentiation in a UV sexual system, and suggest that the mechanisms of epigenetic regulation of genes on the U/V sex chromosomes may differ from those operating on autosomal genes.

Project description:In poultry, in vitro derived primordial germ cells (PGCs) represent an important tool for management of genetic resources. However, several studies have highlighted sexual differences exhibited by PGCs through in vitro steps, which may compromise their reproductive capacities. To understand this phenomenon, we compared the proteome of pregonadal chicken male (ZZ) and female (ZW) PGCs expanded in vitro by quantitative proteomic analysis using a GeLC-MS/MS strategy. The proteins found to be differentially abundant in chicken male and female PGCs indicated their early sexual identity. Many of the proteins up-accumulated in male PGCs were encoded by genes strongly enriched in the sexual chromosome Z. This suggests that the known lack of dosage compensation of the transcription of Z-linked genes between sexes persists at protein level in PGCs, and that this may be a key factor of their autonomous sex differentiation. Male and female PGCs up-accumulated protein sets were associated with differential biological processes, and contained proteins biologically relevant for male and female germ cell development respectively. This study presents first evidence on early predetermined sex specific cell fate of chicken PGCs that will help to understand their sexual physiological specificities and enable more precise sex-specific adaptation of in vitro culture conditions.

Project description:Metabolism in males and females is distinct. Differences are usually linked to sexual reproduction, with circulating signals (e.g. hormones) playing major roles. By contrast, sex differences prior to sexual maturity and intrinsic to individual metabolic tissues are less understood. We analyzed Drosophila melanogaster larvae and find that males store more fat than females, the opposite of the sexual dimorphism in adults. We show that metabolic differences are intrinsic to the major fat storage tissue, including many differences in the expression of metabolic genes. Our previous work identified fat storage roles for Spenito (Nito), a conserved RNA-binding protein and regulator of sex determination. Nito knockdown specifically in the fat storage tissue abolished fat differences between males and females. We further show that Nito is required for sex-specific expression of the master regulator of sex determination, Sex-lethal (Sxl). “Feminization” of fat storage cells via tissue-specific overexpression of a Sxl target gene made larvae lean, reduced the fat differences between males and females, and induced female-like metabolic gene expression. Altogether, this study supports a model in which Nito autonomously controls sexual dimorphisms and differential expression of metabolic genes in fat cells in part through its regulation of the sex determination pathway.

Project description:The extraordinary range in the degree of sexual dimorphism (SD) among animal species is widely perceived to be caused in part by differences in patterns of sexual selection, but sex-specific adaptations and sex chromosome differences also play a role. Studies in insects have discovered a substantial number of sex-biased genes, but little is known about the epigenetic basis of SD. The degree and genome-wide distribution of sex-biased expression become interesting questions in hymenoptera species with haplodiploid sex-determination. To study the genetic and epigenetic architecture of SD and understand the conservation and evolution of sex-biased expression in a haplodiploid system that lacks sex chromosomes, we performed RNA-seq and whole-genome bisulfite sequencing in female and male adult samples of two parasitoid wasp species, Nasonia vitripennis and Nasonia giraulti. More than 75% of the expressed genes displayed significantly sex-biased expression. Both the number and the degree of sex-biased genes are higher than insects like Drosophila melanogaster, which have sex-chromosome mediated sex determination. Females from the two Nasonia species have far more similar expression profiles than does the contrast between the two sexes within either species. Interestingly, the extremely male- and female-biased genes are enriched for totally different functional categories: male-biased genes are highly enriched for key enzymes in sex-pheromone synthesis; female-biased genes are enriched for nuclear-located genes that are responsible for epigenetic regulation of gene expression. Unlike gene expression profiles, DNA methylomes are more similar within species, and no stable differentially methylated genes have been found between the two sexes, suggesting that DNA methylation is not directly responsible for the molecular basis of SD. However, methylation status does influence sex-biased expression: 80% of female-biased genes are methylated, which is more than two-fold higher than the genome average (30%); almost all male-biased and sex-specific genes are non-methylated, which is consistent with the fact that methylated genes have house-keeping functions and a broader expression breadth. Evolutionarily, male-biased genes have greater sequence divergence between the two species, and they are more likely to have a functional paralog in the Nasonia genome. Sex-specific genes have significantly higher non-synonymous substitution rates and dN/dS ratios. In addition, local clusters of sex-biased genes in the genome may have epigenetic properties similar to the sex chromosome. In summary, Nasonia accomplish a striking degree of sex-differential expression through a difference in ploidy along with associated differences in methylations status. Whole-genome bisulfite sequencing of 24-hour adult whole body samples of Nasonia vitripennis and Nasonia giraulti using Iilumina sequencing.

Project description:The extraordinary range in the degree of sexual dimorphism (SD) among animal species is widely perceived to be caused in part by differences in patterns of sexual selection, but sex-specific adaptations and sex chromosome differences also play a role. Studies in insects have discovered a substantial number of sex-biased genes, but little is known about the epigenetic basis of SD. The degree and genome-wide distribution of sex-biased expression become interesting questions in hymenoptera species with haplodiploid sex-determination. To study the genetic and epigenetic architecture of SD and understand the conservation and evolution of sex-biased expression in a haplodiploid system that lacks sex chromosomes, we performed RNA-seq and whole-genome bisulfite sequencing in female and male adult samples of two parasitoid wasp species, Nasonia vitripennis and Nasonia giraulti. More than 75% of the expressed genes displayed significantly sex-biased expression. Both the number and the degree of sex-biased genes are higher than insects like Drosophila melanogaster, which have sex-chromosome mediated sex determination. Females from the two Nasonia species have far more similar expression profiles than does the contrast between the two sexes within either species. Interestingly, the extremely male- and female-biased genes are enriched for totally different functional categories: male-biased genes are highly enriched for key enzymes in sex-pheromone synthesis; female-biased genes are enriched for nuclear-located genes that are responsible for epigenetic regulation of gene expression. Unlike gene expression profiles, DNA methylomes are more similar within species, and no stable differentially methylated genes have been found between the two sexes, suggesting that DNA methylation is not directly responsible for the molecular basis of SD. However, methylation status does influence sex-biased expression: 80% of female-biased genes are methylated, which is more than two-fold higher than the genome average (30%); almost all male-biased and sex-specific genes are non-methylated, which is consistent with the fact that methylated genes have house-keeping functions and a broader expression breadth. Evolutionarily, male-biased genes have greater sequence divergence between the two species, and they are more likely to have a functional paralog in the Nasonia genome. Sex-specific genes have significantly higher non-synonymous substitution rates and dN/dS ratios. In addition, local clusters of sex-biased genes in the genome may have epigenetic properties similar to the sex chromosome. In summary, Nasonia accomplish a striking degree of sex-differential expression through a difference in ploidy along with associated differences in methylations status. Profiling of expression levels in Nasonia vitripennis and Nasonia giraulti adult male and female samples using Illumina RNA-seq

Project description:The extraordinary range in the degree of sexual dimorphism (SD) among animal species is widely perceived to be caused in part by differences in patterns of sexual selection, but sex-specific adaptations and sex chromosome differences also play a role. Studies in insects have discovered a substantial number of sex-biased genes, but little is known about the epigenetic basis of SD. The degree and genome-wide distribution of sex-biased expression become interesting questions in hymenoptera species with haplodiploid sex-determination. To study the genetic and epigenetic architecture of SD and understand the conservation and evolution of sex-biased expression in a haplodiploid system that lacks sex chromosomes, we performed RNA-seq and whole-genome bisulfite sequencing in female and male adult samples of two parasitoid wasp species, Nasonia vitripennis and Nasonia giraulti. More than 75% of the expressed genes displayed significantly sex-biased expression. Both the number and the degree of sex-biased genes are higher than insects like Drosophila melanogaster, which have sex-chromosome mediated sex determination. Females from the two Nasonia species have far more similar expression profiles than does the contrast between the two sexes within either species. Interestingly, the extremely male- and female-biased genes are enriched for totally different functional categories: male-biased genes are highly enriched for key enzymes in sex-pheromone synthesis; female-biased genes are enriched for nuclear-located genes that are responsible for epigenetic regulation of gene expression. Unlike gene expression profiles, DNA methylomes are more similar within species, and no stable differentially methylated genes have been found between the two sexes, suggesting that DNA methylation is not directly responsible for the molecular basis of SD. However, methylation status does influence sex-biased expression: 80% of female-biased genes are methylated, which is more than two-fold higher than the genome average (30%); almost all male-biased and sex-specific genes are non-methylated, which is consistent with the fact that methylated genes have house-keeping functions and a broader expression breadth. Evolutionarily, male-biased genes have greater sequence divergence between the two species, and they are more likely to have a functional paralog in the Nasonia genome. Sex-specific genes have significantly higher non-synonymous substitution rates and dN/dS ratios. In addition, local clusters of sex-biased genes in the genome may have epigenetic properties similar to the sex chromosome. In summary, Nasonia accomplish a striking degree of sex-differential expression through a difference in ploidy along with associated differences in methylations status.

Project description:The extraordinary range in the degree of sexual dimorphism (SD) among animal species is widely perceived to be caused in part by differences in patterns of sexual selection, but sex-specific adaptations and sex chromosome differences also play a role. Studies in insects have discovered a substantial number of sex-biased genes, but little is known about the epigenetic basis of SD. The degree and genome-wide distribution of sex-biased expression become interesting questions in hymenoptera species with haplodiploid sex-determination. To study the genetic and epigenetic architecture of SD and understand the conservation and evolution of sex-biased expression in a haplodiploid system that lacks sex chromosomes, we performed RNA-seq and whole-genome bisulfite sequencing in female and male adult samples of two parasitoid wasp species, Nasonia vitripennis and Nasonia giraulti. More than 75% of the expressed genes displayed significantly sex-biased expression. Both the number and the degree of sex-biased genes are higher than insects like Drosophila melanogaster, which have sex-chromosome mediated sex determination. Females from the two Nasonia species have far more similar expression profiles than does the contrast between the two sexes within either species. Interestingly, the extremely male- and female-biased genes are enriched for totally different functional categories: male-biased genes are highly enriched for key enzymes in sex-pheromone synthesis; female-biased genes are enriched for nuclear-located genes that are responsible for epigenetic regulation of gene expression. Unlike gene expression profiles, DNA methylomes are more similar within species, and no stable differentially methylated genes have been found between the two sexes, suggesting that DNA methylation is not directly responsible for the molecular basis of SD. However, methylation status does influence sex-biased expression: 80% of female-biased genes are methylated, which is more than two-fold higher than the genome average (30%); almost all male-biased and sex-specific genes are non-methylated, which is consistent with the fact that methylated genes have house-keeping functions and a broader expression breadth. Evolutionarily, male-biased genes have greater sequence divergence between the two species, and they are more likely to have a functional paralog in the Nasonia genome. Sex-specific genes have significantly higher non-synonymous substitution rates and dN/dS ratios. In addition, local clusters of sex-biased genes in the genome may have epigenetic properties similar to the sex chromosome. In summary, Nasonia accomplish a striking degree of sex-differential expression through a difference in ploidy along with associated differences in methylations status.

Project description:Chromatin modifications have essential roles in directing nervous system development and behavior. Drosophila courtship is an ideal model for understanding the relationships between chromatin modifications, gene expression, sexual dimorphisms in neuroanatomy, and reproductive behaviors. These behaviors are largely innate and are under the control of sex determination hierarchy genes doublesex (dsx) and fruitless (fru) that encode sex-specific transcription factors. Transcripts from the fru P1 promoter are sex-specifically spliced, resulting in male-specific proteins, FruM, which are required for male courtship behaviors. FruM has been shown to form a complex with Bonus/TIF1, a transcriptional cofactor, and interact with chromatin modifying proteins. This indicates that sex-differential modification of the chromatin landscape contributes to creating and maintaining the potential for sexually dimorphic behavior. To examine chromatin modifications genome-wide in fru P1-expressing neurons, we have developed a method to purify chromatin in a cell-type-specific manner using a tagged histone H2B under UAS control, “Chromatag”, paired with sequential ChIP-seq. Here, we evaluate five chromatin modifications: H3K27ac, H3K4me3, H3K36me3, H3K9me3, and H3K27me3 to investigate fru P1-expressing neurons at three developmental stages in both sexes. These modifications have been well characterized for their roles in transcriptional activation or repression. We observe greater changes in chromatin modification profiles across developmental stages than between sexes. In addition, we have generated cell-type specific RNA-seq data sets, using Translating Ribosome Affinity Purification (TRAP), to examine gene expression in fru P1-expressing neurons of both sexes. Informed by these data sets, we have identified several genes with roles in neuronal function and examined their expression in fru P1-expressing neurons, revealing sexually dimorphic expression patterns. Altogether, this work offers insights into stage and sex-differences in chromatin modifications and gene expression in fru P1-expressing neurons.

Project description:Chromatin modifications have essential roles in directing nervous system development and behavior. Drosophila courtship is an ideal model for understanding the relationships between chromatin modifications, gene expression, sexual dimorphisms in neuroanatomy, and reproductive behaviors. These behaviors are largely innate and are under the control of sex determination hierarchy genes doublesex (dsx) and fruitless (fru) that encode sex-specific transcription factors. Transcripts from the fru P1 promoter are sex-specifically spliced, resulting in male-specific proteins, FruM, which are required for male courtship behaviors. FruM has been shown to form a complex with Bonus/TIF1, a transcriptional cofactor, and interact with chromatin modifying proteins. This indicates that sex-differential modification of the chromatin landscape contributes to creating and maintaining the potential for sexually dimorphic behavior. To examine chromatin modifications genome-wide in fru P1-expressing neurons, we have developed a method to purify chromatin in a cell-type-specific manner using a tagged histone H2B under UAS control, “Chromatag”, paired with sequential ChIP-seq. Here, we evaluate five chromatin modifications: H3K27ac, H3K4me3, H3K36me3, H3K9me3, and H3K27me3 to investigate fru P1-expressing neurons at three developmental stages in both sexes. These modifications have been well characterized for their roles in transcriptional activation or repression. We observe greater changes in chromatin modification profiles across developmental stages than between sexes. In addition, we have generated cell-type specific RNA-seq data sets, using Translating Ribosome Affinity Purification (TRAP), to examine gene expression in fru P1-expressing neurons of both sexes. Informed by these data sets, we have identified several genes with roles in neuronal function and examined their expression in fru P1-expressing neurons, revealing sexually dimorphic expression patterns. Altogether, this work offers insights into stage and sex-differences in chromatin modifications and gene expression in fru P1-expressing neurons.

Project description:Chromatin modifications have essential roles in directing nervous system development and behavior. Drosophila courtship is an ideal model for understanding the relationships between chromatin modifications, gene expression, sexual dimorphisms in neuroanatomy, and reproductive behaviors. These behaviors are largely innate and are under the control of sex determination hierarchy genes doublesex (dsx) and fruitless (fru) that encode sex-specific transcription factors. Transcripts from the fru P1 promoter are sex-specifically spliced, resulting in male-specific proteins, FruM, which are required for male courtship behaviors. FruM has been shown to form a complex with Bonus/TIF1, a transcriptional cofactor, and interact with chromatin modifying proteins. This indicates that sex-differential modification of the chromatin landscape contributes to creating and maintaining the potential for sexually dimorphic behavior. To examine chromatin modifications genome-wide in fru P1-expressing neurons, we have developed a method to purify chromatin in a cell-type-specific manner using a tagged histone H2B under UAS control, “Chromatag”, paired with sequential ChIP-seq. Here, we evaluate five chromatin modifications: H3K27ac, H3K4me3, H3K36me3, H3K9me3, and H3K27me3 to investigate fru P1-expressing neurons at three developmental stages in both sexes. These modifications have been well characterized for their roles in transcriptional activation or repression. We observe greater changes in chromatin modification profiles across developmental stages than between sexes. In addition, we have generated cell-type specific RNA-seq data sets, using Translating Ribosome Affinity Purification (TRAP), to examine gene expression in fru P1-expressing neurons of both sexes. Informed by these data sets, we have identified several genes with roles in neuronal function and examined their expression in fru P1-expressing neurons, revealing sexually dimorphic expression patterns. Altogether, this work offers insights into stage and sex-differences in chromatin modifications and gene expression in fru P1-expressing neurons.