Project description:Sex estimation of human remains from demineralized blocks of tooth enamel by liquid chromatography tandem mass spectrometry (LC- MS/MS) and proteomic analysis of sexually dimorphic amelogenin peptides. The detection of the Y-isoform of amelogenin is used to estimate male sex. The combined signal intensity of the sexually dimorphic peptides from each samples of known sex is used to establish a statistical framework for the estimation of the female sex probability.

Project description:Complex autoimmune diseases are sexually dimorphic. An interplay between predisposing genetics and sex-related factors likely determines the sex discrepancy in the immune response, but conclusive evidence regarding the underlying molecular mechanisms is lacking. Using forward genetics, we positionally identified a polymorphic estrogen receptor binding site that regulates CD2 expression, leading to female-specific differences in mouse models of T cell-dependent autoimmunity. Female mice with reduced CD2 levels displayed a diminished T cell activation and autoimmune T cell response. Mechanistically, CD2 affected LAG-3 expression. Our findings help to explain the sexual dimorphism in human autoimmunity, as CD2 associated with rheumatoid arthritis and its regulation through 17-β-estradiol was conserved in human T cells. Hormonal regulation of CD2 has implications for CD2-targeted therapy. Indeed, anti-CD2 treatment more potently affected female mice. In conclusion, our results demonstrate the relevance of sex-genotype interactions and deliver strong evidence for CD2 as a sex-sensitive predisposing factor in autoimmunity.

Project description:During lactation, mothers initiate cycles of bone formation followed by significant bone loss to meet the high calcium (Ca2+) demand by progeny. While estrogen functions typically as an anabolic driver of bone remodeling, this sex steroid is absent in postpartum females. Here, we report that a brain-derived secreted from neurons of the arcuate nucleus (ARC) fills this void and functions as a potent osteogenic factor to promote bone mass in lactating females. We previously reported an extraordinarily sex-specific high bone mass phenotype in female mice that persists with aging and is central in origin after eliminating estrogen receptor alpha signaling in ARCKISS1 neurons. Parabiosis and bone transplant studies established that a humoral factor in mutant females accounts for this unusual skeletal phenotype. High bone mass in mutant females could be traced back to the skeletal stem cell (SSC) level, reflected by their increased frequency and osteochondrogenic potential. Based on ex-vivo, in vivo, and in vitro assays, one protein emerged as the most promising secreted pro-osteogenic factor from the ARC, acting in mice and human SSCs at low concentrations (<nM) independent of age and sex. The role of this brain-derived factor in bone formation was confirmed by in vivo gain and loss of function studies. Unexpectedly, in wild-type females, a transient spike of this protein appears in ARCKISS1 neurons coincident with lactation when bone remodeling and high calcium demand intensify in estrogen-depleted mothers. Our findings establish a potentially new therapeutic anabolic bone hormone that functions in a novel female-specific brain-bone axis to ensure mammalian species survival.

Project description:Mammalian organs exhibit distinct physiology, disease susceptibility and injury responses between the sexes. In the mouse kidney, sexually dimorphic gene activity maps predominantly to proximal tubule (PT) segments. Bulk RNA-seq data analyses demonstrated sex differences were established from 4 and 8 weeks after birth under gonadal control. Hormone injection studies and genetic removal of androgen and estrogen receptors highlighted direct androgen receptor (AR) mediated regulation of gene activity in PT cells as the primary regulatory mechanism. Single-nuclear multiomic analysis identified putative cis regulatory regions and cooperating factors mediating PT responses to AR activity. In the human kidney, a limited set of genes showed conserved sex-linked regulation. Comparative analysis of the mouse liver underscored organ-specific differences in the regulation of sexually dimorphic gene expression. The organ-specific pathways of sexual differentiation identified here raise interesting questions on the evolution, physiological significance, and disease-linkage of sexually dimorphic gene activity.

Project description:Multiple sclerosis (MS) is a T-cell mediated autoimmune disease that has a sexually dimorphic pattern in disease susceptibility. Consistent with many autoimmune diseases, females are more susceptible than males to MS. Sexual dimorphisms may be due to differences in sex hormones, sex chromosome genes, or both. Regarding sex chromosome genes, a small percentage of X chromosome genes escape the dosage compensation mechanism of X inactivation and have higher expression in females (XX) compared to males (XY). According to the high throughput analysis, the top sexually dimorphic gene with higher expression in CD4+ T cells from females (vs. males) and from XX mice (vs. XY) was Kdm6a, a histone demethylase and transcription factor on the X chromosome. Deletion of Kdm6a specifically in CD4+ T cells ameliorated clinical disease and reduced neuropathology in the classic CD4+ T cell mediated autoimmune disease, experimental autoimmune encephalomyelitis (EAE). Global transcriptome analysis in CD4+ T cells from EAE mice with a specific deletion of Kdm6a showed upregulation of Th2 and Th1 activation pathways and downregulation of neuroinflammation signaling pathways. Together, this demonstrates that the X escapee Kdm6a regulates multiple immune response genes, providing a mechanism for sex differences in autoimmune disease susceptibility.

Project description:Multiple sclerosis (MS) is a T-cell mediated autoimmune disease that has a sexually dimorphic pattern in disease susceptibility. Consistent with many autoimmune diseases, females are more susceptible than males to MS. Sexual dimorphisms may be due to differences in sex hormones, sex chromosome genes, or both. Regarding sex chromosome genes, a small percentage of X chromosome genes escape the dosage compensation mechanism of X inactivation and have higher expression in females (XX) compared to males (XY). According to the high throughput analysis, the top sexually dimorphic gene with higher expression in CD4+ T cells from females (vs. males) and from XX mice (vs. XY) was Kdm6a, a histone demethylase and transcription factor on the X chromosome. Deletion of Kdm6a specifically in CD4+ T cells ameliorated clinical disease and reduced neuropathology in the classic CD4+ T cell mediated autoimmune disease, experimental autoimmune encephalomyelitis (EAE). Global transcriptome analysis in CD4+ T cells from EAE mice with a specific deletion of Kdm6a showed upregulation of Th2 and Th1 activation pathways and downregulation of neuroinflammation signaling pathways. Together, this demonstrates that the X escapee Kdm6a regulates multiple immune response genes, providing a mechanism for sex differences in autoimmune disease susceptibility.

Project description:The sexually dimorphic expression of genes across 26 somatic rat tissues was using Affymetrix RAE-230 genechips. We considered probesets to be sexually dimorphically expressed (SDE) if they were measurably expressed above background in at least one sex, there was at least a two-fold difference in expression (dimorphism) between the sexes, and the differences were statistically significant after correcting for false discovery. 14.5% of expressed probesets were SDE in at least one tissue, with higher expression nearly twice as prevalent in males compared to females. Most were SDE in a single tissue. Surprisingly, nearly half of the probesets that were (SDE) in multiple tissues were oppositely sex biased in different tissues, and most SDE probesets were also expressed without sex bias in other tissues. Two genes were widely SDE: Xist (female-only) and Eif2s3y (male-only). The frequency of SDE probesets varied widely between tissues, and was highest in the duodenum (6.2%), whilst less than 0.05% in over half of the surveyed tissues. The occurrence of SDE probesets was not strongly correlated between tissues. Within individual tissues, however, relational networks of SDE genes were identified. In the liver, networks relating to differential metabolism between the sexes were seen. The estrogen receptor was implicated in differential gene expression in the duodenum. To conclude, sexually dimorphic gene expression is common, but highly tissue-dependent. Sexually dimorphic gene expression may provide insights into mechanisms underlying phenotypic sex differences. 5 male and 5 female animals used. Data provided for all files that meet QC criteria

Project description:To investigate the genomic distribution of genes with sex- biased expression patterns in mice we analyzed the chromosomal distribution of genes preferentially expressed in sexually dimorphic tissues such as testis and ovary.

Project description:The sexually dimorphic expression of genes across 26 somatic rat tissues was using Affymetrix RAE-230 genechips. We considered probesets to be sexually dimorphically expressed (SDE) if they were measurably expressed above background in at least one sex, there was at least a two-fold difference in expression (dimorphism) between the sexes, and the differences were statistically significant after correcting for false discovery. 14.5% of expressed probesets were SDE in at least one tissue, with higher expression nearly twice as prevalent in males compared to females. Most were SDE in a single tissue. Surprisingly, nearly half of the probesets that were (SDE) in multiple tissues were oppositely sex biased in different tissues, and most SDE probesets were also expressed without sex bias in other tissues. Two genes were widely SDE: Xist (female-only) and Eif2s3y (male-only). The frequency of SDE probesets varied widely between tissues, and was highest in the duodenum (6.2%), whilst less than 0.05% in over half of the surveyed tissues. The occurrence of SDE probesets was not strongly correlated between tissues. Within individual tissues, however, relational networks of SDE genes were identified. In the liver, networks relating to differential metabolism between the sexes were seen. The estrogen receptor was implicated in differential gene expression in the duodenum. To conclude, sexually dimorphic gene expression is common, but highly tissue-dependent. Sexually dimorphic gene expression may provide insights into mechanisms underlying phenotypic sex differences.

Project description:To investigate the genomic distribution of genes with sex- biased expression patterns in mice we analyzed the chromosomal distribution of genes preferentially expressed in sexually dimorphic tissues such as testis and ovary. Keywords: repeat sample