Project description:Despite holding a central role for fertilisation success, reproductive traits often show elevated rates of evolution and diversification. The rapid evolution of seminal fluid proteins (Sfps) within populations is predicted to cause mis-signalling between the male ejaculate and female reproductive tract between populations resulting in postmating prezygotic (PMPZ) isolation. Crosses between populations of Drosophila montana show PMPZ isolation in the form of reduced fertilisation success in both noncompetitive and competitive contexts. Here we test whether male ejaculate proteins deriving from either the accessory glands or the ejaculatory bulb differ between populations using liquid chromatography tandem mass spectrometry. We find more than 150 differentially abundant proteins between populations which may contribute to PMPZ isolation. These proteins include a number of proteases and peptidases, and several orthologs of D. melanogaster Sfps, all known to mediate fertilisation success and which mimic PMPZ isolation phenotypes. Males of one population typically produced greater quantities of Sfps and the strongest PMPZ isolation occurs in this direction. The accessory glands and ejaculatory bulb have different functions and the ejaculatory bulb contributes more to population differences than the accessory glands. Proteins with a secretory signal, but not Sfps, evolve faster than non-secretory proteins although the conservative criteria used to define Sfps may have impaired the ability to identify rapidly evolving proteins. We take advantage of quantitative proteomics data from three Drosophila species to determine shared and unique functional enrichments of Sfps that could be subject to selection between taxa and subsequently mediate PMPZ isolation. Our study provides the first high throughput quantitative proteomic evidence showing divergence of reproductive proteins implicated in the emergence of PMPZ isolation between populations.

Project description:Seminal fluid factors modulate the female immune response at conception to facilitate embryo implantation and reproductive success. Whether sperm affect this response has not been clear. We evaluated global gene expression by microarray in the mouse uterus after mating with intact or vasectomized males. Intact males induced greater changes in gene transcription, prominently affecting pro-inflammatory cytokine and immune regulatory genes, with TLR4 signaling identified as a top-ranked upstream driver. Recruitment of neutrophils and expansion of peripheral regulatory T cells were elevated by seminal fluid of intact males. In vitro, epididymal sperm induced IL6, CXCL2, and CSF3 in uterine epithelial cells of wild-type, but not Tlr4 null females. Collectively these experiments show that sperm assist in promoting female immune tolerance by eliciting uterine cytokine expression through TLR4-dependent signaling. The findings indicate a biological role for sperm beyond oocyte fertilization, in modulating immune mechanisms involved in female control of reproductive investment. We used microarrays to detail the global programme of gene expression in mice following exposure to different components of seminal fluid

Project description:Ejaculates contain a diverse mixture of sperm and seminal fluid proteins, the combination of which is crucial to male reproductive success under competitive conditions. Males should therefore tailor the production of different ejaculate components according to their social environment, with particular sensitivity to cues of sperm competition risk (i.e. how likely it is that females will mate promiscuously). Here we test this hypothesis using an established vertebrate model system, the house mouse (Mus musculus domesticus), combining experimental data with a quantitative proteomics analysis of seminal fluid composition. Our study tests for the first time how both sperm and seminal fluid components of the ejaculate are tailored to the social environment.

Project description:We conducted a proteomic investigation into sperm and seminal fluid proteins on individual drones (n = 3-5 per colony) from six colonies. The colonies were either from Southern Californian lineages (N = 2) or Northern Californian lineages (N = 4). The purpose of this dataset is to assess the individual- and colony-level variability in sperm and seminal fluid protein expression.

Project description:Transcriptome of testes was examined for comparison of transcript abundance with that of sperm/seminal fluid (as sequenced in separate study)

Project description:During mammalian reproduction, sperm are delivered to the female reproductive tract bathed in a complex medium known as seminal fluid, which plays key roles in signaling to the female reproductive tract and in nourishing sperm for their onwards journey. The majority of seminal fluid is produced by a somewhat understudied organ known as the seminal vesicle. Here, we report a single-cell RNA-Seq atlas of the mouse seminal vesicle, generated using tissues obtained from 23 mice of varying ages, exposed to a range of dietary challenges. We define the transcriptome of the secretory epithelial cells in this tissue, identifying a relative homogeneous population of the epithelial cells responsible for producing the majority of seminal fluid. We also define the immune cell populations – including large populations of macrophages, dendritic cells, T cells, and NKT cells – which have the potential to play roles in producing various immune mediators present in seminal plasma. Together, our data provide a resource for understanding the composition of an understudied reproductive tissue with potential implications for paternal control of offspring development and metabolism.

Project description:The seminal vesicles are male accessory sex glands that contribute the bulk of the seminal plasma in which mammalian spermatozoa are bathed during ejaculation. In addition to helping convey sperm through the ejaculatory duct, seminal vesicle secretions support sperm survival after ejaculation and influence the female reproductive tract to promote receptivity to pregnancy. Despite its biological importance, there is limited understanding of seminal vesicle fluid (SVF) composition with only 75 proteins having been identified in publicly available proteomic analyses. To address this limitation, here we report new preparative methodology involving sequential solubilization of mouse SVF in guanidine hydrochloride, prior to acetone precipitation and analysis by label-free quantitative mass spectrometry. This strategy identified 126 proteins, including 83 previously undetected in SVF. Members of the seminal vesicle secretory protein family were the most abundant, accounting for 79% of all peptide spectrum matches. Functional analysis of SVF proteins identified inflammation and formation of the vaginal plug as the two most prominent biological processes. Notable additional processes included modulation of sperm function and regulation of the female reproductive tract immune environment. Together, these findings provide a robust methodological framework for future SVF studies and identify novel proteins with the potential to influence both male and female reproductive health.

Project description:The objective of this study was to determine whether prostate cancer-associated miRNAs are present in seminal fluid and, if so, evaluate their diagnostic potential. Small RNA sequencing was used to profile and compare miRNAs in the non-sperm cellular fraction of seminal fluid from men with biopsy-proven cancer (one pooled sample from 6 men) and men with elevated serum PSA but negative biopsy results (one pooled sample from 6 men).

Project description:Transcriptome of testes was examined for comparison of transcript abundance with that of sperm/seminal fluid (as sequenced in separate study) Commercially available (Ambion) human testes RNA was prepared and sequenced in two replicates

Project description:Seminal fluid proteins determine reproductive success in a wide range of animals. In the Drosophila male accessory gland, seminal fluid is mainly produced by two cell types, a vast majority of main cells and a small number of secondary cells that are characterized by a specialized secretory apparatus with unusually enlarged dense core granule vesicles. Loss of Abdominal-B expression from secondary cells in the enhancer mutant iab-6cocu disrupts their transcriptional and secretory identity. In consequence, mutant males fail to induce the long-term post-mating response, concomitant with loss of receptivity and sustained egg laying, in females. Here, we determine how secondary cells shape the seminal transferome and the female response by assessing iab-6cocu male accessory gland and female mate reproductive tract proteomes. We find downregulation of seminal fluid proteins constituting a signaling network that enables sperm binding and sustained action of key regulator Sex peptide and identify two new Sex peptide network proteins crucial for female fecundity, Cornutus (CG1701) and Hanrej (CG42564). Cornutus is required for dense core granule vesicle release, providing a link between the products of these compartments and the female long-term post-mating response. Our data highlights the importance of secondary cell signaling and secretion for overall seminal fluid composition and Sex peptide network function as well as the interdependence of main and secondary cells and their secretory products, advancing the general understanding of how seminal fluid signaling pathways modulate female physiology, sperm use and offspring production.