Project description:In Drosophila melanogaster, mating radically transforms female physiology and behavior. Post-mating responses include an increase in the oviposition rate, a reduction in female receptivity, and an activation of the immune system . The fitness consequences of mating are similarly dramatic – females must mate once in order to produce fertile eggs, but additional matings have a clear negative effect. Previously, microarrays have been used to examine gene expression of females differing in their reproductive status with the aim of identifying genes influenced by mating. However, since only virgin and single mated females were compared, transcriptional changes associated with reproduction (under natural selection) and the effects of male-induced harm (under sexually antagonistic selection) cannot be disentangled. We partitioned these fundamentally different effects by instead examining the expression profiles of virgin, single mated and double mated females. We found substantial effects relating to reproduction and further effects that are only attributable to a second mating. Immune response genes dominate this male-induced harm effect indicating that the cost of mating may be due partly to this system's activation. We propose that both sexually antagonistic and natural selection have been important in the evolution of the innate immunity genes, thereby contributing to the sexual dimorphismand rapid evolution at these loci. Keywords: Female response to mating Female flies were flash frozen in liquid nitrogen either as virgins or 6 hours after mating and stored at -80°C until RNA extraction was performed (not more than 2 days). 8 whole flies – randomly selected within each treatment – were pooled for each extraction. Total RNA was extracted using Trizol (Invitrogen) and purified with an RNeasy Mini Kit (Qiagen). RNA quantity and quality was checked with an Agilent Bioanalyzer. According to the manufacturer's instructions, samples were prepared and hybridized to Affymetrix GeneChip Drosophila Genome 2.0 (Affymetrix, Santa Clara, CA, USA) by the Uppsala Array Platform (Uppsala, Sweden). Each experimental treatment consisted of 4 independent RNA extractions and hybridizations, giving a total of 12 arrays.

Project description:To gain better insight into the molecular link between the post-mating transcriptional and morphological changes and the behavioral and physiological shift induced by copulation in An. gambiae females, we performed an in-depth transcriptional analysis of the female lower reproductive tract (LRT), comprising the atrium and the spermatheca, to identify the molecular pathways specifically regulated in these female reproductive tissues. We analyzed three time points post mating (3, 12 and 24 hours post mating) in order to capture transcriptional changes occurring within a broad time window after copulation. For each time point, tissues were collected from mated and age-matched virgin females and the transcriptional profile compared across 4 biological replicates using Agilent one-color microarrays.

Project description:Changes in gene expression in whole Anopheles gambiae female bodies between virgin mosquitoes and females samples at 2h, 6h, and 24h after mating.

Project description:Male Anophele gambiae mosquitoes transfer the steroid hormone 20-hydroxyecdysone (20E) to the female lower reproductive tract during mating. We have shown that this sexually transferred hormone is a key regulator of monandry and oviposition in An. gambiae females. In order to identify possible molecular pathways underlying the effects induced by sexually transferred 20E we investigated the transcriptional response in the atrium and spermatheca at 24 hours after 20E injection in the thorax of virgin females, which delivers to these reproductive tissues 20E levels comparable to those detected after mating. By comparing these results to those of microarrays assessing the post-mating transcriptional response in the female lower reproductive tract (LRT) at 24 hours post copulation, we were able to identify mating responsive genes likely regulated by male transferred 20E. For each experiment atrium and spermatheca were dissected from females 24 hours after 20E or ethanol (10%) injection and transcriptional profiles compared across 4 biological replicates using Agilent two-color microarrays

Project description:Seminal fluid proteins (SFPs) exert potent effects on male and female fitness. These rapidly evolving and molecularly diverse proteins derive from multiple male secretory cells and tissues. In Drosophila melanogaster most SFPs are produced in the accessory glands, which are composed of ~1000 fertility-enhancing ‘main cells’ and ~40, more functionally cryptic, ‘secondary cells’. Previous work shows that inhibition of BMP-signalling in secondary cells suppresses secretion, leading to a surprising uncoupling of normal female post-mating responses: refractoriness stimulation is impaired, but offspring production is not. Secondary cell secretions might therefore make a highly specific contribution to the seminal proteome and ejaculate function; alternatively, they might play a more global – but hitherto-undiscovered – role in regulating SFPs and their interconnected functions. Here, we present data that supports the latter model. We show that in addition to previously reported phenotypes, secondary cell-specific BMP-inhibition compromises sperm storage and increases female sperm use efficiency. Moreover, it alters sperm competition: second male sperm enter storage more slowly, ejaculates are ejected later, and first male paternity share improves. This result suggests a novel constraint on ejaculate evolution whereby female refractoriness and sperm competitiveness cannot be simultaneously maximised. Using quantitative proteomics, we reveal changes to the seminal proteome that surprisingly encompass alterations to main cell-derived proteins, indicating important cross-talk between classes of SFP-secreting cells. Our results demonstrate that ejaculate composition and function emerge from the integrated action of multiple secretory cell-types suggesting that modification to the cellular make-up of seminal fluid-producing tissues is an important factor in ejaculate evolution.

Project description:In insects, male accessory gland proteins (ACPs) are important reproductive proteins secreted by male accessory glands (MAGs) of the internal male reproductive system. During mating, ACPs were transferred along with sperms inside female bodies and have a significant impact on the physiology of female reproduction. Under sexual selection pressures, the ACPs exhibit remarkably rapid and divergent evolution and varies from species to species. The diamondback moth, Plutella xylostella (L.) (Lepidoptera: Plutellidae), is a major insect pest of cruciferous vegetables worldwide. The reproductive physiology on post-mating state of this species is still largely unknown, which is important for management of this pest. In this study, the ACPs transferred into females during mating were identified by using a tandem mass tags quantitative proteomic analysis. The MAGs were compared before and after mating immediately. In total, we identified 123 putative secreted ACPs, including most important physiological: regulators of proteolysis, transporters and protein export machinery, signal transduction and immunity. Comparing P. xylostella with other four insect ACPs, trypsins were the only ACPs detected in all insect species. This was the first time to identify and analyze ACPs in P. xylostella. Our results have provided an important list of putative secreted ACPs, and have set the stage for further explore functions of these putative proteins in P. xylostella reproduction.

Project description:To gain insight into the molecular pathways and processes controlling the behavioral and physiological shift induced by copulation in An. gambiae, we performed an in-depth transcriptional analysis of the heads of mated females. We analyzed three time points post-mating (3, 12 and 24 hours post mating) in order to capture transcriptional changes occurring within a broad time window after copulation. For each time point, heads were collected from mated and age-matched virgin females and the transcriptional profile compared across 4 biological replicates using Agilent one-color microarrays.

Project description:Since Anopheles gambiae female mosquitoes mate only once in their lifetime, and store sperm received from males potentially for weeks, genes and pathways regulated by mating in the sperm storage organ (spermatheca) to preserve sperm function may represent new targets for vector control. The transcriptional response to mating in the spermatheca was investigated using Agilent two-color microarrays. Spermathecae from mated females were collected 24 h after mating and compared to age-matched virgins. 4 biological replicates were performed.

Project description:We used RNA sequencing to examine the transcriptomes of male and female heads from experimentally-evolved D. melanogaster populations after 117 generations of mating system manipulation in order to examine the pattern of evolution in sex-biased genes. Examined head transcriptomes of 3 monogamous populations and 3 polygamous populations, both males and females, for 12 total samples.

Project description:In insects, male accessory gland proteins (ACPs) are important reproductive proteins secreted by male accessory glands (MAGs) of the internal male reproductive system. During mating, ACPs were transferred along with sperms inside female bodies and have a significant impact on the physiology of female reproduction. Under sexual selection pressures, the ACPs exhibit remarkably rapid and divergent evolution and varies from species to species. The diamondback moth, Plutella xylostella (L.) (Lepidoptera: Plutellidae), is a major insect pest of cruciferous vegetables worldwide. The reproductive physiology on post-mating state of this species is still largely unknown, which is important for management of this pest. In this study, the ACPs transferred into females during mating were identified by using a tandem mass tags quantitative proteomic analysis. The MAGs were compared before and after mating immediately. The proteomes of copulatory bursas (CB) in mated females shortly after mating were also analyzed by shotgun LC-MS/MS technique. In total, we identified 123 putative secreted ACPs, including most important physiological: regulators of proteolysis, transporters and protein export machinery, signal transduction and immunity. Comparing P. xylostella with other four insect ACPs, trypsins were the only ACPs detected in all insect species. We also identified some new insect ACPs, including protein with chitin binding Peritrophin-A domain, PMP-22/EMP/MP20/Claudin tight junction domain-containing protein, netrin-1, type II inositol 1,4,5-trisphosphate 5-phosphatase, two spaetzles, allatostatin-CC and cuticular protein. This was the first time to identify and analyze ACPs in P. xylostella. Our results have provided an important list of putative secreted ACPs, and have set the stage for further explore functions of these putative proteins in P. xylostella reproduction.