Quantitative proteomics reveals rapid divergence in the postmating response of female reproductive tracts among sibling species.

Fertility depends, in part, on interactions between male and female reproductive proteins inside the female reproductive tract (FRT) that mediate postmating changes in female behaviour, morphology, and physiology. Coevolution between interacting proteins within species may drive reproductive incompatibilities between species, yet the mechanisms underlying postmating-prezygotic (PMPZ) isolating barriers remain poorly resolved. Here, we used quantitative proteomics in sibling Drosophila species to investigate the molecular composition of the FRT environment and its role in mediating species-specific postmating responses. We found that (i) FRT proteomes in D. simulans and D. mauritiana virgin females express unique combinations of secreted proteins and are enriched for distinct functional categories, (ii) mating induces substantial changes to the FRT proteome in D. mauritiana but not in D. simulans, and (iii) the D. simulans FRT proteome exhibits limited postmating changes irrespective of whether females mate with conspecific or heterospecific males, suggesting an active female role in mediating reproductive interactions. Comparisons with similar data in the closely related outgroup species D. melanogaster suggest that divergence is concentrated on the D. simulans lineage. Our study suggests that divergence in the FRT extracellular environment and postmating response contribute to previously described patterns of PMPZ isolation and the maintenance of species boundaries.

Mouse strain-dependent egg factors regulate calcium signals at fertilization.

Calcium (Ca2+ ) signals triggered at fertilization initiate resumption of the cell cycle and initial steps of embryonic development. In mammals, the sperm factor phospholipase Cζ triggers the release of Ca2+ from the endoplasmic reticulum (ER), initiating an oscillatory pattern of Ca2+ transients that is modulated by egg factors including Ca2+ influx channels, Ca2+ transporters, and phosphoinositide-regulating enzymes. Here we compared characteristics of Ca2+ oscillations following in vitro fertilization (IVF) and ER Ca2+ stores among nine common laboratory mouse strains: CF1, C57BL6, SJL, CD1, DBA, FVB, 129X1, BALBc, 129S1, and the F1 hybrid B6129SF1. Sperm from B6SJLF1/J males was used for all IVF experiments. There were significant differences among the strains with respect to duration and maximum amplitude of the first Ca2+ transient, frequency of oscillations, and ER Ca2+ stores. With male strain held constant, the differences in Ca2+ oscillation patterns observed result from variation in egg factors across different mouse strains. Our results support the importance of egg-intrinsic properties in determining Ca2+ oscillation patterns and have important implications for the interpretation and comparison of studies on Ca2+ dynamics at fertilization.

Author Correction: An alternative hypothesis for the evolution of same-sex sexual behaviour in animals.

An amendment to this paper has been published and can be accessed via a link at the top of the paper.

An alternative hypothesis for the evolution of same-sex sexual behaviour in animals.

Same-sex sexual behaviour (SSB) has been recorded in over 1,500 animal species with a widespread distribution across most major clades. Evolutionary biologists have long sought to uncover the adaptive origins of 'homosexual behaviour' in an attempt to resolve this apparent Darwinian paradox: how has SSB repeatedly evolved and persisted despite its presumed fitness costs? This question implicitly assumes that 'heterosexual' or exclusive different-sex sexual behaviour (DSB) is the baseline condition for animals, from which SSB has evolved. We question the idea that SSB necessarily presents an evolutionary conundrum, and suggest that the literature includes unchecked assumptions regarding the costs, benefits and origins of SSB. Instead, we offer an alternative null hypothesis for the evolutionary origin of SSB that, through a subtle shift in perspective, moves away from the expectation that the origin and maintenance of SSB is a problem in need of a solution. We argue that the frequently implicit assumption of DSB as ancestral has not been rigorously examined, and instead hypothesize an ancestral condition of indiscriminate sexual behaviours directed towards all sexes. By shifting the lens through which we study animal sexual behaviour, we can more fruitfully examine the evolutionary history of diverse sexual strategies.

Reproductive Impacts of Endocrine-Disrupting Chemicals on Wildlife Species: Implications for Conservation of Endangered Species.

Wildlife have proven valuable to our understanding of the potential effects of endocrine-disrupting chemicals (EDCs) on human health by contributing considerably to our understanding of the mechanisms and consequences of EDC exposure. But the threats EDCs present to populations of wildlife species themselves are significant, particularly for endangered species whose existence is vulnerable to any reproductive perturbation. However, few studies address the threats EDCs pose to endangered species owing to challenges associated with their study. Here, we highlight those barriers and review the available literature concerning EDC effects on endangered species. Drawing from other investigations into nonthreatened wildlife species, we highlight opportunities for new approaches to advance our understanding and potentially mitigate the effects of EDCs on endangered species to enhance their fertility.

Proteomics of reproductive systems: Towards a molecular understanding of postmating, prezygotic reproductive barriers.

Following mating and insemination, fertility is dependent on the successful execution of a complex array of morphological, physiological and molecular interactions between male and female proteins, cells and tissues. Many of these interacting components bear hallmarks of co-evolving systems and are suspected to contribute to postmating, prezygotic (PMPZ) reproductive barriers involved in the formation of new species. Although PMPZ reproductive isolation has historically been more difficult to study than precopulatory and postzygotic barriers, recent research has highlighted its potential role in speciation and revealed the impact of molecular investigation utilizing proteomic approaches. Proteomics, in conjunction with transcriptomic and evolutionary genomic studies, has been widely used to identify rapidly evolving male and female reproductive proteins. Increased access to high-throughput and quantitative proteomic techniques, as well as the ease of generating genomic and transcriptomic resources necessary for protein identification, can facilitate the extension of proteomics from traditional model species to systems of relevance to PMPZ phenotypes and hence greatly expand our understanding of how rapidly diverging molecular systems may contribute to PMPZ barriers. Here we review the influence proteomic analyses can have on our understanding of the function and evolution of the complex cellular and molecular processes governing postcopulatory male-female interactions and the study of PMPZ reproductive isolation, with the goal of expanding our understanding of the contribution of PMPZ processes to speciation.

Frequency of exogenous hormone therapy impacts spermiation in male Fowler's toad (Bufo fowleri).

Amphibians are experiencing a global extinction crisis and captive assurance colonies, along with reintroduction programs, are necessary to prevent further losses. Assisted reproductive technologies (ART), such as hormone-stimulated gamete collection and in vitro fertlisation (IVF), are conservation methods that can be used to increase reproductive output for breeding and reintroduction programs when animals fail to breed naturally. In order to maximise the production of offspring using ART, it is important to establish the physiological limitations on the frequency that hormone therapy can be used to collect gametes for IVF or assisted breeding. The present study examined the effects of the frequency of hormone-induced spermiation on sperm quantity and quality in Fowler's toad (Bufo fowleri) by comparing four levels of hormone injection frequencies: twice a week, once a week, every other week, and every 3 weeks. Sperm release was induced with an intraperitoneal injection of 300IU human chorionic gonadotropin (hCG). Spermatozoa were collected at three time points after injection (5, 7 and 9h) and sperm concentration, motility and quality of forward progressive movement were measured. A significant decrease in sperm concentration (P<0.01) was observed with the most frequent treatment (twice a week hormone injections). However, there was no negative effect of the treatments on sperm motility (P=0.06) or forward movement (P=0.06). We also observed a significant decrease in the concentration (P<0.01), motility (P=0.02) and quality of forward progressive movement (P=0.01) of spermatozoa at the 9h collection compared with earlier collection times. These results have clear implications for amphibian captive breeding programs, where more frequent hormone-induced spermiation could have a negative effect on male performance. We recommend that hormone injections be spaced a minimum of 2 weeks apart to optimise the health of the animals, assisted breeding, IVF or collection of gametes for genome resource banking.

CaV3.2 T-type channels mediate Ca²âº entry during oocyte maturation and following fertilization.

Initiation of mouse embryonic development depends upon a series of fertilization-induced rises in intracellular Ca(2+). Complete egg activation requires influx of extracellular Ca(2+); however, the channels that mediate this influx remain unknown. Here, we tested whether the α1 subunit of the T-type channel CaV3.2, encoded by Cacna1h, mediates Ca(2+) entry into oocytes. We show that mouse eggs express a robust voltage-activated Ca(2+) current that is completely absent in Cacna1h(-/-) eggs. Cacna1h(-/-) females have reduced litter sizes, and careful analysis of Ca(2+) oscillation patterns in Cacna1h(-/-) eggs following in vitro fertilization (IVF) revealed reductions in first transient length and oscillation persistence. Total and endoplasmic reticulum (ER) Ca(2+) stores were also reduced in Cacna1h(-/-) eggs. Pharmacological inhibition of CaV3.2 in wild-type CF-1 strain eggs using mibefradil or pimozide reduced Ca(2+) store accumulation during oocyte maturation and reduced Ca(2+) oscillation persistence, frequency and number following IVF. Overall, these data show that CaV3.2 T-type channels have prev8iously unrecognized roles in supporting the meiotic-maturation-associated increase in ER Ca(2+) stores and mediating Ca(2+) influx required for the activation of development.

Regulator of G-protein signaling 2 (RGS2) suppresses premature calcium release in mouse eggs.

During oocyte maturation, capacity and sensitivity of Ca(2+) signaling machinery increases dramatically, preparing the metaphase II (MII)-arrested egg for fertilization. Upon sperm-egg fusion, Ca(2+) release from IP3-sensitive endoplasmic reticulum stores results in cytoplasmic Ca(2+) oscillations that drive egg activation and initiate early embryo development. Premature Ca(2+) release can cause parthenogenetic activation prior to fertilization; thus, preventing inappropriate Ca(2+) signaling is crucial for ensuring robust MII arrest. Here, we show that regulator of G-protein signaling 2 (RGS2) suppresses Ca(2+) release in MII eggs. Rgs2 mRNA was recruited for translation during oocyte maturation, resulting in ∼ 20-fold more RGS2 protein in MII eggs than in fully grown immature oocytes. Rgs2-siRNA-injected oocytes matured to MII; however, they had increased sensitivity to low pH and acetylcholine (ACh), which caused inappropriate Ca(2+) release and premature egg activation. When matured in vitro, RGS2-depleted eggs underwent spontaneous Ca(2+) increases that were sufficient to cause premature zona pellucida conversion. Rgs2(-/-) females had reduced litter sizes, and their eggs had increased sensitivity to low pH and ACh. Rgs2(-/-) eggs also underwent premature zona pellucida conversion in vivo. These findings indicate that RGS2 functions as a brake to suppress premature Ca(2+) release in eggs that are poised on the brink of development.

Advances in conservation endocrinology: the application of molecular approaches to the conservation of endangered species.

Among the numerous societal benefits of comparative endocrinology is the application of our collective knowledge of hormone signaling towards the conservation of threatened and endangered species - conservation endocrinology. For several decades endocrinologists have used longitudinal hormone profiles to monitor reproductive status in a multitude of species. Knowledge of reproductive status among individuals has been used to assist in the management of captive and free-ranging populations. More recently, researchers have begun utilizing molecular and cell-based techniques to gain a more complete understanding of hormone signaling in wildlife species, and to identify potential causes of disrupted hormone signaling. In this review we examine various in vitro approaches we have used to compare estrogen receptor binding and activation by endogenous hormones and phytoestrogens in two species of rhinoceros; southern white and greater one-horned. We have found many of these techniques valuable and practical in species where access to research subjects and/or tissues is limited due to their conservation status. From cell-free, competitive binding assays to full-length receptor activation assays; each technique has strengths and weaknesses related to cost, sensitivity, complexity of the protocols, and relevance to in vivo signaling. We then present a novel approach, in which receptor activation assays are performed in primary cell lines derived from the species of interest, to minimize the artifacts of traditional heterologous expression systems. Finally, we speculate on the promise of next generation sequencing and transcriptome profiling as tools for characterizing hormone signaling in threatened and endangered species.