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1. A Transient Hermaphroditic Stage in Early Male Gonadal Development in Little Yellow Croaker, Larimichthys polyactis

   https://doi.org/10.3389/fendo.2020.542942  

   Xie, Qing-Ping; Li, Bing-Bing; Zhan, Wei; Liu, Feng; Tan, Peng; Wang, Xu; Lou, Bao (January 2021, Frontiers in Endocrinology)

   Animal taxa show remarkable variability in sexual reproduction, where separate sexes, or gonochorism, is thought to have evolved from hermaphroditism for most cases. Hermaphroditism accounts for 5% in animals, and sequential hermaphroditism has been found in teleost. In this study, we characterized a novel form of the transient hermaphroditic stage in little yellow croaker ( Larimichthys polyactis ) during early gonadal development. The ovary and testis were indistinguishable from 7 to 40 days post-hatching (dph). Morphological and histological examinations revealed an intersex stage of male gonads between 43 and 80 dph, which consist of germ cells, somatic cells, efferent duct, and early primary oocytes (EPOs). These EPOs in testis degenerate completely by 90 dph through apoptosis yet can be rescued by exogenous 17- β -estradiol. Male germ cells enter the mitotic flourishing stage before meiosis is initiated at 180 dph, and they undergo normal spermatogenesis to produce functional sperms. This transient hermaphroditic stage is male-specific, and the ovary development appears to be normal in females. This developmental pattern is not found in the sister species Larimichthys crocea or any other closely related species. Further examinations of serum hormone levels indicate that the absence of 11-ketotestosterone and elevated levels of 17- β -estradiol delineate the male intersex gonad stage, providing mechanistic insights on this unique phenomenon. Our research is the first report on male-specific transient hermaphroditism and will advance the current understanding of fish reproductive biology. This unique gonadal development pattern can serve as a useful model for studying the evolutionary relationship between hermaphroditism and gonochorism, as well as teleost sex determination and differentiation strategies. 

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2. Unraveling the Neural Basis of Behavioral Isolation through the Lens of Audition in Anurans

   https://doi.org/10.1159/000542575  

   Anderson, Carlie B (June 2025, Brain, Behavior and Evolution)

   Background: The origin and maintenance of species is a unifying theme in evolutionary biology. Mate choice and selection on sexual signals have emerged as powerful drivers of reproductive isolation – the key pillar of the biological species concept. The mechanistic underpinnings of isolating behaviors lie in the circuit- and cellular-level properties of the brain and remain relatively understudied. Summary: Here, I argue that temporal auditory selectivity in anuran amphibians offers a window into the proximate mechanisms of reproductive isolation. First, I discuss anuran behaviors as a longstanding neuroethological model with which to examine behavioral reproductive isolation and its neural correlates. Next, I review how modern neurobiological techniques are revealing the proximate mechanisms of the evolution of divergent mate preferences in anurans, highlighting cellular-level neural shifts in temporal coding. Finally, I discuss future research directions to reveal the neural mechanisms through which behavioral isolation is generated and maintained in anuran model systems. Key Messages: Anurans offer a powerful model for addressing questions about how neural barriers to gene flow arise across biological scales and how changes in the brain contribute to speciation. Modern evolutionary neurobiology will benefit from applying new tools to this longstanding neuroethological model clade. 

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3. Monoicy, dioicy, and genetic structure in three species of Sheathia (Batrachospermales, Rhodophyta)

   https://doi.org/10.1111/jpy.70032  

   Shainker‐Connelly, Sarah_J; Stoeckel, Solenn; Vis, Morgan_L; Krueger‐Hadfield, Stacy_A (May 2025, Journal of Phycology)

   Abstract Sexual systems (i.e., separate vs. combined sexes) vary widely among eukaryotes and influence the evolution of reproductive systems, which shape genetic structure and evolutionary trajectories. In diploid‐dominant angiosperms, combined (i.e., hermaphroditism) and separate sexes are expected to correlate with selfing and outcrossing, respectively. When sex is determined in the haploid phase, selfing is possible even when there are separate sexes. The freshwater red macroalgal genusSheathia(Batrachospermales) displays sexual system variation within and among populations, but no prior data exist on the reproductive systems of these populations. We developed 16 polymorphic microsatellite loci to characterize the reproductive system and genetic structure of threeSheathiaspecies. We observed cross‐amplification of loci across the three targeted species, suggesting these markers may be useful in otherSheathiaspp. We observed variation in monoicy (i.e., hermaphroditism) versus dioicy (i.e., separate sexes) in each species, includingS. americana, which was previously believed to be obligately dioicous. Our data suggest thatS. americanaandS. involutadisplay more variation in their prevailing reproductive modes as compared toS. grandis. Generally, dioicy resulted in greater diversity in contrast to monoicy. We observed strong population structure that is likely driven by uniparental reproduction and limited dispersal; however, there is limited population connectivity that may be facilitated by long‐distance dispersal events. Overall, these data contribute to our knowledge of the relationship between the sexual system, reproductive system, and population genetic structure in haploid‐diploid taxa, thereby informing a broader understanding of the evolution of sex. 

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4. Neural basis of acoustic species recognition in a cryptic species complex

   https://doi.org/10.1242/jeb.243405  

   Gupta, Saumya; Alluri, Rishi K.; Rose, Gary J.; Bee, Mark A. (December 2021, Journal of Experimental Biology)

   ABSTRACT Sexual traits that promote species recognition are important drivers of reproductive isolation, especially among closely related species. Identifying neural processes that shape species differences in recognition is crucial for understanding the causal mechanisms of reproductive isolation. Temporal patterns are salient features of sexual signals that are widely used in species recognition by several taxa, including anurans. Recent advances in our understanding of temporal processing by the anuran auditory system provide an opportunity to investigate the neural basis of species-specific recognition. The anuran inferior colliculus consists of neurons that are selective for temporal features of calls. Of potential relevance are auditory neurons known as interval-counting neurons (ICNs) that are often selective for the pulse rate of conspecific advertisement calls. Here, we tested the hypothesis that ICNs mediate acoustic species recognition by exploiting the known differences in temporal selectivity in two cryptic species of gray treefrog (Hyla chrysoscelis and Hyla versicolor). We examined the extent to which the threshold number of pulses required to elicit behavioral responses from females and neural responses from ICNs was similar within each species but potentially different between the two species. In support of our hypothesis, we found that a species difference in behavioral pulse number thresholds closely matched the species difference in neural pulse number thresholds. However, this relationship held only for ICNs that exhibited band-pass tuning for conspecific pulse rates. Together, these findings suggest that differences in temporal processing of a subset of ICNs provide a mechanistic explanation for reproductive isolation between two cryptic treefrog species. 

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5. Molecular evolution of the sex peptide network in Drosophila

   https://doi.org/10.1111/jeb.13597  

   McGeary, Meaghan K.; Findlay, Geoffrey D. (February 2020, Journal of Evolutionary Biology)

   Abstract Successful reproduction depends on interactions between numerous proteins beyond those involved directly in gamete fusion. Although such reproductive proteins evolve in response to sexual selection pressures, how networks of interacting proteins arise and evolve as reproductive phenotypes change remains an open question. Here, we investigated the molecular evolution of the ‘sex peptide network’ ofDrosophila melanogaster,a functionally well‐characterized reproductive protein network. In this species, the peptide hormone sex peptide (SP) and its interacting proteins cause major changes in female physiology and behaviour after mating. In contrast, females of more distantly relatedDrosophilaspecies do not respond to SP. In spite of these phenotypic differences, we detected orthologs of all network proteins across 22 diverseDrosophilaspecies and found evidence that most orthologs likely function in reproduction throughout the genus. Within SP‐responsive species, we detected the recurrent, adaptive evolution of several network proteins, consistent with sexual selection acting to continually refine network function. We also found some evidence for adaptive evolution of several proteins along two specific phylogenetic lineages that correspond with increased expression of the SP receptor in female reproductive tracts or increased sperm length, respectively. Finally, we used gene expression profiling to examine the likely degree of functional conservation of the paralogs of an SP network protein that arose via gene duplication. Our results suggest a dynamic history for the SP network in which network members arose before the onset of robust SP‐mediated responses and then were shaped by both purifying and positive selection. 

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