In the complex and ever-evolving landscape of sex determination mechanisms, the European seabass (Dicentrarchus labrax) emerges as a compelling model for understanding how environmental factors and genetic architecture intertwine. Recent groundbreaking research published in Heredity illuminates the nuances of polygenic sex determination (PSD) within distinct populations of this species, revealing population-specific responses driven by thermal environments. This discovery not only advances our understanding of evolutionary biology but also underscores the intricate adaptive strategies organisms employ in a rapidly changing world.
Sex determination in vertebrates is often portrayed as a binary and genetically fixed trait, but the reality is far more intricate, especially in fish species where environmental cues play a crucial role. The European seabass exhibits a fascinating PSD system, heavily influenced by temperature, which varies across three genetically distinct populations: the Atlantic (AT), Western Mediterranean (WM), and Eastern Mediterranean (EM). By interrogating these populations through controlled experimental offspring cohorts reared under four distinct thermal regimes mimicking natural temperature gradients, this study provides novel insights into the evolutionary dynamics of sex ratios and related genetic determinants.
The researchers meticulously crafted four thermal treatments reflective of ecological realities: conditions found in the Atlantic (rAT), Western Mediterranean (rWM), Eastern Mediterranean (rEM), alongside an artificial husbandry regime designed to maximize female output (rAQUA). Such an experimental design allowed for an unprecedented dissection of how temperature modulates sex ratios across populations with distinct genetic backgrounds, shedding light on adaptive trajectories shaped by both environmental pressures and genetic architecture.
One of the study’s most striking revelations was the relatively balanced sex ratio observed in the Atlantic population under all thermal regimens, with a notable female bias relative to Mediterranean cohorts. Conversely, the Western Mediterranean group exhibited significantly male-skewed sex ratios in colder regimes (rAT and rWM), a trend that was statistically indistinguishable from the Eastern Mediterranean population, which remained consistently male-biased. Interestingly, warmer regimes (rEM and rAQUA) elicited a partial shift in WM sex ratios towards equilibrium, suggesting temperature-dependent plasticity in sex determination that is finely tuned to local thermal conditions.
The quantitative genetic analyses unveiled consistently high genetic correlations underpinning sex tendencies across populations and thermal treatments. Heritability estimates stood robustly at 0.62 ± 0.07—a testament to the strong genetic contribution to sex ratio variation despite environmental modulation. This high heritability challenges prior assumptions that environmental sex determination predominates in fish and highlights the complex interplay between inherited genetic factors and temperature-dependent cues in shaping sexual phenotype outcomes.
Delving deeper into sexual dimorphism, the research illuminated the existence of significant population-by-temperature interactions affecting sexual size dimorphism (SSD). Notably, the Atlantic fish displayed SSD patterns favoring females, with a pronounced increase linked to rising temperatures—an adaptive feature potentially associated with reproductive strategies or energy allocation differentials. Mediterranean populations, on the other hand, demonstrated much weaker or absent SSD responses to temperature, underscoring divergent evolutionary paths influencing growth dynamics in tandem with sex ratio shifts.
At the molecular level, genome-wide association studies (GWAS) offered compelling evidence for genetically encoded sex determination cues, particularly in the Atlantic lineage. Seven significant single nucleotide polymorphisms (SNPs) were detected on linkage group 19 (LG19), with one quantitative trait locus (QTL) region harboring a gene known to participate in sex determination pathways. Such genetic markers emerge as candidates for understanding the mechanistic basis of PSD and could pave the way for advanced selective breeding strategies or conservation efforts. Intriguingly, no significant QTLs were identified in the WM or EM populations, implying that their sex determination architectures may involve more polygenic or environmentally malleable elements beyond the resolution of current GWAS.
These findings convincingly demonstrate that the PSD system in European seabass does not evolve uniformly but is shaped by locally specific selective pressures and historical genetic divergences. Environmental temperatures act as a potent selective force capable of molding sex ratios and associated phenotypes in distinct populations, potentially driving adaptive divergence or resilience in face of climate fluctuations. This research implicates PSD as a dynamic evolutionary trait, pliable and responsive to ecological context.
The implications extend beyond evolutionary biology into aquaculture and fisheries management, where sex ratio manipulation often constitutes a vital component of sustainable stock management and productivity optimization. Understanding how sex ratios respond to temperature and population-genetic background can enhance predictive models for breeding outcomes, particularly as global warming alters oceanic thermal profiles. For the European seabass, a commercially valuable species, such insights align economic and ecological imperatives in a changing climate era.
Moreover, this study exemplifies the powerful synergy between quantitative genetics and genomic technologies in disentangling complex traits. By integrating controlled environmental conditions with precise genomic mapping, the researchers provide a blueprint for similar investigations across taxa exhibiting PSD or environmentally influenced sex determination systems. The approach underscores a shift towards holistic frameworks that accommodate gene-environment interactions rather than simplistic gene-centric views.
The recognition of genetically differentiated populations within a species exhibiting PSD challenges classical models and suggests that natural populations may harbor diverse genetic architectures underpinning similar phenotypes. This diversity offers raw material for natural selection and evolutionary innovation but also poses challenges for conservation, as population-specific adaptations may limit the transferability of management strategies across geographic ranges.
Future research will undoubtedly benefit from the foundational datasets and methodological advancements presented here. Areas ripe for exploration include functional validation of candidate genes within identified QTL regions, extended cross-population comparisons incorporating additional environmental variables, and long-term monitoring to capture evolutionary trajectories under shifting climate conditions. Understanding the mechanisms mediating the balance between genetic predisposition and environmental plasticity in sex determination could unlock new vistas in developmental biology, evolutionary ecology, and applied aquaculture.
In summation, this profound study unearths the multifaceted nature of polygenic sex determination in the European seabass, mapping a landscape where genetics and temperature dance together to shape population-specific sex ratios and sexual dimorphism. The intricate interplay revealed within three genetically distinct populations illuminates the adaptive potential of PSD systems, heralding new perspectives on how species may navigate an uncertain environmental future through genomic and phenotypic flexibility. Such insights invigorate ongoing dialogues in evolutionary science and underscore the profound value of integrative, multidisciplinary approaches to unraveling life’s complexities.
Subject of Research: Polygenic sex determination and the genetic and environmental factors influencing sex ratio responses in European seabass populations
Article Title: Quantitative genetics and GWAS reveal population-specific sex-ratio responses in wild European seabass (Dicentrarchus labrax) under various temperature scenarios
Article References:
Crestel, D., Vergnet, A., Delpuech, E. et al. Quantitative genetics and GWAS reveal population-specific sex-ratio responses in wild European seabass (Dicentrarchus labrax) under various temperature scenarios. Heredity (2026). https://doi.org/10.1038/s41437-026-00841-w
Image Credits: AI Generated
DOI: 10.1038/s41437-026-00841-w
Keywords: European seabass, polygenic sex determination, temperature-dependent sex determination, sexual size dimorphism, GWAS, QTL, heritability, evolutionary adaptation, fish genetics
Tags: adaptive strategies in marine speciesAtlantic versus Mediterranean seabass geneticsclimate change impact on marine sex determinationenvironmental influence on vertebrate sex determinationEuropean seabass polygenic sex determinationevolutionary biology of Dicentrarchus labraxexperimental thermal regimes in fish studiesgenetic adaptation to thermal environmentsheritability of sex ratios in fishpopulation-specific sex determination mechanismstemperature effects on fish developmenttemperature-dependent sex ratios in fish
