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Section: Evolutionary Biology ; Topics: Ecology, Evolution

A gene-regulatory network model for density-dependent and sex-biased dispersal evolution during range expansions

Deshpande, Jhelam N.; Fronhofer, Emanuel A.

10.24072/pcjournal.626 - Peer Community Journal, Volume 5 (2025), article no. e127
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Dispersal is key to understanding ecological and evolutionary dynamics. Dispersal may itself evolve and exhibit phenotypic plasticity. Specifically, organisms may modulate their dispersal rates in response to the density of their conspecifics (density-dependent dispersal) and their own sex (sex-biased dispersal). While optimal dispersal plastic responses have been derived from first principles, the genetic and molecular basis of dispersal plasticity has not been modelled. An understanding of the genetic architecture of dispersal plasticity is especially relevant for understanding dispersal evolution during rapidly changing spatial ecological conditions such as range expansions. In this context, we develop an individual-based metapopulation model of the evolution of density-dependent and sex-biased dispersal during range expansions. We represent the dispersal trait as a gene-regulatory network (GRN), which can take population density and an individual's sex as an input and analyse emergent context- and condition-dependent dispersal responses. We compare dispersal evolution and ecological dynamics in this GRN model to a standard reaction norm (RN) approach under equilibrium metapopulation conditions and during range expansions. We find that under equilibrium metapopulation conditions, the GRN model produces emergent density-dependent and sex-biased dispersal plastic response shapes that match the theoretical expectation of the RN model. However, during range expansion, when mutation effects are large enough, the GRN model leads to faster range expansion because GRNs can maintain higher adaptive potential. Our results imply that, in order to understand eco-evolutionary dynamics in contemporary time, the genetic architecture of traits must be taken into account.
Section: Animal Science ; Topics: Agricultural sciences, Applied mathematics

Dynamic sensitivity analysis of a mathematical model describing the effect of the macroalgae Asparagopsis taxiformis on rumen fermentation and methane production under in vitro continuous conditions

Blondiaux, Paul; Kiessé, Tristan Senga; Eugène, Maguy; Muñoz-Tamayo, Rafael

10.24072/pcjournal.644 - Peer Community Journal, Volume 5 (2025), article no. e126
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Ruminants play an important role in global warming by emitting enteric methane (CH₄) through the degradation of feeds by the rumen microbiota. To better understand the dynamics fermentation outputs, including CH₄ and volatile fatty acids (VFA) production, mathematical models have been developed. Sensitivity analysis (SA) methods quantify the contribution of model input parameters (IP) to the variation of an output variable of interest. In animal science, SA are usually conducted in static condition. In this work, we hypothesized that including the dynamic aspect of the rumen fermentation to SA can be useful to inform on optimal experimental conditions aimed at quantifying the key mechanisms driving CH₄ and VFA production. Accordingly, the objective of this work was to conduct a dynamic SA of a rumen fermentation model under in vitro continuous conditions (close to the real in vivo conditions). Our model case study integrates the effect of the macroalgae Asparagopsis taxiformis (AT) on the fermentation. AT has been identified as a potent CH₄ inhibitor via the presence of bromoform, an anti-methanogenic compound. We computed Shapley effects over time for quantifying the contribution of 16 IPs to CH₄ (mol/h) and VFA (mol/l) variation. Shapley effects integrate the three contribution types of an IP to output variable variation (individual, via the interactions and via the dependence/correlation). We studied three diet scenarios accounting for several doses of AT relative to Dry Matter (DM): control (0% DM of AT), low treatment (LT: 0.25% DM of AT) and high treatment (HT: 0.50% DM of AT). Shapley effects revealed that hydrogen (H₂) utilizers microbial group via its Monod H₂affinity constant highly contributed (> 50%) to CH₄ variation with a constant dynamic over time for control and LT. A shift on the impact of microbial pathways driving CH₄ variation was revealed for HT. IPs associated with the kinetic of bromoform utilization and with the factor modeling the direct effect of bromoform on methanogenesis were identified as influential on CH₄ variation in the middle of fermentation. Whereas, VFA variation for the three diet scenarios was mainly explained by the kinetic of fibers degradation, showing a high constant contribution (> 30%) over time. The simulations computed for the SA were also used to analyze prediction uncertainty. It was related to the dynamic of dry matter intake (DMI, g/h), increasing during the high intake activity periods and decreasing when the intake activity was low. Moreover, CH₄ (mol/h) simulations showed a larger variability than VFA simulations, suggesting that the reduction of the uncertainty of IPs describing the activity of the H₂ utilizers microbial group is a promising lead to reduce the overall model uncertainty. Our results highlighted the dynamic nature of the influence of metabolic pathways on CH₄ productions under an anti-methanogenic treatment. SA tools can be further exploited to design optimal experiments studying rumen fermentation and CH₄ mitigation strategies. These optimal experiments would be useful to build robust models that can guide the development of sustainable nutrition strategies.
Section: Archaeology ; Topics: Archaeology, Anthropology, History

Rethinking Caribbean Archaeology: Towards an ethical position for a truly decolonial practice

Herrera Malatesta, Eduardo; Fricke, Felicia J.; de Waal, Maaike; Seferidou, Eleni; Cunningham, Andreana; Nägele, Kathrin; Victorina, Amy; kok, marjolijn; Chiappa, Oriana; Farmer, Kevin; van Litsenburg, Zoë; Aguasvivas, Marianny; Ammerlaan, Lauriane

10.24072/pcjournal.648 - Peer Community Journal, Volume 5 (2025), article no. e125
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Caribbean archaeology faces urgent ethical challenges rooted in colonial histories, global inequities, and local socio-political realities. This paper advances a decolonial framework for addressing these issues, grounded in best practices emerging from a workshop held in late 2023. Specifically, we: (1) summarize the key issues discussed, (2) present the goals of our network in tackling them, and (3) define our priorities for fostering ethical archaeological and heritage practices in the Caribbean. While many of these challenges resonate beyond the region, we argue that their resolution requires context-specific, Caribbean-oriented strategies. Our aim is not to provide a comprehensive catalogue of ethical issues and solutions, nor to imply that projects omitting the aspects we emphasize are inherently unethical. Rather, we seek to establish a foundation for sustained dialogue and debate on ethics in Caribbean archaeology, encouraging engagement among both local and international researchers. Although we acknowledge the vital role of communities in shaping archaeological practice, this paper reflects the disciplinary perspective of professional archaeologists, oriented toward fulfilling our ethical and social responsibilities to those communities. In doing so, we hope to contribute to a more equitable and contextually grounded archaeological practice in the Caribbean.
Section: Ecotoxicology & Environmental Chemistry ; Topics: Environmental sciences

Investigation of the combined influence of salinity and particle concentration on the adsorption of anionic and zwitterionic PFAS onto estuarine sediment using the RSM modelling approach

Gao, Chan; Budzinski, Hélène; Pardon, Patrick; Le Menach, Karyn; Labadie, Pierre

10.24072/pcjournal.645 - Peer Community Journal, Volume 5 (2025), article no. e124
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Salinity (S) and suspended particulate matter (SPM) are key factors influencing the sorption of micropollutants in estuaries, due to strong gradients in these ecosystems. Previous laboratory or field-based studies have typically investigated the impact of S or SPM separately. Thus, the combined effects of S and SPM as well as their interactions on the sorption of micropollutants such as per- and polyfluoroalkyl substances (PFAS) in estuarine environments still remain poorly understood. We initially investigated the adsorption kinetics of 11 anionic and zwitterionic PFAS onto estuarine sediment under one S/SPM combination in laboratory-controlled conditions, as well as their adsorption isotherms under two S/SPM combinations. We also determined their distribution coefficients (K_d) across 35 S/SPM combinations covering a wide range of estuarine conditions. The adsorption kinetics of PFAS could be described by a pseudo-second-order model (equilibrium time <24h). Sorption isotherms were fitted by both linear and Freundlich models; the linear sorption range was in the range 0.12–1.31 nM and K_d varied between 0.6 and 55271 L/kg. Based on response surface modelling, both S and SPM were significant factors, i.e. K_d was positively related to S (salting-out effect), while it was negatively related to SPM concentration (third-phase effect). SPM had a stronger effect than S for short-chain carboxylates, whereas S was the dominant factor for most other compounds. We also present, for the first time, evidence of a significant negative interaction between these two factors. This study therefore provides a new perspective to model the fate of PFAS at the land-sea interface.

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The network image was drawn by Martin Grandjean: A force-based network visualization CC BY-SA