Because coevolution takes place across a broad scale of time and space, it is virtually impossible to understand its dynamics and trajectories by studying a single pair of interacting populations at one time. Comparing populations across a range of an interaction, especially for long-lived species, can provide insight into these features of coevolution by sampling across a diverse set of conditions and histories. We used measures of prey traits (tetrodotoxin toxicity in newts) and predator traits (tetrodotoxin resistance of snakes) to assess the degree of phenotypic mismatch across the range of their coevolutionary interaction. Geographic patterns of phenotypic exaggeration were similar in prey and predators, with most phenotypically elevated localities occurring along the central Oregon coast and central California. Contrary to expectations, however, these areas of elevated traits did not coincide with the most intense coevolutionary selection. Measures of functional trait mismatch revealed that over one-third of sampled localities were so mismatched that reciprocal selection could not occur given current trait distributions. Estimates of current locality-specific interaction selection gradients confirmed this interpretation. In every case of mismatch, predators were "ahead" of prey in the arms race; the converse escape of prey was never observed. The emergent pattern suggests a dynamic in which interacting species experience reciprocal selection that drives arms-race escalation of both prey and predator phenotypes at a subset of localities across the interaction. This coadaptation proceeds until the evolution of extreme phenotypes by predators, through genes of large effect, allows snakes to, at least temporarily, escape the arms race.
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| http://dx.doi.org/10.1371/journal.pbio.0060060 | DOI Listing |
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Article Synopsis
- Co-evolution between species can create varying traits, but the reasons for these differences across different regions are not well understood, particularly in traits controlled by multiple genes.
- Using simulations based on the newt and garter snake relationship, researchers found that newts have varying levels of toxin depending on the area, while snakes develop resistance, showing a geographic correlation.
- The study indicated that simple co-evolutionary models don't fully explain the observed levels of toxicity and resistance; ecological factors and genetic makeup play a significant role in shaping these dynamics.
Coevolution with toxic prey produces functional trade-offs in sodium channels of predatory snakes.
bioRxiv
December 2023
University of Nevada, Reno, Department of Biology, Reno, Nevada, USA, 89557.
Article Synopsis
- Traits can have molecular mechanisms that link them, leading to trade-offs where improving one trait may hinder another, affecting evolution.
- * In garter snakes, resistance to tetrodotoxin (TTX), a toxin from their newt prey, is achieved through specific mutations in muscle sodium channels, but these mutations also compromise basic sodium functions.
- * These mutations result in reduced muscle performance in the snakes, demonstrating that adaptations for toxin resistance can come with significant costs, impacting their overall effectiveness and evolutionary success in the predator-prey dynamic.
The ripple effects of clines from coevolutionary hotspots to coldspots.
Mol Ecol
August 2023
Department of Ecology and Evolutionary Biology, University of California, Santa Cruz, Santa Cruz, California, USA.
Coevolution has the potential to alter not only the ecological interactions of coevolving partners, but also their interactions with yet other species. The effects of coevolution may ripple throughout networks of interacting species, cascading across trophic levels, swamping competitors, or facilitating survival or reproduction of yet other species linked only indirectly to the coevolving partners. These ripple effects of coevolution may differ among communities, amplifying how the coevolutionary process produces geographic mosaics of traits and outcomes in interactions among species.
View Article and Find Full Text PDFConspicuous coloration of toxin-resistant predators implicates additional trophic interactions in a predator-prey arms race.
Mol Ecol
August 2023
Department of Biology, University of Virginia, Charlottesville, Virginia, USA.
Antagonistic coevolution between natural enemies can produce highly exaggerated traits, such as prey toxins and predator resistance. This reciprocal process of adaptation and counter-adaptation may also open doors to other evolutionary novelties not directly involved in the phenotypic interface of coevolution. We tested the hypothesis that predator-prey coevolution coincided with the evolution of conspicuous coloration on resistant predators that retain prey toxins.
View Article and Find Full Text PDFGreen spotted puffers detect a nontoxic TTX analog odor using crypt olfactory sensory neurons.
Chem Senses
January 2022
Laboratory of Fish Biology, Department of Animal Sciences, Graduate School of Bioagricultural Sciences, Nagoya University, Furo-cho, Chikusa-ku, Nagoya, Aichi 464-8601, Japan.
Toxic puffers accumulate their defense substance (tetrodotoxin; TTX) through the food chain. Although the previous study suggests that 5,6,11-trideoxyTTX, a nontoxic TTX analog detected simultaneously with TTX in toxic puffers or their prey, acts as an olfactory chemoattractant for grass puffers, it is unclear whether toxic puffers are commonly attracted to 5,6,11-trideoxyTTX, and which types of olfactory sensory neurons (OSNs) detect 5,6,11-trideoxyTTX. Here, we demonstrated that green spotted puffer, a phylogenetically distant species from the grass puffer, is attracted to 5,6,11-trideoxyTTX.
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