Abstract
Most of the shell material in snails is composed of calcium carbonate but the organic shell matrix determines the properties of calcium carbonate crystals. It has been shown that the deposition of calcium carbonate is affected by the ingestion of organic compounds. We hypothesize that organic compounds not synthesized by the snails are important for shell strength and must be obtained from the diet. We tested this idea indirectly by evaluating whether the abundance of the organic matter that snails eat is related to the strength of their shells. We measured shell crushing resistance in the snail Mexipyrgus churinceanus and the abundance of the most common aquatic macrophyte, the water lily Nymphaea ampla, in ten bodies of water in the valley of Cuatro Ciénegas, Mexico. We used stable isotopes to test the assumption that these snails feed on water lily organic matter. We also measured other factors that can affect crushing resistance, such as the density of crushing predators, snail density, water pH, and the concentration of calcium and phosphorus in the water. The isotope analysis suggested that snails assimilate water lily organic matter that is metabolized by sediment bacteria. The variable that best explained the variation in crushing resistance found among sites was the local abundance of water lilies. We propose that the local amount of water lily organic matter provides organic compounds important in shell biomineralization, thus determining crushing resistance. Hence, we propose that a third trophic level could be important in the coevolution of snail defensive traits and predatory structures.
Highlights
Anti-predator mechanisms are common in animals and occur in many forms
After confirming that snails consume water lily organic matter metabolized by sediment bacteria, we tested whether the local abundance of water lilies is related to local levels of shell crushing resistance
Trophic Analysis The results of the trophic analysis are consistent with the assumption that snails feed on water lily organic matter metabolized by sediment bacteria
Summary
Anti-predator mechanisms are common in animals and occur in many forms. Animals can reduce the risk of predation through changes in behavior, life history, morphology, and chemistry [1,2,3]. Because calcium carbonate is deposited at a constant rate, if snails reduce food intake (e.g. to avoid predators) they grow more slowly and develop thicker shells, which can be more resistant to crushing [9,17] This metabolic process can be limited by calcium availability [18] and by the availability of organic material [16]. Snails may grow thinner but stronger shells in environments rich in both P and organic matter (expensive shell material) For this reason, we tested for a potential positive correlation between P concentration and crushing resistance, and between water lily abundance and P concentration. If lower growth rates result in thicker, stronger shells, any observed pattern could be driven directly by snail density To evaluate this possibility, we tested for potential correlations between water lily abundance and snail density, and between snail density and crushing resistance. We considered the potential effect of water pH on crushing resistance because this variable can be related to the concentration of Ca in the water and can affect the rate at which snail shells dissolve naturally, but should not affect calcification rates [47,48]
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