Rickey D. Cothran

Precopulatory mate guarding affects predation risk in two freshwater amphipod species

Contact mate guarding may increase predation risk in the presence of active, size-selective predators by increasing the apparent size or decreasing the escape ability of an individual. These same characteristics may, however, make paired individuals less vulnerable to sit-and-wait, non-size-selective predators. Because the costs and benefits associated with mate guarding are likely to depend on local ecological conditions, species or populations should vary in the duration of the guarding phase. In this study, I investigate whether precopulatory mate guarding increases an individuals predation risk for two freshwater amphipod species within the Hyalella azteca species complex that experience different predators. When larval dragonflies, Anax junius and Tramea lacerata, were used as predators in laboratory trials, single, unpaired individuals were more likely to be consumed than paired individuals. Conversely, predatory fish consumed paired females more often than single females. Therefore, the short precopulatory mate guarding duration observed in the species that co-occurs with predatory fish may be due to habitat-specific, predator-driven costs associated with precopulatory mate guarding. Furthermore, the predation cost associated with precopula was greater for females than males when predatory fish were used as predators, implying that intersexual conflict over the duration of the guarding period may be more intense for the species that co-occurs with predatory fish.

Proximity to agriculture is correlated with pesticide tolerance: evidence for the evolution of amphibian resistance to modern pesticides

Anthropogenic environmental change is a powerful and ubiquitous evolutionary force, so it is critical that we determine the extent to which organisms can evolve in response to anthropogenic environmental change and whether these evolutionary responses have associated costs. This issue is particularly relevant for species of conservation concern including many amphibians, which are experiencing global declines from many causes including widespread exposure to agrochemicals. We used a laboratory toxicity experiment to assess variation in sensitivity to two pesticides among wood frog (Lithobates sylvaticus) populations and a mesocosm experiment to ascertain whether resistance to pesticides is associated with decreased performance when animals experience competition and fear of predation. We discovered that wood frog populations closer to agriculture were more resistant to a common insecticide (chlorpyrifos), but not to a common herbicide (Roundup). We also found no evidence that this resistance carried a performance cost when facing competition and the fear of predation. To our knowledge, this is the first study demonstrating that organophosphate insecticide (the most commonly applied class of insecticides in the world) resistance increases with agricultural land use in an amphibian, which is consistent with an evolutionary response to agrochemicals.

Niche diversity in crustacean cryptic species: complementarity in spatial distribution and predation risk

Recent genetic studies indicate that species with very close phenotypic similarity (“cryptic species”) are a common feature of nature, and that such cryptic species often coexist in communities. Because traditional views of species coexistence demand that species differ in phenotype to coexist stably, the existence of sympatric cryptic species appears to challenge traditional perspectives of coexistence. We evaluated niche diversity in three recently discovered species of Hyalella amphipods that occur sympatrically in lakes and share close phenotypic similarity. We found that, in some cases, these species exhibited strong complementary spatial distributions within the littoral zone of lakes, both across a distance-from-shore gradient, and a vertical depth gradient. Additionally, we compared fish stomach contents with habitat samples and found that species differed in their vulnerability to predation from sunfish (Lepomis spp.). Complementarity among species across axes of spatial distribution and predation risk, two important niche components, suggests that species with close phenotypic similarity may differ appreciably along ecologically relevant axes. Our results, considered in the light of previous studies, suggest a community structured by predator-mediated coexistence or sequential dominance across environmental gradients in the littoral zone.

Testing the ecological consequences of evolutionary change using elements

Understanding the ecological consequences of evolutionary change is a central challenge in contemporary biology. We propose a framework based on the ˜25 elements represented in biology, which can serve as a conduit for a general exploration of poorly understood evolution-to-ecology links. In this framework, known as ecological stoichiometry, the quantity of elements in the inorganic realm is a fundamental environment, while the flow of elements from the abiotic to the biotic realm is due to the action of genomes, with the unused elements excreted back into the inorganic realm affecting ecological processes at higher levels of organization. Ecological stoichiometry purposefully assumes distinct elemental composition of species, enabling powerful predictions about the ecological functions of species. However, this assumption results in a simplified view of the evolutionary mechanisms underlying diversification in the elemental composition of species. Recent research indicates substantial intraspecific variation in elemental composition and associated ecological functions such as nutrient excretion. We posit that attention to intraspecific variation in elemental composition will facilitate a synthesis of stoichiometric information in light of population genetics theory for a rigorous exploration of the ecological consequences of evolutionary change.

CONDITION DEPENDENCE OF A SEXUALLY SELECTED TRAIT IN A CRUSTACEAN SPECIES COMPLEX: IMPORTANCE OF THE ECOLOGICAL CONTEXT

The genic capture model offers a promising solution to the lek paradox. Heightened condition dependency of sexually selected traits is a prerequisite of this model. Condition dependency is empirically inferred by the sensitivity of traits to stressors. The magnitude of ecological stress (e.g., competition and predation) experienced by populations varies considerably. Thus, condition dependence should manifest more in populations experiencing higher levels of stress. We experimentally assessed the sensitivity of a sexually selected trait (posterior gnathopod) to food resource stress in an amphipod species. We found that gnathopod size variation was 59% higher under food stress, with no corresponding effect on nonsexually selected traits. In addition, we assessed levels of gnathopod variation and the allometry of gnathopods for males sampled from natural populations for two amphipod species that experience different levels of stress (driven by contrasting size‐selective predation and associated life‐history trade‐offs). Populations that experience higher resource stress had both steeper allometries and greater gnathopod size variation. These results suggest that the magnitude of ecological stress experienced by natural populations strongly impacts condition dependency of sexually selected traits, and could play an important role in shaping trait variation and thus the opportunity for sexual selection.

Direct and indirect fitness consequences of female choice in a crustacean.

Abstract Understanding the evolution and maintenance of female mate choice requires information on both the benefits (the sum of direct and indirect benefits) and costs of selective mating. In this study, I assessed the fitness consequences of female mate choice in a freshwater crustacean. In Hyalella amphipods, males attempt to form precopulatory pairs with females. Large males, bearing large posterior gnathopods, tend to be over-represented in precopulatory pairs. I show that females receive both direct (reduced risk of predation while paired) and indirect (sexy sons) benefits from mating with these males. Furthermore, the behavioral mechanisms used to filter male phenotypes carry no detectable energetic cost for females. Thus, females that choose males with successful phenotypes are expected to have higher Darwinian fitness than females that mate at random. This study shows that direct and indirect selection act together to favor large male size, which explains the sexual size dimorphism and size-based mating biases observed in this species.

Cross-tolerance in amphibians: wood frog mortality when exposed to three insecticides with a common mode of action.

Insecticide tolerance and cross-tolerance in nontarget organisms is often overlooked despite its potential to buffer natural systems from anthropogenic influence. We exposed wood frog tadpoles from 15 populations to three acetylcholine esterase-inhibiting insecticides and found widespread variation in insecticide tolerance and evidence for cross-tolerance to these insecticides. Our results demonstrate that amphibian populations with tolerance to one pesticide may be tolerant to many other pesticides.

Phenotypic manipulation reveals sexual conflict over precopula duration

Sexual conflict is common in nature, but detailed behavioral studies on the role female resistance behavior plays in shaping mating patterns are rare. I manipulated female resistance to examine its effects on pairing dynamics in two ecologically different freshwater amphipods. I found evidence for female behavior playing a role in both the outcome of pre-pairing interactions and the initiation of pairing in both species. In these species, the male optimum pairing duration is greater than the value preferred by females or compromised pairing durations observed under natural conditions, thus indicating sexual conflict. Furthermore, the proportion of male–female encounters producing male grasping was greater and the duration of such interactions was longer when female resistance was reduced. Thus, sexual conflict over pairing duration may select simultaneously for female resistance and for male persistence both of which mediate the outcome of pre-pairing interactions in Hyalella. Contact precopulatory mate guarding and the interactions that precede it are common components of crustacean and insect mating systems, suggesting that such conflicts may play an important role in the evolution of mating traits in many taxa.

The contribution of phenotypic plasticity to the evolution of insecticide tolerance in amphibian populations

Understanding population responses to rapid environmental changes caused by anthropogenic activities, such as pesticides, is a research frontier. Genetic assimilation (GA), a process initiated by phenotypic plasticity, is one mechanism potentially influencing evolutionary responses to novel environments. While theoretical and laboratory research suggests that GA has the potential to influence evolutionary trajectories, few studies have assessed its role in the evolution of wild populations experiencing novel environments. Using the insecticide, carbaryl, and 15 wood frog populations distributed across an agricultural gradient, we tested whether GA contributed to the evolution of pesticide tolerance. First, we investigated the evidence for evolved tolerance to carbaryl and discovered that population‐level patterns of tolerance were consistent with evolutionary responses to pesticides; wood frog populations living closer to agriculture were more tolerant than populations living far from agriculture. Next, we tested the potential role of GA in the evolution of pesticide tolerance by assessing whether patterns of tolerance were consistent with theoretical predictions. We found that populations close to agriculture displayed constitutive tolerance to carbaryl whereas populations far from agriculture had low naïve tolerance but high magnitudes of induced tolerance. These results suggest GA could play a role in evolutionary responses to novel environments in nature.

EUTROPHICATION AND PREDATION RISK INTERACT TO AFFECT SEXUAL TRAIT EXPRESSION AND MATING SUCCESS

Sexual traits are especially sensitive to low food resources. Other environmental parameters (e.g., predation) should also affect sexual trait expression by favoring investment in viability traits rather than sexual traits. We know surprisingly little about how predators alter investment in sexual traits, or how predator and resource environments interact to affect sexual trait investment. We explored how increasing phosphorous (P) availability, at a level mimicking cultural eutrophication, affects the development of sexual, nonsexual, and viability traits of amphipods in the presence and absence of predators. Sexual traits and growth were hypersensitive to low P compared to nonsexual traits. However, a key sexual trait responded to low P only when predator cues were absent. Furthermore, investment trade‐offs between sexual traits and growth only occurred when P was low. The phenotypic changes caused by predator cues and increased P availability resulted in higher male mating success. Thus, eutrophication not only affects sexual trait expression but also masks the trade‐off between traits with similar P demand. Sensitivity of sexually selected traits to changes in P, combined with the important roles these traits play in determining fitness and driving speciation, suggests that human‐induced environmental change can greatly alter the evolutionary trajectories of populations.