Your search keyword '"Angélica L. González"' showing total 3 results

1. Temperature dependency of predation: Increased killing rates and prey mass consumption by predators with warming

Author

Ryan Walker, Shawn M. Wilder, and Angélica L. González

Subjects

arthropods, feeding rates, nutritional ecology, predator–prey interactions, spiders, temperature change, Ecology, QH540-549.5

Abstract

Abstract Temperature dependency of consumer–resource interactions is fundamentally important for understanding and predicting the responses of food webs to climate change. Previous studies have shown temperature‐driven shifts in herbivore consumption rates and resource preference, but these effects remain poorly understood for predatory arthropods. Here, we investigate how predator killing rates, prey mass consumption, and macronutrient intake respond to increased temperatures using a laboratory and a field reciprocal transplant experiment. Ectothermic predators, wolf spiders (Pardosa sp.), in the lab experiment, were exposed to increased temperatures and different prey macronutrient content (high lipid/low protein and low lipid/high protein) to assess changes in their killing rates and nutritional demands. Additionally, we investigate prey mass and lipid consumption by spiders under contrasting temperatures, along an elevation gradient. We used a field reciprocal transplant experiment between low (420 masl; 26°C) and high (2,100 masl; 15°C) elevations in the Ecuadorian Andes, using wild populations of two common orb‐weaver spider species (Leucauge sp. and Cyclosa sp.) present along the elevation gradient. We found that killing rates of wolf spiders increased with warmer temperatures but were not significantly affected by prey macronutrient content, although spiders consumed significantly more lipids from lipid‐rich prey. The field reciprocal transplant experiment showed no consistent predator responses to changes in temperature along the elevational gradient. Transplanting Cyclosa sp. spiders to low‐ or high‐elevation sites did not affect their prey mass or lipid consumption rate, whereas Leucauge sp. individuals increased prey mass consumption when transplanted from the high to the low warm elevation. Our findings show that increases in temperature intensify predator killing rates, prey consumption, and lipid intake, but the responses to temperature vary between species, which may be a result of species‐specific differences in their hunting behavior and sensitivity to temperature.

Published

2020

2. Temperature dependency of predation: Increased killing rates and prey mass consumption by predators with warming

Author

Angélica L. González, Shawn M. Wilder, and Ryan Walker

Subjects

0106 biological sciences, Low protein, Cyclosa, Zoology, arthropods, Leucauge, 010603 evolutionary biology, 01 natural sciences, Predation, spiders, 03 medical and health sciences, lcsh:QH540-549.5, temperature change, Predator, Ecology, Evolution, Behavior and Systematics, Original Research, 030304 developmental biology, Nature and Landscape Conservation, Pardosa, 0303 health sciences, Herbivore, nutritional ecology, Ecology, biology, predator–prey interactions, biology.organism_classification, Ectotherm, feeding rates, lcsh:Ecology

Abstract

Temperature dependency of consumer–resource interactions is fundamentally important for understanding and predicting the responses of food webs to climate change. Previous studies have shown temperature‐driven shifts in herbivore consumption rates and resource preference, but these effects remain poorly understood for predatory arthropods. Here, we investigate how predator killing rates, prey mass consumption, and macronutrient intake respond to increased temperatures using a laboratory and a field reciprocal transplant experiment. Ectothermic predators, wolf spiders (Pardosa sp.), in the lab experiment, were exposed to increased temperatures and different prey macronutrient content (high lipid/low protein and low lipid/high protein) to assess changes in their killing rates and nutritional demands. Additionally, we investigate prey mass and lipid consumption by spiders under contrasting temperatures, along an elevation gradient. We used a field reciprocal transplant experiment between low (420 masl; 26°C) and high (2,100 masl; 15°C) elevations in the Ecuadorian Andes, using wild populations of two common orb‐weaver spider species (Leucauge sp. and Cyclosa sp.) present along the elevation gradient. We found that killing rates of wolf spiders increased with warmer temperatures but were not significantly affected by prey macronutrient content, although spiders consumed significantly more lipids from lipid‐rich prey. The field reciprocal transplant experiment showed no consistent predator responses to changes in temperature along the elevational gradient. Transplanting Cyclosa sp. spiders to low‐ or high‐elevation sites did not affect their prey mass or lipid consumption rate, whereas Leucauge sp. individuals increased prey mass consumption when transplanted from the high to the low warm elevation. Our findings show that increases in temperature intensify predator killing rates, prey consumption, and lipid intake, but the responses to temperature vary between species, which may be a result of species‐specific differences in their hunting behavior and sensitivity to temperature., An important issue in ecological theory is to understand how increased temperatures will affect trophic interactions and food web dynamics. Our study provides an important step towards understanding the consequences of rising temperatures and changes in prey macronutrient content on predator killing rates and prey macronutrient consumption.

Published

2020

3. Caught in the web: Spider web architecture affects prey specialization and spider-prey stoichiometric relationships

Author

Leticia Avilés, Matthew A. Barbour, Jennifer Guevara, Angélica L. González, and Lorraine Ludwig

Subjects

0106 biological sciences, 0301 basic medicine, Range (biology), Nitrogen, Threshold elemental ratio, Biology, Generalist and specialist species, 010603 evolutionary biology, 01 natural sciences, nitrogen, Predation, 03 medical and health sciences, Spider webs, Ecological stoichiometry, phosphorus, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation, Trophic level, Original Research, Biomass (ecology), Spider, ecological stoichiometry, spider webs, Ecology, Food webs, predator–prey interactions, threshold elemental ratio, Phosphorus, 030104 developmental biology, food webs, Species richness, Predator–prey interactions

Abstract

Quantitative approaches to predator–prey interactions are central to understanding the structure of food webs and their dynamics. Different predatory strategies may influence the occurrence and strength of trophic interactions likely affecting the rates and magnitudes of energy and nutrient transfer between trophic levels and stoichiometry of predator–prey interactions. Here, we used spider–prey interactions as a model system to investigate whether different spider web architectures—orb, tangle, and sheet‐tangle—affect the composition and diet breadth of spiders and whether these, in turn, influence stoichiometric relationships between spiders and their prey. Our results showed that web architecture partially affects the richness and composition of the prey captured by spiders. Tangle‐web spiders were specialists, capturing a restricted subset of the prey community (primarily Diptera), whereas orb and sheet‐tangle web spiders were generalists, capturing a broader range of prey types. We also observed elemental imbalances between spiders and their prey. In general, spiders had higher requirements for both nitrogen (N) and phosphorus (P) than those provided by their prey even after accounting for prey biomass. Larger P imbalances for tangle‐web spiders than for orb and sheet‐tangle web spiders suggest that trophic specialization may impose strong elemental constraints for these predators unless they display behavioral or physiological mechanisms to cope with nutrient limitation. Our findings suggest that integrating quantitative analysis of species interactions with elemental stoichiometry can help to better understand the occurrence of stoichiometric imbalances in predator–prey interactions.

Published

2017