Linking time budgets to habitat quality suggests that beavers (Castor canadensis) are energy maximizers

According to optimal foraging theory, consumers make choices that maximize their net energy intake per unit of time. We used foraging theory as a framework to understand the foraging behaviour of North American beavers (Castor canadensis Kuhl, 1820), an important herbivore that engineers new habitats. We tested the hypothesis that beavers are energy maximizers by verifying the prediction that they allocate time to foraging activities independently of habitat quality in Kouchibouguac National Park of Canada in New Brunswick, where nearly five decades of unabated colonization by beavers led to family units established in habitats of varying quality. We observed the behaviour of 27 beavers at seven ponds from May to August 2001, at dusk and dawn. Habitat quality did not influence time that beavers allocated to foraging. This finding supported our hypothesis. The only factor in the best model explaining time spent foraging was the progression of spring and summer seasons (weekly periods). Limiting factors such as infrastructure maintenance and intermittent reactions to danger remain poorly understood for this important herbivore. Future research should focus on establishing the importance that habitat quality (food availability) and environmental stress (weather, predators) have on shaping its time budget and, consequently, its survival and reproductive success.

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An extensive study of the foraging ecology of beavers (Castor canadensis) in relation to habitat quality

Canadian Journal of Zoology ◽

10.1139/z04-067 ◽

2004 ◽

Vol 82 (6) ◽

pp. 922-933 ◽

Cited By ~ 36

Author(s):

D Gallant ◽

C H Bérubé ◽

E Tremblay ◽

L Vasseur

Keyword(s):

Habitat Quality ◽

Foraging Behaviour ◽

Foraging Ecology ◽

Castor Canadensis ◽

Central Place ◽

Foraging Theory ◽

Extensive Study ◽

Food Items ◽

Partial View ◽

Selection Of

The objective of this study was to examine the foraging behaviour of the beaver (Castor canadensis Kuhl, 1820) and to explain its selection of terrestrial woody plant species according to central place foraging theory. Limitations in variety of food items in most studies with regard to size and (or) distance from the central place and information on availability of forage choices give a partial view of the subject. In this study, the theory is tested in a natural environment with high variability in food items with regard to these factors. Foraging choices by beavers were inspected by measuring variables on cut and uncut trees of every species encountered within 1 m of trail systems made by 25 beaver colonies in Kouchibouguac National Park in New Brunswick, Canada, thereby quantifying the availability of the different food items. The effect of habitat quality (food availability) on the foraging behaviour of beavers was also tested. The results of this study suggest that with increasing distance from the pond, beavers in high-quality habitats selected fewer, but larger, trees and are more species selective. This selectivity was diminished in habitats of lower quality. The results of this study are consistent with the predictions of the central foraging theory.

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Foraging modes of carnivorous plants

Israel Journal of Ecology and Evolution ◽

10.1163/22244662-20191066 ◽

2019 ◽

Vol 66 (1-2) ◽

pp. 101-112 ◽

Cited By ~ 1

Author(s):

Aaron M. Ellison

Keyword(s):

Prey Availability ◽

Soil Nutrient ◽

Optimal Foraging Theory ◽

Foraging Theory ◽

Carnivorous Plants ◽

Foraging Strategies ◽

Nutrient Concentrations ◽

Future Research ◽

Single Location ◽

Foraging Modes

Abstract Carnivorous plants are pure sit-and-wait predators: they remain rooted to a single location and depend on the abundance and movement of their prey to obtain nutrients required for growth and reproduction. Yet carnivorous plants exhibit phenotypically plastic responses to prey availability that parallel those of non-carnivorous plants to changes in light levels or soil-nutrient concentrations. The latter have been considered to be foraging behaviors, but the former have not. Here, I review aspects of foraging theory that can be profitably applied to carnivorous plants considered as sit-and-wait predators. A discussion of different strategies by which carnivorous plants attract, capture, kill, and digest prey, and subsequently acquire nutrients from them suggests that optimal foraging theory can be applied to carnivorous plants as easily as it has been applied to animals. Carnivorous plants can vary their production, placement, and types of traps; switch between capturing nutrients from leaf-derived traps and roots; temporarily activate traps in response to external cues; or cease trap production altogether. Future research on foraging strategies by carnivorous plants will yield new insights into the physiology and ecology of what Darwin called “the most wonderful plants in the world”. At the same time, inclusion of carnivorous plants into models of animal foraging behavior could lead to the development of a more general and taxonomically inclusive foraging theory.

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Bioenergetic calculations evaluate changes to habitat quality for salmonid fishes in streams treated with salmon carcass analog

Canadian Journal of Fisheries and Aquatic Sciences ◽

10.1139/cjfas-2015-0265 ◽

2016 ◽

Vol 73 (5) ◽

pp. 819-831 ◽

Cited By ~ 5

Author(s):

Ernest R. Keeley ◽

Steven O. Campbell ◽

Andre E. Kohler

Keyword(s):

Habitat Quality ◽

Invertebrate Drift ◽

Physical Habitat ◽

Net Energy ◽

Energy Availability ◽

Salmonid Fishes ◽

Nutrient Supplementation ◽

Habitat Features ◽

Net Energy Intake ◽

Salmon Carcass

Nutrient supplementation in oligotrophic streams is proposed as a means of mitigating losses of marine-derived subsidies from declining or extirpated populations of anadromous fishes. One of the central predictions of nutrient addition is an increased production of fish through bottom-up increases in invertebrate abundance. Such changes in food availability may increase growth and production rates for stream fishes by increasing habitat quality. In this study we apply bioenergetic calculations to estimate changes to habitat quality based on predicted increases in net energy intake. We compared invertebrate drift abundance and estimated changes in energy availability in streams treated with salmon carcass analog versus untreated controls. Our results revealed a two- to threefold increase in invertebrate drift abundance following the addition of salmon carcass analog; however, this effect appeared to be short-term. Measures of the energetic profitability of stream habitat for salmonid fishes revealed small, yet significant, increases in net energy availability in streams that received analog additions, but only after controlling for differences in physical habitat features such as temperature and stream flow.

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