Behaviour, temperature and terrain slope impact estimates of energy expenditure using oxygen and dynamic body acceleration

David M. Scantlebury,Philip A. Stephens,Nikki J. Marks,Eleanor R. Dickinson,Rory P. Wilson

doi:10.1186/s40317-021-00269-5

David M. Scantlebury, Philip A. Stephens + Show 3 more

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https://doi.org/10.1186/s40317-021-00269-5

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Abstract

The energy used by animals is influenced by intrinsic (e.g. physiological) and extrinsic (e.g. environmental) factors. Accelerometers within biologging devices have proven useful for assessing energy expenditures and their behavioural context in free-ranging animals. However, certain assumptions are frequently made when acceleration is used as a proxy for energy expenditure, with factors, such as environmental variation (e.g. ambient temperature or slope of terrain), seldom accounted for. To determine the possible interactions between behaviour, energy expenditure and the environment (ambient temperature and terrain slope), the rate of oxygen consumption ({dot{text{V}}text{O}}_{2}) was measured in pygmy goats (Capra hircus aegarus) using open-flow indirect calorimetry. The effect of temperature (9.7–31.5 °C) on resting energy expenditure was measured. The relationship between {dot{text{V}}text{O}}_{2} and dynamic body acceleration (DBA) was measured at different walking speeds (0.8–3.0 km h−1) and on different inclines (0, + 15°, − 15°). The daily behaviour of individuals was measured in two enclosures: enclosure A (level terrain during summer) and enclosure B (sloped terrain during winter) and per diem energy expenditures of behaviours estimated using behaviour, DBA, temperature, terrain slope and {dot{text{V}}text{O}}_{2}. During rest, energy expenditure increased below 22 °C and above 30.5 °C. {dot{text{V}}text{O}}_{2} (ml min−1) increased with DBA when walking on the level. Walking uphill (+ 15°) increased energetic costs three-fold, whereas walking downhill (− 15°) increased energetic costs by one third. Based on these results, although activity levels were higher in animals in enclosure A during summer, energy expenditure was found to be significantly higher in the sloped enclosure B in winter (means of enclosures A and B: 485.3 ± 103.6 kJ day−1 and 744.5 ± 132.4 kJ day−1). We show that it is essential to account for extrinsic factors when calculating animal energy budgets. Our estimates of the impacts of extrinsic factors should be applicable to other free ranging ungulates.

Highlights

At the core of understanding an animal’s survival and reproductive fitness is calculating the energetic costs of the ecological processes involved [1, 2]
We aimed to describe the interaction between temperature and terrain slope using a caprid as a model species, by simultaneous measurements of V O2 using indirect calorimetry and body movement with triaxial accelerometers
The aims of the study were to: (1) measure the resting energy expenditure (REE) of individuals at different temperatures (9.7 to 31.5 °C); (2) measure the relationship between dynamic body acceleration (DBA) and VO2 when individuals are resting and walking at different speeds (0.8–3.0 km/h; increments of 0.1 km h −1 at temperatures between 11 and 28 °C) and to test how this relationship varies with terrain slope; (3) classify behaviours from accelerometry data; (4) and using the measured energy expenditure and daily tri-axial acceleration data to estimate the daily behaviour and daily energy expenditure (DEE) of individuals allowed to roam freely in two different enclosures; enclosure A during summer and enclosure B during winter

Summary

Introduction

At the core of understanding an animal’s survival and reproductive fitness is calculating the energetic costs of the ecological processes involved [1, 2]. Variation in energy expenditure associated with the extents and intensities of different behaviours impact the fitness and Dickinson et al Animal Biotelemetry (2021) 9:47 and this is immensely important in understanding the consequences of this variation in a changing world [12,13,14]. The majority of mammals are homeotherms and as a consequence must invest energy into maintaining core body temperature (Tb) when the Ta is on either side of the thermoneutral zone [8, 17]. Mammals occurring in seasonal environments may need to invest excess energy into thermoregulation [10, 18], or they may evolve physiological, morphological or behavioural traits to moderate the energetic costs of thermoregulation [16, 19, 20]

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