Use of bio-loggers to characterize red fox behavior with implications for studies of magnetic alignment responses in free-roaming animals

Michael S. Painter, Justin A. Blanco, E. Pascal Malkemper, Chris Anderson, Daniel C. Sweeney, Charles W. Hewgley, Jaroslav Červený, Vlastimil Hart, Václav Topinka, Elisa Belotti, Hynek Burda, John B. Phillips

Research output: Contribution to journalArticlepeer-review

18 Scopus citations

Abstract

Background: Spontaneous magnetic alignment (SMA), in which animals position their body axis in fixed alignments relative to magnetic field lines, has been shown in several classes of vertebrates and invertebrates. Although these responses appear to be widespread, the functional significance and sensory mechanism(s) underlying SMA remain unclear. An intriguing example comes from observations of wild red foxes (Vulpes vulpes) that show a ~fourfold increase in hunting success when predatory 'mousing' attacks are directed toward magnetic north-northeast. This form of SMA is proposed to receive input from a photoreceptor-based magnetoreception mechanism perceived as a 'visual pattern' and used as a targeting system to increase the accuracy of mousing attempts targeting hidden prey. However, similar to previous observational studies of magnetic orientation in vertebrates, direct evidence for the use of magnetic cues, and field-based experiments designed to characterize the biophysical mechanisms of SMA are lacking. Here, we develop a new approach for studies of SMA using triaxial accelerometer and magnetometer bio-loggers attached to semidomesticated red foxes. Results: Accelerometer data were recorded from 415 ground-truth events of three behaviors exhibited by an adult red fox. A 5-nearest neighbor classifier was developed for behavioral analysis and performed with an accuracy of 95.7% across all three behaviors. To evaluate the generalizability of the classifier, data from a second fox were tested yielding an accuracy of 66.7%, suggesting the classifier can extract behaviors across multiple foxes. A similar classification approach was used to identify the fox's magnetic alignment using two 8-way classifiers with differing underlying assumptions to distinguish magnetic headings in eight equally spaced 45° sectors. The magnetic heading classifiers performed with 90.0 and 74.2% accuracy, suggesting a realistic performance range for a classifier based on an independent set of training events equal in size to our sample. Conclusions: We report the development of 'magnetic ethograms' in which the behavior and magnetic alignment of foxes can be accurately extracted from raw sensor data. These techniques provide the basis for future studies of SMA where direct observation is not necessary and may allow for more sophisticated experimental designs aimed to characterize the sensory mechanisms mediating SMA behavior.

Original languageEnglish
Article number20
JournalAnimal Biotelemetry
Volume4
Issue number1
DOIs
StatePublished - Nov 15 2016
Externally publishedYes

Funding

This work was funded by the Virginia Tech Doctoral Scholarship Program and Sigma-Xi. The study was also supported by the Grant Agency of the Czech Republic (Project No. 506/11/2121). JBP was supported by National Science Foundation, IOS 07-48175 and IOS 13-49515.

FundersFunder number
National Science FoundationIOS 07-48175, IOS 13-49515
Grantová Agentura České Republiky506/11/2121

    Keywords

    • Accelerometer
    • Compass
    • Light-dependent
    • Magnetometer
    • Magnetoreception
    • Radio-frequency
    • Red fox
    • Spontaneous magnetic alignment
    • Vulpes vulpes

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