Machine Learning Reveals Singing Rhythms of Male Pacific Field Crickets Are Clock Controlled

Overview

Journal Behav Ecol

Publisher Oxford University Press

Date 2023 Dec 25

PMID 38144906

Authors

Mary L Westwood

Quentin Geissmann

Aidan J ODonnell

Jack Rayner

Will Schneider

Marlene Zuk

Nathan W Bailey

Sarah E Reece

Affiliations

Soon will be listed here.

Abstract

Circadian rhythms are ubiquitous in nature and endogenous circadian clocks drive the daily expression of many fitness-related behaviors. However, little is known about whether such traits are targets of selection imposed by natural enemies. In Hawaiian populations of the nocturnally active Pacific field cricket (, males sing to attract mates, yet sexually selected singing rhythms are also subject to natural selection from the acoustically orienting and deadly parasitoid fly, . Here, we use to test whether singing rhythms are endogenous and scheduled by circadian clocks, making them possible targets of selection imposed by flies. We also develop a novel audio-to-circadian analysis pipeline, capable of extracting useful parameters from which to train machine learning algorithms and process large quantities of audio data. Singing rhythms fulfilled all criteria for endogenous circadian clock control, including being driven by photoschedule, self-sustained periodicity of approximately 24 h, and being robust to variation in temperature. Furthermore, singing rhythms varied across individuals, which might suggest genetic variation on which natural and sexual selection pressures can act. Sexual signals and ornaments are well-known targets of selection by natural enemies, but our findings indicate that the circadian timing of those traits' expression may also determine fitness.

Citing Articles

Machine learning reveals singing rhythms of male Pacific field crickets are clock controlled.

Westwood M, Geissmann Q, ODonnell A, Rayner J, Schneider W, Zuk M Behav Ecol. 2023; 35(1):arad098.

PMID: 38144906 PMC: 10748470. DOI: 10.1093/beheco/arad098.

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