White‐crowned sparrow males show immediate flexibility in song amplitude but not in song minimum frequency in response to changes in noise levels in the field

White‐crowned sparrow males show immediate flexibility in song amplitude but not in song minimum frequency in response to changes in noise levels in the field

The soundscape acts as a selective agent on organisms that use acoustic signals to communicate. A number of studies document variation in structure, amplitude, or timing of signal production in correspondence with environmental noise levels thus supporting the hypothesis that organisms are changing...

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Veröffentlicht in:Ecology and evolution 2017-07, Vol.7 (13), p.4991-5001
Hauptverfasser: Derryberry, Elizabeth P., Gentry, Katherine, Derryberry, Graham E., Phillips, Jennifer N., Danner, Raymond M., Danner, Julie E., Luther, David A.
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Sprache:eng
Schlagworte:
Acoustic noise
Amplitudes
anthropogenic noise
Background noise
behavioral plasticity
Biological evolution
birdsong
cultural evolution
Flexibility
Hypotheses
Males
Masking
Noise
Noise levels
Observational studies
Ontogeny
Original Research
Real time
Signal processing
Song
soundscape
Studies
Time
Urban areas
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container_end_page 5001
container_issue 13
container_start_page 4991
container_title Ecology and evolution
container_volume 7
creator Derryberry, Elizabeth P.
Gentry, Katherine
Derryberry, Graham E.
Phillips, Jennifer N.
Danner, Raymond M.
Danner, Julie E.
Luther, David A.
description The soundscape acts as a selective agent on organisms that use acoustic signals to communicate. A number of studies document variation in structure, amplitude, or timing of signal production in correspondence with environmental noise levels thus supporting the hypothesis that organisms are changing their signaling behaviors to avoid masking. The time scale at which organisms respond is of particular interest. Signal structure may evolve across generations through processes such as cultural or genetic transmission. Individuals may also change their behavior during development (ontogenetic change) or in real time (i.e., immediate flexibility). These are not mutually exclusive mechanisms, and all must be investigated to understand how organisms respond to selection pressures from the soundscape. Previous work on white‐crowned sparrows (Zonotrichia leucophrys) found that males holding territories in louder areas tend to sing higher frequency songs and that both noise levels and song frequency have increased over time (30 years) in urban areas. These previous findings suggest that songs are changing across generations; however, it is not known if this species also exhibits immediate flexibility. Here, we conducted an exploratory, observational study to ask whether males change the minimum frequency of their song in response to immediate changes in noise levels. We also ask whether males sing louder, as increased minimum frequency may be physiologically linked to producing sound at higher amplitudes, in response to immediate changes in environmental noise. We found that territorial males adjust song amplitude but not minimum frequency in response to changes in environmental noise levels. Our results suggest that males do not show immediate flexibility in song minimum frequency, although experimental manipulations are needed to test this hypothesis further. Our work highlights the need to investigate multiple mechanisms of adaptive response to soundscapes. The soundscape acts as a selective agent on organisms that use acoustic signals to communicate. Individuals may be able to change their behavior in real time (i.e., immediate flexibility) to avoid masking. We found that territorial white‐crowned sparrow males adjust song amplitude but not minimum frequency in response to changes in ambient noise levels. Our results suggest that behavioral flexibility in song minimum frequency is not contributing to soundscape‐based patterns in song variation in this species.
doi_str_mv 10.1002/ece3.3037
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source DOAJ Directory of Open Access Journals; Wiley Online Library Journals Frontfile Complete; Elektronische Zeitschriftenbibliothek - Frei zugängliche E-Journals; Wiley Online Library Open Access; PubMed Central
subjects Acoustic noise
Amplitudes
anthropogenic noise
Background noise
behavioral plasticity
Biological evolution
birdsong
cultural evolution
Flexibility
Hypotheses
Males
Masking
Noise
Noise levels
Observational studies
Ontogeny
Original Research
Real time
Signal processing
Song
soundscape
Studies
Time
Urban areas
title White‐crowned sparrow males show immediate flexibility in song amplitude but not in song minimum frequency in response to changes in noise levels in the field
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