Embryonic exposure to predation risk and hatch time variation in fathead minnows.

Organisms are exposed to a wealth of chemical information during their development. Some of these chemical cues indicate present or future dangers, such as the presence of predators that feed on either the developing embryos or their nearby parents. Organisms may use this information to modify their...

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Main Authors: Marianna E Horn, Douglas P Chivers
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2021-01-01
Series:PLoS ONE
Online Access:https://doi.org/10.1371/journal.pone.0255961
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spelling doaj-8eaef118019a4b9a900b501d307240ea2021-08-17T04:30:38ZengPublic Library of Science (PLoS)PLoS ONE1932-62032021-01-01168e025596110.1371/journal.pone.0255961Embryonic exposure to predation risk and hatch time variation in fathead minnows.Marianna E HornDouglas P ChiversOrganisms are exposed to a wealth of chemical information during their development. Some of these chemical cues indicate present or future dangers, such as the presence of predators that feed on either the developing embryos or their nearby parents. Organisms may use this information to modify their morphology or life-history, including hatching timing, or may retain information about risk until it gains relevance. Previous research has shown predation-induced alterations in hatching among embryonic minnows that were exposed to mechanical-injury-released alarm cues from conspecific embryos. Here, we test whether minnows likewise hatch early in response to alarm cues from injured adult conspecifics. We know that embryonic minnows can detect adult alarm cues and use them to facilitate learned recognition of predators; however, it is unknown whether these adult alarm cues will also induce a change in hatching time. Early hatching may allow animals to rapidly disperse away from potential predators, but late hatching may allow animals to grow and develop structures that allow them to effectively escape when they do hatch. Here, we found here that unlike embryonic fathead minnows (Pimephales promelas) exposed to embryonic cues, embryonic minnows exposed to adult alarm cues do not exhibit early hatching. The ability of embryos to recognize adult alarm cues as a future threat, but not a current one, demonstrates sophisticated ontogenetic specificity in the hatching response of embryonic minnows.https://doi.org/10.1371/journal.pone.0255961
collection DOAJ
language English
format Article
sources DOAJ
author Marianna E Horn
Douglas P Chivers
spellingShingle Marianna E Horn
Douglas P Chivers
Embryonic exposure to predation risk and hatch time variation in fathead minnows.
PLoS ONE
author_facet Marianna E Horn
Douglas P Chivers
author_sort Marianna E Horn
title Embryonic exposure to predation risk and hatch time variation in fathead minnows.
title_short Embryonic exposure to predation risk and hatch time variation in fathead minnows.
title_full Embryonic exposure to predation risk and hatch time variation in fathead minnows.
title_fullStr Embryonic exposure to predation risk and hatch time variation in fathead minnows.
title_full_unstemmed Embryonic exposure to predation risk and hatch time variation in fathead minnows.
title_sort embryonic exposure to predation risk and hatch time variation in fathead minnows.
publisher Public Library of Science (PLoS)
series PLoS ONE
issn 1932-6203
publishDate 2021-01-01
description Organisms are exposed to a wealth of chemical information during their development. Some of these chemical cues indicate present or future dangers, such as the presence of predators that feed on either the developing embryos or their nearby parents. Organisms may use this information to modify their morphology or life-history, including hatching timing, or may retain information about risk until it gains relevance. Previous research has shown predation-induced alterations in hatching among embryonic minnows that were exposed to mechanical-injury-released alarm cues from conspecific embryos. Here, we test whether minnows likewise hatch early in response to alarm cues from injured adult conspecifics. We know that embryonic minnows can detect adult alarm cues and use them to facilitate learned recognition of predators; however, it is unknown whether these adult alarm cues will also induce a change in hatching time. Early hatching may allow animals to rapidly disperse away from potential predators, but late hatching may allow animals to grow and develop structures that allow them to effectively escape when they do hatch. Here, we found here that unlike embryonic fathead minnows (Pimephales promelas) exposed to embryonic cues, embryonic minnows exposed to adult alarm cues do not exhibit early hatching. The ability of embryos to recognize adult alarm cues as a future threat, but not a current one, demonstrates sophisticated ontogenetic specificity in the hatching response of embryonic minnows.
url https://doi.org/10.1371/journal.pone.0255961
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AT douglaspchivers embryonicexposuretopredationriskandhatchtimevariationinfatheadminnows
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