Costly plastic morphological responses to predator specific odour cues in three-spined sticklebacks (Gasterosteus aculeatus)

Frommen, Joachim G.; Herder, Fabian; Engqvist, Leif; Mehlis, Marion; Bakker, Theo C. M.; Schwarzer, Julia; Thünken, Timo

doi:10.1007/s10682-010-9454-6

Cited by 56 publications

(68 citation statements)

References 73 publications

(65 reference statements)

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…For example, predation pressure on sticklebacks (and other species; see Endler, 1995; Relyea, 2004; Vervust et al, 2007) is associated with smaller body size at sexual maturity (Bell, Dingemanse, Hankison, Langenhof, & Rollins, 2011), lower body condition (Frommen et al, 2011), reduced male nuptial coloration (Candolin, 1998) and reduced activity (Lacasse & Aubin-Horth, 2012). In this study, offspring of predator-exposed fathers had traits associated with predator-rich conditions: they were smaller, in poorer body condition, had reduced nuptial coloration (males) and were less active than offspring of unexposed fathers.…”

Section: Discussionmentioning

confidence: 99%

Paternal programming in sticklebacks

Stein¹,

Bell²

2014

Animal Behaviour

View full text Add to dashboard Cite

In a wide range of organisms, including humans, mothers can influence offspring via the care they provide. Comparatively little is known about the effects of fathering on offspring. Here, we test the hypothesis that fathers are capable of programming their offspring for the type of environment they are likely to encounter. Male threespine sticklebacks, Gasterosteus aculeatus, were either exposed to predation risk while fathering or not. Fathers altered their paternal behaviour when exposed to predation risk, and consequently produced adult offspring with phenotypes associated with strong predation pressure (smaller size, reduced body condition, reduced behavioural activity). Moreover, more attentive fathers produced offspring that showed stronger antipredator responses. These results are consistent with behaviourally mediated paternal programming: fathers can alter offspring phenotypes to match their future environment and influence offspring traits well into adulthood.

show abstract

Section: Discussionmentioning

confidence: 99%

Paternal programming in sticklebacks

Stein¹,

Bell²

2014

Animal Behaviour

View full text Add to dashboard Cite

show abstract

“…During this treatment, half of the juvenile sticklebacks were exposed recurrently to predation threat in the form of visual and olfactory cues of live perch, chemical alarm cues from conspecifics, and visual cues of predation (perch feeding on pieces of sacrificed adult sticklebacks). Olfactory cues were included because threespine sticklebacks are known to respond to them (Frommen et al 2011). For the control, the other half of the juveniles were treated otherwise identically, except that they did not receive any visual predator cues and received water instead of the chemical cues.…”

Section: Study Speciesmentioning

confidence: 99%

Resemblance to the Enemy’s Eyes Underlies the Intimidating Effect of Eyespots

Kjernsmo

Merilaita

2017

The American Naturalist

View full text Add to dashboard Cite

General rightsThis document is made available in accordance with publisher policies. Please cite only the published version using the reference above. Full terms of use are available: http://www.bristol.ac.uk/pure/about/ebr-terms Online enhancement: appendix.abstract: Eyespots of some prey are known to deter predators, but the reason for this response has not yet been established, and thus the taxonomically widespread occurrence of this color pattern has remained an evolutionary conundrum. Two alternative hypotheses propose that (1) the eyelike appearance of the pattern falsely indicates the presence of the predator's own enemy or (2) predators are hardwired to be cautious toward conspicuous prey. Earlier research has pertained mainly to eyespots in butterflies. Here we tested the hypothesis that eyespots resemble eyes by utilizing the lateral position of eyes in fishes. This allowed us to produce eyelike displays that did not have the round appearance of eyespots. Our study indicates that eye mimicry is an important factor evoking hesitation in predators. Moreover, we present direct evidence that this is because predators associate eyelike displays with the threat posed by their own enemies.

show abstract

“…Although thermally induced plasticity has been highly documented Moksness, 1994, 1997;Fuiman et al, 1998;Mabee et al, 2000;Georgakopoulou et al, 2007;Schmidt and Starck, 2010;Kawajiri et al, 2011), numerous environmental/experimental factors have also been investigated such as dissolved oxygen (Schmidt and Starck, 2010), salinity (Schmidt and Starck, 2010), diet (Meyer, 1987;Huysseune et al, 1994;Muschick et al, 2011), predator odors (Frommen et al, 2011), hormonal conditions (Shkil et al, 2010), habitat heterogeneity (Garduno-Paz et al, 2010), and water velocity (Pakkasmaa and Piironen, 2001;PeresNeto and Magnan, 2004;Grü nbaum et al, 2007Grü nbaum et al, , 2008Cloutier et al, 2010;Totland et al, 2011). Water velocity is of primary interest for at least two reasons.…”

Section: Introductionmentioning

confidence: 99%

“…A wide range of plastic responses has been reported in the literature. Focusing on anatomical plasticity, the following traits exemplify the types of responses: size [e.g., gills (Crispo and Chapman, 2010), brain (Crispo and Chapman, 2010), head (Meyer, 1987), body (Pakkasmaa and Piironen, 2001;Peres-Neto and Magnan, 2004;Georgakopoulou et al, 2007;Grü nbaum et al, 2008;Schmidt and Starck, 2010;Frommen et al, 2011;Kawajiri et al, 2011), fins (Fischer-Rousseau et al, 2009)] and shape changes [e.g., head (Meyer, 1987), pharyngeal (Muschnick et al, 2011) and oral jaws (Meyer, 1987), body (Pakkasmaa and Piironen, 2001;Peres-Neto and Magnan, 2004;Georgakopoulou et al, 2007;Grü nbaum et al, 2007;Fischer-Rousseau et al, 2009;Garduno-Paz et al, 2010;Frommen et al, 2011)], bone matrix (Totland et al, 2011), number of serially repeated elements [e.g., pharyngeal teeth, vertebrae, fin rays, spines (Arratia and Schultze, 1992;Mabee et al, 2000;Georgakopoulou et al, 2007;Shkil et al, 2010;Kawajiri et al, 2011)], and timing of ossification Moksness, 1994, 1997;Fuiman et al, 1998;Mabee et al, 2000;Cloutier et al, 2010, Fiaz et al, 2012. It is also known that fin positioning is plastic with respect to changes in hydrodynamic conditions …”

Section: Introductionmentioning

confidence: 99%

Dynamic skeletogenesis in fishes: Insight of exercise training on developmental plasticity

Grünbaum

Cloutier

Vincent

2012

Developmental Dynamics

View full text Add to dashboard Cite

Background: Through developmental and evolutionary time, organisms respond variably to their environment not only in terms of size and shape but also in terms of timing. Developmental plasticity can potentially act on various aspects of the timing of developmental events (i.e., appearance, cessation, duration, sequence). In this study, we address the developmental plasticity of median fin endoskeleton by using exercise training on newly‐hatched Arctic charr (Salvelinus alpinus). Results: Developmental progress of cartilage formation (i.e., chondrification) in all fins is less influenced than ossification by an increase of water velocity. The most responsive elements, meaning those elements with greater onset plasticity owing to a water velocity increase, differ in terms of early versus late developmental events. The most responsive elements are those that chondrify and to a greater extent ossify later in the development. Conclusions: Plasticity is documented for the timing of appearance (i.e., onset) and the timing of transition from cartilage to bone (i.e., transitions of skeletal states) rather than the order of events within a sequence. Similarities of plastic response in developmental patterns could be used as a powerful criterion to strengthen the identification of phenotypic modules. Developmental Dynamics 241:1507–1524, 2012. © 2012 Wiley Periodicals, Inc.

show abstract

Costly plastic morphological responses to predator specific odour cues in three-spined sticklebacks (Gasterosteus aculeatus)

Cited by 56 publications

References 73 publications

Paternal programming in sticklebacks

Paternal programming in sticklebacks

Resemblance to the Enemy’s Eyes Underlies the Intimidating Effect of Eyespots

Dynamic skeletogenesis in fishes: Insight of exercise training on developmental plasticity

Contact Info

Product

Resources

About