Repeatability of Host Female and Male Aggression Towards a Brood Parasite

Trnka, Alfréd; Požgayová, Milica; Samaš, Peter; Honza, Marcel

doi:10.1111/eth.12133

Cited by 20 publications

(14 citation statements)

References 78 publications

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“…Interestingly, chip production for yellow warblers in general also varied over the breeding season for some treatments, with significantly more chip calls being produced toward blue jay playbacks later in the season, and less chip calls toward cowbirds. Similar patterns have been observed in other alarm‐calling species from nest predator (see Montgomerie & Weatherhead, 1988, for review) and brood parasite (Brooke et al., 1998; Trnka et al., 2013) presentation studies. These responses may be due to lower benefits of renesting later in season and the typically reduced parasitism pressure over time (Montgomerie & Weatherhead, 1988; Trnka et al., 2013).…”

Section: Discussionsupporting

confidence: 76%

Pairing status moderates both the production of and responses to anti‐parasitic referential alarm calls in male yellow warblers

et al. 2021

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Defending offspring incurs temporal and energetic costs and can be dangerous for the parents. Accordingly, the intensity of this costly behavior should reflect the perceived risk to the reproductive output. When facing costly brood parasitism by brown‐headed cowbirds (Molothrus ater), where cowbirds lay eggs in heterospecific nests and cause the hosts to care for their young, yellow warblers (Setophaga petechia) use referential “seet” calls to warn their mates of the parasitic danger. Yellow warblers of both sexes produce this call only in response to cowbirds or seet‐calling conspecifics. Seet calls are mainly produced during the laying and incubation stages of breeding, when risk of brood parasitism is highest, rather than during the nestling stage. On the other hand, general alarm calls (chips) are produced throughout the nesting cycle and are also used in conspecific interactions unrelated to nesting. We hypothesized that context shapes responses prior to breeding as well, such that yellow warblers without a mate and active nest would be less likely to respond to playbacks that simulate brood parasitism risk. To test this hypothesis, we presented playbacks of two nest threats, cowbirds (brood parasite) and blue jays (Cyanocitta cristata; nest predator), on territories of unmated male warblers (unpaired) and male warblers with a known mate (paired). We found that unpaired males were unresponsive toward playbacks indicating nest threats, whereas paired males were significantly more aggressive and vocal toward these playbacks compared to control playbacks. However, both paired and unpaired males were vocally responsive toward chip calls, which are informative for males regardless of pairing status. Male yellow warblers appear to adjust their responses during the earliest stages of breeding depending on the contextual relevance of specific threat stimuli, and together with prior studies, our work further supports that referential seet calls are associated with stage‐specific risk of brood parasitism.

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Section: Discussionsupporting

confidence: 76%

Pairing status moderates both the production of and responses to anti‐parasitic referential alarm calls in male yellow warblers

et al. 2021

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“…The most common of these threats comes from predators, to which parents often defend against using a variety of aggressive behaviours, from mobbing and alarm calling in avian species ( Hollander, Van Overveld, Tokka, & Matthysen, 2008 ; Redondo & Carranza, 1989 ; Wiklund, 1990 ), to biting and lunging in fish ( Itzkowitz, 1985 ; Ridgway, 1988 ), to striking and grabbing with chelae in crayfish ( Figler, Blank, & Peeke, 2001 ; Martin & Moore, 2010 ). Similar behaviours are used to counter other biotic threats such infanticidal females ( Wolff & Peterson, 1998 ) and brood parasites ( Trnka, Požgayová, Samaš, & Honza, 2013 ). Defending against these threats yields obvious fitness benefits in the form of offspring survival, yet comes at a potential cost of injury or death to parents.…”

mentioning

confidence: 99%

“…Such individual differences may also occur in the context of nest defence, whereby some individuals invest more in protecting their offspring than others ( Burtka & Grindstaff, 2013 ). Recently, a number of studies on avian species have demonstrated such individual differences in behavioural nest defences, measured by repeatability, whereby individual females are consistent across breeding seasons in how intensely they defend their nests ( Burtka & Grindstaff, 2013 ; Hollander et al, 2008 ; Trnka et al, 2013 ). This raises the question of how those individuals who consistently invest less in behavioural defence compensate for the potential fitness losses.…”

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confidence: 99%

Plasticity in extended phenotype increases offspring defence despite individual variation in web structure and behaviour

DiRienzo

Aonuma

2018

Animal Behaviour

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Many animals actively defend their offspring using a range of behaviours from calling and mobbing in birds, to physical grappling in crustaceans, and the expression of these behaviours positively scale with offspring value. While this role of behaviour in defence is well studied, very little is known about how other traits, specifically the structure of architectural constructions such as webs and nests, contribute to offspring defence. Additionally, although some tax a show consistent individual differences in offspring defence behaviour, it is completely unknown whether individuals also differ in defensive structures. We addressed these questions in the redback spider, Latrodectus hasselti, by measuring how a female laying an eggcase influences female behaviour and web structure, and whether those traits scale with relative reproductive investment. Our results show that females modified web structure in response to an eggcase, but only the protective elements of web structure positively scaled with the relative value of that eggcase. Finally, despite the significant correlations, fixed effects (e.g. eggcase possession/value) in the models explained only 5–23% of the variation in behaviour and web structure, while the random effect of individual identity explained 46–65% of the variation. This variation drove moderate to high repeatability estimates across all traits, suggesting that some individuals consistently invest relatively more in defence, while some invest less. These results highlight that extended phenotypic traits may be a critical component of offspring defence in some taxa. Furthermore, individual variation in these traits suggest that different reproductive strategies may exist, whereby some individuals invest more in reproduction at a cost to safety/foraging and vice versa.

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“…We tested for antipredator behaviours that instead resulted as enemy-specific responses in yellow 32 and reed 33 warblers (Supplementary Table 1 ). Model presentations conducted within the above-cited investigations are part of a long-used field-experimental technique, largely shown to be a reliable test to discriminate abilities and information transfer (Supplementary Methods) 12 , 16 , 32 , 50 .…”

Section: Methodsmentioning

confidence: 99%

Evolutionary significance of antiparasite, antipredator and learning phenotypes of avian nest defence

Campobello

Sealy

2018

Sci Rep

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Avian nest defence, which is expected to serve both antiparasite and antipredator functions, may benefit or be detrimental to birds, although selective forces that potentially operate on nest defence have not been quantified as a whole. Together with fitness values, we analysed two traits of nest defence, intensity and plasticity, in two distantly related passerine species, yellow warbler (Setophaga petechia) in North America and reed warbler (Acrocephalus scirpaceus) in Europe, both favourite host species for brood parasites. Breeders that escaped parasitism were the most vocal among reed warblers, whereas there was no specific defence phenotype that predicted prevention of parasitism in yellow warblers. Breeders that escaped nest predation were, in both species, those with the most distractive response at the first exposure to a nest-threatening event, such as the experimental predation or parasitism simulated at the nest. However, increasing defence intensity benefited yellow warblers but was detrimental to reed warblers, because intense defence responses attracted predators. Adaptiveness of nest defence was revealed by nest defence phenotypes when examined in concert with the seasonal fitness (i.e. measures of reproductive success). Results revealed selective forces favoured yellow warblers with strong defence phenotypes. Opposite forces were instead revealed among reed warblers whose favoured phenotypes were strong, yet less flexible, defenders.

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Repeatability of Host Female and Male Aggression Towards a Brood Parasite

Cited by 20 publications

References 78 publications

Pairing status moderates both the production of and responses to anti‐parasitic referential alarm calls in male yellow warblers

Pairing status moderates both the production of and responses to anti‐parasitic referential alarm calls in male yellow warblers

Plasticity in extended phenotype increases offspring defence despite individual variation in web structure and behaviour

Evolutionary significance of antiparasite, antipredator and learning phenotypes of avian nest defence

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