Sex differences in helping effort reveal the effect of future reproduction on cooperative behaviour in birds

Downing, Philip A.; Griffin, Ashleigh S.; Cornwallis, Charlie K.

doi:10.1098/rspb.2018.1164

Cited by 24 publications

(71 citation statements)

References 65 publications

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“…In birds, the sex that remains, and therefore has a chance of inheriting the nest, helps at higher levels than the sex that disperses, and so is less likely to gain a direct benefit from helping 74 . A role of direct fitness benefits in birds is further supported by the observation that longer subordinate lifespans, which can increase the chance of inheriting a patch, have favoured the evolution of cooperative breeding, but especially in species where rates of polyandry are high, and so kin selection will be weaker 75 .…”

Section: Direct and Indirect Benefits Disentangledmentioning

confidence: 99%

“…• Which sex cooperates? Across different species, both the likelihood of helping and the effort put into helping varies between the sexes 74,139 . • Why do individuals preferentially direct help towards relatives (kin discrimination) in some species, such as long-tailed tits, but not others, such as superb fairy-wrens 55 ?…”

Section: Box 2 New Questions and Future Directionsmentioning

confidence: 99%

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Ten recent insights for our understanding of cooperation

et al. 2021

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Since Hamilton published his seminal papers in 1964, our understanding of the importance of cooperation for life on earth has evolved beyond recognition. Early research was focused on altruism in the social insects, where the problem of cooperation was easy to see. In more recent years, research into cooperation has expanded across the entire tree of life, and has been revolutionised by advances in genetic, microbiological, and analytical techniques. We highlight ten insights that have arisen from these advances, which have illuminated generalisations across different taxa, making the world simpler to explain. Furthermore, progress in these areas has opened up numerous new problems to solve, suggesting exciting directions for future research. Relatedness: from anecdotes to broad generalisationsInclusive fitness theory shows how cooperation can be favoured by kin selection if it is directed towards relatives, who carry the gene for cooperation (relatives) 2 (Box 1). But how widespread is the importance of kin selection? And if it is important, how do we explain variation between individuals in the level of cooperation, or explain why cooperation is favoured in some species and not others?Recent research has shown that the relatedness (R) between interacting individuals has a clear and consistent influence on the evolution of cooperation, with both theory and data suggesting that the same factors play analogous roles at all levels of biology, from simple replicators and viruses, to complex animal groups (see below; Supplementary Tables 1 & 2). This role of relatedness has been demonstrated with a combination of methodologies, including observational, experimental, experimental evolution, across-species comparisons, and genomic.1a. Group formation. Consistent with kin selection favouring cooperation, there is considerable evidence that population structure and how groups form is a major determinant of whether cooperation is favoured 2 (Fig. 2).(i) Individuals are more cooperative in species where social groups form by staying together, compared with species where social groups form by aggregation, across a range of taxa, including bacteria, fungi, slime moulds, insects, and birds [19][20][21][22][23] .(ii) Individuals are more cooperative in species where females mate monogamously or with few males, in birds, mammals, insects and shrimps 13,19,21,[24][25][26] .(iii) When population structure is manipulated experimentally, in a range of microorganisms, including bacteria, fungi and viruses, the conditions which lead to high relatedness favour greater cooperation 15,[27][28][29][30][31][32] .(iv) The role of group formation has also been supported by sequence data. If a trait is favoured by kin selection, then lower relatedness will lead to weaker selection for that trait, and so the removal of deleterious mutations will be slower and less likely [33][34][35][36] . Consistent with kin selection playing an important role: (a) ant and bee species with either multiple mating or multiple queens, and hence reduced relatedn...

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Section: Direct and Indirect Benefits Disentangledmentioning

confidence: 99%

Section: Box 2 New Questions and Future Directionsmentioning

confidence: 99%

Ten recent insights for our understanding of cooperation

et al. 2021

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“…Our findings thereby support recent evidence from meta-analyses on the importance of direct benefits deriving from breeding position inheritance in driving helping behavior, even when controlling for sex differences in dispersal. 9,49 Indirect benefits did not predict subordinate investment in nest defense (''kin selection'' hypothesis). 10,11,13,30,33 In contrast to our predictions, subordinates that were more related to the brood did not defend the nest more often than less related ones (p R 0.08; Table S2); in fact, the likelihood of nest defense was lowest at the highest level of relatedness, and subordinates often helped defend unrelated broods (Figure S1).…”

Section: Probability Of Breeding Position Inheritance Drives Nest Defensementioning

confidence: 99%

Context-dependent social benefits drive cooperative predator defense in a bird

et al. 2021

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“…Helper foray behavior is affected by both ecological and social factors. Helper male acorn woodpeckers, as in many other avian cooperative breeders, inherit their natal territories more often and typically disperse closer to their natal territory than females (Koenig et al , Downing et al ). However, we found no difference in foray distance or foray duration between helper males and females, a pattern that may be an artifact of the spatial extent of our receiver array, whose limits are substantially less than many female foray movements (Koenig et al ).…”

Section: Discussionmentioning

confidence: 99%

Wandering woodpeckers: foray behavior in a social bird

Barve

Hagemeyer

Winter

et al. 2020

Ecology

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In many cooperatively breeding taxa, nonbreeding subordinates, or helpers, use extra-territorial forays to discover dispersal opportunities. Such forays are considered energetically costly and foraying birds face aggression from conspecific members of the territories they visit. In contrast, breeders in cooperatively breeding taxa are expected to foray seldomly. We used novel tracking technologies to follow 62 acorn woodpeckers (Melanerpes formicivorus), a cooperatively breeding bird, to study extra-territorial foray behavior. Both helpers and breeders engaged in extra-territorial forays routinely and often several times per day. Helpers forayed earlier in the day and invested more time when foraying to high-quality territories. Unexpectedly, breeders forayed as often and as far as helpers. Breeders from high-quality territories forayed closer to their home territories than breeders from low-quality territories, reflecting a potential trade-off between foraying and territory defense. Such a routine pattern of extra-territorial forays in both helpers and breeders suggests that the motives behind forays differ by sex and social status and involve more than simply searching for dispersal opportunities.

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Sex differences in helping effort reveal the effect of future reproduction on cooperative behaviour in birds

Cited by 24 publications

References 65 publications

Ten recent insights for our understanding of cooperation

Ten recent insights for our understanding of cooperation

Context-dependent social benefits drive cooperative predator defense in a bird

Wandering woodpeckers: foray behavior in a social bird

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