Males compete over mating and fertilization, and often harm females in the process. Inclusive fitness theory predicts that increasing relatedness within groups of males may relax competition and discourage male harm of females as males gain indirect benefits. Recent studies in Drosophila melanogaster are consistent with these predictions, and have found that within-group male relatedness increases female fitness, though others have found no effects. Importantly, these studies did not fully disentangle male genetic relatedness from larval familiarity, so the extent to which modulation of harm to females is explained by male familiarity remains unclear. Here we performed a fully factorial design, isolating the effects of male relatedness and larval familiarity on female harm. While we found no differences in male courtship or aggression, there was a significant interaction between male genetic relatedness and familiarity on female reproduction and survival. Relatedness among males increased female lifespan, reproductive lifespan and overall reproductive success, but only when males were familiar. By showing that both male relatedness and larval familiarity are required to modulate female harm, these findings reconcile previous studies, shedding light on the potential role of indirect fitness effects on sexual conflict and the mechanisms underpinning kin recognition in fly populations.
Few bottlenecks of wild populations are sufficiently well-documented to constitute models for testing theories about the impact of bottlenecks on genetic variation, and subsequent population persistence. Relevant details of the Bennett's wallaby (Macropus rufogriseus rufogriseus) introduction into New Zealand were recorded (founder number, source and approximate bottleneck duration) and suggest this may provide a rare opportunity to examine the efficacy of tests designed to detect recent bottlenecks in wild populations. We first assessed the accuracy of historic accounts of the introduction using genetic diversity detected in mitochondrial DNA (mtDNA) and at five microsatellite loci. Phylogenetic analyses of mtDNA D-loop sequence haplotypes were consistent with the reported origin of the founders as Tasmania, rather than one of the Bass Strait islands in which Bennett's wallabies are also found. Microsatellite allele frequencies from the Tasmanian source population were then used to seed bottleneck simulations encompassing varying sizes and numbers of generations, in order to assess the severity of bottleneck consistent with diversity observed in the New Zealand population. The results suggested that the founder number was unlikely to have been as small as the three animals suggested by the account of the introduction. Nonetheless, the bottleneck was probably severe; in the range of three to five pairs of wallabies for one to three generations. It resulted in significantly reduced levels of allelic diversity and heterozygosity relative to the source population. This bottleneck is only detectable under the infinite allele model (IAM) and not under the stepwise mutation model (SMM) or the two-phase model (TPM), and possible explanations for this are discussed.
Cannibalism is taxonomically widespread and can have large impacts on individual fitness and population‐level processes. As such, identifying how cannibalism rates vary in response to ecological cues is important for predicting species evolution and population dynamics. In this study, we aimed to identify several eco‐evolutionary factors that affect cannibalism rate and measure how they interacted with one another. To do this, we conducted two experiments using complimentary methods to measure how cannibalism rates varied among larval Drosophila melanogaster and Drosophila simulans in response to changes in conspecific relatedness, social familiarity and density. We found that larvae were more likely to cannibalise non‐related larval victims in both species, and that this effect increased at high densities in D. simulans. We found no evidence that Drosophila larvae use social familiarity to assess relatedness. Finally, in D. melanogaster, cannibalistic larvae prefer to cannibalise larvae that are being attacked by a greater number of conspecifics, implying that cues linked to conspecific abundance encourage cooperative cannibalism. By showing that cannibalism frequency in Drosophila spp. is sensitive to relatedness and several other factors, we reveal the complex relationship between cannibalism frequency and species ecology. Also, by showing that the effect of relatedness on cannibalism frequency is density dependent, we advance the current understanding of how ecological variables interact to affect kin selection. A free Plain Language Summary can be found within the Supporting Information of this article.
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