Center for Adaptive Rationality, Max Planck Institute for Human Development, Lentzeallee 94, 14195 Berlin, Germany; Department of Biology and Ecology of Fishes, Leibniz-Institute of Freshwater Ecology and Inland Fisheries, Mueggelseedamm 310, 12587 Berlin, Germany.
Department of Electrical Engineering and Computer Science, Lübeck University of Applied Sciences, 23562 Lübeck, Germany.
Curr Biol. 2017 Feb 20;27(4):521-526. doi: 10.1016/j.cub.2016.12.044. Epub 2017 Feb 9.
Lateralization is widespread throughout the animal kingdom [1-7] and can increase task efficiency via shortening reaction times and saving on neural tissue [8-16]. However, lateralization might be costly because it increases predictability [17-21]. In predator-prey interactions, for example, predators might increase capture success because of specialization in a lateralized attack, but at the cost of increased predictability to their prey, constraining the evolution of lateralization. One unexplored mechanism for evading such costs is group hunting: this would allow individual-level specialization, while still allowing for group-level unpredictability. We investigated this mechanism in group hunting sailfish, Istiophorus platypterus, attacking schooling sardines, Sardinella aurita. During these attacks, sailfish alternate in attacking the prey using their elongated bills to slash or tap the prey [22-24]. This rapid bill movement is either leftward or rightward. Using behavioral observations of identifiable individual sailfish hunting in groups, we provide evidence for individual-level attack lateralization in sailfish. More strongly lateralized individuals had a higher capture success. Further evidence of lateralization comes from morphological analyses of sailfish bills that show strong evidence of one-sided micro-teeth abrasions. Finally, we show that attacks by single sailfish are indeed highly predictable, but predictability rapidly declines with increasing group size because of a lack of population-level lateralization. Our results present a novel benefit of group hunting: by alternating attacks, individual-level attack lateralization can evolve, without the negative consequences of individual-level predictability. More generally, our results suggest that group hunting in predators might provide more suitable conditions for the evolution of strategy diversity compared to solitary life.
偏侧性在动物王国中广泛存在[1-7],通过缩短反应时间和节省神经组织[8-16]可以提高任务效率。然而,偏侧性可能是有代价的,因为它会增加可预测性[17-21]。例如,在捕食者-猎物相互作用中,由于偏侧化攻击的专业化,捕食者可能会增加捕获成功率,但代价是它们的猎物可预测性增加,限制了偏侧化的进化。逃避这种代价的一种未被探索的机制是群体狩猎:这将允许个体水平的专业化,同时仍然允许群体水平的不可预测性。我们在群体狩猎的箭鱼(Istiophorus platypterus)攻击成群的沙丁鱼(Sardinella aurita)中研究了这种机制。在这些攻击中,箭鱼交替使用它们狭长的喙来攻击猎物,要么向左,要么向右划或轻拍猎物[22-24]。这种快速的喙运动是向左或向右的。通过对可识别的个体箭鱼在群体中狩猎的行为观察,我们提供了箭鱼个体水平攻击偏侧性的证据。偏侧性更强的个体捕获成功率更高。来自箭鱼喙的形态分析也提供了偏侧性的证据,显示出单侧微齿磨损的强烈证据。最后,我们表明,单条箭鱼的攻击确实是高度可预测的,但随着群体规模的增加,可预测性迅速下降,因为缺乏群体水平的偏侧性。我们的研究结果提出了群体狩猎的一个新的好处:通过交替攻击,个体水平的攻击偏侧性可以进化,而不会产生个体水平的可预测性的负面后果。更一般地说,我们的研究结果表明,与独居生活相比,捕食者的群体狩猎可能为策略多样性的进化提供了更合适的条件。
