Wardill Trevor J, Knowles Katie, Barlow Laura, Tapia Gervasio, Nordström Karin, Olberg Robert M, Gonzalez-Bellido Paloma T
Department of Physiology, Development and Neuroscience, University of Cambridge, Cambridge, UK.
Brain Behav Evol. 2015 Sep;86(1):28-37. doi: 10.1159/000435944. Epub 2015 Sep 24.
Predatory animals have evolved to optimally detect their prey using exquisite sensory systems such as vision, olfaction and hearing. It may not be so surprising that vertebrates, with large central nervous systems, excel at predatory behaviors. More striking is the fact that many tiny insects, with their miniscule brains and scaled down nerve cords, are also ferocious, highly successful predators. For predation, it is important to determine whether a prey is suitable before initiating pursuit. This is paramount since pursuing a prey that is too large to capture, subdue or dispatch will generate a substantial metabolic cost (in the form of muscle output) without any chance of metabolic gain (in the form of food). In addition, during all pursuits, the predator breaks its potential camouflage and thus runs the risk of becoming prey itself. Many insects use their eyes to initially detect and subsequently pursue prey. Dragonflies, which are extremely efficient predators, therefore have huge eyes with relatively high spatial resolution that allow efficient prey size estimation before initiating pursuit. However, much smaller insects, such as killer flies, also visualize and successfully pursue prey. This is an impressive behavior since the small size of the killer fly naturally limits the neural capacity and also the spatial resolution provided by the compound eye. Despite this, we here show that killer flies efficiently pursue natural (Drosophila melanogaster) and artificial (beads) prey. The natural pursuits are initiated at a distance of 7.9 ± 2.9 cm, which we show is too far away to allow for distance estimation using binocular disparities. Moreover, we show that rather than estimating absolute prey size prior to launching the attack, as dragonflies do, killer flies attack with high probability when the ratio of the prey's subtended retinal velocity and retinal size is 0.37. We also show that killer flies will respond to a stimulus of an angular size that is smaller than that of the photoreceptor acceptance angle, and that the predatory response is strongly modulated by the metabolic state. Our data thus provide an exciting example of a loosely designed matched filter to Drosophila, but one which will still generate successful pursuits of other suitable prey.
掠食性动物已经进化出利用视觉、嗅觉和听觉等精妙的感官系统来最佳地探测猎物。拥有大型中枢神经系统的脊椎动物擅长掠食行为,这或许并不那么令人惊讶。更引人注目的是,许多微小的昆虫,尽管它们的大脑极小且神经索也相应缩小,却也是凶猛且极为成功的掠食者。对于掠食而言,在开始追捕之前确定猎物是否合适很重要。这至关重要,因为追捕太大而无法捕获、制服或杀死的猎物会产生大量代谢成本(以肌肉输出的形式),却没有任何代谢收益(以食物的形式)的机会。此外,在所有追捕过程中,掠食者会打破其潜在的伪装,从而有自身成为猎物的风险。许多昆虫利用眼睛最初探测并随后追捕猎物。蜻蜓是极其高效的掠食者,因此拥有巨大的眼睛,具有相对较高的空间分辨率,这使得它们在开始追捕之前能够有效地估计猎物大小。然而,体型小得多的昆虫,如食蚜蝇,也能视觉化并成功追捕猎物。这是一种令人印象深刻的行为,因为食蚜蝇的小体型自然限制了其神经能力以及复眼提供的空间分辨率。尽管如此,我们在此表明食蚜蝇能有效地追捕天然猎物(黑腹果蝇)和人工猎物(珠子)。天然猎物的追捕起始距离为7.9±2.9厘米,我们证明这个距离太远,无法利用双目视差进行距离估计。此外,我们表明,与蜻蜓在发动攻击前估计猎物绝对大小不同,食蚜蝇在猎物的视网膜张角速度与视网膜大小之比为0.37时,有很高的概率发动攻击。我们还表明,食蚜蝇会对小于光感受器接受角的角大小刺激做出反应,并且掠食反应受到代谢状态的强烈调节。因此,我们的数据提供了一个令人兴奋的例子,说明针对果蝇设计的匹配滤波器虽然设计宽松,但仍能成功追捕其他合适的猎物。
