Abstract
Cuttlefish are highly efficient predators, which strongly rely on their anterior binocular visual field for hunting and prey capture. Their complex eyes possess adaptations for low light conditions. Recently, it was discovered that they display camouflaging behavior at night, perhaps to avoid detection by predators, or to increase their nighttime hunting success. This raises the question whether cuttlefish are capable of foraging during nighttime. In the present study, prey capture of the common cuttlefish (Sepia officinalis) was filmed with a high-speed video camera in different light conditions. Experiments were performed in daylight and with near-infrared light sources in two simulated nightlight conditions, as well as in darkness. The body of the common cuttlefish maintained a velocity of less than 0.1 m/s during prey capture, while the tentacles during the seizing phase reached velocities of up to 2.5 m/s and accelerations reached more than 450 m/s2 for single individuals. There was no significant difference between the day and nighttime trials, respectively. In complete darkness, the common cuttlefish was unable to catch any prey. Our results show that the common cuttlefish are capable of catching prey during day- and nighttime light conditions. The common cuttlefish employ similar sensory motor systems and prey capturing techniques during both day- and nighttime conditions.
Highlights
Prey capture behavior of coleoid cephalopods have been described for several species (Wilson, 1946; Messenger, 1968; Hurley, 1976; Duval et al, 1984; Mendes et al, 2006)
Every selected hunting sequence in day, moon, and starlight conditions roughly followed the same pattern in the way the cuttlefish changed its attention, positioning and seized the moving prey (Figures 2, 3)
The day- and moonlight trials showed no significant difference in all three phases of predatory behavior
Summary
Prey capture behavior of coleoid cephalopods have been described for several species (Wilson, 1946; Messenger, 1968; Hurley, 1976; Duval et al, 1984; Mendes et al, 2006). Once the seizure phase has been initiated, the common cuttlefish loses any motor-control of the tentacles, and has no further ability to re-adjust their aim or speed (Messenger, 1968; Duval et al, 1984) This rather “stereotypic” three-phase hunting strategy has been observed in all species of squid and cuttlefish where prey capture behavior has been studied (Messenger, 1968; Hurley, 1976; Duval et al, 1984; Mather and Scheel, 2014; Sykes et al, 2014). The purpose was to elucidate whether high versus low light conditions influenced the hunting technique and tentacle fast-seizure characteristics of common cuttlefish
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