Cuttlefish exhibit typical hunting behavior, including elongating tentacles against specific prey such as prawn and mysid shrimp. Cuttlefish hunting behavior involves three different actions: attention, positioning, and seizure. Hunting behavior is innate and stereotypic behavior, and it is present in newly hatched juveniles. Factors associated with prey are known to induce this behavior, similar to the sign stimulus, whereby young herring chicks imitate pecking behavior against a red dot on their parent's bill. Although the hunting behavior of cuttlefish has been described and used as an indicator to test learning and memory, details of a stimulus that can elicit this behavior remain unknown. Here, we used a variety of visual stimuli presented on a computer screen to investigate the factors that induce hunting behavior of pharaoh cuttlefish, Sepia pharaonis. We found that the appearance of prey (western king prawn, Melicertus latisulcatus) and their movement at a vertical angle of 45° are specific factors that can initiate hunting behavior. We also showed that the height of prey can attract cuttlefish and initiate hunting. To the best of our knowledge, this is the first report of a stimulus that elicits stereotyped hunting behavior by coleoid cephalopods.
We examined the effects of environmental enrichment on the behavior of the tropical octopus Callistoctopus aspilosomatis. Five individuals of adult C. aspilosomatis from Okinawa Island of the Ryukyu Archipelago were observed in the following three environments for 7 days: (1) poor environment (neither objects nor sand were provided on the bottom);(2) standard environment (sanded bottom), and (3) enriched environment (coral skeletons and artificial sea glass were provided on a sandy bottom). Behaviors were videotaped during the day and the night. In addition, reactions to a stimulus -approaching or touching an octopus with a pipette -were videotaped for these three environments. Octopuses were more exploratory in the standard environment and the enriched environment than in the poor environment. Octopuses in the poor environment frequently showed bold body patterns, but this tendency was not observed with octopuses in the standard or enriched environments. Octopuses in the poor environment showed less avoidance of the pipette, whereas octopuses in the remaining two environments tended to attack the stimulus.
We examined effect of environmental enrichment on cuttlefish, the most neutrally advanced invertebrate, to compare species variation of genetic and environmental influences. Cuttlefish were reared from seven to 117 days in one of three environments, namely, "poor" (artificial bottom without objects), "standard" (sandy bottom), and "enriched" (sandy bottom with objects). In Experiment 1, we explored whether enrichment affects the exhibition of crypsis in the cuttlefish. The cuttlefish in the standard and enriched environments spent most of their time at the bottom, exhibiting the mottled or disruptive pattern starting at 27 days of age. On the contrary, those in the poor environment exhibited uniform pattern starting at 87 days of age. Additionally, they repeatedly attempted to dig from 27 to 87 days of age, and moved around by hovering from 77 to 117 days of age. In Experiment 2, we exposed the cuttlefish to six novel substrates every other month after 53 days of age to verify whether enrichment actually affected the maturation of cryptic ability. Cuttlefish from the poor environment tended not to dig into white sandy bottom at 53-55 days of age. Additionally, they did not clearly exhibit appropriate body patterns in response to the six substrates compared to those from the other two environments at 81-83 days of age. However, at 113-115 days of age, most cuttlefish from the three environments exhibited similar cryptic behaviors in response to novel substrates. We conclude that physical enrichment promotes crypsis and accelerates the maturation of this ability in cuttlefish.
Cephalopods are able to control their arms sophisticatedly and use them for various behaviors, such as camouflage, startling predators and hunting prey. Here, we report a previously undescribed arm-flapping behavior of the pharaoh cuttlefish, Sepia pharaonis, observed in captivity. S. pharaonis raised the first pair of arms and wrinkled the parts near the distal end, where the skin color was darkened. Additionally, S. pharaonis spread the second and third pairs of arms and bent them as if they were jointed, and flapped the distal ends. S. pharaonis showed this behavior in two different situations: after being introduced into a large space, and during hunting. We discuss the putative functions of this behavior, including possible mimicry of a hermit crab, considering the situations in which the behavior was observed.Electronic supplementary materialThe online version of this article (doi:10.1007/s10164-017-0519-7) contains supplementary material, which is available to authorized users.
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