Life in the Open Ocean. Joseph J. Torres
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Название: Life in the Open Ocean

Автор: Joseph J. Torres

Издательство: John Wiley & Sons Limited

Жанр: Биология

Серия:

isbn: 9781119840312

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СКАЧАТЬ bell, giving it an encounter volume like that shown in Figure 3.17a. It is believed to feed largely on small prey such as copepods.

      Dichotomia cannoides has a conical bell with about 50 tentacles arranged around the bell margin. Its tentacles are deployed in a disc (Figure 3.17a) or cone (Figure 3.17c) configuration. It is believed to feed on small prey.

       Trachymedusae

      Liriope tetraphylla has four tentacles that extend as much as 25 times the bell diameter and an unusually long gastric peduncle with a stomach at the end. Its hunting strategy is most like Stomotoca (Figure 3.17b), with a large spherical encounter volume and the tentacles only occupying a small fraction of it.

       Narcomedusae

      Solmundella bitentaculata (Figure 3.17d) has two tentacles that are held in front of the bell (aboral side) as it swims, forming a cylindrical or conical volume of about three bell diameters in front of the bell.

      Aeginopsis laurentii is another D‐type (Figure 3.17d) predator but with four tentacles that extend out in front of the bell in a cone. Like Solmundella, Aeginopsis is a mesopelagic species and little information is available on diet.

      Solmaris is a narcomedusan genus with several species living at epi‐ and mesopelagic depths. It conforms to the narcomedusan D‐type tentacle deployment; it has an array of several tentacles forming a larger cone.

       Scyphomedusae

      Pelagia noctiluca is a semeaostome scyphomedusa. As a scyphozoan, it is larger than its hydrozomedusan brethren with a bell diameter of up to 15 cm and tentacles extending outward up 30 times the bell diameter. It swims continuously as a C‐type predator feeding on a wide variety of prey types including salps, doliolids, pteropods, forams, amphipods, chaetognaths, and fishes.

      The Model

      Madin (1988) proposed a general model to describe tentaculate predation incorporating the best elements of previous studies (Gerritsen and Strickler 1977; Mills 1981; Greene 1985; Greene et al. 1986; Larson 1987a, 1987b; Purcell and Mills 1988) and the author’s own observations. A successful predatory sequence consists of four parts: encounter, capture/selection, ingestion, and digestion.

      Interaction with prey begins with the “encounter” phase, which is determined by the size and type of encounter zone (Figure 3.17a–d) and the swimming behavior of the medusa. It was assumed that sensory mechanisms were not used to target individual prey. Once a prey item is within its encounter zone, how effective a species will be at capturing it will be determined by a suite of characteristics: tentacle density and spacing, prey size and swimming behavior, and effectiveness of the nematocysts and venom.

      Once a prey item is captured, successful digestion will depend on whether the item can be conveyed to the mouth by the tentacles and whether it can be successfully introduced to the gastric cavity through the mouth and broken down into useful nutrients by the digestive apparatus.

      Swimming and Hunting Behavior

      As a congener of Stomotoca pterophylla, Stomotoca atra is a B‐type (see Figure 3.18b) predator. By adding its swimming behavior, we gain a better understanding of how it uses its two long tentacles to hunt. It employs a hop–sink swim cycle to drag its long tentacles up and down through the water column. As it swims and sinks, the tentacles describe a sine curve about the width of the bell and 2 meters from top to bottom. It feeds on large prey (hydromedusae), and it greatly increases the probability of contacting a prey item by its method of interrogating the water column.

      The third species, Phialidium gregarium, is the primary prey of Stomotoca atra. P. gregarium also employs a hop–sink feeding strategy but a very different one from that of S. atra. It swims upward, bell uppermost, then sinks down with the bell oriented downward and its tentacles trailing behind (Figure 3.18c). As it does so, vortices are created behind the bell that circulate small prey into the tentacles. P. gregarium would be classified as a C‐type predator in Madin’s Figure 3.17 model.

      The last example is Polyorchis pencillatus, a resident of shallow bays where it spends a great deal of its time on the bottom. Its hunting strategy on the bottom is to perch on its tentacles (Figure 3.18e) and use its manubrium to ingest prey from the surface sediments. At intervals it hops up off the bottom, stirring up the sediments, and then back down. Occasionally it swims up to the surface and drifts downward bell up (Figure 3.18d), becoming an A‐type predator in the Figure 3.17 model.

      Mills (1981) lists seven factors that contribute to feeding efficiency in medusae: (i) tentacle number and length; (ii) geometry of tentacle posture; (iii) velocity of tentacles moving through water; (iv) swimming pattern of medusa; (v) streamlining effects of the medusa bell on water flow; СКАЧАТЬ