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termed the siphosome. It makes up the majority of the stem in most species of physonects and calycophorans and the entire stem in the cystonects. Nectophores are budded from a zone of proliferation just below the float in the physonects. Similarly, the siphosome proliferates from a budding region just below the nectosome, producing repetitive groups of medusoid and polypoid persons called cormidia (Figure 3.31). Within the Calycophorae, a cormidium often consists of a single gastrozooid, to the base of which is attached a tentacle along with one to several gonophores (Pugh 1999). Overlying the cormidium is a bract that has a characteristic shape and is often useful in identifying species (Figure 3.31c). Cormidia within the physonects are larger and more complex, usually possessing several leaf‐like bracts, a gastrozooid, dactylozooids, and clusters of gonophores. The cystonects have simple cormidia consisting of a gastrozooid and clusters of gonophores radiating from a gonodendron or stalk. The cystonects have no bracts.

Schematic illustration of siphonophore cormidia.

      Sources: (a) Adapted from Alvarino (1983), figure 1 (p. 342); (b) Kaestner (1967), figure 4‐34 (p. 74); (c) Adapted from Hyman (1940), figure 150 (p. 174).

      Life Histories

      The Siphonophore Conundrum

Schematic illustration of comparison of the life cycle of an agalmid siphonophore with that of an athecate hydroid.

      Source: Reproduced from G. O. Mackie (1986), From Aggregates to Integrates: Physiological Aspects of Modularity in Colonial Animals, Philosophical Transactions of the Royal Society of London Series B, Biological Sciences, 1986, Vol 313, No. 1159, page 179, by permission of the Royal Society.

      They have developed colonialism to the point where it has provided them with a means of escaping the diploblastic body plan. The higher animals escaped these limitations by becoming triploblastic using the new layer, the mesoderm, to form organs. The siphonophores have reached the organ grade of construction by a different method – that of converting whole individuals into organs.

      It is important to understand the concept that siphonophores function as highly coordinated individual organisms and not as a loosely collected gaggle of different zooids. Natural selection acts on the whole individual.

Schematic illustration of cyclic fishing behavior and optimization of feeding space.

      Feeding

      Fishing Behavior

      Digestion

      When prey contacts a tentacle, only the tentacles attached to the prey contract to bring the prey to the mouth of the gastrozooid. The rest of the colony continues fishing. Gastrozooids work individually or in teams. If the prey is too large to be completely engulfed by a single zooid (e.g. a fish in the case of Physalia), more zooids will be recruited to finish the job. Presumably, the additional zooids are joining the job in response to chemical signals released by the captured prey. Digestion of small prey items such as copepods can be quite rapid: 1–2 minutes (Mackie et al. 1987).

      As is the case with other cnidarian groups, digestion of prey is achieved using both extracellular and intracellular mechanisms. It takes place primarily in the gastrozooid, where breakdown of

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