Basic body forms polyp Most adult cnidarians appear as either free-swimming
medusae or
sessile polyps, and many
hydrozoans species are known to alternate between the two forms. Both are
radially symmetrical, like a wheel and a tube respectively. Since these animals have no heads, their ends are described as "oral" (nearest the mouth) and "aboral" (furthest from the mouth). Most have fringes of tentacles equipped with
cnidocytes around their edges, and medusae generally have an inner ring of tentacles around the mouth. Some hydroids may consist of colonies of
zooids that serve different purposes, such as defence, reproduction and catching prey. The
mesoglea of polyps is usually thin and often soft, but that of medusae is usually thick and springy, so that it returns to its original shape after muscles around the edge have contracted to squeeze water out, enabling medusae to swim by a sort of
jet propulsion. and in subphylum Medusozoa in three
hydrozoan families in order
Anthoathecata;
Milleporidae,
Stylasteridae and
Hydractiniidae (the latter with a mix of calcified and uncalcified species).
Main cell layers Cnidaria are
diploblastic animals; in other words, they have two main cell layers, while more complex animals are
triploblasts having three main layers. The two main cell layers of cnidarians form
epithelia that are mostly one cell thick, and are attached to a fibrous
basement membrane, which they
secrete. They also secrete the jelly-like
mesoglea that separates the layers. The layer that faces outwards, known as the
ectoderm ("outside skin"), generally contains the following types of cells: •
Cnidocytes, the harpoon-like "nettle cells" that give the
phylum Cnidaria its name. These appear between or sometimes on top of the muscle cells. In
Hydrozoans, colonial individuals arising from individual zooids will take on separate tasks. For example, in
Obelia there are feeding individuals, the
gastrozooids; the individuals capable of asexual reproduction only, the gonozooids, blastostyles and free-living or sexually reproducing individuals, the
medusae.
Cnidocytes These "nettle cells" function as
harpoons, since their
payloads remain connected to the bodies of the cells by threads. Three types of
cnidocytes are known:) • A tube-like extension of the wall of the cnida that points into the cnida, like the finger of a rubber glove pushed inwards. When a cnidocyte fires, the finger pops out. If the cell is a venomous nematocyte, the "finger"'s tip reveals a set of barbs that anchor it in the prey. • The thread, which is an extension of the "finger" and coils round it until the cnidocyte fires. The thread is usually hollow and delivers chemicals from the cnida to the target. • An
operculum (lid) over the end of the cnida. The lid may be a single hinged flap or three flaps arranged like slices of pie. • The cell body, which produces all the other parts. It is difficult to study the firing mechanisms of cnidocytes as these structures are small but very complex. At least four hypotheses have been proposed: These sensory structures, usually called rhopalia, can generate signals in response to various types of stimuli such as light, pressure, chemical changes, and much more. Medusa usually have several of them around the margin of the bell that work together to control the motor nerve net, that directly innervates the swimming muscles. Most cnidarians also have a parallel system. In scyphozoans, this takes the form of a diffuse nerve net, which has modulatory effects on the nervous system. As well as forming the "signal cables" between sensory neurons and motoneurons, intermediate neurons in the nerve net can also form ganglia that act as local coordination centers. Communication between nerve cells can occur by chemical synapses or gap junctions in hydrozoans, though gap junctions are not present in all groups. Cnidarians have many of the same neurotransmitters as bilaterians, including chemicals such as glutamate, GABA, and glycine. Serotonin, dopamine, noradrenaline, octopamine, histamine, and acetylcholine, on the other hand, are absent. This structure ensures that the musculature is excited rapidly and simultaneously, and can be directly stimulated from any point on the body, and it also is better able to recover after injury. Although the eyes probably do not form images, Cubozoa can clearly distinguish the direction from which light is coming as well as negotiate around solid-colored objects.
Feeding and excretion Cnidarians feed in several ways:
predation, absorbing dissolved
organic chemicals,
filtering food particles out of the water, obtaining
nutrients from
symbiotic algae within their cells, and parasitism. Most obtain the majority of their food from predation but some, including the
corals
Hetroxenia and
Leptogorgia, depend almost completely on their
endosymbionts and on absorbing dissolved nutrients. Cnidaria give their symbiotic algae
carbon dioxide, some nutrients, and protection against predators. Predatory species use their
cnidocytes to poison or entangle prey, and those with venomous
nematocysts may start digestion by injecting digestive
enzymes. The "smell" of fluids from wounded prey makes the tentacles fold inwards and wipe the prey off into the mouth. In medusae, the tentacles around the edge of the bell are often short and most of the prey capture is done by "oral arms", which are extensions of the edge of the mouth and are often frilled and sometimes branched to increase their surface area. These "oral arms" aid in cnidarians' ability to move prey towards their mouth once it has been poisoned and entangled. Medusae often trap prey or suspended food particles by swimming upwards, spreading their tentacles and oral arms and then sinking. In species for which suspended food particles are important, the tentacles and oral arms often have rows of
cilia whose beating creates currents that flow towards the mouth, and some produce nets of
mucus to trap particles. Their digestion is both intra and extracellular. Once the food is in the digestive cavity,
gland cells in the
gastroderm release enzymes that reduce the prey to slurry, usually within a few hours. This circulates through the digestive cavity and, in colonial cnidarians, through the connecting tunnels, so that gastroderm cells can absorb the nutrients. Absorption may take a few hours, and digestion within the cells may take a few days. The circulation of nutrients is driven by water currents produced by cilia in the gastroderm or by muscular movements or both, so that nutrients reach all parts of the digestive cavity. Nutrients reach the outer cell layer by
diffusion or, for animals or zooids such as medusae which have thick
mesogleas, are transported by mobile cells in the mesoglea. Indigestible remains of prey are expelled through the mouth. The main waste product of cells' internal processes is
ammonia, which is removed by the external and internal water currents.
Respiration There are no respiratory organs, and both cell layers absorb oxygen from and expel
carbon dioxide into the surrounding water. When the water in the digestive cavity becomes stale it must be replaced, and nutrients that have not been absorbed will be expelled with it. Some
Anthozoa have ciliated grooves on their tentacles, allowing them to pump water out of and into the digestive cavity without opening the mouth. This improves respiration after feeding and allows these animals, which use the cavity as a
hydrostatic skeleton, to control the water pressure in the cavity without expelling undigested food. Cnidaria that carry
photosynthetic symbionts may have the opposite problem, an excess of oxygen, which may prove
toxic. The animals produce large quantities of
antioxidants to neutralize the excess oxygen.
Regeneration All cnidarians can
regenerate, allowing them to recover from injury and to reproduce
asexually. Medusae have limited ability to regenerate, but polyps can do so from small pieces or even collections of separated cells. This enables corals to recover even after apparently being destroyed by predators. ==Reproduction==