Chiton glaucus

Species description

The species Chiton glaucus are part of a very primitive group of Mollusc with evidence of being present in up to 80 million years of the fossil record. Taxonomists primarily use characteristics of the valves and the girdle to tell the difference between species and this is the case for Chiton glaucus (Creese, New Zealand Coastal Marine Invertebrates, 2010).

Chiton glaucus are oval in shape, with a slightly elevated yet definite ridge running down the back of the organism. This results in a bilateral symmetry.

The size of the organism is commonly 30-35mm long. The shell consists of eight overlapping valves. It is fairly large, up to 55 mm in length, with 6 intermediate valves between 2 terminal valves at either end of the organism.

These valves are surrounded by a girdle, which helps with adhesion to the preferred surface and in the case of Chiton glaucus it is covered in large scales.

The valves and girdle are generally uniform in a green colour, but individuals brown, buff and even light blue have been known to be found, especially in the North of New Zealand. This is sometimes combined with individuals who lighter chevron or zig zag markings. Underneath the body of the Chiton, there is a large foot which spans its total length. This is used to keep suction onto the chosen substrate. Gills are not obvious, instead being found in a set on either side of the foot. It has a small mouth at one end of the foot, however the mouth is merely a simple cavity.

Natural global range

This species is found throughout New Zealand. It is also present in Tasmania, becoming very common in estuaries (Powell, 1937). It is thought to have been introduced by shipping activity between Australia and New Zealand.

New Zealand range

Chiton glaucus is found on the North, South and Stewart Islands, including the Chatham Islands.

Life cycle/Phenology

Little is known about the habits of chiton in general but observations have been made to further understand the processes relating to spawning amongst other processes (Powell, 1961). Early research conducted by a member of the great barrier reef investigation in Queensland saw that a common chiton of this area seemed to every time choose a night of full moon to conduct its spawning (Powell, 1961). This also depended on the conditions at the time as if they were not favourable or the sea was rough, spawning would not occur and was delayed until the next full moon. This was the case even if in between full moons was a favourable time period where the weather was right (Powell, 1961). We now know that the spawning of chiton is usually synchronous but not necessarily correlated with any particular stage of the lunar or solar cycle.

Generally chitons have separate sexes and sperm and eggs are spawned through a simple gonad near the posterior end of the foot (Eernisse, 2007). Chitons do not have a free swimming larval stage so distribution of the organism is not particularly great (Powell, 1961). Once the egg has been released through the anus it moves through currents into plankton where it hatches after about 2 days. Next metamorphosis occurs to promote larval settlement. The changes are not dramatic but it does start the biomineralisation of the valves and radula present in the adult stage. After this the prototroch and apical tuft are cast off and the shape of the organism changes from elongated to oval in outline about 0.5mm in length with only seven calcareous valves. A month later the eighth valve becomes apparent and two red larval spots present themselves which are lost when the organism reaches maturity. The process then repeats if the organism reaches maturity through avoiding both invertebrate and vertebrate predators.

Diet / Prey / Predators

Chiton glaucus show clear daily patterns of activity; they remain hidden during the day to escape visual predators and then during the night they travel to the tops of the rock to feed on the algae that has grown there since the previous night.

According to research done by Robert Creese (Creese, Ecology of molluscan grazers and their interactions with marine algae in north-eastern New Zealand: A review, 2010) who analysed the contents in the gut of Amaurochiton glaucus it was found that the main component of its diet is that of coralline algae. Other research suggests a broader range of organisms within its diet including encrusting organisms (sponges, bryozans etc.) and on diatoms and algae in a grazing type method. The prey is removed from the surface through the teeth on their radula that are hardened by incorporation of metallic ions in the tooth matrix (David L, 2007). They also exhibit homing behaviour where they return to a specific spot after grazing, sometimes forming depressions after repeated trips (David L, 2007).

Predators, Parasites, and Diseases

Although not much is known about Chiton glaucus it is thought that they have a variety of predators both invertebrate and vertebrate including sea stars, crabs and sea snails of invertebrate type and birds and fish of the vertebrate (Creese, New Zealand Coastal Marine Invertebrates, 2010). One of the main predators of green chiton are oystercatchers. All species of New Zealand oystercatchers prey on chiton from rocky shores. The birds have adopted a technique where they first, strike a sharp angled blow on the shell plates and if this does not dislodge the organism then the bird will apply pressure on the margin between the foot and the rock surface and use a sissor like motion to release the grip (Knox, Stonehouse, & B, 1974). This is done until the organism is separated from the surface and after the valves are taken off by the oystercatcher the chiton is eaten in one piece (Knox, Stonehouse, & B, 1974).

Many species of Chiton are susceptible to the parasite Minchinia chitonis (Bradbury, 1994). This releases spores into all tissue types of the Chiton. It is unknown how, but the parasite is able to travel through the digestive tract and be excreted to prey on other Chiton individuals (Bradbury, 1994).

Interesting fact/s

Recent analysis of the ultra structural and mechanical properties of the teeth present in that of Chiton glaucus and other organisms in the class Polyplacophora, one of the seven classes of mollusks, have shown to exhibit teeth of the most hardness and stiffness of any biomaterials known to date. This translates to as much as three times as hard as human enamel and the carbonate based shells of other mollusks. They achieve this feat through arranging a hard shell of organic incased and highly orientated magnetite rods that surround a soft core of organic rich iron phosphate in such a way that results in a tooth that is tough and wear resistant. By microscopically and spectroscopically analysing ultra structural features to figure out the structure/mechanical property relationships we can further our understanding relating to the architecture within the chiton tooth. The result of this would be wear resistant materials which could be developed for use in machines and tools, or coatings on medical implants and equipment.

It has been found that chiton living on open coastlines are brighter in colour. They have richer greens, yellows and blues, compared to those found in estuaries (Morley, 2004).