Everything about Corals totally explained
Corals belong to the
class Anthozoa and are divided into two subclasses, depending on the number of tentacles or lines of symmetry, and a series of orders corresponding to their exoskeleton, nematocyst type and
mitochondrial
genetic analysis. Those with eight tentacles are called octocorallia or
Alcyonaria and comprise
soft corals,
sea fans and
sea pens. Those with more than eight in a multiple of six are called hexacorallia or
Zoantharia. This group includes reef-building corals (
Scleractinians),
sea anemones and
zoanthids.
Anatomy
While a coral head appears to be a single organism, it's actually a head of many individual, yet
genetically identical,
polyps. The polyps are multicellular organisms that feed on a variety of small organisms, from microscopic
plankton to small fish.
Polyps are usually a few millimeters in diameter, and are formed by a layer of outer
epithelium and inner jellylike tissue known as the
mesoglea. They are radially symmetrical with tentacles surrounding a central mouth, the only opening to the stomach or coelenteron, through which both food is ingested and waste expelled.
The stomach closes at the base of the polyp, where the epithelium produces an
exoskeleton called the basal plate or calicle (
L. small cup). This is formed by a thickened calciferous ring (annular thickening) with six supporting radial ridges (
as shown below). These structures grow vertically and project into the base of the polyp. When polyps are physically stressed, they contract into the calyx so that virtually no part is exposed above the skeletal platform. This protects the organism from predators and the elements (Barnes, R.D., 1987; Sumich, 1996).
The polyp grows by extension of vertical calices which are occasionally septated to form a new, higher, basal plate. Over many generations this extension forms the large calciferous (
Calcium containing) structures of corals and ultimately coral reefs.
Formation of the calciferous exoskeleton involves deposition of the mineral
aragonite by the polyps from
calcium ions they acquire from seawater. The rate of deposition, while varying greatly between species and environmental conditions, can be as much as 10 g / m² of polyp / day (0.3 ounce / sq yd / day). This is light dependent, with night-time production 90% lower than that during the middle of the day.
The polyp's tentacles trap prey using stinging cells called
nematocysts. These are cells modified to capture and immobilize prey, such as plankton, by injecting poisons, firing very rapidly in response to contact. These poisons are usually weak but in
fire corals they're potent enough to harm humans. Nematocysts can also be found in
jellyfish and
sea anemones. The toxins injected by nematocysts immobilize or kill prey, which can then be drawn into the polyp's stomach by the tentacles through a contractile band of epithelium called the
pharynx.
The polyps are interconnected by a complex and well developed system of
gastrovascular canals allowing significant sharing of nutrients and symbiotes. In soft corals these range in size from 50-500 μm in diameter and to allow transport of both metabolites and cellular components.
Aside from feeding on plankton, many corals as well as other
cnidarian groups such as
sea anemones (for example
Aiptasia), form a
symbiotic relationship with a class of
algae,
zooxanthellae, of the genus
Symbiodinium. The sea anemone
Aiptasia, while considered a pest among coral reef aquarium hobbyists, has served as a valuable model organism in the scientific study of cnidarian-algal
symbiosis. Typically a polyp will harbor one particular species of algae. Via photosynthesis, these provide energy for the coral, and aid in calcification.
The algae benefit from a safe environment, and use the carbon dioxide and nitrogenous waste produced by the polyp. Due to the strain the algae can put on the polyp, stress on the coral often triggers ejection of the algae, known on a large scale as
coral bleaching, as it's the algae
that contribute to the brown coloration of corals; other colors, however, are due to host coral pigments, such as GFPs (
green fluorescent protein). Ejecting the algae increases the polyps' chances of surviving stressful periods - they can regain the algae at a later time. If the stressful conditions persist, the polyps, and corals, will eventually die.
Reproduction
Corals maintain a variety of ways to propagate and settle new areas, the two main methods being by sexual and asexual means. Corals can be both
gonochoristic and
hermaphroditic, each of which can utilize sexual and asexual means of reproduction.
Sexual
Corals predominantly reproduce
sexually, with 25% of
hermatypic corals (stony corals) forming single sex (
gonochoristic) colonies, whilst the rest are
hermaphroditic. About 75% of all hermatypic corals "broadcast spawn" by releasing gametes - eggs and sperm - into the water to spread colonies over large distances. The gametes fuse during fertilisation to form a microscopic larvum called a
planula, typically pink and elliptical in shape; a moderately sized coral colony can form several thousands of these larvae per year to overcome the huge odds against formation of a new colony.
The planula swims towards light, exhibiting positive
phototaxis, to surface waters where they drift and grow for a time before swimming back down to locate a surface on which it can attach and establish a new colony. At many stages of this process there are high failure rates, and even though millions of gametes are released by each colony very few new colonies are formed. The time from spawning to settling is usually 2 or 3 days, but can be up to 2 months. The larva grows into a coral polyp and eventually becomes a coral head by asexual budding and growth, creating new polyps.
Corals that don't broadcast spawn are called brooders, with most non-stony corals displaying this characteristic. These corals release sperm but harbour the eggs, allowing larger, negatively buoyant, planulae to form which are later released ready to settle. In some places the coral spawn can be dramatic, usually occurring at night, where the usually clear water becomes cloudy with gametes.
Corals must rely on environmental cues, varying from species to species, to determine the proper time to release gametes into the water. There are two methods corals use for sexual reproduction which differ in whether the female gametes are released:
