Predators that appear
UNLIKE many predators who use stealth, speed and camouflage to catch prey there are some who pretend to be innocuous, nonchalant or doing something that will not harm the prey, but once the prey comes into striking range, the predator springs a surprise attack at the last minute. Sea-anemones that attach themselves firmly to the substrata by sucker-like base and can not move around freely are highly active predators.
Contrary to popular belief, these soft-bodied coelenterates (aquatic invertebrates having simple tube-shaped or cup-shaped body with a double skin) are neither blind nor deaf. They are quite aware of the world around them. They can hear and smell their prey approaching and are always ready to strike. While they appear totally at rest, they tune into a high frequency — about 55Hz or 55 cycles per second.
The hair-like cilia which detect
vibrations in the water are relatively short and might pick up fish movements or
something similar. If, however, a favourite species of shrimp approaches,
chemoreceptors detect the smell of the prey ( in fact, the chitin-like sugars of
the shrimp’s shell) and the vibration detectors lengthen. This enables them to
pick up vibrations at 5Hz, the frequency of the swimming movements of the
shrimp. In this way, the sea-anemone is alert at the moment it is brushed by the
shrimp, and it can act immediately and immobilise the shrimp before it has time
Sea anemones that festoon the coral reefs of the world carry millions of tiny stinging-cells that are capable of immobilising ordinary fish, which are then drawn into the anemone’s mouth and devoured. But there is a group of about 30 species of small reef fish, all of which are immune to the poison in the sea anemone’s tentacles.
Known as anemone fish, damsel fish, or clown fish, these brightly marked reef-dwellers spend most of their lives lolling in the lethal tentacles of their poisonous partners. Their secret defence is a thick layer of special mucus that completely covers their bodies. It possesses a chemical quality that stops the anemone’s poison-cells from firing when they are touched by the fish. The chemical involved is still unknown and the precise way it operates remains to be explained, but it somehow manages to deceive the anemone into thinking the fish is not food.
Some investigators believe that the fish’s trick is to transfer part of the anemone’s mucus covering to it own body mucus. The anemone’s many tentacles are constantly rubbing against one another, and must have some kind of sting-inhibitor covering them or the animal would keep stinging itself. If the fish thoroughly impregnates its own mucus shield with this inhibitor, it will give the impression that its body is part of the anemone and it will be completely safe. This is indeed what seems to happen. A special characteristic of these particular fish must be the possession of a body-surface mucus that will ‘marry’ with the tentacle mucus. Other fish lack this property, the mucus marriage never takes place, and they are stung to death.
The immunity of anemone fish may have a genetic
basis but it requires considerable acclimatisation to function properly.