coloration Camouflagebiology

Background matching is probably the most common form of concealment. It makes little difference whether the background model is an animate or inanimate object since both involve the initial establishment and continued maintenance of the concealment. Not only coloration but also the form and the activities or behaviour of the organism in relation to its model are important.

The simplest examples of background matching are provided by the fish eggs and planktonic (free-floating) larval fishes that exist in the uniformly blue environment of the open sea—i.e., those that are pelagic. They usually possess minimal pigmentation and are transparent.

In other organisms and environments the behaviour and form of the organism become more important as adjuncts to coloration. Evidence of the importance of the choice of a proper background is provided by three differently coloured species of lizards of the genus Anolis, which form mixed hunting groups over the same background. Many of the individuals are easily perceived on this background, but, when disturbed, they conceal themselves by segregating according to species over the appropriately coloured backgrounds. Camouflage may also be accomplished through a change in coloration. Many flatfishes, for example, show a remarkable ability to match the pattern of the surface on which they are resting. Some nudibranchs, a group of marine gastropods, such as Phestilla melanobrachia, manage to establish and maintain their resemblance to the background by ingesting portions of their model, which is the living coral on which they live. The pigments in the coral polyps are deposited in diverticula (branches) of the gut and occasionally in the epidermis and show through as nearly perfect camouflage. The slow-moving nudibranchs are very difficult to see on their coral host, and when they move to differently coloured coral, their coloration changes as their food source changes.

Some of the parasites that live on marine fishes conceal themselves in a similar manner. Flukes, or monogenean trematodes, gorge themselves on their hosts’ tissues and biochromes and appear to remain within areas on the host that have similar pigmentation. The adaptive significance of the coloration is known to lie in escape from predation by the third party, cleaning organisms such as the fish Labroides, which feeds on the external parasites of other fishes. Several decorator crabs use portions of the model for concealment by picking up algae and sponges and placing them on the carapace (upper shell) to cover their own coloration; the algae and sponges continue to live as if in their normal habitat.

Disruptive patterns, frequently a part of camouflage coloration, serve the function of visual disruption by forming a pattern that does not coincide with the contour and outline of the body (see photograph). The blenny Hypsoblennius sordidus, for example, usually has a mottled coloration that crudely matches its background in terms of the size and colour of differently pigmented areas; it also has a series of darkly pigmented “saddles” that break up the outline contour of its back. This species also demonstrates the fact that the type of disruptive patterning may change when an individual shifts to another type of background. The saddled condition is found when the background is composed of disruptive elements of the same approximate size—e.g., small sponges, barnacles, and patches of algae. But when the fish moves to an evenly coloured area, its coloration becomes stripes that run horizontally from head to tail.

Disruptive patterns are found in the coloration of many fish that form schools over the reef during daylight hours for protection against predation. When a predator approaches, the fishes form dense schools in which all of the individuals orient in the same direction. The movement of many individuals, coupled with their similar disruptive coloration, presents an extremely confusing spectacle, presumably one that makes it difficult for a predator to fix upon and attack any one.

Some forms of disruptive coloration also function to conceal movement. Forward movement in concentrically banded snakes, for example, is difficult to perceive when the animal moves between reeds or long blades of grass.

Another clue can lead to the recognition of an organism: its three-dimensional form, which causes the unilluminated portion of the body to be in shadow. Countershading is a form of coloration in which the upper surfaces of the body are more darkly pigmented than the unilluminated lower areas, giving the body a more uniform darkness and a lack of depth relief. Widespread among vertebrates, countershading is frequently superimposed over camouflage and disruptive colorations.

The light-producing organs, or photophores, of many deepwater fishes provide a unique form of countershading. Photophores occur in bands along the lower parts of the sides and are directed downward. Deepwater fishes live in the twilight zone of the sea, in which the illumination is too weak to allow little more than a silhouette of prospective prey sighted by a predator from below. The downward-projecting photophores may provide countershading by obliterating the silhouette when it is viewed by a predator from below.

The shape of an organism is important in determining the total configuration for protection. Both concealment and mimicry may depend strongly on imitation of both the shape and coloration of the model. Deep-bodied schooling fishes frequently show vertical banding, and elongated forms usually bear horizontal stripes. This dichotomy may be partially related to different swimming patterns: deep-bodied fishes perform frequent lateral turns; elongated forms show frequent horizontal movement and change of position.