Adaptations
- Key People:
- René Jeannel
- Related Topics:
- water beetle
- Myxophaga
- Archostemata
- Colopterus truncatus
- Adephaga
Protection
Coleoptera protect themselves against enemies in various ways. Some closely resemble their surroundings; the upper surface of one African species (Petrognatha gigas), for example, resembles dead velvety moss, and its irregular antennae are very much like dried tendrils or twigs. Many weevils fall and feign death at the least alarm and, folding their limbs closely around the body, look like seeds or particles of soil, thus escaping observation.
Certain beetles, especially those living in ants’ nests, resemble ants, and the common wasp beetle of Europe (Clytus arietis) closely resembles a wasp in both its movements and coloration.
Some beetles obtain some measure of protection possibly from their repellent appearance or from their foul-smelling or distasteful secretions, either in the form of exudations of blood from definite parts of the body or as the product of special fetid glands. The so-called bombardier beetles of the Carabidae have the property of secreting a foul-smelling defensive fluid from the anal end of the body. In some cases this fluid volatilizes explosively into a gas at high temperature when it comes into contact with the air; it acts as a repellent to other insects or enemies. A number of beetles secure protection by virtue of their agility; many ground beetles and tiger beetles run rapidly, and the latter also readily take flight. The flea beetles (a group of the Chrysomelidae) have remarkable powers of leaping.
Sound production
Many beetles produce sound, usually by rubbing one part of the body (a scraper) against another part (the file). These stridulating organs are generally present in both sexes and probably serve for mutual sex calling. Some beetles have a filelike area on the head that is rasped by the front margin of the prothorax. Among the cerambycids, sound is produced either by rubbing the rear margin of the prothorax over a grooved area on the mesothorax or by rubbing the femurs of the hind legs against the margins of the elytra.
Stridulation, however, is not confined to adult beetles; it occurs also in certain larvae. Some larvae of the Scarabaeoidea, for example, have a series of ridges, or tubercles, on the coxal segment of the middle pair of legs, and the hind legs are modified in various ways as rasping organs. In the larvae of some chafers (Melolonthinae), a ridged area on the mandible is rasped by a series of teeth on the maxillae. Stridulation in larvae is independent of sex and may be used to warn neighbouring larvae to avoid getting in each other’s way.
Light production
Some beetles emit a bright light, whose source is in special luminous organs that consist of an outer light-producing layer and an inner reflector layer. The outer layer is supplied with oxygen by means of air tubes (tracheae), and the reflector layer contains crystals that apparently act as a background, scattering the light and preventing its dispersion internally. The light is produced during a reaction involving a compound (luciferin) and an enzymelike substance (luciferase) in the outer layer of the luminous organ. Luminous beetles include the Lampyridae (fireflies), Phengodidae, Drilidae, and certain Elateridae (click beetles). A familiar example of a firefly is the common European glowworm (Lampyris noctiluca), whose wingless female emits a bright light near the hind end of the body; the winged male emits a much feebler light. Both sexes of the elaterid genera Pyrophorus and Photophorus are winged and luminous.
Evolution and paleontology
Coleopterans are very ancient insects; they date from the Permian Period (about 225 million–280 million years ago), after the appearance of gymnosperm plants. Although the beetles have a number of similarities to another ancient group of insects, the cockroaches (Blattaria), they probably evolved from ancestors of the present-day Neuroptera. This theory is based largely on the nature of the life cycle of beetles and on their larval structure. Although many beetle fossils are known, they consist mostly of isolated elytra, which reveal little about the history of the order. Complete fossil specimens are closely related to living forms. The evolution of elytra may have been associated with the habit of living under the bark of trees, where protection for flying wings is required. Most of the insects that live under bark are beetles.
Classification
Distinguishing taxonomic features
One distinctive feature of coleopterans is wing structure. Most beetles have two pairs of wings. The front pair, which may be thickened, leathery, or hard and brittle, are called elytra and usually serve only as protective covers. A few beetles have greatly reduced wings. Variations in the structure of the first abdominal segment is one criterion used to separate the various suborders of Coleoptera; the hind coxal leg segments (by which the legs are attached to the body) may divide the abdominal segment partially or completely. Sometimes the abdominal segments are fused, the articulations marked by form sutures.
Variation in length, texture, and appearance of elytra, as well as the number of abdominal segments exposed by short elytra, are used to distinguish the various superfamilies. Characters associated with the size and shape of the coxae also are used as distinguishing features. Structure of antennae and legs are important considerations for taxonomic criteria, as are larval structure, head structure (including mandibles, or jaws), pattern of veins in wings, habitats, and behaviour.