Electron micrograph of antenna surface detail of a wasp (Vespula vulgaris)

Antennae (singular: antenna) in biology have historically been paired appendages used for sensing in arthropods and crustaceans. More recently, the term has also been applied to cilium structures present in many cell types of eukaryotes.

In arthropods, antennae are connected to the front-most segments. In crustaceans, they are biramous and present on the first two segments of the head, with the smaller pair known as antennules. All other arthropod groups, except chelicerates, proturans and arachnids which have none, have a single, uniramous pair of antennae. These antennae are jointed, at least at the base, and generally extend forward from the head. They are sensory organs, although the exact nature of what they sense and how they sense it is not the same in all groups, nor always clear. Functions may variously include sensing touch, air motion, heat, vibration (sound), and especially olfaction (smell) or gustation (taste).

[edit] Insects

Terms used to describe antennae shapes

Antennal shape in the Lepidoptera from C. T. Bingham (1905)

Antenna are the primary olfactory sensors of an insect and are accordingly well-equipped with a wide variety of sensilla (singular : sensillum). Paired, mobile, and segmented, they are located between the eyes on the forehead. Embryologically, they represent the appendages of the second head segment.^[1]

All insects have antenna though these may be greatly reduced in the larval forms. Amongst the non-insect classes of Hexapoda, Collembola and Diplura have antenna, but Protura do not.^[2]

[edit] Structure

The three basic segments of the typical insect antenna are the scape (base), the pedicel (stem), and finally the flagellum, which often comprises many units known as flagellomeres.

Muscles are only present in the two first segments, the scape and pedicel. The scape is surrounded by a membranous region of the head. It pivots on a single marginal point called the antennifer, allowing it to move in any direction.

The number of flagellomeres can vary greatly, and is often of diagnostic importance. True flagellomeres have a membranous articulation between them, but in many insects, especially the more primitive groups, the flagellum is entirely or partially composed of a flexible series of small annuli, which are not true flagellomeres.

In many beetles and in the chalcidoid wasps, the apical flagellomeres form a club, and the collective term for the segments between the club and the antennal base is the funicle; for traditional reasons, in beetles it is the segments between the club and the scape, but in wasps, it is the segments between the club and the pedicel.

In the groups with more uniform antennae (for example: Diplopoda), all segments are called antennomeres. Some groups have a simple or variously modified apical or subapical bristle called an arista (this may be especially well-developed in various Diptera).^{[citation needed]}

[edit] Functions

Olfactory receptors on the antennae bind to odour molecules, including pheromones. The neurons that possess these receptors signal this binding by sending action potentials down their axons to the antennal lobe in the brain. From there, neurons in the antennal lobes connect to mushroom bodies that identify the odour. The sum of the electrical potentials of the antenna to a given odor can be measured using an electroantennogram.^{[citation needed]}

In the case of the Monarch, it has been shown that antennae are necessary for proper time-compensated Sun compass orientation during migration, that antennal clocks exist in monarchs, and that they likely provide the primary timing mechanism for Sun compass orientation.^[3]

[edit] Crustaceans

Antennules of Caribbean hermit crab

Crustaceans bear two pairs of antennae. The first pair are uniramous and are often referred to as antennules, while the second pair are biramous, meaning that each antenna is composed of two parts, joined at their base ^[4]. In most adults, the antenna are sensory organs, but they are used by the nauplius larva for swimming. In some groups of crustaceans, such as the spiny lobsters and slipper lobsters, the second antennae are enlarged, while in others, such as crabs, the antennae are reduced in size.

A spiny lobster, showing the enlarged second antennae	The large flattened plates in front of the eyes of a slipper lobster are the modified second antennae	The crab Cancer pagurus, showing its reduced antennae

[edit] Cellular antennae

Within the biological and medical disciplines, recent discoveries have noted that primary cilia in many types of cells within eukaryotes serve as cellular antennae. These cilia play important roles in chemosensation, mechanosensation, and thermosensation. The current scientific understanding of primary cilia organelles views them as "sensory cellular antennae that coordinate a large number of cellular signaling pathways, sometimes coupling the signaling to ciliary motility or alternatively to cell division and differentiation."^[5]

[edit] Footnotes

1. ^ pg 38, Gullan,P.J. & Cranston,P.S. The insects: an outline of entomology (2005).
2. ^ Chapman, R.F. (1998). The Insects:Structure and Function.
3. ^ Merlin,C.; Gegear,R.J. & Reppert,S. M. (2009) Antennal Circadian Clocks Coordinate Sun Compass Orientation in Migratory Monarch Butterflies.
4. ^ "Superphylum Arthropoda". University of Arizona. http://www.geo.arizona.edu/geo3xx/geo308_fall2002/6arthropods.htm. 
5. ^ Satir,P. & Christensen,S.T. (2008) Structure and function of mammalian cilia. in Histochemistry and Cell Biology, Vol 129:6.

[edit] References

• Chapman, R.F. The Insects: Structure and Function, (4th ed). New York: Cambridge University Press, 1998. (paperback). ISBN 0-521-57890-6.
• Gullan,P.J. & Cranston,P.S. The insects: an outline of entomology (3/ed) (2005), Blackwell Publishing, Oxford, UK 2005, 505 pp., hard cover. ISBN 1-4051-1113-5.
• Merlin,Christine; Gegear,R.J. & Reppert, Steven M. Antennal Circadian Clocks Coordinate Sun Compass Orientation in Migratory Monarch Butterflies. (2009) 'Science' 25 September 2009: Vol. 325. no. 5948, pp. 1700 - 1704. DOI: 10.1126/science.1176221.

• Satir, Peter; Søren T. Christensen (2008-03-26). "Structure and function of mammalian cilia". Histochemistry and Cell Biology (Springer Berlin / Heidelberg) 129 (6): 687–693. doi:10.1007/s00418-008-0416-9. 1432-119X. http://www.springerlink.com/content/x5051hq648t3152q/. Retrieved 2009-09-11.