Scolopidia

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Left: Frontal view of a small fruit fly antenna. The scolopidia in the second segment (a2, pedicel) with their neurons are illustrated. Sound energy absorption leads to vibration of the arista and rotation of the third segment a3. The rotation leads to deformation of the scolopidia, leading to activation or deactivation. Right: The antenna located on the head of the fruit fly.

A scolopidium (historically, scolopophore) is the fundamental unit of a mechanoreceptor organ in insects. It is a composition of three cells: a scolopale cap cell which caps the scolopale cell, and a bipolar sensory nerve cell.

The general term of these overall sense organs is the chordotonal organs, with the scolopidia usually lying just under the exoskeleton. Scolopidia may be located within:

There are many types of scolopidia, depending on the sense organ in which they belong.

Mechanosensation[]

Function[]

Scolopidia are sensitive to mechanical disturbances, such as sound (vibrations of the air) or substrate vibrations (vibrations of surrounding solid material), depending on the structure of the overall sense organ in which they reside. While many species using mechanoreceptors to transduce and locate sources of sound, functions such as detecting gravitational forces or airflow have also been demonstrated.[3] Airflow direction detection by mechanoreceptors appears to be key in the navigational behavior of flying insects, particularly in environments with slow or absent visual feedback.[4][5]

A single individual may possess scolopidia that are capable of sensing a range of low to high frequencies. This enables a single organ to serve multiple functions, ranging from gravity sensing to acoustic sensing.[3]

Physiology[]

Scolopidia ultimately convert mechanical vibration into a nerve impulse, which is sent on to higher ganglion where the information is combined and/or processed into a resultant behavior. Mechanosensory information received by scolopidia is typically transduced faster than visual feedback,[3] due to the physical mechanism of activating a neural impulse. Sensory neurons coupled to scolopidia are also of larger diameter, increasing conduction rate.[3]

In some moths, honeybees, and fruit flies, projections from scolopidia in Johnston's organs project directly to regions in the brain.

Types of scolopidia[]

Classification and nomenclature of cells is not always uniform.[6]

Scolopidia may be classified by their location:

  • subintegumental: distal end (cap end) is contained within the body wall of the insect
  • integumental: distal end is free, exterior to the insect

Classification may also be performed based on the ciliary processes of the cells:[7]

  • ciliary structures expand and constrict near the attachment cell
  • ciliary structures display consistent expansion throughout
  • one cilium expands distally, while the other two are unmodified

Scolopidia sensory cells may also be grouped by structure, location, and number of sensory cells (e.g. two, or three).[2]

Locations[]

Integumental scolopidia are found in the subgenual organ (also known as the supratympanal organ), subintegumental scolopidia are found in the crista acustica and the .

The subgenual organ ('organ below the knee') is found in all insects legs, and the probably an evolutionary artifact of prior insect body-types which used their legs to detect vibrations from the substrate (viz., treehoppers). The intermediate organ and the crista acustica, on the other hand, are only found where there is a tympanum, such as on the front legs of insects.

Number diversity[]

Swarming insects must detect the wing sounds of conspecifics in order to identify potential mates, and do so by using vibrations present in the air.[3] The antennal Johnston's organ in swarming Diptera (e.g. midges and mosquitos) may contain tens of thousands of scolopophorous sense cells, which are grouped by two's or three's into individual scolopidia.[2] The high number of scolopidia in Johnston's organ provides an evolutionary advantage in acoustically identifying and locating mates.

Non-swarming insects accordingly possess less scolopidia. Certain Hemiptera and Diptera may possess as few as 25 scolopidia.

See also[]

References[]

  1. ^ The Insects: An Outline of Entomology, P. J. Gullan, Peter Cranston.
  2. ^ Jump up to: a b c Saeng Boo, K., Richards, A.G. (29 July 1975). "Fine structure of the scolopidia in the Johnston's organ of male Aedes aegypti (L.) (Diptera: Culicidae)". Int. J. Insect Morphol. Embryol. 4 (6): 549–566. doi:10.1016/0020-7322(75)90031-8.CS1 maint: multiple names: authors list (link)
  3. ^ Jump up to: a b c d e Krishnan, Anand; Sane, Sanjay P. (2015-01-01), Jurenka, Russell (ed.), "Chapter Three - Antennal Mechanosensors and Their Evolutionary Antecedents", Advances in Insect Physiology, Academic Press, 49: 59–99, doi:10.1016/bs.aiip.2015.06.003
  4. ^ Budick; et al. (207). "The role of visual and mechanosensory cues in structuring forward flight in Drosophila melanogaster". J. Exp. Biol. 210 (Pt 23): 4092–4103. doi:10.1242/jeb.006502. PMID 18025010.
  5. ^ Sane; et al. (2007). "Antennal mechanosensors mediate flight control in moths". Science. 315 (5813): 863–866. Bibcode:2007Sci...315..863S. doi:10.1126/science.1133598. PMID 17290001.
  6. ^ Methods in insect sensory neuroscience, Thomas A. Christensen
  7. ^ J.S. Vande Berg (1971). "Fine structural studies of Johnston's organ in tobacco hornworm moth, Manduca sexta (Johansson)". J. Morphol. 133 (4): 439–455. doi:10.1002/jmor.1051330407. PMID 30366495.
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