Subgenual organ

Last updated
Neuroanatomy of the subgenual organ, a sensory organ in Troglophilus neglectus. SGO is the Subgenual organ, pIO is the proximal intermediary organ and dIO is the distal intermediary organ Troglophilus neglectus-Subgenual organ and nerves.jpg
Neuroanatomy of the subgenual organ, a sensory organ in Troglophilus neglectus. SGO is the Subgenual organ, pIO is the proximal intermediary organ and dIO is the distal intermediary organ

The subgenual organ is an organ in insects that is involved in the perception of sound. The name (Latin sub: "below" and genus: "knee") refers to the location of the organ just below the knee in the tibia of all legs in most insects.

Contents

The function of the organ is performed by aggregations of scolopidia, the unit mechanoreceptor in invertebrates. The organ is thought to be an evolutionary artifact of ancestral insects who used their legs to detect vibrations in the underlying substrate.[ citation needed ]

The anatomy and innervation of the organ is highly variable between species. However, the organ may be sensitive enough to detect less than 1 nm of displacement in the ground, and sometimes airborne sound waves. [1] [2] [3] [4] The sensitivity of the organ varies from species to species; in Orthoptera, Hymenoptera and Lepidoptera, sensitivity is on the order of one (or greater) kilohertz, while in Hemiptera sensitivity reaches only a few hundred hertz. [5]

Characteristics within orders

Development

Teleogryllus commodus

Each larval stage forms one scolopidium that contributes to the organogenesis. All scolopidia are formed by the third larval stage and the organ has already its final shape by the time of egg hatching. [7] A bilobar structure in the locust embry forms the precursor of the subgenual organ. [8] Axon growth from the subgenual organ in grasshoppers is contingent on semaphorin I. [9]

Ephippiger ephippiger

In the bushcricket, all scolopidia (22-24 in total) are already present in the first larval stage. In the latter, the organ increases in size proportionally to the growth of the limb containing it and has the shape of a fan. [10]

Anatomy in specific species

Honeybees

In the honeybee Apis mellifera , the sensing by the subgenual organ is directed by the inertia of the haemolymph; it causes a differential movement of the organ swimming in the haemolymph with respect to the rest of the limb. More than 39 scolopidia, sensory cells, are involved in sensing the movement of the haemolymph between the cuticle and two tracheae. The functionality is similar to the vestibular system of vertebrates. [11] The bee organ is cone shaped branching out from its nerve and almost obstructs haemolymph flow through the limb. [12]

Carpenter ants

In the carpenter ant Camponotus ligniperda, the subgenual organ has the form of a deformed sphere.[ citation needed ] On one end attachment cells connect it to the cuticle; on the other it is innervated by the tibial nerve. The organ has the shape of a cavity surrounded with a monocellular membrane that is heavily folded on the inside. Sensilla extend into the cavity, each containing one neuron with associated dendrites, cilia and glial cells within a lymphatic cavity that is connected to the cavity of the subgenual organ. [13]

Termites

In the termite Zootermopsis angusticollis and the cockroach Periplaneta americana , the vibration is perceived after about 10-20 milliseconds and stops being perceived after one or two seconds. There are two types of cells with different spatial orientation in the organ; possibly, oscillation causes the cells to shift with respect to each other and generate a signal. [14] Some early research claimed that the sensitivity of the Periplaneta subgenual organ might be far higher than the threshold of about one atom diameter determined for cochlear cells; newer investigation indicated that such a sensitivity may have been the result of artifacts, with the actual sensitivity being comparable to the cochlea. [15]

Cockroaches

In cockroaches Blaberus discoidalis and Blattella germanica , the organ has the shape of a fan that is placed across the limb. Much of its volume is filled with discoidal cells that serve accessory purposes; they are placed between an epidermal cell layer attached to the cuticle and connective tissue. Sensory structures called chordotonal sensilla are involved in the perception of movement proper and contain a neuron per sensillum, about 40–50 in total. This neuron has a single dendrite and several cilia extend from it. [16]

Green lacewing

In Chrysoperla carnea , the green lacewing, the organ is involved in sexual behaviour and interindividual or even interspecies communication. A velum spans the interior of each leg and is formed by cap cells. Three scolopidia stretch from the velum to the leg wall, each containing one sensory neuron with a dendrite and attached cilia. The dendrite is accompaigned by a so-called scolopale cell which generates an electron-rich intracellular structure surrounding the dendrite. [17]

Crickets

In the cave cricket Troglophilus neglectus the subgenual organ is fairly simple and is associated with an intermediary organ . Both are innervated either by one or two nerves, depending on the individual animal. [3]

In the splay-footed cricket Comicus calcaris , the subgenual organ is associated with a crista acustica homolog and an intermediary organ. This organ system is not suitable for hearing sounds, but it is possible that this organ system formed through reduction of a previously existing hearing organ. All three organs are innervated by the same nerve and the subgenual organ of this genus has the largest number of nerve cells of all Ensifera without tympana. [18]

In the heelwalker Karoophasma biedouwense , the subgenual organ is associated with four additional organs containing scolopidia, a trait shared with Mantophasmatodea. Between 15 and 30 scolopidial cells make up the subgenual organ, more in the hind limbs. They form a fan-like structure branching out from the anterior side of the limb. Campaniform sensilla are also associated with the organ. There are no sex differences in the SG organ. All five organs have less sensitivity for high frequencies and appear to be used for male specimens at identifying female animals. [19]

In the cricket Gryllus assimilis the sub genual organ fills up most of the tibia and has a fan-like shape. It is connected to two different neuronal ganglia, one with three bipolar neurons and the other with tens of neurons that also supplies other insect sensory organs located in the leg. Most of the subgenual organ is innervated by this major ganglion, except for the more proximal part. There is also an intermediary organ and a tympanal organ. [20]

Stinkbugs

In the stinkbug Nezara viridula the organ contains only two scolopidia. The organ is appended to the forward side of the tibia and hangs into the tibial blood cavity. Two cap cells give it a fan-like shape. Analysis of the neuronal response to vibration indicates that the organ undergoes resonance after stimulation, only slowly dampening. The sensitivity is correlated to the insect's own sounds. [21]

Stick insects

In the stick insects Carausius morosus and Siyploidea sipylus , a highly developed distal organ is present in addition to the subgenual organ, but it contains less scolopidia than the subgenual organ. The organ itself has a semicircular shape inside the limb and is supplied by three different nerves, one of which also targets the distal organ. In both species, there are more than 40 scolopidia in the subgenual organ. [22]

Related Research Articles

<span class="mw-page-title-main">Nervous system</span> Part of an animal that coordinates actions and senses

In biology, the nervous system is the highly complex part of an animal that coordinates its actions and sensory information by transmitting signals to and from different parts of its body. The nervous system detects environmental changes that impact the body, then works in tandem with the endocrine system to respond to such events. Nervous tissue first arose in wormlike organisms about 550 to 600 million years ago. In vertebrates, it consists of two main parts, the central nervous system (CNS) and the peripheral nervous system (PNS). The CNS consists of the brain and spinal cord. The PNS consists mainly of nerves, which are enclosed bundles of the long fibers, or axons, that connect the CNS to every other part of the body. Nerves that transmit signals from the brain are called motor nerves (efferent), while those nerves that transmit information from the body to the CNS are called sensory nerves (afferent). The PNS is divided into two separate subsystems, the somatic and autonomic, nervous systems. The autonomic nervous system is further subdivided into the sympathetic, parasympathetic and enteric nervous systems. The sympathetic nervous system is activated in cases of emergencies to mobilize energy, while the parasympathetic nervous system is activated when organisms are in a relaxed state. The enteric nervous system functions to control the gastrointestinal system. Nerves that exit from the brain are called cranial nerves while those exiting from the spinal cord are called spinal nerves.

<span class="mw-page-title-main">Motor neuron</span> Nerve cell sending impulse to muscle

A motor neuron is a neuron whose cell body is located in the motor cortex, brainstem or the spinal cord, and whose axon (fiber) projects to the spinal cord or outside of the spinal cord to directly or indirectly control effector organs, mainly muscles and glands. There are two types of motor neuron – upper motor neurons and lower motor neurons. Axons from upper motor neurons synapse onto interneurons in the spinal cord and occasionally directly onto lower motor neurons. The axons from the lower motor neurons are efferent nerve fibers that carry signals from the spinal cord to the effectors. Types of lower motor neurons are alpha motor neurons, beta motor neurons, and gamma motor neurons.

<span class="mw-page-title-main">Olfactory bulb</span> Neural structure

The olfactory bulb is a neural structure of the vertebrate forebrain involved in olfaction, the sense of smell. It sends olfactory information to be further processed in the amygdala, the orbitofrontal cortex (OFC) and the hippocampus where it plays a role in emotion, memory and learning. The bulb is divided into two distinct structures: the main olfactory bulb and the accessory olfactory bulb. The main olfactory bulb connects to the amygdala via the piriform cortex of the primary olfactory cortex and directly projects from the main olfactory bulb to specific amygdala areas. The accessory olfactory bulb resides on the dorsal-posterior region of the main olfactory bulb and forms a parallel pathway. Destruction of the olfactory bulb results in ipsilateral anosmia, while irritative lesions of the uncus can result in olfactory and gustatory hallucinations.

A mechanoreceptor, also called mechanoceptor, is a sensory receptor that responds to mechanical pressure or distortion. Mechanoreceptors are innervated by sensory neurons that convert mechanical pressure into electrical signals that, in animals, are sent to the central nervous system.

<span class="mw-page-title-main">Dorsal column–medial lemniscus pathway</span> Sensory spinal pathway

The dorsal column–medial lemniscus pathway (DCML) is a sensory pathway of the central nervous system that conveys sensations of fine touch, vibration, two-point discrimination, and proprioception from the skin and joints. It transmits information from the body to the primary somatosensory cortex in the postcentral gyrus of the parietal lobe of the brain. The pathway receives information from sensory receptors throughout the body, and carries this in nerve tracts in the white matter of the dorsal column of the spinal cord to the medulla, where it is continued in the medial lemniscus, on to the thalamus and relayed from there through the internal capsule and transmitted to the somatosensory cortex. The name dorsal-column medial lemniscus comes from the two structures that carry the sensory information: the dorsal columns of the spinal cord, and the medial lemniscus in the brainstem.

<span class="mw-page-title-main">Range fractionation</span>

Range fractionation is a term used in biology to describe the way by which a group of sensory neurons are able to encode varying magnitudes of a stimulus. Sense organs are usually composed of many sensory receptors measuring the same property. These sensory receptors show a limited degree of precision due to an upper limit in firing rate. If the receptors are endowed with distinct transfer functions in such a way that the points of highest sensitivity are scattered along the axis of the quality being measured, the precision of the sense organ as a whole can be increased.

<span class="mw-page-title-main">Dog anatomy</span> Studies of the visible part of a canine

Dog anatomy comprises the anatomical study of the visible parts of the body of a domestic dog. Details of structures vary tremendously from breed to breed, more than in any other animal species, wild or domesticated, as dogs are highly variable in height and weight. The smallest known adult dog was a Yorkshire Terrier that stood only 6.3 cm (2.5 in) at the shoulder, 9.5 cm (3.7 in) in length along the head and body, and weighed only 113 grams (4.0 oz). The heaviest dog was an English Mastiff named Zorba, which weighed 314 pounds (142 kg). The tallest known adult dog is a Great Dane that stands 106.7 cm (42.0 in) at the shoulder.

<span class="mw-page-title-main">Campaniform sensilla</span> Class of mechanoreceptors found in insects

Campaniform sensilla are a class of mechanoreceptors found in insects, which respond to local stress and strain within the animal's cuticle. Campaniform sensilla function as proprioceptors that detect mechanical load as resistance to muscle contraction, similar to mammalian Golgi tendon organs. Sensory feedback from campaniform sensilla is integrated in the control of posture and locomotion.

The arthropod leg is a form of jointed appendage of arthropods, usually used for walking. Many of the terms used for arthropod leg segments are of Latin origin, and may be confused with terms for bones: coxa, trochanter, femur, tibia, tarsus, ischium, metatarsus, carpus, dactylus, patella.

<span class="mw-page-title-main">Death's head cockroach</span> Species of cockroach

The death's head cockroach is a species of cockroach belonging to the family Blaberidae. It is often confused with the discoid cockroach, Blaberus discoidalis, due to its similar appearance. It is distinguished by jet black cloak-like marking on its wings and a skull-shaped, amber/black marking on its pronotum. The name death's head comes from the markings on the top of the pronotum: "cranii", which is Latin for "of the head", and "fer", meaning "carry" or "carrier". Due to their unique appearance and certain characteristics, they make an easy to care for pet or display insect for entomologists and hobbyists.

Chordotonal organs are stretch receptor organs found only in insects and crustaceans. They are located at most joints and are made up of clusters of scolopidia that either directly or indirectly connect two joints and sense their movements relative to one another. They can have both extero- and proprioceptive functions, for example sensing auditory stimuli or leg movement. The word was coined by Vitus Graber in 1882, though he interpreted them as being stretched between two points like a string, sensing vibrations through resonance.

Insect physiology includes the physiology and biochemistry of insect organ systems.

<span class="mw-page-title-main">Sense of smell</span> Sense that detects smells

The sense of smell, or olfaction, is the special sense through which smells are perceived. The sense of smell has many functions, including detecting desirable foods, hazards, and pheromones, and plays a role in taste.

A sense is a biological system used by an organism for sensation, the process of gathering information about the surroundings through the detection of stimuli. Although, in some cultures, five human senses were traditionally identified as such, many more are now recognized. Senses used by non-human organisms are even greater in variety and number. During sensation, sense organs collect various stimuli for transduction, meaning transformation into a form that can be understood by the brain. Sensation and perception are fundamental to nearly every aspect of an organism's cognition, behavior and thought.

<span class="mw-page-title-main">Insect morphology</span> Description of the physical form of insects

Insect morphology is the study and description of the physical form of insects. The terminology used to describe insects is similar to that used for other arthropods due to their shared evolutionary history. Three physical features separate insects from other arthropods: they have a body divided into three regions, three pairs of legs, and mouthparts located outside of the head capsule. This position of the mouthparts divides them from their closest relatives, the non-insect hexapods, which include Protura, Diplura, and Collembola.

<span class="mw-page-title-main">Scolopidia</span>

A scolopidium 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.

Crista acustica is a part of the hearing organ in some insects. It is a collection of sensory cells that form a crest on top of the hollow tube behind the hearing membrane (tympanum) on the legs of the insect.

Hair plates are a type of proprioceptor found in the folds of insect joints. They consist of a cluster of hairs, in which each hair is innervated by a single mechanosensory neuron. Functionally, hair plates operate as "limit-detectors" by signaling the extremes of joint movement, which then drives reflexive leg movement.

<span class="mw-page-title-main">Femoral chordotonal organ</span> Sensory organ in insect legs

The femoral chordotonal organ is a group of mechanosensory neurons found in an insect leg that detects the movements and the position of the femur/tibia joint. It is thought to function as a proprioceptor that is critical for precise control of leg position by sending the information regarding the femur/tibia joint to the motor circuits in the ventral nerve cord and the brain

References

  1. Virant-Doberlet, Meta; Cokl, Andrej (2004). "Vibrational communication in insects". Neotropical Entomology. 33 (2): 121–134. doi: 10.1590/S1519-566X2004000200001 . ISSN   1519-566X.
  2. R. F. Chapman; Stephen J. Simpson; Angela E. Douglas (January 2013). The Insects: Structure and Function. Cambridge University Press. p. 752. ISBN   978-0-521-11389-2.
  3. 1 2 3 Strauss, J.; Stritih, N.; Lakes-Harlan, R. (2014). "The subgenual organ complex in the cave cricket Troglophilus neglectus (Orthoptera: Rhaphidophoridae): comparative innervation and sensory evolution". Royal Society Open Science. 1 (2): 140240. Bibcode:2014RSOS....140240S. doi:10.1098/rsos.140240. ISSN   2054-5703. PMC   4448885 .
  4. John L. Capinera (11 August 2008). Encyclopedia of Entomology. Springer Science & Business Media. p. 864. ISBN   978-1-4020-6242-1.
  5. 1 2 Autrum, Hansjochem; Schneider, Wilfriede (1948). "Vergleichende Untersuchungen über den Erschütterungssinn der Insekten". Zeitschrift für vergleichende Physiologie. 31 (1): 77–88. doi:10.1007/BF00333879. ISSN   0340-7594.
  6. Broad, G. R.; Quicke, D. L. J. (2000). "The adaptive significance of host location by vibrational sounding in parasitoid wasps". Proceedings of the Royal Society B: Biological Sciences. 267 (1460): 2403–2409. doi:10.1098/rspb.2000.1298. ISSN   0962-8452. PMC   1690826 . PMID   11133030.
  7. Ball, Eldon; Young, David (1974). "Structure and development of the auditory system in the prothoracic leg of the cricket Teleogryllus commodus (walker)". Zeitschrift für Zellforschung und mikroskopische Anatomie. 147 (3): 313–324. doi:10.1007/BF00307467. ISSN   0302-766X.
  8. Kutsch, Wolfram (1989). "Formation of the receptor system in the hind limb of the locust embryo". Roux's Archives of Developmental Biology. 198 (1): 39–47. doi:10.1007/BF00376369. ISSN   0930-035X.
  9. J. T. Wong, W. T. Yu & T. P. O'Connor (September 1997). "Transmembrane grasshopper Semaphorin I promotes axon outgrowth in vivo". Development . 124 (18): 3597–3607. doi:10.1242/dev.124.18.3597. PMID   9342052.
  10. Rössler, Wolfgang (1992). "Postembryonic development of the complex tibial organ in the foreleg of the bushcricket Ephippiger ephippiger (Orthoptera, Tettigoniidae)". Cell and Tissue Research. 269 (3): 505–514. doi:10.1007/BF00353905. ISSN   0302-766X.
  11. Kilpinen, O.; Storm, J. (1997). "Biophysics of the subgenual organ of the honeybee, Apis mellifera". Journal of Comparative Physiology A. 181 (4): 309–318. doi:10.1007/s003590050117. ISSN   0340-7594.
  12. Storm, Jesper; Kilpinen, Ole (1998). "Modelling the subgenual organ of the honeybee, Apis mellifera". Biological Cybernetics. 78 (3): 175–182. doi:10.1007/s004220050424. ISSN   0340-1200.
  13. Menzel, Johannes G.; Tautz, Jürgen (1994). "Functional morphology of the subgenual organ of the carpenter ant". Tissue and Cell. 26 (5): 735–746. doi:10.1016/0040-8166(94)90056-6. ISSN   0040-8166. PMID   18621288.
  14. Howse, P.E. (1964). "An investigation into the mode of action of the subgenual organ in the termite, Zootermopsis angusticollis Emerson, and in the cockroach, Periplaneta americana L.". Journal of Insect Physiology. 10 (3): 409–424. Bibcode:1964JInsP..10..409H. doi:10.1016/0022-1910(64)90065-4. ISSN   0022-1910.
  15. Shaw, Stephen R. (1994). "Re-evaluation of the absolute threshold and response mode of the most sensitive know ?vibration? detector, the cockroach's subgenual organ: A cochlea-like displacement threshold and a direct response to sound". Journal of Neurobiology. 25 (9): 1167–1185. doi:10.1002/neu.480250911. ISSN   0022-3034. PMID   7815071.
  16. Moran, David T.; Carter Rowley, J. (1975). "The fine structure of the cockroach subgenual organ". Tissue and Cell. 7 (1): 91–105. doi:10.1016/S0040-8166(75)80009-7. ISSN   0040-8166. PMID   1118860.
  17. Devetak, Dušan; Pabst, Maria Anna (1994). "Structure of the subgenual organ in the green lacewing, Chrysoperla carnea". Tissue and Cell. 26 (2): 249–257. doi:10.1016/0040-8166(94)90100-7. ISSN   0040-8166. PMID   18621270.
  18. Strauß, Johannes; Lakes-Harlan, Reinhard (2010). "Neuroanatomy of the complex tibial organ in the splay-footed cricket Comicus calcaris Irish 1986 (Orthoptera: Ensifera: Schizodactylidae)". The Journal of Comparative Neurology. 518 (22): 4567–4580. doi:10.1002/cne.22478. ISSN   0021-9967. PMID   20886622.
  19. Eberhard, M.J.B.; Lang, D.; Metscher, B.; Pass, G.; Picker, M.D.; Wolf, H. (2010). "Structure and sensory physiology of the leg scolopidial organs in Mantophasmatodea and their role in vibrational communication". Arthropod Structure & Development. 39 (4): 230–241. Bibcode:2010ArtSD..39..230E. doi:10.1016/j.asd.2010.02.002. ISSN   1467-8039.
  20. Friedman, Morton H. (1972). "A light and electron microscopic study of sensory organs and associated structures in the foreleg tibia of the cricket, Gryllus assimilis". Journal of Morphology. 138 (3): 263–327. doi:10.1002/jmor.1051380302. ISSN   0362-2525. PMID   4636814.
  21. Čokl, Andrej (1983). "Functional properties of viboreceptors in the legs of Nezara viridula (L.) (Heteroptera, Pentatomidae)". Journal of Comparative Physiology A. 150 (2): 261–269. doi:10.1007/BF00606376. ISSN   0340-7594.
  22. Strauß, Johannes; Lakes-Harlan, Reinhard (2013). "Sensory neuroanatomy of stick insects highlights the evolutionary diversity of the orthopteroid subgenual organ complex". Journal of Comparative Neurology. 521 (16): 3791–3803. doi:10.1002/cne.23378. ISSN   0021-9967. PMID   23749306.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.