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Ampullae of Lorenzini

From Wikipedia, the free encyclopedia

Ampullae of Lorenzini, found in several basal groups of fishes, are jelly-filled canals connecting pores in the skin to sensory bulbs. They detect small differences in electric potential between their two ends.

Ampullae of Lorenzini (SG: ampulla) are electroreceptors, sense organs able to detect electric fields. They form a network of mucus-filled pores in the skin of cartilaginous fish (sharks, rays, and chimaeras) and of basal bony fishes such as reedfish,[1] sturgeon,[2] and lungfish.[1] They are associated with and evolved from the mechanosensory lateral line organs of early vertebrates. Most bony fishes and terrestrial vertebrates have lost their ampullae of Lorenzini.

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  • How Do Sharks and Rays Use Electricity to Find Hidden Prey? | Deep Look
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  • INTERVIEW EXTRA: Ampullae of Lorenzini
  • “Biomimicry”- sharks sixth Sense - The Ampullae of Lorenzini/electroreceptors !!

Transcription

We live in a world full of electric fields. Animals, plants -- even the earth itself -- creates them. But only a handful of creatures can actually sense them. Sharks -- also rays and skates... a whole group, animals called elasmobranchs -- can actually detect electricity Maybe it's like feeling the presence of someone hiding in a dark room. A different way of experiencing their world - an extra sense that we don't have. And for sharks and rays? an extra edge for finding their prey. The discovery of this exceptional sense dates back three hundred years -- long before the discovery of electricity -- to a man named Stefano Lorenzini. Lorenzini was a doctor with a passion for anatomy, who one day found himself dissecting a ray. ...which is where he noticed the strangest thing: tiny pores that dotted the ray’s skin. He drew a picture. It shows how each pore led to a tube full of goo, and each tube ended in a little pouch. Those little round pouches reminded him of ancient roman flasks, called ampullae, so that’s what he called them. But when it came to the function of those ampullae, Lorenzini was stumped. Three hundred years later, we’re still figuring out exactly how electroreception works... and a big part of that is studying what makes these electrical fields in the first place. Every time a fish opens its mouth to breathe it exposes its mucus membranes to the salty water, creating a tiny voltage that disappears every time the mouth closes. At Florida Atlantic University, scientists are actually able to measure this phenomenon. That repeating on off pattern is an electric frequency, carried easily through salt water. 2 hertz. 2 breaths a second. Stingrays like these can tune in to that same frequency, like a radio channel. Take a close look at a stingray, and you can see those pores. They lead to long canals, that cluster together. When an electric charge enters a pore, it travels through the highly conductive gel in the canal to the ampulla... where special cells detect the current and send a message along nerves to the brain. That’s how stingrays can spot prey hidden beneath them, even though their eyes are on top of their heads. But the ampullae aren’t just for hunting. Pores on the ray’s back also let it know if someone’s trying to sneak up on it from behind. Here, the researchers place diodes on the floor of a tank-- replicating the same electric frequency as a breathing fish. They flip the current from circle to circle, and the ray strikes at the active target. Maybe by studying how this sense works we can learn better ways to coexist with these ancient creatures. Find new ways to keep them out of our nets and away from our surfers. Of course none of this really explains what it’s like to feel electricity. Is it as simple as flipping a switch on and off? or as varied and subtle as smell or taste? A whole spectrum of experiences hidden to the rest of us.

History

Ampullae were initially described by Marcello Malpighi and later given an exact description by the Italian physician and ichthyologist Stefano Lorenzini in 1679, though their function was unknown.[3] Electrophysiological experiments in the 20th century suggested a sensibility to temperature, mechanical pressure, and possibly salinity. In 1960 the ampullae were identified as specialized receptor organs for sensing electric fields.[4][5] One of the first descriptions of calcium-activated potassium channels was based on studies of the ampulla of Lorenzini in the skate.[6]

Evolution

Further information: Electroreception and electrogenesis

Ampullae of Lorenzini are physically associated with and evolved from the mechanosensory lateral line organs of early vertebrates. Passive electroreception using ampullae is an ancestral trait in the vertebrates, meaning that it was present in their last common ancestor.[7] Ampullae of Lorenzini are present in cartilaginous fishes (sharks, rays, and chimaeras), lungfishes, bichirs, coelacanths, sturgeons, paddlefishes, aquatic salamanders, and caecilians. Ampullae of Lorenzini appear to have been lost early in the evolution of bony fishes and tetrapods, though the evidence for absence in many groups is incomplete and unsatisfactory.[7]

Vertebrates
Lampreys

Jawed fishes

Cartilaginous fishes

430 mya
Bony fishes
Lobe-finned fishes

Coelacanths

Lungfish

Amphibians

(aquatic salamanders, caecilians)

Other tetrapods

(lost)
Ray-finned fishes

bichirs, reedfishes

sturgeons, paddlefishes

Most bony fishes

(lost)
425 mya
Ampullae of Lorenzini

Anatomy

Each ampulla is a bundle of sensory cells containing multiple nerve fibres in a sensory bulb (the endampulle) in a collagen sheath, and a gel-filled canal (the ampullengang) which opens to the surface by a pore in the skin. The gel is a glycoprotein-based substance with the same resistivity as seawater, and electrical properties similar to a semiconductor.[8][3][9]

Pores are concentrated in the skin around the snout and mouth of sharks and rays, as well as the anterior nasal flap, barbel, circumnarial fold and lower labial furrow.[10] Canal size typically corresponds to the body size of the animal but the number of ampullae remains the same. The canals of the ampullae of Lorenzini can be pored or non-pored. Non-pored canals do not interact with external fluid movement but serve a function as a tactile receptor to prevent interferences with foreign particles.[10]

  • Pores of ampullae of Lorenzini in snout of tiger shark

    Pores of ampullae of Lorenzini in snout of tiger shark

  • The electroreceptive ampullae of Lorenzini (red dots) evolved from the mechanosensory lateral line organs (gray lines) of early vertebrates.

    The electroreceptive ampullae of Lorenzini (red dots) evolved from the mechanosensory lateral line organs (gray lines) of early vertebrates.

  • Inner view of ampullae of Lorenzini. The bulbs appear as many pale translucent spheres on either side of the midline.

    Inner view of ampullae of Lorenzini. The bulbs appear as many pale translucent spheres on either side of the midline.

Electroreception

Further information: Electroreception and electrogenesis
How an ampulla of Lorenzini detects an electric field

The ampullae detect electric fields in the water, or more precisely the potential difference between the voltage at the skin pore and the voltage at the base of the electroreceptor cells.[11][12][6]

A positive pore stimulus decreases the rate of nerve activity coming from the electroreceptor cells, while a negative pore stimulus increases the rate. Each ampulla contains a single layer of receptor cells, separated by supporting cells. The cells are connected by apical tight junctions so that no current leaks between them. The apical faces of the receptor cells have a small surface area with a high concentration of voltage-dependent calcium channels (which trigger depolarisation) and calcium-activated potassium channels (for repolarisation afterwards).[13]

Because the canal wall has a very high resistance, all the voltage difference between the pore of the canal and the ampulla is dropped across the 50 micron-thick receptor epithelium. Because the basal membranes of the receptor cells have a lower resistance, most of the voltage is dropped across the excitable apical faces which are poised at the threshold. Inward calcium current across the receptor cells depolarises the basal faces, causing a large action potential, a wave of depolarisation followed by repolarisation (as in a nerve fibre). This triggers presynaptic calcium release and release of excitatory transmitter onto the afferent nerve fibres. These fibres signal the size of the detected electric field to the fish's brain.[14]

The ampulla contains large conductance calcium-activated potassium channels (BK channels). Sharks are much more sensitive to electric fields than electroreceptive freshwater fish, and indeed than any other animal, with a threshold of sensitivity as low as 5 nV/cm. The collagen jelly, a hydrogel, that fills the ampullae canals has one of the highest proton conductivity capabilities of any biological material. It contains keratan sulfate in 97% water, and has a conductivity of about 1.8 mS/cm.[14][11] All animals produce an electrical field caused by muscle contractions; electroreceptive fish may pick up weak electrical stimuli from the muscle contractions of their prey.[6]

The sawfish has more ampullary pores than any other cartilaginous fish, and is considered an electroreception specialist. Sawfish have ampullae of Lorenzini on their head, ventral and dorsal side of their rostrum leading to their gills, and on the dorsal side of their body.[15]

Magnetoreception

Further information: Magnetoreception

Ampullae of Lorenzini also contribute to the ability to receive geomagnetic information. As magnetic and electrical fields are related, magnetoreception via electromagnetic induction in the ampullae of Lorenzini is possible. Many cartilaginous fish respond to artificially generated magnetic fields in association with food rewards, demonstrating their capability. Magnetoreception may explain the ability of sharks and rays to form strict migratory patterns and to identify their geographic location.[16]

Temperature sense

The mucus-like substance inside the tubes was thought in 2003 perhaps to function as a thermoelectric semiconductor, transducing temperature changes into an electrical signal that the animal could use to detect temperature gradients.[17] A 2007 study appeared to disprove this.[18] The question remained open,[19] and in 2023 it was predicted that the ampullae of Lorenzini in sharks would be able to detect a temperature difference of 0.001 Kelvin (a thousandth of a degree). An artificial sensor using the same principle is able to detect a difference of 0.01 Kelvin.[20]

See also

  • Knollenorgan – a non-homologous type of electroreceptor, found in mormyrid fishes

References

  1. ^ a b Roth A, Tscharntke H (October 1976). "Ultrastructure of the ampullary electroreceptors in lungfish and Brachiopterygii". Cell and Tissue Research. 173 (1): 95–108. doi:10.1007/BF00219268. PMID 991235. S2CID 2431185.
  2. ^ Gibbs MA, Northcutt RG (2004). "Development of the lateral line system in the shovelnose sturgeon". Brain, Behavior and Evolution. 64 (2): 70–84. doi:10.1159/000079117. PMID 15205543. S2CID 24967528.
  3. ^ a b Baranes, Avi; Fishelson, Lev (6 January 1999). "Distribution, morphology, and cytology of ampullae of Lorenzini in the Oman shark, Iago omanensis (Triakidae), from the Gulf of Aqaba, Red Sea". The Anatomical Record. 251 (251: 417–430): 417–430. doi:10.1002/(SICI)1097-0185(199808)251:4<417::AID-AR1>3.0.CO;2-P. PMID 9713980. S2CID 46064651. Retrieved 21 March 2022.
  4. ^ Murray RW (September 1960). "Electrical sensitivity of the ampullae of Lorenzini". Nature. 187 (4741): 957. Bibcode:1960Natur.187..957M. doi:10.1038/187957a0. PMID 13727039.
  5. ^ Murray RW (March 1962). "The response of the ampullae of Lorenzini of elasmobranchs to electrical stimulation". The Journal of Experimental Biology. 39: 119–28. doi:10.1242/jeb.39.1.119. PMID 14477490.
  6. ^ a b c Fields RD (August 2007). "The shark's electric sense". Scientific American. 297 (2): 74–81. Bibcode:2007SciAm.297b..74F. doi:10.1038/scientificamerican0807-74. JSTOR 26069417. PMID 17894175.
  7. ^ a b Bullock TG, Bodznick DA, Northcutt RG (1983). "The phylogenetic distribution of electroreception: Evidence for convergent evolution of a primitive vertebrate sense modality" (PDF). Brain Research Reviews. 6 (1): 25–46. doi:10.1016/0165-0173(83)90003-6. hdl:2027.42/25137. PMID 6616267. S2CID 15603518.
  8. ^ Fields RD, Fields KD, Fields MC (October 2007). "Semiconductor gel in shark sense organs?". Neuroscience Letters. 426 (3): 166–70. doi:10.1016/j.neulet.2007.08.064. PMC 2211453. PMID 17904741.
  9. ^ Wueringer BE, Tibbetts IR, Whitehead DL (2009-02-01). "Ultrastructure of the ampullae of Lorenzini of Aptychotrema rostrata (Rhinobatidae)". Zoomorphology. 128 (1): 45–52. doi:10.1007/s00435-008-0073-5. ISSN 1432-234X. S2CID 25440327.
  10. ^ a b Winther-Janson M, Wueringer BE, Seymour JE (2012). "Electroreceptive and mechanoreceptive anatomical specialisations in the epaulette shark (Hemiscyllium ocellatum)". PLOS One. 7 (11): e49857. Bibcode:2012PLoSO...749857W. doi:10.1371/journal.pone.0049857. PMC 3511481. PMID 23226226.
  11. ^ a b King B, Hu Y, Long JA (May 2018). "Electroreception in early vertebrates: survey, evidence and new information". Palaeontology. 61 (3): 325–58. doi:10.1111/pala.12346.
  12. ^ Newton KC, Gill AB, Kajiura SM (July 2019). "Electroreception in marine fishes: chondrichthyans". Journal of Fish Biology. 95 (1): 135–154. doi:10.1111/jfb.14068. PMID 31169300.
  13. ^ Clusin WT, Bennett MV (February 1977). "Calcium-activated conductance in skate electroreceptors: current clamp experiments". The Journal of General Physiology. 69 (2): 121–43. doi:10.1085/jgp.69.2.121. PMC 2215012. PMID 190338.
  14. ^ a b Bellono NW, Leitch DB, Julius D (June 2018). "Molecular tuning of electroreception in sharks and skates". Nature. 558 (7708): 122–126. Bibcode:2018Natur.558..122B. doi:10.1038/s41586-018-0160-9. PMC 6101975. PMID 29849147.
  15. ^ Wueringer BE, Peverell SC, Seymour J, Squire L, Kajiura SM, Collin SP (2011). "Sensory systems in sawfishes. 1. The ampullae of Lorenzini". Brain, Behavior and Evolution. 78 (2): 139–49. doi:10.1159/000329515. PMID 21829004. S2CID 16357946.
  16. ^ Newton KC, Kajiura SM (2020-09-29). "The yellow stingray (Urobatis jamaicensis) can discriminate the geomagnetic cues necessary for a bicoordinate magnetic map". Marine Biology. 167 (10): 151. doi:10.1007/s00227-020-03763-1. S2CID 224948807.
  17. ^ Brown BR (30 January 2003). "Sensing temperature without ion channels". Nature. 421 (6922): 495–495. doi:10.1038/421495a. ISSN 0028-0836.
  18. ^ Fields RD, Fields KD, Fields MC (2007-10-22). "Semiconductor gel in shark sense organs?". Neuroscience Letters. 426 (3): 166–170. doi:10.1016/j.neulet.2007.08.064. ISSN 0304-3940. PMC 2211453. PMID 17904741.
  19. ^ Brown BR (March 2010). "Temperature response in electrosensors and thermal voltages in electrolytes". Journal of Biological Physics. 36 (2): 121–134. doi:10.1007/s10867-009-9174-8. PMC 2825305. PMID 19760113.
  20. ^ Zhang Y, Ye D, Li M, Zhang X, Di C, Wang C (12 January 2023). "Solid state ionics enabled ultra-sensitive detection of thermal trace with 0.001K resolution in deep sea". Nature Communications. 14 (1). doi:10.1038/s41467-022-35682-8. ISSN 2041-1723. PMC 9837202.
This page was last edited on 22 September 2023, at 18:26
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