Cone snail
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| Image:Conus-geographicus.jpg Geography cone, Conus geographus
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The cone snails or cone shells (family Conidae) are predatory marine snails found in coral reefs. The shells of cone snails are often brightly colored, and have interesting patterns, although in some species the color patterns may be partially or completely hidden under an opaque layer of periostracum.
Some species of cone snails can grow up to 23 cm in length and are found in tropical or subtropical waters. There are about 500 different species. They are carnivorous, generally eating marine worms, small fish, molluscs, and even other cone snails. Because cone snails are slow-moving, they use a venomous harpoon (called a toxoglossan radula) to capture faster-moving prey such as fish. The venom of a few larger species is powerful enough to kill a human being.
Harpoon and venom
The cone snail's harpoon is a modification of the radula, an organ in molluscs which acts as both tongue and teeth. The harpoon is hollow and barbed, and is attached to the tip of the radula inside the snail's throat. When the snail detects a prey animal nearby, it turns its mouth - a long flexible tube called a proboscis - towards the prey. The harpoon is loaded with venom and, still attached to the radula, is fired from the proboscis into the prey by a powerful muscular contraction. The venom paralyzes small fish almost instantly. The snail then retracts the radula, drawing the subdued prey into the mouth. After the prey is digested, the cone snail will regurgitate any indigestible material such as spines and scales, along with the disposable harpoon.
The venom of cone snails contains hundreds of different compounds, and its composition varies widely from one species of cone snail to another. The toxins in these various venoms are called conotoxins. These are various peptides, each targeting a specific nerve channel or receptor. Some cone snail venoms also contain a pain-reducing toxin, which the snail uses to pacify the victim before immobilising and then killing it. Some cone snail venoms contain a tetrodotoxin, which is similar to the paralytic neurotoxins found in pufferfish, the blue-ringed octopus, and the Rough-skinned Newt.
Danger to humans
The bright colours and patterns of cone snails have led inquisitive people to pick them up and hold them in their hand for a while. This is not a safe thing to do, because the snail may fire its harpoon in self-defense. The "sting" of many of the smaller cone species is no worse than that of a bee or hornet sting, but in the case of a few of the larger tropical species, handling the snail can have tragic consequences. About 30 human deaths have been recorded from cone snail envenomation. One species, the Geography cone, Conus geographus, is also known colloquially as the "cigarette snail," in the belief that the victim will have only enough time to smoke a cigarette before perishing. Especially in the case of these larger species of cone snail, the harpoon can penetrate gloves or even wetsuits.
Symptoms of a cone snail sting include intense pain, swelling, numbness and tingling. Symptoms can start immediately or can be delayed in onset for days. Severe cases involve muscle paralysis, changes in vision and respiratory failure that can lead to death. There is no antivenom, and treatment involves providing life support until the venom is metabolised by the victim.
Medical use
The venom of some cone snails, such as the Magician cone, Conus magus, shows much promise for providing a non-addictive pain reliever 1000 times as powerful as, and possibly a replacement for, morphine. Many peptides produced by the cone snails show prospects for being potent pharmaceuticals, such as AVC1, isolated from the Australian species, the Queen Victoria cone, Conus victoriae. This has proved very effective in treating post-surgical and neuropathic pain, even accelerating recovery from nerve injury. The first painkiller Ziconotide derived from cone snail toxins was approved by the U.S. Food and Drug Administration in December 2004 under the name "Prialt". Other drugs are in clinical and preclinical trials, such as compounds of the toxin that may be used in the treatment of Alzheimer's disease, Parkinson's disease, and epilepsy.
Collection
Because of the intricate color patterns of cone shells, they have been called the most popular collectible shells.[1] [1] Conus gloriamaris, the Glory of the Seas cone, was historically one of the most famous and sought-after seashells, with only a few specimens known which changing hands at high prices, until its habitat was finally discovered and sizable populations were located.[1]
Naturally-occurring beachworn cone shell "tops" are collected, or these days more often mimicked, in order to make puka shell jewelry.
Footnotes
External links
- Cone snail and conotoxins page
- One slip, and you’re dead... (Nature news article)
- The Conus Biodiversity website
- Conidae from worldwide.conchology.com. Scroll down for many photographs.
- Pain-killer comes out of its shell (The Age news article)
- Venomous snails aid medical science (BBC News Article).
- ConeShell Collection Giancarlo Paganelli
- Cone Snail Videode:Kegelschneckenfr:Conidae
lt:Kūgeniniai nl:Conidae ja:イモガイsk:Homôlkovité th:หอยเต้าปูน
Acknowledgement and Attribution Regarding Sources of Content
Some of the initial content on this page may be incorporated in part from copyleft sources in the public domain including wikis such as Wikipedia and AskDrWiki. Drug information for patients came from the The National Library of Medicine. Infectious disease information may have come from the Centers for Disease Control (CDC). Differential Diagnoses are drawn from clinicians as well as an amalgamation of 3 sources: 1.The Disease Database; 2. Kahan, Scott, Smith, Ellen G. In A Page: Signs and Symptoms. Malden, Massachusetts: Blackwell Publishing, 2004:3; 3. Sailer, Christian, Wasner, Susanne. Differential Diagnosis Pocket. Hermosa Beach, CA: Borm Bruckmeir Publishing LLC, 2002:7 .
