Cone snail

Cone snails, or cones, are highly venomous sea snails that constitute the family Conidae. Conidae is a taxonomic family of predatory marine gastropod molluscs in the superfamily Conoidea.
The 2014 classification of the superfamily Conoidea groups only cone snails in the family Conidae. Some previous classifications grouped the cone snails in a subfamily, Coninae. As of March 2015 Conidae contained over 800 recognized species, varying widely in size from lengths of 1.3 cm to 21.6 cm. Working in 18th-century Europe, Carl Linnaeus knew of only 30 species that are still considered valid.
Fossils of cone snails have been found from the Eocene to the Holocene epochs. Cone snail species have shells that are roughly conical in shape. Many species have colorful patterning on the shell surface. Cone snails are almost exclusively tropical in distribution.
All cone snails are venomous and capable of stinging. Cone snails use a modified radula tooth and a venom gland to attack and paralyze their prey before engulfing it. The tooth, which is likened to a dart or a harpoon, is barbed and can be extended some distance out from the head of the snail at the end of the proboscis.
Cone snail venoms are mainly peptide-based, and contain many different toxins that vary in their effects. The sting of several larger species of cone snails can be serious, and even fatal to humans. Cone snail venom also shows promise for medical use.

Distribution and habitat

Species in the family Conidae are found in the tropical and subtropical seas of the world, in four biogeographic regions, including: the Indo-Pacific, the Tropical Eastern Pacific, the western Tropical Atlantic, and the eastern Tropical Atlantic, plus 10 species in the warm temperate Agulhas bioregion on the southern coast of South Africa. Fewer than one percent of fossil species have been found in more than one of the above regions.
Cone snails are typically found in warm tropical seas and oceans worldwide. Cone snails reach their greatest diversity in the Western Indo-Pacific region. While the majority of cone snails are found in warm tropical waters, some species have adapted to temperate/semi-tropical environments and are endemic to areas such as the Cape coast of South Africa, the Mediterranean, or the cool subtropical waters of southern California.
They live on a variety of substrates, from the intertidal zone and deeper areas, to sand, rocks or coral reefs.

Paleontology

The oldest known fossil of Conidae is from the lower Eocene, about 55 million years ago. Analysis of nucleotide sequences indicate that all living species of Conidae belong to one of two clades that diverged about 33 million years ago. One clade includes most of the species in the eastern Pacific and western Atlantic regions, which were connected by the Central American Seaway until the emergence of the Isthmus of Panama less than three million years ago. The other clade includes most of the species in the eastern Atlantic and Indo-Pacific regions, which were connected by the Neo-Tethys Sea until 21 to 24 million years ago.

Shell

Cone snails have a large variety of shell colors and patterns, with local varieties and color forms of the same species often occurring. This variety in color and pattern has led to the creation of a large number of known synonyms and probable synonyms, making it difficult to give an exact taxonomic assignment for many snails in this genus. As of 2009, more than 3,200 different species names have been assigned, with an average of 16 new species names introduced each year.
The shells of cone snails vary in size and are conical in shape. The shell is whorled in the form of an inverted cone, with the anterior end being narrower. The protruding parts of the top of the whorls, that form the spire, are in the shape of another more flattened cone. The aperture is elongated and narrow with the sharp operculum being very small. The outer lip is simple, thin, and sharp, without a callus, and has a notched tip at the upper part. The columella is straight.
The larger species of cone snails can grow up to in length. The shells of cone snails are often brightly colored with a variety of patterns. Some species color patterns may be partially or completely hidden under an opaque layer of periostracum. In other species, the topmost shell layer is a thin periostracum, a transparent yellowish or brownish membrane.

Physiology and behavior

The snails within this family are sophisticated predatory animals. They hunt and immobilize prey using a modified radular tooth along with a venom gland containing neurotoxins; the tooth is launched out of the snail's mouth in a harpoon-like action.
Cone snails are carnivorous. Their prey consists of marine worms, small fish, molluscs, and other cone snails. Cone snails are slow-moving, and use their venomous harpoon to disable faster-moving prey.
The osphradium in cone snails is more specialized than in other groups of gastropods. It is through this sensory modality that cone snails are able to sense their prey. The cone snails immobilize their prey using a modified, dartlike, barbed radular tooth, made of chitin, along with a venom gland containing neurotoxins.
Molecular phylogeny research has shown that preying on fish has evolved at least twice independently in cone snails. Some species appear to have also evolved prey mimicry, where they release chemicals that resemble the sex pheromones certain ragworms release during their short breeding season. The researchers hypothesize that these chemicals cause the prey to be more easily harpooned, but are still uncertain as to exactly how this occurs in the wild.

Harpoon

Cone snails use a harpoon-like structure called a radula tooth for predation. Radula teeth are modified teeth, primarily made of chitin and formed inside the mouth of the snail, in a structure known as the toxoglossan radula. Each specialized cone snail tooth is stored in the radula sac, except for the tooth that is in current use.
Cone snails employ two main hunting strategies: vermivores typically use a 'sting and retract' method, injecting venom directly into the worm. They patiently hunt, sting the worm, wait for it to be paralyzed, and then ingest it. This is a deliberate, slower process. In contrast, piscivores often employ a sophisticated 'venom net' strategy, releasing toxins into the surrounding water to instantly paralyze the prey before delivering the harpoon. The harpoon is then used to pull the paralyzed fish into the mouth. The snail engulfs it and may release further enzymes to liquefy the tissue, which is then consumed as fluid.
The radula tooth is hollow and barbed, and is attached to the tip of the radula in the radular sac, inside the snail's throat. When the snail detects a prey animal nearby, it extends a long flexible tube called a proboscis towards the prey. The radula tooth is loaded with venom from the venom bulb and, still attached to the radula, is fired from the proboscis into the prey by a powerful muscular contraction. The venom can paralyze smaller fish almost instantly. The snail then retracts the radula, drawing the subdued prey into the mouth. After the prey has been digested, the cone snail will regurgitate any indigestible material, such as spines and scales, along with the harpoon. There is always a radular tooth in the radular sac. A tooth may also be used in self-defense when the snail feels threatened.
The harpoon attack of the species Conus catus has been found to be one of the fastest complete movements recorded in animals, with a maximum speed of 90 km/h, an acceleration of 400,000 m/s², and a deceleration of 700,000 m/s². The speed of other animals such as the peacock mantis shrimp and the trap-jaw ant was measured at the free end of a fixed appendage, while the speed of the harpoon was measured from its base and traveling inside the proboscis.
The reason for this speed relies in hydrostatic pressure by the fluid inside the proboscis which propels the harpoon inside until it is almost completely out. A sphincter acts as a valve to keep fluid in the proximal half and in the distal half a constriction of ephitelial tissue together with a thicker harpoon base helps to build up hydrostatic pressure when the sphincter opens. The deceleration may help release the venom from the harpoon.

Venom

There are approximately 30 records of humans killed by cone snails. Human victims suffer little pain, because the venom contains an analgesic component. Some species reportedly can kill a human in under five minutes, thus the name "cigarette snail" as supposedly one only has time to smoke a cigarette before dying. Cone snails can sting through a wetsuit with their harpoon-like radular tooth, which resembles a transparent needle.
Normally, cone snails use their venom to immobilize prey before engulfing it. The venom consists of a mixture of peptides, called conopeptides. The venom is typically made up of 10 to 30 amino acids, but in some species as many as 60. The venom of each cone snail species may contain as many as 200 pharmacologically active components. It is estimated that more than 50,000 conopeptides can be found, because every species of cone snail is thought to produce its own specific venom.
Cone-snail venom has come to interest biotechnologists and pharmacists because of its potential medicinal properties. Production of synthetic conopeptides has started, using solid-phase peptide synthesis.
A component of the venom of Conus magus, ω-conotoxin, is now marketed as the analgesic ziconotide, which is used as a last resort in chronic and severe pain. Conopeptides are also being looked at as anti-epileptic agents and to help stop nerve-cell death after a stroke or head injury. Conopeptides also have potential in helping against spasms due to spinal cord injuries, and may be helpful in diagnosing and treating small cell carcinomas in the lung.
The biotechnology surrounding cone snails and their venom has promise for medical breakthroughs; with more than 50,000 conopeptides to study, the possibilities are numerous.