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Cone snail

Cone snails are predatory marine gastropods belonging to the family , renowned for their distinctive cone-shaped shells and sophisticated venom delivery systems. These snails, primarily in the Conus, comprise approximately 850 extant that inhabit tropical and subtropical ocean waters worldwide, often in shallow coastal environments such as coral reefs, sandy flats, and seagrass beds, though some dwell at depths up to several hundred meters. As active hunters, cone snails employ a extendable proboscis to deploy a harpoon-like radular tooth that injects a complex venom cocktail known as conotoxins, which are disulfide-rich peptides targeting channels, receptors, and transporters to paralyze prey. Their diet varies by species and evolutionary lineage: vermivorous types primarily consume polychaete worms, molluscivorous ones prey on other gastropods, and piscivorous species hunt , with the latter often possessing the most potent venoms. This specialized predation has driven remarkable venom diversity, with each species producing hundreds of unique conotoxins tailored to their ecological niche. While most encounters with humans are harmless, stings from certain piscivorous cone snails can cause severe , including and, in rare cases, , due to the neurotoxic effects of their . Conversely, the pharmacological potential of conotoxins has led to significant biomedical applications; for instance, , derived from the venom of , is an FDA-approved analgesic for . Conservation efforts highlight threats from habitat loss and shell collection, underscoring the need to protect this biodiverse group.

Description and anatomy

Shell

The shells of cone snails exhibit an elongated, conical shape, typically forming an inverted with a narrow anterior end, a long and slender , and a short siphonal . These dimensions allow for efficient retraction of the soft body while maintaining a streamlined profile. Shell lengths vary widely among , generally ranging from 10 to 230 mm. Surface features of cone snail shells include axial ribs, nodules, and spiral ridges that contribute to structural reinforcement and visual distinction. Intricate color patterns, often featuring bands, spots, or mottling in , , and , provide against sandy or substrates and assist in identification. The shell's material composition consists primarily of in the polymorph, arranged in a crossed-lamellar microstructure of rod-shaped that enhances toughness and fracture resistance. An outer periostracum layer, composed of organic proteins, covers the shell and offers initial against environmental . These shells serve adaptive roles in predator protection, with their robust, layered structure deterring crushing by larger animals such as octopuses or . Additionally, the shell provides , anchoring muscles that enable the projection of the during feeding. Variations in shell occur across , with some displaying smooth surfaces and others featuring pronounced sculpturing like ribs or tubercles. Color morphs are more vibrant and diverse in tropical , aiding in reefs, while temperate tend toward subdued patterns better suited to cooler, sediment-rich environments. Shell also plays a crucial role in taxonomic , as differences in , ornamentation, and patterning help delineate boundaries.

Radula and harpoon

In cone snails, the has undergone significant modification compared to the typical gastropod structure, which consists of a flexible bearing multiple rows of chitinous arranged in transverse series for scraping or cutting food. Instead, the Conus is reduced to a single per row, forming a specialized, hollow, -like structure that serves as the primary tool for prey capture. This single , known as the radular , is barbed to anchor into the prey and features a that allows for upon deployment. The tooth exhibits a distinct consisting of a bulbous , a narrow shaft, and a bladed tip equipped with backward-facing barbs. The bulbous base attaches to the for loading and propulsion, the hollow shaft provides structural support and serves as a conduit for delivery, and the bladed tip facilitates penetration and securement of the prey. This design enables the to function like a , piercing tissues to inject directly. The integrates with the apparatus by drawing fluid from the venom bulb through its hollow core during projection. Projection of the occurs via a hydrostatic mechanism, where pressurized fluid from the venom bulb builds within the extended , engaging a cellular at the base until release. Upon prey contact, the disengages, propelling the forward at peak velocities averaging 19.3 m/s and exceeding 25 m/s in fish-hunting species, with average peak accelerations exceeding 280,000 m/s² (approximately 28,600 g) and maximal accelerations over 400,000 m/s² (about 40,800 g). This rapid deployment represents an evolutionary adaptation for overcoming the escape responses of mobile prey like . Evolutionarily, the Conus radula's specialization as a disposable, single-use reflects adaptations from ancestral worm-hunting forms, with piscivorous lineages independently evolving enhanced barbs and speed for tethering larger prey. Each is expended after use—often regurgitated shortly thereafter—and the radular sac continuously produces replacements, regenerating a new within days to maintain readiness for subsequent hunts. This disposable nature contrasts sharply with the multi-tooth, reusable radulae of other gastropods, underscoring the Conidae's shift toward venom-mediated predation.

Venom apparatus

The venom apparatus of cone snails comprises an unpaired venom gland, a venom duct, and a muscular . The venom gland is a long, highly convoluted structure extending from the posterior end of the animal, lined with glandular responsible for synthesis, and connected to the via the duct. The duct facilitates the transport of components, while the muscular bulb at the proximal end of the gland serves for storage and generates hydrostatic pressure to propel the venom during injection. Cone snail venom consists of a complex mixture of 50 to 200 conotoxins per , primarily small disulfide-rich peptides known as conopeptides that target specific neuronal components. These include alpha-conotoxins, which antagonize nicotinic receptors; omega-conotoxins, which block N-type voltage-gated calcium channels; and mu-conotoxins, which inhibit voltage-gated sodium channels, among other families. Conotoxins are produced through the of precursor proteins in the glandular of the , where they undergo post-translational processing, including disulfide bond formation and proteolytic cleavage. Genetic diversity arises from hypermutation in conotoxin-encoding genes, enabling rapid and species-specific variations in sequences and structures. Venom composition exhibits significant variability across cone snail species, tailored to their dietary preferences: approximately 70% of species are vermivores with venoms optimized for immobilizing polychaete worms, 15% are molluscivores targeting other gastropods, and 15% are piscivores adapted for capturing . This prey-specific ensures efficient strategies distinct from those in other clades. The evolutionary refinement of conotoxins over millions of years has positioned them as valuable models for , owing to their precise targeting of channels and receptors honed by for prey capture.

Habitat and ecology

Distribution

Cone snails are predominantly distributed in tropical and subtropical marine waters worldwide, exhibiting their highest species diversity in the region, where the majority of the over 850 described occur. This region accounts for approximately 60% of known cone snail diversity, spanning vast coral reef systems from the in the west to in the east. In contrast, species richness is considerably lower in the and eastern Pacific, with around 98 species documented in the eastern and even fewer in the western and eastern Pacific regions. These gastropods occupy a wide bathymetric range, from shallow intertidal zones to depths exceeding 700 meters, though most species prefer shallow waters less than 50 meters deep. Deep-water species, particularly those in genera such as Profundiconus, extend this range further, with records from collections reaching up to 1,260 meters in areas like New Caledonia's . Endemism is a prominent feature of cone snail distribution, with numerous confined to specific islands or archipelagos due to biogeographic isolation. For instance, the Islands host 55 , 52 of which are endemic (noting one recent as of 2025), highlighting hotspots of localized in the eastern Atlantic. Similarly, many Indo-Pacific islands support unique assemblages, contributing to the overall pattern of restricted ranges observed in about 37.5% of with areas of occupancy under 100 km². Limited larval dispersal plays a key role in shaping these distribution patterns, as most cone snails produce planktotrophic larvae that, despite enabling some oceanic transport, often result in constrained by oceanographic barriers and developmental constraints. This contributes to low migration rates across major biogeographic divides, such as those separating the from and eastern Pacific.

Preferred environments

Cone snails, genus Conus, predominantly occupy tropical and subtropical marine habitats, with a strong preference for coral reefs where they achieve the highest species diversity and abundance. They also inhabit sandy or muddy bottoms, beds, and fringes, often in shallow coastal waters from the to depths of around 50 meters. These environments provide the structural complexity and prey availability essential for their predatory lifestyle. Within these habitats, cone snails exploit diverse microhabitats, such as burrowing partially or fully into loose sediment on flats or floors to remain concealed during daylight hours, or attaching to rocks, rubble, and sponges for stability. Many species are nocturnal, emerging at night to while retreating to protective crevices, algal mats, or under overhangs during the day to avoid predators and in intertidal areas. For instance, species like frequently burrow in near reefs, enhancing their capabilities. Cone snails exhibit environmental tolerances suited to stable tropical conditions, typically thriving in seawater salinities of 30–35 and temperatures ranging from 20–30°C, though some can endure broader fluctuations such as salinities from 5–40 under optimal temperatures around 20°C. Certain deep-water or sediment-dwelling show adaptations to lower oxygen levels, such as in hypoxic environments or deeper slopes. These tolerances reflect their reliance on consistent and Atlantic coastal ecosystems. Adaptations to these environments include intricate shell coloration and patterning that provide camouflage against sandy, rubbly, or coral backgrounds, allowing the snails to blend seamlessly with their surroundings for predatory ambushes. Burrowing behaviors, facilitated by a muscular foot, enable them to create temporary shelters in sediment while maintaining sensory awareness through extended siphons. Such traits are particularly evident in reef-associated species, where shell patterns mimic surrounding algae or rubble. Habitat change poses acute risks to cone snails, particularly those reliant on reefs, where bleaching events driven by rising sea temperatures and degrade structural habitats and reduce microhabitat availability. For example, widespread mortality has led to population declines in reef-dependent species across the , disrupting their preferred niches.

Feeding behavior

Cone snails are classified into three primary dietary guilds based on their prey preferences: piscivorous species that primarily hunt fish, molluscivorous species that target other mollusks such as other snails, and vermivorous species that feed on polychaete worms and similar invertebrates. This specialization influences their venom composition and hunting efficiency, with piscivorous species generally exhibiting the most potent and rapid-acting toxins to subdue fast-moving fish. For instance, species like Conus geographus and Conus textile are piscivorous and rely on fish as their main prey. Hunting strategies among cone snails emphasize stealth and precision, often involving ambush predation where the snail remains camouflaged on the substrate until prey approaches within striking distance. Piscivorous frequently employ a lightning strike technique, rapidly everting the —up to 20 times their body length in milliseconds—to impale the prey with a harpoon-like radular . Alternatively, some utilize a "net-hunting" or "cabling" strategy, extending the in a lasso-like manner to ensnare and tether before , as observed in like Conus catus. Vermivorous and molluscivorous tend toward slower, more deliberate approaches, such as probing sediments or luring prey with protrusible structures mimicking food or mates. The process is initiated by the strike, which injects a complex mixture of through the apparatus, leading to near-instantaneous —often within 2-5 seconds for prey—by disrupting neuromuscular transmission and channels. Following immobilization, external are sometimes released to begin liquefying the prey's tissues externally, facilitating consumption. The entire prey is then engulfed whole via the highly extensible and mouth, with ongoing effects preventing any post-capture resistance; indigestible remnants, such as shells or exoskeletons, are expelled hours later. Behavioral variations in feeding reflect ecological adaptations, with many species exhibiting nocturnal to exploit crepuscular prey activity, though some temperate piscivores like Conus californicus hunt diurnally in response to availability. Active involves siphon-mediated prey detection and pursuit over short distances, contrasting with passive tactics where snails position themselves in high-traffic prey areas and wait. These patterns can shift ontogenetically, as seen in , where juveniles are strictly vermivorous with cautious probing behaviors before transitioning to piscivory in adulthood via bolder strikes.

Evolutionary history

Paleontology

The fossil record of cone snails (genus Conus) dates back to the early Eocene epoch, approximately 55 million years ago, when primitive Conus-like forms first appeared in shallow marine deposits across what is now . These earliest known s, including such as Eoconus edwardsi (Hampshire Basin) and E. deperditus (Paris Basin), have been recovered from Lower Eocene sediments in the of and the Hampshire Basin of , indicating an origin in temperate to subtropical shelf environments during a period of following the Paleocene-Eocene Thermal Maximum. Fossil diversity expanded significantly through the , with over 1,000 described extinct species documented to date, though many may represent synonyms due to similarities in shell morphology. Diversity peaked during the epoch (23–5 million years ago), a time of rapid and geographic radiation coinciding with the expansion of tropical shallow-water habitats and the closure of the Tethys Sea, which facilitated dispersal into the and Atlantic regions. Key fossil assemblages from this period include those from coral reef deposits in the , where well-preserved shells reveal insights into coloration patterns and ecological roles, and chalk and limestone formations in , such as those in and the . Morphological evolution in the fossil record reflects adaptations to predatory lifestyles, with coiling transitioning from loosely coiled, more globose forms in Eocene ancestors to the tightly coiled, elongated conical shapes characteristic of later , enhancing mobility and in environments. Concurrently, the underwent specialization, evolving from a multi- typical of ancestral vermivorous neogastropods to the single, hypodermic harpoon-like seen in modern molluscivorous and piscivorous Conus, enabling precise delivery for prey capture. These changes are evident in comparative analyses of radular remnants and microstructures from and sites. Significant extinctions occurred during the Pleistocene epoch (2.6 million–11,700 years ago), driven by repeated glacio-eustatic sea-level fluctuations that contracted shallow tropical habitats, particularly affecting island-endemic and reef-associated species in the western Atlantic and . Fossil evidence from deposits shows a decline in and average body size among surviving lineages, with approximately 70% of regional Conus lost in the western Atlantic due to and reduced nutrient availability.

Phylogenetic relationships

Cone snails, belonging to the family , are placed within the superfamily Conoidea of the order , formerly grouped under the toxoglossan gastropods. This positioning reflects their shared characteristics with other venomous marine gastropods, including a harpoon-like for prey . Within Conoidea, molecular phylogenies indicate that is monophyletic and forms a distinct lineage, with some analyses suggesting a close relationship to (auger snails) as part of a broader diversification of toxiferous families. The family underwent significant diversification approximately 50 million years ago during the Eocene, coinciding with the radiation of and the evolution of complex venom systems. Large-scale molecular studies, incorporating (e.g., ) and nuclear markers (e.g., 28S rRNA and ), reveal a rapid radiation of primarily in the region, the ancestral cradle of the group. This phylogeny, based on over , identifies four major highly divergent clades (Clades A–D), with limited subsequent dispersal to other oceans, underscoring the Indo-Pacific's role in driving through ecological opportunities like diverse prey availability. Phylogenetic analyses further delineate key clades by dietary specialization, separating piscivorous (fish-hunting) lineages from non-piscivorous ones (e.g., vermivorous or molluscivorous). Piscivory has arisen independently at least three times, in distinct subclades such as those including and , highlighting in venom composition and hunting strategies. Non-piscivorous clades, often basal, retain ancestral worm- or mollusk-hunting behaviors, with transitions to fish predation linked to innovations in conotoxin diversity. The of Conus sensu lato has been challenged by these molecular data, which demonstrate within the traditional genus, prompting a 2014 reclassification that recognizes multiple genera across the four clades to better reflect evolutionary relationships. This shift emphasizes the polyphyletic nature of shell-based taxonomy and advocates for integrating genetic evidence in systematics.

Life history

Reproduction

Cone snails are gonochoristic, possessing separate sexes with distinct s and s. occurs during copulation, in which the mounts the using its foot and inserts a ribbon-like verge—analogous to a —into the 's mantle cavity opening to transfer . is facilitated by chemical cues, as individuals secrete pheromones to attract potential partners; the then approaches the , and copulation may last several hours depending on the . Following fertilization, females deposit eggs in gelatinous capsules attached to hard substrates such as rocks or , often in clusters to protect against environmental hazards. Each capsule typically contains dozens to hundreds of eggs, with species like producing about 40 eggs per capsule in masses of multiple capsules, while others may yield up to 1,000 eggs per capsule across 20–50 capsules per mass. Within these capsules, embryos develop either into free-swimming veliger larvae, which hatch and enter the , or directly into juvenile snails via intracapsular , depending on the species' life history strategy. Cone snails exhibit no after egg deposition; females abandon the capsules, relying on high —often thousands of eggs per reproductive event—to offset high rates of predation and mortality in early life stages. is minimal across the , with males and females generally similar in shape, color, and size, though some show slight differences in maximum adult size, such as females growing marginally larger in certain vermivorous taxa.

Development and growth

Cone snails display two primary larval developmental modes: planktotrophic veligers, which are free-swimming larvae that actively feed on to fuel their growth, and lecithotrophic larvae, which are non-feeding and depend on internal yolk reserves for energy during their brief pelagic phase. Most species in the Conus employ planktotrophic , allowing larvae to sustain longer planktonic periods, whereas lecithotrophic occurs in select species, such as those endemic to the archipelago, where larvae derive nourishment from an egg sac without external feeding. In planktotrophic species, veliger larvae can disperse for 10 to 50 days—or up to several weeks to months in natural conditions—via currents, facilitating the wide geographic observed across tropical and subtropical environments. This pelagic phase ends with settlement onto appropriate substrates, such as sandy or coralline bottoms, triggering ; during this process, the velum (a larval ) regresses, the operculum forms, and the protoconch transitions into the adult teleoconch shell, marking the onset of benthic life. Following , juvenile cone snails exhibit steady growth, typically at rates of 1 to 2 mm per month in shallow-water like Conus pennaceus, though variability exists across taxa due to environmental factors such as and availability. is generally attained within 1 to 3 years, with smaller reaching reproductive size sooner (e.g., 6 to 12 months in Conus geographus) compared to larger forms. Lifespans range from 5 to 20 years, influenced by ; deep-water often display slower growth rates and extended longevity owing to lower metabolic demands in cooler, stable environments.

Taxonomy and classification

Current taxonomy

The family Conidae comprises over 1,000 extant species of cone snails, classified into 8 accepted genera and numerous subgenera following updates to the 2015 taxonomic revision. This revision, building on a comprehensive molecular phylogeny, restructured the traditional broad genus Conus to reflect evolutionary relationships more accurately. The current system, as endorsed by the () as of 2025, recognizes the family with 8 genera: Californiconus, Conasprella, Conus, Kenyonia, Lilliconus, Profundiconus, Pseudolilliconus, and Pygmaeconus, along with many subgenera. For instance, Conus includes well-known subgroups like the textile cones (Conus textile and relatives), while Conasprella, Profundiconus, and others represent distinct lineages adapted to varied habitats, such as deep-water environments in the latter. This framework has evolved from the 803 valid species recognized in 2015, with subsequent additions and reclassifications bringing the total over 1,000. The classification criteria integrate molecular data from mitochondrial genes, including subunit I (), 16S rRNA, and 12S rRNA, analyzed across 329 species, with supporting morphological evidence from shell morphology and radular dentition. These approaches revealed four major divergent clades initially, but subsequent studies have justified further separations into additional genera. Post-2015 updates have included descriptions of new deep-water species and taxonomic adjustments, such as the 2023 review of New Caledonian fauna that described one new species (Conus samadiae) but preserved the overall structure while noting ongoing refinements. As of November 2025, the system continues to evolve, with reflecting the latest accepted genera.

Historical developments

The genus Conus was established by in his (10th edition) in , initially encompassing all known cone snails within a single , with approximately 30 species described based on shell characteristics from global collections. This Linnaean framework treated the diverse morphologies of cone snails as variations within one , reflecting the limited understanding of their biology at the time. Throughout the 19th and early 20th centuries, taxonomists expanded the by introducing subgenera primarily based on , , and coloration, as anatomical details like the apparatus were not yet central to . A key contribution came from William J. Clench in 1942, who proposed subgenera such as Dauciconus and Jaspidiconus for western Atlantic , emphasizing regional variations to organize the growing number of described taxa. By the , around 500 were recognized within Conus, highlighting the genus's remarkable diversity but also the challenges in delineating boundaries solely on morphological grounds. In 1993, John D. Taylor and colleagues provided the first detailed anatomical classification of the superfamily Conoidea, analyzing structures and feeding mechanisms across families, which suggested the of Conus by revealing deep divergences unsupported by traditional shell-based groupings. This work marked a shift toward integrating internal , laying groundwork for questioning the of the genus. Building on emerging molecular data, John K. Tucker and Manuel J. Tenorio proposed a major revision in 2009, elevating many subgenera to full genera and recognizing 82 genera within three families for over 600 living cone snail species, based on combined morphological and preliminary genetic evidence. In 2011, Philippe Bouchet and coauthors refined this framework in a new operational classification of the Conoidea, incorporating molecular phylogenies to validate 82 taxa and underscore the need for further splits in Conus sensu lato, paving the way for contemporary .

Diversity and genera

Cone snails, belonging to the family , exhibit remarkable diversity, with over 1,000 valid worldwide. This is classified into 8 principal genera—Californiconus, Conasprella, Conus, Kenyonia, Lilliconus, Profundiconus, Pseudolilliconus, and Pygmaeconus—encompassing numerous subgenera, based on molecular phylogenetic analyses and updates to the 2015 framework. The genus Conus dominates with over 700 , primarily inhabiting shallow tropical waters, while Conasprella includes around 160 specialized as worm-hunters. Deep-sea adapted groups, such as Profundiconus with approximately 30 , occupy colder, abyssal environments. Diversity is highest in the Indo-West Pacific region, which hosts over 60% of all known species, exceeding 600 taxa. Regional hotspots include the , with more than 150 species recorded, and , supporting around 150 species, reflecting the family's concentration in and subtropical habitats. Species delineation in cone snails faces significant challenges due to cryptic —morphologically similar but genetically distinct forms—and evidence of hybridization, complicating traditional . Molecular studies suggest that up to 20% of the actual remains undescribed, particularly in understudied deep-water and remote populations. Recent assessments confirm one (Conus lugubris, 2025 IUCN update). Conservation assessments by the IUCN indicate that approximately 10-15% of evaluated cone snail species are threatened or near-threatened, primarily due to their rarity, limited distributions, and pressures from habitat loss and collection.

Human relevance

Risks to humans

Cone snails pose risks to humans primarily through accidental envenomation via their harpoon-like radular tooth, which can penetrate skin during handling of live specimens, often by shell collectors or divers. The venom, composed of conotoxins, includes peptides such as δ-conotoxins that block or modulate voltage-gated sodium channels, leading to intense localized pain by disrupting nerve signaling. Envenomations are rare globally, with fewer than 200 documented cases historically, most occurring among individuals handling the snails in tropical marine environments. Symptoms of a cone snail sting typically begin with sharp, burning pain at the site, followed by swelling, numbness, and tingling that may radiate proximally. In severe cases, particularly from piscivorous species like Conus geographus (known as the "cigarette snail" due to the time victims have to smoke one last cigarette before death), systemic effects can include muscle , , and , progressing within hours if untreated. Approximately 30 to 36 fatalities have been recorded worldwide, predominantly before 2000 and attributed to C. geographus, with no confirmed deaths reported in recent years owing to increased awareness and prompt medical intervention. There is no specific antivenom available for cone snail envenomations, so first aid focuses on symptom management and rapid transport to a medical facility. Immediate measures include immobilizing the affected limb to slow venom spread, immersing the sting site in hot water (as tolerable, up to 45–50°C) for 30–90 minutes to denature heat-labile toxins and alleviate pain, and monitoring for respiratory distress. Supportive care in a hospital setting, such as mechanical ventilation if needed, is critical for severe cases.

Biomedical applications

Cone snail venoms contain conotoxins, a diverse array of disulfide-rich peptides with high specificity for channels and receptors, making them valuable for biomedical research and . The most prominent example is (Prialt), an ω-conotoxin MVIIA derived from , approved by the FDA in 2004 for intrathecal treatment of severe chronic pain in patients unresponsive to other therapies. By selectively antagonizing N-type voltage-gated calcium channels (Cav2.2), ziconotide inhibits glutamate and release in the , providing non-opioid analgesia without respiratory depression or addiction risk. Ongoing research explores conotoxins for additional therapeutic applications, particularly in . Mu-conotoxins, such as μ-conotoxin CnIIIC, block voltage-gated sodium channels (Nav1.4), offering potential for treating muscle disorders like by reducing hyperexcitability without affecting cardiac or neuronal channels. Alpha-conotoxins, including α-conotoxin Vc1.1, target nicotinic receptors (nAChRs) and are under investigation for , where nAChR dysregulation contributes to seizures, as well as and inflammatory conditions. Several conotoxin analogs, such as contulakin-G and χ-conotoxin MrIA, have advanced to phase I/II clinical trials for pain and , though challenges like delivery and persist; as of , at least five compounds remain in early-stage development. Drug development from conotoxins involves solid-phase to produce these complex, 10-40 sequences with multiple bonds, followed by oxidative folding to achieve native . A key hurdle is their poor pharmacokinetic profile, including rapid enzymatic degradation and limited oral ; this is addressed through backbone cyclization, which links the N- and C-termini via amide bonds, enhancing serum stability by up to 100-fold while preserving activity, as demonstrated in cyclic analogs of α-conotoxin RgIA and Vc1.1. Beyond , conotoxins show promise in other areas. Chi-conotoxins, like χ-conotoxin MrIA, inhibit norepinephrine transporters and have icidal potential by disrupting neurotransmitter systems, with recombinant forms exhibiting lethality against agricultural pests in preclinical assays. Certain conotoxins, such as those targeting voltage-gated potassium channels, display anti-cancer effects by inducing in tumor cells, with studies on venom showing against ovarian and cell lines via modulation. Biotech firms have driven this field, with historical examples like Cognetix patenting over 100 conotoxins.

Collecting and trade

Cone snails have long been prized by collectors for their ornate shells, with interest dating back to the 17th and 18th centuries when they featured prominently in European due to their aesthetic appeal and exotic origins. During this period, a frenzy of shell collecting swept through Europe, fueled by trade routes such as those of the , which supplied rare specimens from tropical waters. Collecting peaked in the 1970s and 1980s, particularly in the , where the shell industry became a major export earner, with cone shells among the highly sought-after items traded internationally. Today, the trade in cone snail shells persists primarily for ornamental purposes, with specimens sold to collectors and jewelers; rare species can fetch prices ranging from $10 to over $500 per shell, depending on size, condition, and scarcity. While exact global volumes are difficult to quantify, the ornamental shell trade, including cones, involves tens of thousands of specimens annually, sourced mainly from regions. Collection methods remain labor-intensive, typically involving hand-gathering by free-diving or snorkeling in shallow tropical waters, often using tongs or nets to safely extract live snails without direct contact, as their venomous can pose risks to handlers. Efforts to establish for cone snails have been limited and largely unsuccessful outside settings, due to challenges in replicating their complex dietary and environmental needs, with most attempts focused on extraction rather than commercial shell production. Overharvesting has significantly impacted endemic species, such as Conus gloriamaris (the glory-of-the-sea cone), once among the rarest shells known, with only a few specimens documented until the 1960s; intensified collecting in the subsequently flooded the market but depleted local populations. Habitat loss from coastal development, pollution, and destructive fishing exacerbates these pressures, particularly in biodiversity hotspots like the . In October 2025, the confirmed the extinction of Conus lugubris, an endemic species from , underscoring the severity of these threats. According to the , as of 2013 approximately 6.5% of assessed cone snail species (out of 632) are threatened with extinction globally, with higher rates—up to 45% as of 2016—in isolated regions like , where endemism amplifies vulnerability. Regulatory measures aim to curb these threats, though cone snails are not currently listed under appendices. In , collection of marine snails, including cones, is strictly regulated under state fisheries laws, with bans on taking live specimens in many areas to protect native and prevent risks. The , a major sourcing hub, has implemented fishing quotas and marine protected areas to limit cone snail harvesting, with ongoing enforcement as of 2025 to sustain populations amid trade demands.

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