Scaly-foot snail


Chrysomallon squamiferum, commonly known as the scaly-foot gastropod, scaly-foot snail, or sea pangolin, is a species of deep-sea hydrothermal-vent snail, a marine gastropod mollusc in the family Peltospiridae. This vent-endemic gastropod is known only from deep-sea hydrothermal vents in the Indian Ocean, where it has been found at depths of about. Chrysomallon squamiferum differs greatly from other deep-sea gastropods, even the closely related neomphalines. In 2019, it was declared endangered on the IUCN Red List, the first species to be listed as such due to risks from deep-sea mining of its vent habitat that also produce high-quality metal ores.
The shell is of a unique construction, with three layers; the outer layer consists of iron sulfides, the middle layer is equivalent to the organic periostracum found in other gastropods, and the innermost layer is made of aragonite. The foot is also unusual, being armored at the sides with iron-mineralised sclerites.
The snail's oesophageal gland houses symbiotic gammaproteobacteria from which the snail appears to obtain its nourishment. This species is considered to be one of the most peculiar deep-sea hydrothermal-vent gastropods, and it is the only known extant animal that incorporates iron sulfide into its skeleton. Its heart is, proportionately speaking, unusually large for any animal: the heart comprises approximately 4% of its body volume.

Taxonomy

This species was first discovered in April 2001, and has been referred to as the "scaly-foot" gastropod since 2001. In terms of its scientific name, it has been referred as Chrysomallon squamiferum since 2003, but it was not formally described in the sense of the International Code of Zoological Nomenclature until Chen et al. named it in 2015. Type specimens are stored in the Natural History Museum, London. During the time when the name was not yet formalized, an incorrect spelling variant was "Crysomallon squamiferum".
C. squamiferum is the type species and the sole species within the genus Chrysomallon. The generic name Chrysomallon is from the Ancient Greek language, and means "golden haired", because pyrite is golden in color. The specific name squamiferum is from the Latin language and means "scale-bearing", because of its sclerites. At first it was not known to which family this species belonged. Warén et al. classified this species in the family Peltospiridae, within the Neomphalina in 2003. Molecular analyses based on sequences of cytochrome-c oxidase I genes confirmed the placement of this species within the Peltospiridae. Morphotypes from two localities are dark; a morphotype from a third locality is white. These different colored snails appear to be simply "varieties" of the same species, according to the results of genetic analysis.

Distribution

The scaly-foot gastropod is a vent-endemic gastropod known only from the deep-sea hydrothermal vents of the Indian Ocean, which are around in depth. The species was discovered in 2001, living on the bases of black smokers in the Kairei hydrothermal vent field,, on the Central Indian Ridge, just north of the Rodrigues Triple Point. The species has subsequently also been found in the Solitaire field,, Central Indian Ridge, within the Exclusive Economic Zone of Mauritius and Longqi field,, Southwest Indian Ridge. Longqi field was designated as the type locality; all type material originated from this vent field. The distance between Kairei and Solitaire is about. The distance between Solitaire and Longqi is about. These three sites belong to the Indian Ocean biogeographic province of hydrothermal vent systems sensu Rogers et al.. The distance between sites is large, but the total distribution area is very small, less than.
Peltospiridae snails are mainly known to live in Eastern Pacific vent fields. Nakamura et al. hypothetized that the occurrence of scaly-foot gastropods in the Indian Ocean suggests a relationship of the hydrothermal vent faunas between these two areas.
Research expeditions have included:

Sclerites

In this species, the sides of the snail's foot are extremely unusual, in that they are armoured with hundreds of iron-mineralised sclerites; these are composed of iron sulfides greigite and pyrite. Each sclerite has a soft epithelial tissue core, a conchiolin cover, and an uppermost layer containing pyrite and greigite. Prior to the discovery of the scaly-foot gastropod, it was thought that the only extant molluscs possessing scale-like structures were in the classes Caudofoveata, Solenogastres and Polyplacophora. Sclerites are not homologous to a gastropod operculum. The sclerites of scaly-foot gastropods are also not homologous to the sclerites found in chitons. It has been hypothesized that the sclerites of Cambrian halwaxiids such as Halkieria may potentially be more analogous to the sclerites of this snail than are the sclerites of chitons or aplacophorans. As recently as 2015, detailed morphological analysis for testing this hypothesis had not been carried out.
The sclerites of Chrysomallon squamiferum are mainly proteinaceous ; in contrast, the sclerites of chitons are mainly calcareous. There are no visible growth lines of conchiolin in cross-sections of sclerites. No other extant or extinct gastropods possess dermal sclerites, and no other extant animal is known to use iron sulfides in this way, either in its skeleton, or exoskeleton.
The size of each sclerite is about 1 × 5 mm in adults. Juveniles have scales in few rows, while adults have dense and asymmetric scales. The Solitaire population of snails has white sclerites instead of black; this is due to a lack of iron in the sclerites. The sclerites are imbricated. The purpose of sclerites has been speculated to be protection or detoxification. The sclerites may help protect the gastropod from the vent fluid, so that its bacteria can live close to the source of electron donors for chemosynthesis. Or alternatively, the sclerites may result from deposition of toxic sulfide waste from the endosymbionts, and therefore represent a novel solution for detoxification. But the true function of sclerites is, as yet, unknown. The sclerites of the Kairei population, which have a layer of iron sulfide, are ferrimagnetic. The non-iron-sulfide-mineralized sclerite from the Solitaire morphotype showed greater mechanical strength of the whole structure in the three-point bending stress test than did the sclerite from the Kairei morphotype.
In life, the external surfaces of sclerites host a diverse array of epibionts: Epsilonproteobacteria and Deltaproteobacteria. These bacteria probably provide their mineralization. Goffredi et al. hypothetized that the snail secretes some organic compounds that facilitate the attachment of the bacteria.

Shell

The shell of these species has three whorls. The shape of the shell is globose and the spire is compressed. The shell sculpture consists of ribs and fine growth lines. The shape of the aperture is elliptical. The apex of the shell is fragile and it is corroded in adults.
This is a very large peltospirid compared to the majority of other species, which are usually below in shell length. The width of the shell is ; the maximum width of the shell reaches. The average width of the shell of adult snails is 32 mm. The average shell width in the Solitaire population was slightly less than that in the Kairei population. The height of the shell is. The width of the aperture is. The height of the aperture is.
The snail's shell is also unusual. The shell structure consists of three layers. The outer layer is about 30 μm thick, black, and is made of iron sulfides, containing greigite Fe3S4. This feature makes this gastropod the only extant animal known so far that employs this material in its skeleton. The middle layer is equivalent to the organic periostracum which is also found in other gastropods. The periostracum is thick and brown. The innermost layer is made of aragonite, a form of calcium carbonate that is commonly found both in the shells of molluscs and in various corals. The color of the aragonite layer is milky white.
Each shell layer appears to contribute to the effectiveness of the snail's defence in different ways. The middle organic layer appears to absorb mechanical strain and energy generated by a squeezing attack, making the shell much tougher. The organic layer also acts to dissipate heat. Features of this composite material are in focus of researchers for possible use in civilian and military protective applications.

Operculum

In this species, the shape of the operculum changes during growth, from a rounded shape in juveniles to a curved shape in adults. The relative size of the operculum decreases as individuals grow. About a half of all adult snails of this species possess an operculum among the sclerites at the rear of the animal. It seems likely that the sclerites gradually grow and fully cover the whole foot for protection, and the operculum loses its protective function as the animal grows.

External anatomy

The scaly-foot gastropod has a thick snout, which tapers distally to a blunt end. The mouth is a circular ring of muscles when contracted and closed. The two smooth cephalic tentacles are thick at the base and gradually taper to a fine point at their distal tips. This snail has no eyes. There is no specialised copulatory appendage. The foot is red and large, and the snail cannot withdraw the foot entirely into the shell. There is no pedal gland in the front part of the foot. There are also no epipodial tentacles.

Internal anatomy

In Chrysomallon squamiferum, the soft parts of the animal occupy approximately two whorls of the interior of the shell. The shell muscle is horseshoe-shaped and large, divided in two parts on the left and right, and connected by a narrower attachment. The mantle edge is thick but simple without any distinctive features. The mantle cavity is deep and reaches the posterior edge of the shell. The medial to left side of the cavity is dominated by a very large bipectinate ctenidium. Ventral to the visceral mass, the body cavity is occupied by a huge esophageal gland, which extends to fill the ventral floor of the mantle cavity.
The digestive system is simple, and is reduced to less than 10% of the volume typical in gastropods. The radula is "weak", of the rhipidoglossan type, with a single pair of radular cartilages. The formula of the radula is ∼50 + 4 + 1 + 4 + ∼50. The radula ribbon is 4 mm long, 0.5 mm wide; the width to length ratio is approximately 1:10. There is no jaw, and no salivary glands. A part of the anterior oesophagus rapidly expands into a huge, hypertrophied, blind-ended esophageal gland, which occupies much of the ventral face of the mantle cavity. When the snail grows, the esophageal gland is increasing isometrically with growth. The oesophageal gland has a uniform texture, and is highly vascularised with fine blood vessels. The stomach has at least three ducts at its anterior right, connecting to the digestive gland. There are consolidated pellets in both the stomach and in the hindgut. These pellets are probably granules of sulfur produced by the endosymbiont as a way to detoxify hydrogen sulfide. The intestine is reduced, and only has a single loop. The extensive and unconsolidated digestive gland extends to the posterior, filling the shell apex of the shell. The rectum does not penetrate the heart, but passes ventral to it. The anus is located on the right side of the snail, above the genital opening.
In the excretory system, the nephridium is central, tending to the right side of the body, as a thin dark layer of glandular tissue. The nephridium is anterior and ventral of the digestive gland, and is in contact with the dorsal side of the foregut.
The respiratory system and circulatory system consist of a single left bipectinate ctenidium, which is very large, and is supported by many large and mobile blood sinuses filled with haemocoel. On dissection, the blood sinuses and lumps of haemocoel material are a prominent feature throughout the body cavity. Although the circulatory system in Chrysomallon is mostly closed, the prominent blood sinuses appear to be transient, and occur in different areas of the body in different individuals. There are thin gill filaments on either side of the ctenidium. The bipectinate ctenidium extends far behind the heart into the upper shell whorls; it is much larger than in Peltospira. Although this species has a similar shell shape and general form to other peltospirids, the ctenidium is proportional size to that of Hirtopelta, which has the largest gill among peltospirid genera that have been investigated anatomically so far.
The ctenidium provides oxygen for the snail, but the circulatory system is enlarged beyond the scope of other similar vent gastropods. There are no endosymbionts in or on the gill of C. squamiferum. The enlargement of the gill is probably to facilitate extracting oxygen in the low-oxygen conditions that are typical of hydrothermal-vent ecosystems.
At the posterior of the ctenidium is a remarkably large and well-developed heart. The heart is unusually large for any animal proportionally. Based on the volume of the single auricle and ventricle, the heart complex represents approximately 4% of the body volume. The ventricle has size 0.64 mm in juvenile animal with a shell length of 2.2 mm and the ventricle will reach size 8 mm in adults. This proportionally giant heart primarily sucks blood through the ctenidium and supplies the highly vascularised oesophageal gland. In C. squamiferum the endosymbionts are housed in an esophageal gland, where they are isolated from the vent fluid. The host is thus likely to play a major role in supplying the endosymbionts with necessary chemicals, leading to increased respiratory needs. Detailed investigation of the haemocoel of C. squamiferum will reveal further information about its respiratory pigments.
.
ct – ctenidium,
pm – pedal muscle,
sc – scales,
si – blood sinus,
te – testis.
The scale bar is 1 cm.|alt=A cross section with dark scales on its sides, a large foot in light color, a large oesophageal gland of light color inside the body. Other parts of the body are light brown.
The scaly-foot gastropod is a chemosymbiotic holobiont. It hosts thioautotrophic gammaproteobacterial endosymbionts in a much enlarged oesophageal gland, and appears to rely on these symbionts for nutrition. The closest known relative of this endosymbiont is that one from Alviniconcha snails. In this species, the size of the oesophageal gland is about two orders of magnitude larger than the usual size. There is a significant embranchment within the oesophageal gland, where the blood pressure likely decreases to almost zero. The elaborate cardiovascular system most likely evolved to oxygenate the endosymbionts in an oxygen-poor environment, and/or to supply hydrogen sulfide to the endosymbionts. Thioautotrophic gammaproteobacteria have a full set of genes required for aerobic respiration, and are probably capable of switching between the more efficient aerobic respiration, and the less efficient anaerobic respiration, depending on oxygen availability. In 2014, the endosymbiont of the scaly-foot gastropod become the first endosymbiont of any gastropod for which the complete genome was known. C. squamiferum was previously thought to be the only species of Peltospiridae that has an enlarged oesophageal gland, but later it was discovered that both species of Gigantopelta also have an enlarged oesophageal gland. Chrysomallon and Gigantopelta are the only vent animals, except siboglinid tubeworms, that house endosymbionts within an enclosed part of the body not in direct contact with vent fluid.
The nervous system is large, and the brain is a solid neural mass without ganglia. The nervous system is reduced in complexity and enlarged in size compared to other neomphaline taxa. As is typical of gastropods, the nervous system is composed of an anterior oesophageal nerve ring and two pairs of longitudinal nerve cords, the ventral pair innervating the foot and the dorsal pair forming a twist via streptoneury. The frontal part of the oesophageal nerve ring is large, connecting two lateral swellings. The huge fused neural mass is directly adjacent to, and passes through, the oeosophageal gland, where the bacteria are housed. There are large tentacular nerves projecting into the cephalic tentacles. The sensory organs of the scaly-foot gastropod include statocysts surrounded by the oesophageal gland, each statocyst with a single statolith. There are also sensory ctenidial bursicles on the tip of the gill filaments; these are known to be present in most vetigastropods, and are present some neomphalines.
The reproductive system has some unusual features. The gonads of adult snails are not inside the shell; they are in the head-foot region on the right side of the body. There are no gonads present in juveniles with shell length of 2.2 mm. Adults possess both testis and ovary in different levels of development. The testis is placed ventrally; the ovary is placed dorsally, and the nephridium lies between them. There is a "spermatophore packaging organ" next to the testis. Gonoducts from the testis and ovary are initially separate, but apparently fuse to a single duct, and emerge as a single genital opening on the right of the mantle cavity. The animal has no copulatory organ.
It is hypothetized that the derived strategy of housing endosymbiotic microbes in an oesophageal gland, has been the catalyst for anatomical innovations that serve primarily to improve the fitness of the bacteria, over and above the needs of the snail. The great enlargement of the oesophageal gland, the snail's protective dermal sclerites, its highly enlarged respiratory and circulatory systems and its high fecundity are all considered to be adaptations which are beneficial to its endosymbiont microbes. These adaptations appear to be a result of specialisation to resolve energetic needs in an extreme chemosynthetic environment.

Ecology

Habitat

This species inhabits the hydrothermal vent fields of the Indian Ocean. It lives adjacent to both acidic and reducing vent fluid, on the walls of black-smoker chimneys, or directly on diffuse flow sites.
The depth of the Kairei field varies from, and its dimensions are approximately. The slope of the field is 10° to 30°. The substrate rock is troctolite and depleted mid-ocean ridge basalt. The Kairei-field scaly-foot gastropods live in the low-temperature diffuse fluids of a single chimney. The transitional zone, where these gastropods were found, is about in width, with temperature of 2–10 °C. The preferred water temperature for this species is about 5 °C. These snails live in an environment which has high concentrations of hydrogen sulfide, and low concentrations of oxygen.
The abundance of scaly-foot gastropods was lower in the Kairei field than in the Longqi field. The Kairei hydrothermal-vent community consists of 35 taxa, including sea anemones Marianactis sp., crustaceans Austinograea rodriguezensis, Rimicaris kairei, Mirocaris indica, Munidopsis sp., Neolepadidae genus and sp., Eochionelasmus sp., bivalves Bathymodiolus marisindicus, gastropods Lepetodrilus sp., Pseudorimula sp., Eulepetopsis sp., Shinkailepas sp., and Alviniconcha marisindica, Desbruyeresia marisindica, Bruceiella wareni, Phymorhynchus sp., Sutilizona sp., slit limpet sp. 1, slit limpet sp. 2, Iphinopsis boucheti, solenogastres Helicoradomenia? sp., annelids Amphisamytha sp., Archinome jasoni, Capitellidae sp. 1, Ophyotrocha sp., Hesionoidae sp. 1, Hesionoidae sp. 2, Branchinotogluma sp., Branchipolynoe sp., Harmothoe? sp., Levensteiniella? sp., Prionospio sp., unidentified Nemertea and unidentified Platyhelminthes. Scaly-foot gastropods live in colonies with Alviniconcha marisindica snails, and there are colonies of Rimicaris kairei above them.
The Solitaire field is at a depth of, and its dimensions are approximately. The substrate rock is enriched mid-ocean ridge basalt. Scaly-foot gastropods live near the high-temperature diffuse fluids of chimneys in the vent field. The abundance of scaly-foot gastropods was lower than it was in the Longqi field. The Solitaire hydrothermal-vent community comprises 22 taxa, including: sea anemones Marianactis sp., crustaceans Austinograea rodriguezensis, Rimicaris kairei, Mirocaris indica, Munidopsis sp., Neolepadidae gen et sp., Eochionelasmus sp., bivalves Bathymodiolus marisindicus, gastropods Lepetodrilus sp., Eulepetopsis sp., Shinkailepas sp., Alviniconcha sp. type 3, Desbruyeresia sp., Phymorhynchus sp., annelids Alvinellidae genus and sp., Archinome jasoni, Branchinotogluma sp., echinoderm holothurians Apodacea gen et sp., fish Macrouridae genus and sp., unidentified Nemertea, and unidentified Platyhelminthes.
The Longqi vent field is in a depth of, and its dimensions are approximately. Chrysomallon squamiferum was densely populated in the areas immediately surrounding the diffuse-flow venting. The Longqi hydrothermal-vent community include 23 macro- and megafauna taxa: sea anemones Actinostolidae sp., annelids Polynoidae n. gen. n. sp. “655”, Branchipolynoe n. sp. “Dragon”, Peinaleopolynoe n. sp. “Dragon”, Hesiolyra cf. bergi, Hesionidae sp. indet., Ophryotrocha n. sp. “F-038/1b”, Prionospio cf. unilamellata, Ampharetidae sp. indet., mussels Bathymodiolus marisindicus, gastropods Gigantopelta aegis, Dracogyra subfuscus, Lirapex politus, Phymorhynchus n. sp. “SWIR”, Lepetodrilus n. sp. “SWIR”, crustaceans Neolepas sp. 1, Rimicaris kairei, Mirocaris indica, Chorocaris sp., Kiwa n. sp. “SWIR”17, Munidopsis sp. and echinoderm holothurians Chiridota sp. The density of Lepetodrilus n. sp. “SWIR” and scaly-foot gastropods is over 100 snails per m² in close distance from vent fluid sources at Longqi vent field.

Feeding habits

The scaly-foot gastropod is an obligate symbiotroph throughout post-settlement life. The nutrition of the scaly-foot gastropod throughout its entire post-larval life depends on the chemoautotrophy of its endosymbiotic bacteria, which provide all of its nutrition. The scaly-foot gastropod is neither filter-feeder nor uses other mechanisms for feeding. The radula consist of only 0.4% of body volume in juveniles and radula cartilages consist of 0.8% of body volume in juveniles, because they are not used for feeding anymore.
For identification of trophic interactions in a habitat, where direct observation of feeding habits is complicated, there were measured carbon and nitrogen stable-isotope compositions. There are depleted values of δ13C in the oesophageal gland. Chemoautotrophic symbionts were presumed as a source of such carbon. Chemoautotrophic origin of the stable carbon isotope 13C was confirmed experimentally.
tissueδ13Cδ15N
oesophageal gland−20.7 ± 0.9 ‰3.3 ± 1.8 ‰
gill−18.3 ± 0.6 ‰, from −17.4 to −18.8 ‰3.9 ± 0.6 ‰, from 3.1 to 4.2 ‰
mantlefrom −17.5 to −18.6 ‰from 3.5 to 4.7 ‰
foot−18.2 ± 0.6 ‰3.8 ± 0.5 ‰
scales−16.7 ± 0.6 ‰3.8 ± 0.9 ‰

Life cycle

This gastropod is a simultaneous hermaphrodite. It is the only species in the family Peltospiridae that is so far known to be a simultaneous hermaphrodite. It has a high fecundity. It lays eggs that are probably of lecithotrophic type. Eggs of the scaly-foot gastropods show negative buoyancy under atmospheric pressure. Neither the larvae nor the protoconch is known as of 2016, but it is thought that the species has a planktonic dispersal stage. The smallest Chrysomallon squamiferum juvenile specimens ever collected had a shell length 2.2 mm. The results of statistical analyses revealed no genetic differentiation between the two populations in the Kairei and Solitaire fields, suggesting potential connectivity between the two vent fields. The Kairei population represents a potential source population for the two populations in the Central Indian Ridge. These snails are difficult to keep alive in an artificial environment, however, they survived in aquaria at atmospheric pressure for more than three weeks.

Conservation measures and threats

Scaly-foot gastropod is not protected. Its total distribution area has been estimated to be at most 0.27 km2, restricted to three reported localities, between which only negligible migration occurs. Hydrothermal vents in Southwest Indian Ridge are slow spreading and its communities are considered more sensitive to disturbances and with slow recovery rate. This species is at risk of potential environmental damage of deep sea mining. Commercial mining exploration license to area of Kairei has been granted by International Seabed Authority to Germany from 2015 to 2030. Commercial mining exploration license to area of Longqi has been granted to China from 2011 to 2026. It has been listed as endangered species in the IUCN Red List of Threatened Species at July 4, 2019.