Vampire squid

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Vampire squid
Vampyroteuthis illustration.jpg
Scientific classification OOjs UI icon edit-ltr.svg
Domain: Eukaryota
Kingdom: Animalia
Phylum: Mollusca
Class: Cephalopoda
Order: Vampyromorphida
Family: Vampyroteuthidae
Genus: Vampyroteuthis
Chun, 1903
Species:
V. infernalis
Binomial name
Vampyroteuthis infernalis
Chun, 1903
Synonyms [1]
  • Cirroteuthis macrope Berry, 1911
  • Danateuthis schmidti Joubin, 1929
  • Hansenoteuthis lucensJoubin, 1929
  • Melanoteuthis anderseniJoubin, 1931
  • Melanoteuthis beebei Robson, 1929
  • Melanoteuthis lucensJoubin, 1912
  • Melanoteuthis schmidtiJoubin, 1929
  • Retroteuthis pacificaJoubin, 1929
  • Watasella nigra Sasaki, 1920

The vampire squid (Vampyroteuthis infernalis, lit. 'vampire squid from hell') is a small cephalopod found throughout temperate and tropical oceans in extreme deep sea conditions. [2] The vampire squid uses its bioluminescent organs and its unique oxygen metabolism to thrive in the parts of the ocean with the lowest concentrations of oxygen. It has two long retractile filaments, located between the first two pairs of arms on its dorsal side, [3] which distinguish it from both octopuses and squids, and places it in its own order, Vampyromorphida, although its closest relatives are octopods. As a phylogenetic relict, it is the only known surviving member of its order. [4]

Contents

The first specimens were collected on the Valdivia Expedition and were originally described as an octopus in 1903 by German teuthologist Carl Chun, but later assigned to a new order together with several extinct taxa.

Discovery

The vampire squid was discovered during the Valdivia Expedition (1898–1899), led by Carl Chun. Chun was a zoologist who was inspired by the Challenger Expedition, and wanted to verify that life does indeed exist below 300 fathoms (550 meters). [5] Chun later classified the vampire squid into its family, Vampyroteuthidae. [3] This expedition was funded by the German society Gesellschaft Deutscher Naturforscher und Ärzte , a group of German scientists who believed there was life at depths greater than 550 meters, contrary to the Abyssus theory. Valdivia was fitted with equipment for the collection of deep-sea organisms, as well as laboratories and specimen jars, in order to analyze and preserve what was caught. The voyage began in Hamburg, Germany, followed by Edinburgh, and then traced around the west coast of Africa. After navigating around the southern point of Africa, the expedition studied deep areas of the Indian and Antarctic Ocean. [6] Researchers had not before discovered any species from this family that could be traced back to the Cenozoic. This suggests two ideas which include, a notable preservation bias called the Lazarus effect may exist or an inaccurate determination of when vampire squids originally settled in the deep oceans. The Lazarus effect may result from the scarcity of post-Cretaceous research regions or from the reduced abundance and distribution of vampire squids. In any case, even while the search regions remain the same, it is more difficult to locate and analyze them. [7] [8]

Description

The vampire squid can reach a maximum total length around 30 cm (1 ft). Its 15-centimetre (5.9 in) gelatinous body varies in colour from velvety jet-black to pale reddish, depending on location and lighting conditions. A webbing of skin connects its eight arms, each lined with rows of fleshy spines or cirri; the inner side of this "cloak" is black. Only the distal halves (farthest from the body) of the arms have suckers. Its limpid, globular eyes, which appear red or blue, depending on lighting, are proportionately the largest in the animal kingdom at 2.5 cm (1 in) in diameter. [9] The name of the animal was inspired by its dark colour, and cloaklike webbing, [10] rather than its habits—it feeds on detritus, not blood. [11] [8]

Dorsal view Vampyroteuthis infernalis dorsal view.jpg
Dorsal view
Oral view Vampyroteuthis infernalis arms.jpg
Oral view

Mature adults have a pair of small fins projecting from the lateral sides of the mantle. These earlike fins serve as the adult's primary means of propulsion: vampire squid move through the water by flapping their fins. Their beaklike jaws are white. Within the webbing are two pouches wherein the tactile velar filaments are concealed. The filaments are analogous to a true squid's tentacles, extending well past the arms; but differ in origin, and represent the pair that was lost by the ancestral octopus.

The vampire squid is almost entirely covered in light-producing organs called photophores, capable of producing disorienting flashes of light ranging in duration from fractions of a second to several minutes. The intensity and size of the photophores can also be modulated. Appearing as small, white discs, the photophores are larger and more complex at the tips of the arms and at the base of the two fins, but are absent from the undersides of the caped arms. Two larger, white areas on top of the head were initially believed to also be photophores, but are now identified as photoreceptors.

The chromatophores (pigment organs) common to most cephalopods are poorly developed in the vampire squid. The animal is, therefore, incapable of changing its skin colour in the dramatic fashion of shallow-dwelling cephalopods, though such ability would not be useful at the lightless depths where it lives.

Habitat and adaptations

The vampire squid is an extreme example of a deep sea cephalopod, thought to reside at aphotic (lightless) depths from 600 to 900 metres (2,000 to 3,000 ft) or more. Within this region of the world's oceans is a discrete habitat known as the oxygen minimum zone (OMZ). Within the zone, the saturation of oxygen is too low to support aerobic metabolism in most complex organisms. The vampire squid is the only cephalopod able to live its entire life cycle in the minimum zone, at oxygen saturations as low as 3%.

The vampire squid's worldwide range is confined to the tropics and subtropics. [12]

To cope with life in the suffocating depths, vampire squids have developed several adaptations: Of all deep-sea cephalopods, their mass-specific metabolic rate is the lowest. Their blue blood's hemocyanin binds and transports oxygen more efficiently than in other cephalopods, [13] aided by gills with an especially large surface area. The animals have weak musculature, but maintain agility and buoyancy with little effort because of sophisticated statocysts (balancing organs akin to a human's inner ear) [14] and ammonium-rich gelatinous tissues closely matching the density of the surrounding seawater. The vampire squid's ability to thrive in OMZs also keeps it safe from apex predators that require a large amount of oxygen to live. [15]

The vampire squid possesses large eyes and optic lobes which may be an adaptation to increase sensitivity for long-ranging detection of bioluminescence and monitoring a huge water volume where density of prey and mates is low. [16]

Like many deep-sea cephalopods, the vampire squid lacks ink sacs. If disturbed, it will curl its arms up outwards and wrap them around its body, turning itself inside-out in a way, exposing spiny projections. [17] If highly agitated, it may eject a sticky cloud of bioluminescent mucus containing innumerable orbs of blue light from the arm tips. This luminous barrage, which may last nearly 10 minutes, would presumably serve to dazzle would-be predators and allow the vampire squid to disappear into the blackness without the need to swim far. The glowing ink is also able to stick to the predator, creating what is called a burglar alarm (making the vampire squid's predator more visible to secondary predators). The display is made only if the animal is very agitated, because regenerating the mucus is metabolically costly. The vampire squid also has bioluminescent organs at the end of each of its arms, using them as a lure to attract prey. The ends of squid's arms are also regenerative, so if they are bitten off, they can serve as a diversion allowing the animal to escape while its predator is distracted. [18]

Development and reproduction

Dissected adult (center) and two immature specimens Vampyroteuthis1.jpg
Dissected adult (center) and two immature specimens

Few specifics are known regarding the ontogeny of the vampire squid. Their development progresses through three morphologic forms: the very young animals have a single pair of fins, an intermediate form has two pairs, and the mature form again has one. At their earliest and intermediate phases of development, a pair of fins is located near the eyes; as the animal develops, this pair gradually disappears as the other pair develops. [19] As the animals grow and their surface area to volume ratio drops, the fins are resized and repositioned to maximize gait efficiency. Whereas the young propel themselves primarily by jet propulsion, mature adults find flapping their fins to be the most efficient means. [20] This unique ontogeny caused confusion in the past, with the varying forms identified as several species in distinct families. [21]

If hypotheses may be drawn from knowledge of other deep-sea cephalopods, the vampire squid likely reproduces slowly by way of a small number of large eggs. Ovulation is irregular and there is minimal energy devotion into the development of the gonad. [22] Growth is slow, as nutrients are not abundant at depths frequented by the animals. The vastness of their habitat and its sparse population make procreative encounters a fortuitous event. The female may store a male's hydraulically implanted spermatophore (a tapered, cylindrical satchel of sperm) for long periods before she is ready to fertilize her eggs. Once she does, she may need to brood over them for up to 400 days before they hatch. Their reproductive strategy appears to be iteroparous, which is an exception amongst the otherwise semelparous Coleoidea. [23] During their life, Coleoidea cephalopods are thought to go through only one reproductive cycle whereas vampire squid have shown evidence of multiple reproductive cycles. After releasing their eggs, new batches of eggs are formed after the female vampire squid returns to resting. This process may repeat up to, and sometimes more than, twenty times. [22] It has been hypothesized that the iteroparous lifestyle of the vampire squid has evolved with the squid's relaxed lifestyle. With iteroparity often seen in organisms with high adult survival rates, such as the vampire squid, many low-cost reproductive cycles would be expected for the species. [23]

Hatchlings are about 8 mm in length and are well-developed miniatures of the adults, with some differences. Their arms lack webbing, their eyes are smaller, and their velar filaments are not fully formed. [24] The hatchlings are transparent and survive on a generous internal yolk for an unknown period before they begin to actively feed. [24] The smaller animals frequent much deeper waters, perhaps feeding on marine snow (falling organic detritus). The mature vampire squid is also thought to be an opportunistic hunter of larger prey as fish bones, other squid flesh, and gelatinous matter has been recorded in mature vampire squid stomachs. [25]

Reproduction of the vampire squid is unlike any other coleoid cephalopod. During mating the males pass a “packet” of sperm to a female and the female accepts it and stores it in a special pouch inside her mantle. When the female is ready, she will use the packet to reproduce. The females spawn eggs in separate spawning “events” when she feels the necessity to reproduce. These spawning events happen quite far apart due to the vampire squid's low metabolic rate, meaning they take a long time to accumulate the necessary resources to spawn. This is very rare and needs further research done on it. [22]

Behavior

Juvenile vampire squid MBNMS juvenile vampire squid (49041024167).jpg
Juvenile vampire squid

What behavioral data is known has been gleaned from ephemeral encounters with remotely operated underwater vehicles (ROV); animals are often injured during capture, and survive up to two months in aquaria, although it is hypothesized that they can live for over eight years. [23] An artificial environment makes reliable observation of non-defensive behavior difficult. In May 2014, Monterey Bay Aquarium (California, United States) became the first to ever put this species on display. [26] [27]

With their long velar filaments deployed, vampire squids have been observed drifting along in the deep, black ocean currents. If the filaments contact an entity, or if vibrations impinge upon them, the animals investigate with rapid acrobatic movements. They are capable of swimming at speeds equivalent to two body lengths per second, with an acceleration time of five seconds. However, their weak muscles limit stamina considerably.

Unlike their relatives living in more hospitable climates, deep-sea cephalopods cannot afford to expend energy in protracted flight. Given their low metabolic rate and the low density of prey at such depths, vampire squids must use innovative predator avoidance tactics to conserve energy. Their aforementioned bioluminescent "fireworks" are combined with the writhing of glowing arms, erratic movements, and escape trajectories, making it difficult for a predator to identify multiple targets. The vampire squid's retractile filaments have been suggested to play a larger role in predator avoidance via both detection and escape mechanisms. [3]

In a threat response called the "pumpkin" or "pineapple" posture, the vampire squid inverts its caped arms back over the body, presenting an ostensibly larger form covered in fearsome-looking though harmless spines (called cirri). [28] The underside of the cape is heavily pigmented, masking most of the body's photophores. The glowing arm tips are clustered together far above the animal's head, diverting attack away from critical areas. If a predator were to bite off an arm tip, the vampire squid can regenerate it.

Feeding

Vampire squid have eight arms but lack feeding tentacles, and instead use two retractile filaments in order to capture food. These filaments have small hairs on them, made up of many sensory cells, that help them detect and secure their prey. They combine waste with mucus secreted from suckers to form balls of food. As sedentary generalists, they feed on detritus, including the remains of gelatinous zooplankton (such as salps, larvaceans, and medusae jellies) and complete copepods, ostracods, amphipods, and isopods, [15] [8] as well as faecal pellets of other aquatic organisms that live above. [29] Vampire squids also use a unique luring method where they purposefully agitate bioluminescent protists in the water as a way to attract larger prey for them to consume. [15]

Vampire squids have been found among the stomach contents of large, deepwater fish, including giant grenadiers, [30] and deep-diving mammals, such as whales and sea lions.

Relationships

Pyritized fossil of Vampyronassa rhodanica from the Lower Callovian of La Voulte-sur-Rhone. Vampylarge.JPG
Pyritized fossil of Vampyronassa rhodanica from the Lower Callovian of La Voulte-sur-Rhône.

The Vampyromorphida is the extant sister taxon to all octopuses. Phylogenetic studies of cephalopods using multiple genes and mitochondrial genomes have shown that the Vampyromorphida are the first group of Octopodiformes to evolutionarily diverge from all others. [31] [32] [33] The Vampyromorphida is characterized by derived characters such as the possession of photophores and of two velar filaments which are most probably modified arms. It also shares the inclusion of an internal gladius with other coleoids, including squid, and eight webbed arms with cirrate octopods.

Vampyroteuthis shares its eight cirrate arms with the Cirrata, in which lateral cirri, or filaments, alternate with the suckers. Vampyroteuthis differs in that suckers are present only on the distal half of the arms while cirri run the entire length. In cirrate octopods suckers and cirri run and alternate on the entire length. Also, a close relationship between Vampyroteuthis and the Jurassic-Cretaceous Loligosepiina is indicated by the similarity of their gladii, the internal stiffening structure. Vampyronassa rhodanica from the middle Jurassic La Voulte-sur-Rhône of France is considered as one of a vampyroteuthid that shares some characters with Vampyroteuthis. [34]

The supposed vampyromorphids from the Kimmeridgian-Tithonian (156–146 mya) of Solnhofen, Plesioteuthis prisca , Leptotheuthis gigas , and Trachyteuthis hastiformis , cannot be positively assigned to this group; they are large species (from 35 cm in P. prisca to > 1 m in L. gigas) and show features not found in vampyromorphids, being somewhat similar to the true squids, Teuthida. [35]

Conservation status

The vampire squid is currently not on any endangered or threatened species list and they have no known impact on humans. [36] Vampire squids are at increased risk for micro plastic pollution because their diet is mostly marine snow. [37] Micro plastics can cause death by decreasing feeding activity as they take up space in the digestive tract causing the animal's stomach to feel full without providing nutrients. [38]

Following an article in Rolling Stone magazine by Matt Taibbi [39] after the subprime mortgage crisis of 2008, the term "vampire squid" has been regularly used in popular culture to refer to Goldman Sachs, the American investment bank. [40] [41] [42]

Real vampire squids are shown in the "Ocean Deep" episode of Planet Earth .

Notes

  1. Philippe Bouchet (2018). "Vampyroteuthis infernalis Chun, 1903". MolluscaBase. Retrieved 19 March 2021.
  2. "Vampire Squid, Vampyroteuthis infernalis". MarineBio.org.
  3. 1 2 3 Young, Richard E. (1967). "Homology of Retractile Filaments of Vampire Squid". Science. 156 (3782): 1633–1634. Bibcode:1967Sci...156.1633Y. doi:10.1126/science.156.3782.1633. ISSN   0036-8075. JSTOR   1721610. PMID   6025124. S2CID   24349161.
  4. Yokobori, Shin-ichi; Lindsay, Dhugal J.; Yoshida, Mari; Tsuchiya, Kotaro; Yamagishi, Akihiko; Maruyama, Tadashi; Oshima, Tairo (August 2007). "Mitochondrial genome structure and evolution in the living fossil vampire squid, Vampyroteuthis infernalis, and extant cephalopods". Molecular Phylogenetics and Evolution. 44 (2): 898–910. doi:10.1016/j.ympev.2007.05.009. PMID   17596970.
  5. "The Valdivia Expedition: Carl Chun's diving into the deep sea". Senses Atlas. 2020-06-04. Retrieved 2020-10-29.
  6. "The German Deep-Sea Expedition". The Geographical Journal . 12 (5): 494–496. 1898. Bibcode:1898GeogJ..12..494.. doi:10.2307/1774523. ISSN   0016-7398. JSTOR   1774523.
  7. Košťák, Martin; Schlögl, Ján; Fuchs, Dirk; Holcová, Katarína; Hudáčková, Natalia; Culka, Adam; Fözy, István; Tomašových, Adam; Milovský, Rastislav; Šurka, Juraj; Mazuch1, Martin (February 18, 2021). "Fossil evidence for vampire squid inhabiting oxygen-depleted ocean zones since at least the Oligocene". Communications Biology. 4 (1): 216. doi:10.1038/s42003-021-01714-0. PMC   7893013 . PMID   33603225.{{cite journal}}: CS1 maint: numeric names: authors list (link)
  8. 1 2 3 Krakauer, Hannah (26 September 2012). "Vampire squid from hell eats faeces to survive depths". New Scientist . Retrieved 7 May 2018.
  9. "Introducing Vampyroteuthis infernalis, the vampire squid from Hell". The Cephalopod Page. Dr. James B. Wood. Retrieved 27 April 2012.
  10. "The vampire squid and the vampire fish". National Ocean Service. Retrieved 22 December 2023.
  11. "Vampyroteuthis infernalis, Deep-sea Vampire squid". The Cephalopod Page. Dr. James B. Wood. Retrieved 3 July 2011.
  12. "Vampyroteithis infernalis". Animal Diversity Web. University of Michigan. Retrieved 5 March 2021.
  13. Seibel et al. 1999.
  14. Stephens & Young 2009.
  15. 1 2 3 Hoving & Robison 2012.
  16. Chung, Wen-Sung; Kurniawan, Nyoman D.; Marshall, N. Justin (2021-11-18). "Comparative brain structure and visual processing in octopus from different habitats". Current Biology. 32 (1): 97–110.e4. doi: 10.1016/j.cub.2021.10.070 . ISSN   0960-9822. PMID   34798049. S2CID   244398601.
  17. Monterey Bay Aquarium Research Institute (MBARI) (26 September 2012). "What the vampire squid really eats". Archived from the original on 2021-12-12 via YouTube.
  18. Robison et al. 2003.
  19. Pickford 1949.
  20. Seibel, Thuesen & Childress 1998.
  21. Young 2002.
  22. 1 2 3 Henk-Jan, Hoving (20 April 2015). "Vampire squid reproductive strategy is unique among coleoid cephalopods". Current Biology. 25 (8): R322–R323. doi: 10.1016/j.cub.2015.02.018 . PMID   25898098.
  23. 1 2 3 Hoving, Laptikhovsky & Robison 2015.
  24. 1 2 Young, R. E. (1998). "Morphological Observations On A Hatchling And A Paralarva Of The Vampire Squid, Vampyroteuthis Infernalis Chun (Mollusca : Cephalopoda)". Proceedings of the Biological Society of Washington. 112: 661–666. Retrieved 2020-02-09 via biostor.org.
  25. Golikov, A. V. (2019). "The first global deep-sea stable isotope assessment reveals the unique trophic ecology of Vampire Squid Vampyroteuthis infernalis (Cephalopoda)". Nature. 9 (1): 19099. Bibcode:2019NatSR...919099G. doi:10.1038/s41598-019-55719-1. PMC   6910912 . PMID   31836823.
  26. "World's first vampire squid on display at Monterey Bay Aquarium". KION News . 1 May 2014. Retrieved 31 May 2014.
  27. Adams, J. (5 May 2000). "First ever vampire squid goes on display at the Monterey Bay Aquarium". ReefBuilders. Retrieved 31 May 2014.
  28. "Vampire Squid Turns "Inside Out"". National Geographic. 4 February 2010. Retrieved 3 June 2011.
  29. "Vampyrotheuthis infernalis (Vampire Squid)" (PDF). Sta.uwi.edu. Retrieved 24 May 2022.
  30. Drazen, Jeffrey C; Buckley, Troy W; Hoff, Gerald R (2001). "The feeding habits of slope dwelling macrourid fishes in the eastern North Pacific". Deep-Sea Research Part I: Oceanographic Research Papers. 48 (3): 909–935. Bibcode:2001DSRI...48..909D. doi:10.1016/S0967-0637(00)00058-3.
  31. Uribe, Juan E.; Zardoya, Rafael (May 1, 2017). "Revisiting the phylogeny of Cephalopoda using complete mitochondrial genomes". Journal of Molluscan Studies. 83 (2): 133–144. doi: 10.1093/mollus/eyw052 . hdl: 10261/156228 via academic.oup.com.
  32. Lindgren, Annie R.; Pankey, Molly S.; Hochberg, Frederick G.; Oakley, Todd H. (July 28, 2012). "A multi-gene phylogeny of Cephalopoda supports convergent morphological evolution in association with multiple habitat shifts in the marine environment". BMC Evolutionary Biology. 12 (1): 129. doi: 10.1186/1471-2148-12-129 . PMC   3733422 . PMID   22839506.
  33. Strugnell, Jan; Nishiguchi, Michele K. (November 1, 2007). "Molecular phylogeny of coleoid cephalopods (Mollusca: Cephalopoda) inferred from three mitochondrial and six nuclear loci: a comparison of alignment, implied alignment and analysis methods". Journal of Molluscan Studies. 73 (4): 399–410. doi: 10.1093/mollus/eym038 .
  34. Rowe, Alison J.; Kruta, Isabelle; Landman, Neil H.; Villier, Loïc; Fernandez, Vincent; Rouget, Isabelle (2022-06-23). "Exceptional soft-tissue preservation of Jurassic Vampyronassa rhodanica provides new insights on the evolution and palaeoecology of vampyroteuthids". Scientific Reports. 12 (1): 8292. Bibcode:2022NatSR..12.8292R. doi: 10.1038/s41598-022-12269-3 . ISSN   2045-2322. PMC   9225997 . PMID   35739131.
  35. Fischer & Riou 2002.
  36. "Vampire Squid". Marine Life. The MarineBio Conservation Society. Retrieved 5 March 2021.
  37. Ferreira, Guilherme; Justino, Anne; Eduardo, Leandro; Lenoble, Véronique; Fauvelle, Vincent; Schmidt, Natascha; Vaske, Teodoro; Frédou, Thierry; Lucena-Frédou, Flávia (January 2022). "Plastic in the inferno: Microplastic contamination in deep-sea cephalopods (Vampyroteuthis infernalis and Abralia veranyi) from the southwestern Atlantic". Marine Pollution Bulletin. 174: 113309. Bibcode:2022MarPB.17413309F. doi:10.1016/j.marpolbul.2021.113309. PMID   35090293. S2CID   246387973.
  38. Zolotova, Natalia; Kosyreva, Anna; Dzhalilova, Dzhuliia; Fokichev, Nikolai; Makarova, Olga (Jun 14, 2022). "Harmful effects of the microplastic pollution on animal health: a literature review". PeerJ. 10: e13503. doi: 10.7717/peerj.13503 . PMC   9205308 . PMID   35722253.
  39. Taibbi, Matt (5 April 2010). "The Great American Bubble Machine". Rolling Stone. Retrieved 25 February 2021.
  40. Zamansky, Jake (8 August 2013). "The Great Vampire Squid Keeps On Sucking". Forbes. Retrieved 25 February 2021.
  41. English, Simon (9 January 2020). "Goldman Sachs: the death of the vampire squid". The Evening Standard. Retrieved 25 February 2021.
  42. Blackhurst, Chris (7 February 2020). "Goldman Sachs is still the 'giant vampire squid': When will it decide to change?". The Independent . Retrieved 25 February 2021.

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Taningia danae, the Dana octopus squid, is a species of squid in the family Octopoteuthidae. It is one of the largest known squid species, reaching a mantle length of 1.7 m (5.6 ft) and total length of 2.3 m (7.5 ft). The largest known specimen, a mature female, weighed 161.4 kg (356 lb).

<i>Gonatus onyx</i> Species of squid

The Gonatus onyx is in the class Cephalopoda, in the phylum Mollusca. It is also known as the Clawed arm hook squid or the Black-eyed squid. It got these names from the characteristic black eye and from its two arms with clawed hooks on the end that extend a bit further than the other arms. It is a squid in the family Gonatidae, found most commonly in the northern Pacific Ocean from Japan to California. They are one of the most abundant cephalopods off the coast of California, mostly found at deeper depths, rising during the day most likely to feed.

<i>Vampyronassa</i> Extinct genus of molluscs

Vampyronassa rhodanica is an extinct vampyromorph cephalopod known from around 20 fossils from the Lower Callovian of La Voulte-sur-Rhône, Ardèche, France.

<i>Stauroteuthis syrtensis</i> Species of octopus

Stauroteuthis syrtensis, also known as the glowing sucker octopus or bioluminescent octopus, is a species of small pelagic octopus found at great depths in the north Atlantic Ocean. It is one of a very small number of octopuses to exhibit bioluminescence.

<span class="mw-page-title-main">Counter-illumination</span> Active camouflage using light matched to the background

Counter-illumination is a method of active camouflage seen in marine animals such as firefly squid and midshipman fish, and in military prototypes, producing light to match their backgrounds in both brightness and wavelength.

<span class="mw-page-title-main">Gladius (cephalopod)</span> Bodypart of certain cephalopods

The gladius, or pen, is a hard internal bodypart found in many cephalopods of the superorder Decapodiformes and in a single extant member of the Octopodiformes, the vampire squid. It is so named for its superficial resemblance to the Roman short sword of the same name, and is a vestige of the ancestral mollusc shell, which was external. The gladius is located dorsally within the mantle and usually extends for its entire length. Composed primarily of chitin, it lies within the shell sac, which is responsible for its secretion.

<span class="mw-page-title-main">Cephalopod fin</span>

Cephalopod fins, sometimes known as wings, are paired flap-like locomotory appendages. They are found in ten-limbed cephalopods as well as in the eight-limbed cirrate octopuses and vampire squid. Many extinct cephalopod groups also possessed fins. Nautiluses and the more familiar incirrate octopuses lack swimming fins. An extreme development of the cephalopod fin is seen in the bigfin squid of the family Magnapinnidae.

<i>Histioteuthis heteropsis</i> Species of squid

Histioteuthis heteropsis, also known as the strawberry squid, is a species of small cock-eyed squid. The scientific nomenclature of these squid stems from their set of differently sized eyes, one being small and blue and the other being large and yellow. It is thought that the large eye is used to see objects against dim light, while the smaller eye is more able to view bioluminescent light sources. The squid's vernacular name arose due to its rich red skin pigmentation and the presence of photophores along its body, making it appear like a strawberry with seeds.

<i>Valdivia</i> Expedition 1898–99 oceanographic expedition by the German Empire

The Valdivia Expedition, or Deutsche Tiefsee-Expedition, was a scientific expedition organised and funded by the German Empire under Kaiser Wilhelm II and was named after the ship which was bought and outfitted for the expedition, the SS Valdivia. It was led by the marine biologist Carl Chun and the expedition ran from 1898-1899 with the purpose of exploring the depths of the oceans below 500 fathoms, which had not been explored by the earlier Challenger Expedition.

Richard E. Young is a teuthologist. He is an Emeritus Professor of Oceanography at the University of Hawaii's School of Ocean and Earth Science and Technology.

Histioteuthis meleagroteuthis is a species of small to medium squids that have a dark, wine-red skin pigment. Females at maturity average at 114 mm (4.5 in) in length, while males at maturity average at 65 to 102 mm in length. This species is characterized by tubercles, photophores, and asymmetric features. This species can be found in circumglobal, mesopelagic waters.

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