Pacific sleeper shark explained

The Pacific sleeper shark (Somniosus pacificus) is a sleeper shark of the family Somniosidae, found in the North Pacific on continental shelves and slopes in Arctic and temperate waters between latitudes 70°N and 22°N and in at least two places in the western tropical Pacific near Palau and the Solomon Islands, from the surface to 2000m (7,000feet) deep. The first evidence of the sharks in the western tropical Pacific emerged from a National Geographic video taken near the Solomon Islands in 2015.[1] Its length is up to 4.4m (14.4feet), although it could possibly reach lengths in excess of 7m (23feet).

Feeding habits

Pacific sleeper sharks, which are thought to be both predators and scavengers, can glide through the water with little body movement and little hydrodynamic noise, making them successful stealth predators. They feed by means of suction and cutting of their prey. They have large mouths that can essentially inhale prey and their teeth cut up any pieces that are too large to swallow. They show a characteristic rolling motion of the head when feeding. Only in Alaska has the shark's diet been studied - most sharks' stomachs contain remains of giant Pacific octopus. They are also known to feed on bottom-dwelling teleost fishes, as well as soles, flounders, Alaska pollock, rockfishes, shrimps, hermit crabs, and even marine snails. Larger Pacific sleeper sharks are also found to feed on fast-swimming prey such as squids, Pacific salmon, and harbor porpoises. The diet of the Pacific sleeper shark seems to broaden as they increase in size. For example, a 3.7-m female shark found off Trinidad, California was found to have fed mostly on giant squid. Sleeper sharks found in Alaskan waters from 2to seem to feed mostly on flounder, pollock, and cephalopods, while sleeper sharks 3.3to long seem to consume teleosts and cephalopods, as well as marine mammals. A recent study in the Gulf of Alaska suggests that sleeper sharks may prey on juvenile Steller sea lions.[2]

Reproduction

Very little is known about the early life of Pacific sleeper sharks. They are believed to produce eggs that hatch inside the female's body (reproduction is ovoviviparous), but gestation time is unknown and litter sizes are thought to be about 10 pups. Its length at birth is about 42cm (17inches) or less.

Size

The average mature size is 3.65m (11.98feet) and 318-. The largest Pacific sleeper shark verified in size measured 4.4m (14.4feet) long and weighed 888kg (1,958lb), although it could possibly reach 7m (23feet) or more.[3] In 1989, an enormous Pacific sleeper shark was attracted to a bait in deep water outside Tokyo Bay, Japan, and filmed. The shark was estimated by Eugenie Clark to be about 7m (23feet) long.[4] A single unconfirmed account exists of an enormous Pacific sleeper shark that potentially measured more than 9.2m (30.2feet) long.[5] If true, this would make the species the largest extant macro-predatory shark, and the third largest shark overall after the whale shark and the basking shark.

Adaptations

Due to living in frigid depths, the sleeper shark's liver oil does not contain squalene, which would solidify into a dense, nonbuoyant mass. Instead, the low-density compounds in the sharks' liver are diacylglyceryl ethers and triacylglycerol, which maintain their fluidity even at the lowest temperatures. Also, they store very little urea in their skin (like many deep sea sharks), but like other elasmobranchs, have high concentrations of urea and trimethylamine oxide (nitrogenous waste products) in their tissues as osmoprotectants and to increase their buoyancy.[6] Trimethylamine oxide also serves to counteract the protein-destabilizing tendencies of urea[7] and pressure.[8] Its presence in the tissues of both elasmobranch and teleost fish has been found to increase with depth.[9]

Because food is relatively scarce on the deep sea floor, the sleeper shark is able to store food in its capacious stomach. The sleeper shark's jaws are able to produce a powerful bite due to their short and transverse shape. The upper jaw teeth of the sleeper shark are spike-like, while the lower jaw teeth are oblique cusps and overlapping bases. This arrangement allows grasping and sawing of food too large to swallow. Pacific sleeper sharks have a short caudal fin, which allows them to store energy for fast and violent bursts of energy to catch prey.[4]

In 2015 a pacific sleeper shark was filmed near the Solomon Islands underneath an active volcano. [10] [11]

Known predators

Sleeper sharks are preyed on by the offshore ecotype of killer whale off British Columbia.[12] In addition, like the Greenland shark, the parasitic copepod Ommatokoita elongata can often be observed consuming the shark's corneal tissue.

See also

References

General references

External links

Notes and References

  1. Claassens, L., Phillips, B., Ebert, D. A., Delaney, D., Henning, B., Nestor, V., Ililau, A., & Giddens, J. (2023). First records of the Pacific sleeper shark Somniosus cf. pacificus in the western tropical Pacific. Journal of fish biology, 10.1111/jfb.15487. Advance online publication. https://doi.org/10.1111/jfb.15487
  2. Markus Horning . Jo-Ann Mellish . amp . In cold blood: evidence of Pacific sleeper shark (Somniosus pacificus) predation on Steller sea lions (Eumetopias jubatus) in the Gulf of Alaska . 10.7755/FB.112.4.6 . 2014 . Fishery Bulletin . 112 . 4 . 297–310 . free . 2018-10-24 . 2020-05-29 . https://web.archive.org/web/20200529032441/https://ir.library.oregonstate.edu/downloads/cc08hh483 . live .
  3. Castro, José I., The Sharks of North America. Oxford University Press (2011),
  4. Web site: Martin, R. Aidan . Elasmo Research . ReefQuest . 6 May 2009 . 20 April 2013 . https://web.archive.org/web/20130420170134/http://www.elasmo-research.org/education/ecology/deepsea-pacific_sleeper.htm . live .
  5. The New World of the Oceans: Men and Oceanography
  6. Withers . P. C. . Morrison . G. . Guppy . M. . Buoyancy Role of Urea and TMAO in an Elasmobranch Fish, the Port Jackson Shark, Heterodontus portusjacksoni . Physiological Zoology . 67 . 3 . 693–705 . May 1994 . 30163765 . 10.1086/physzool.67.3.30163765 . 100989392.
  7. Bennion . B. J. . Daggett . V. . Counteraction of urea-induced protein denaturation by trimethylamine N-oxide: a chemical chaperone at atomic resolution . Proceedings of the National Academy of Sciences . 101 . 17 . 27 April 2004 . 6433–6438 . 10.1073/pnas.0308633101 . 15096583 . 404062 . 2004PNAS..101.6433B . free.
  8. Yancey . P. H. . Gerringer . M. E. . Drazen . J. C. . Rowden . A. A. . Jamieson . A. . Marine fish may be biochemically constrained from inhabiting the deepest ocean depths . Proceedings of the National Academy of Sciences . 111 . 12 . 2014-03-03 . 4461–4465 . 10.1073/pnas.1322003111 . 24591588 . 3970477 . 2014PNAS..111.4461Y . free.
  9. Treberg . J. R. . Driedzic . W. R. . Elevated levels of trimethylamine oxide in deep-sea fish: evidence for synthesis and intertissue physiological importance . Journal of Experimental Zoology . 293 . 1 . 2002-05-30 . 39–45 . 10.1002/jez.10109 . 12115917. 2002JEZ...293...39T .
  10. Web site: Mysterious sharks living INSIDE active underwater VOLCANO investigated by robots . Katie . Mansfield . 20 April 2017 . express.co.uk . 21 March 2018 . 22 March 2018 . https://web.archive.org/web/20180322015222/https://www.express.co.uk/news/world/794361/robots-investigate-sharks-living-underwater-volcano-solomon-islands . live .
  11. Web site: Rarely Seen Shark Filmed Near Underwater Volcano - National Geographic . National Geographic . 8 July 2015 . YouTube . 21 March 2018 . 14 April 2019 . https://web.archive.org/web/20190414144206/https://www.youtube.com/watch?time_continue=17&v=d79LoSLD8HU . live .
  12. Web site: Keven Drews . The Canadian Press . Killer whales feast on sharks off B.C. coast . 5 September 2011 . The Canadian Press . 5 Sep 2011 . 13 August 2013 . https://web.archive.org/web/20130813202435/http://bc.ctvnews.ca/killer-whales-feast-on-sharks-off-b-c-coast-1.692711 . live .