Salp Explained

A salp (plural salps, also known colloquially as “sea grape”) or salpa (plural salpae or salpas[1]) is a barrel-shaped, planktonic tunicate in the family Salpidae. It moves by contracting, thereby pumping water through its gelatinous body; it is one of the most efficient examples of jet propulsion in the animal kingdom.[2] The salp strains the pumped water through its internal feeding filters, feeding on phytoplankton.

Distribution

Salps are common in equatorial, temperate, and cold seas, where they can be seen at the surface, singly or in long, stringy colonies. The most abundant concentrations of salps are in the Southern Ocean[3] (near Antarctica), where they sometimes form enormous swarms, often in deep water, and are sometimes even more abundant than krill.[4] Since 1910, while krill populations in the Southern Ocean have declined, salp populations appear to be increasing. Salps have been seen in increasing numbers along the coast of Washington, United States.[5]

Life cycle

Salps have a complex life cycle, with an obligatory alternation of generations. Both portions of the life cycle exist together in the seas—they look quite different, but both are mostly transparent, tubular, gelatinous animals that are typically between long. The solitary life history phase, also known as an oozooid, is a single, barrel-shaped animal that reproduces asexually by producing a chain of tens to hundreds of individuals, which are released from the parent at a small size.

The chain of salps is the 'aggregate' portion of the life cycle. The aggregate individuals are also known as blastozooids; they remain attached together while swimming and feeding, and each individual grows in size. Each blastozooid in the chain reproduces sexually (the blastozooids are sequential hermaphrodites, first maturing as females, and are fertilized by male gametes produced by older chains), with a growing embryo oozooid attached to the body wall of the parent. The growing oozooids are eventually released from the parent blastozooids, and then continue to feed and grow as the solitary asexual phase, closing the life cycle of salps. The alternation of generations allows for a fast generation time, with both solitary individuals and aggregate chains living and feeding together in the sea. When phytoplankton is abundant, this rapid reproduction leads to fairly short-lived blooms of salps, which eventually filter out most of the phytoplankton. The bloom ends when enough food is no longer available to sustain the enormous population of salps. Occasionally, mushroom corals and those of the genus Heteropsammia are known to feed on salps during blooms.[6]

History

The incursion of a large number of salps (Salpa fusiformis) into the North Sea in 1920 led to a failure of the Scottish herring fishery.[7]

Oceanographic importance

A reason for the success of salps is how they respond to phytoplankton blooms. When food is plentiful, salps can quickly bud off clones, which graze on the phytoplankton and can grow at a rate which is probably faster than that of any other multicellular animal, quickly stripping the phytoplankton from the sea. But if the phytoplankton is too dense, the salps can clog and sink to the bottom. During these blooms, beaches can become slimy with mats of salp bodies, and other planktonic species can experience fluctuations in their numbers due to competition with the salps.

Sinking fecal pellets and bodies of salps carry carbon to the seafloor, and salps are abundant enough to have an effect on the ocean's biological pump. Consequently, large changes in their abundance or distribution may alter the ocean's carbon cycle, and potentially play a role in climate change.[8] [9]

Nervous systems and relationships to other animals

Salps are closely related to the pelagic tunicate groups Doliolida and Pyrosoma, as well as to other bottom-living (benthic) tunicates.

Although salps appear similar to jellyfish because of their simple body form and planktonic behavior, they are chordates: animals with dorsal nerve cords, related to vertebrates (animals with backbones).

Small fish swim inside salps as protection from predators.[10]

Classification

The World Register of Marine Species lists the following genera and species in the order Salpida:[11]

External links

Notes and References

  1. Web site: salp - Definitions from Dictionary.com. 2008-09-28.
    Peter Forsskål, in introducing the genus Salpa from waters off Yemen (1763, publication 1775), gave no derivation for his word; the English salp first appeared in 1835 (OED, "salp")
  2. 10.1111/j.1469-7998.1983.tb05071.x . 201 . 4 . Jet propulsion in salps (Tunicata: Thaliacea) . 1983 . Journal of Zoology . 481–506 . Bone . Q..
  3. Web site: Fisherman snags strange see-through, shrimp-like creature . Orlando Sentinel, www.orlandosentinel.com .
  4. Web site: Dive and Discover: Scientific Expedition 10: Antarctica. 2008-09-03.
  5. News: Odd creatures wash ashore on Washington beach. 17 February 2013. NBC. 16 February 2013.
  6. Mehrotra. R. Scott, C.M.. Hoeksema, B.W.. 2015. A large gape facilitates predation on salps by Heteropsammia corals. Marine Biodiversity . 10.1007/s12526-015-0379-8. 46. 2. 323–324. 7397182.
  7. Scottish Fisheries During the War in Book: Rural Scotland During the War . David T. Jones . Joseph F. Duncan . H.M. Conacher . W.R. Scott. 1926. Oxford University Press.
  8. Steinberg . Deborah K. . Stamieszkin . Karen . Maas . Amy E. . Durkin . Colleen A. . Passow . Uta . Estapa . Margaret L. . Omand . Melissa M. . McDonnell . Andrew M. P. . Karp‐Boss . Lee . Galbraith . Moira . Siegel . David A. . 16 December 2022 . The Outsized Role of Salps in Carbon Export in the Subarctic Northeast Pacific Ocean . Global Biogeochemical Cycles . en . 37 . 1 . 10.1029/2022GB007523 . 0886-6236 . 10078299 . 37034114.
  9. Web site: Study reveals salps play outsize role in damping global warming . 2023-09-28 . ScienceDaily . en.
  10. O’Neill . Michael Patrick . 2021-10-07 . One Great Shot: An Invisible Shield for Fish . Hakai . en.
  11. Salpida . 137214 . 20 May 2021.
  12. http://www.marinespecies.org/aphia.php?p=taxdetails&id=137227 Cyclosalpa de Blainville, 1827
  13. http://www.marinespecies.org/aphia.php?p=taxdetails&id=137228 Helicosalpa Todaro, 1902
  14. http://www.marinespecies.org/aphia.php?p=taxdetails&id=137226 Brooksia Metcalf, 1918
  15. http://www.marinespecies.org/aphia.php?p=taxdetails&id=137229 Ihlea
  16. http://www.marinespecies.org/aphia.php?p=taxdetails&id=264921 Metcalfina
  17. http://www.marinespecies.org/aphia.php?p=taxdetails&id=137231 Pegea
  18. http://www.marinespecies.org/aphia.php?p=taxdetails&id=137232 Ritteriella
  19. http://www.marinespecies.org/aphia.php?p=taxdetails&id=137233 Salpa
  20. http://www.marinespecies.org/aphia.php?p=taxdetails&id=137234 Soestia
  21. http://www.marinespecies.org/aphia.php?p=taxdetails&id=137236 Thalia
  22. http://www.marinespecies.org/aphia.php?p=taxdetails&id=137237 Thetys de Blainville, 1827
  23. http://www.marinespecies.org/aphia.php?p=taxdetails&id=137238 Traustedtia
  24. http://www.marinespecies.org/aphia.php?p=taxdetails&id=137239 Weelia Yount, 1954

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