Aquatic locomotion

Swimming is biologically propelled motion through a liquid medium. Swimming has evolved a number of times in a range of organisms ranging from arthropods to fish to molluscs.

Evolution of swimming

Swimming evolved a number of times in unrelated lineages, and the evolutionary pressures leading to its adoption are unknown. Supposed jellyfish fossils occur in the Ediacaran, but the first free-swimming animals appear in the Early to Middle Cambrian. These are mostly related to the arthropods, and include the Anomalocaridids, which swam by means of lateral lobes in a fashion reminiscent of today's cuttlefish. Cephalopods joined the ranks of the nekton in the late Cambrian,^[1] and chordates were probably swimming from the Early Cambrian.^[2] Many terrestrial animals retain some capacity to swim, however some have return to the water and developed the capacities for aquatic locomotion.

Invertebrates

Among the radiata, jellyfish and their kin, the main form of swimming is to flex their cup shaped bodies. All jellyfish are free-swimming, although many of these spend most of their time swimming passively. Passive swimming is akin to gliding; the organism floats, using currents where it can, and does not exert any energy into controlling its position or motion. Active swimming, in contrast, involves the expenditure of energy to travel to a desired location.

In bilateria, there are many methods of swimming. The arrow worms (chaetognatha) undulate their finned bodies, not unlike fish. Nematodes swim by undulating their fin-less bodies. Some Arthropod groups can swim. Many crustaceans can swim. Most, such as shrimp, will usually swim by paddling with special swimming legs (pleopods), however some arthropods can also propel themselves backwards quickly by flicking their tail, known as the Caridoid escape reaction. Swimming crabs swim with modified walking legs (pereiopods). Daphnia, an crustacean, swims by beating it antenna instead.

There are also a number of forms of swimming molluscs. Many free-swimming sea slugs, such as sea angels, flap fin-like structures. Some shelled molluscs, such as scallops can breifly swim by clapping their two shells open and closed. The molluscs most evolved for swimming are the cephalopods.

Octopuses swim headfirst, with arms trailing behind

All cephalopods can move by jet propulsion, but this is a very energy-consuming way to travel compared to the tail propulsion used by fish.^[3] The relative efficiency of jet propulsion decreases further as animal size increases. Since the Paleozoic, as competition with fish produced an environment where efficient motion was crucial to survival, jet propulsion has taken a back role, with fins and tentacles used to maintain a steady velocity.^[4] The stop-start motion provided by the jets, however, continues to be useful for providing bursts of high speed - not least when capturing prey or avoiding predators.^[4] Indeed, it makes cephalopods the fastest marine invertebrates,^{[5]: Preface} and they can outaccelerate most fish.^[6] Oxygenated water is taken into the mantle cavity to the gills and through muscular contraction of this cavity, the spent water is expelled through the hyponome, created by a fold in the mantle. Motion of the cephalopods is usually backward as water is forced out anteriorly through the hyponome, but direction can be controlled somewhat by pointing it in different directions.^[7] Most cephalopods float (i.e. are neutrally buoyant), so do not need to swim to remain afloat.^[3]

Among the Deuterostomia, there are a number of swimmers as well. Feather stars can swim by undulating their many arms [1]. Salps move by pumping waters through their gelatinous bodies. The deuterosomes most evolved for swimming are found among the vertebrates, notably the fish.

Swimming in fish

See also: Fish locomotion

Some fish need to swim in order to maintain flotation; others float naturally by means of swim bladders or other organs. Swimming primarily achieves motion in a certain direction, and the method employed by fish is the most efficient for maintaining a high speed over a significant distance. The same method has been converged upon by cephalopods, who have progressively downplayed the role of jet propulsion in favour of more fish-like swimming.^[8]

Secondary evolution of swimming

While tetrapods lost many of their natural adaptations to swimming when they evolved onto the land, many have re-evolved the ability to swim or have indeed returned to a completely aquatic lifestyle.

Primarily or exclusively aquatic animals have re-evolved from terrestrial tetrapods multiple times: examples include amphibians such as newts, reptiles such as crocodiles, sea turtles, ichthyosaurs, plesiosaurs and mosasaurs, marine mammals such as whales, seals and otters, and birds such as penguins. Many species of snakes are also aquatic and live their entire lives in the water.

A dog is swimming

Even though primarily terrestrial tetrapods have lost many of their adaptations to swimming, the ability to swim has been preserved or re-developed in many of them. It may never have been completely lost.^{[citation needed]}

Examples are: Some breeds of dog swim recreationally. Umbra, a world record-holding dog, can swim 4 miles (6.4 km) in 73 minutes, placing her in the top 25% in human long-distance swimming competitions.^[9] Although most cats hate water, adult cats are good swimmers. The fishing cat is one wild species of cat that has evolved special adaptations for an aquatic or semi-aquatic lifestyle – webbed digits. Tigers and some individual jaguars are the only big cats known to go into water readily, though other big cats, including lions, have been observed swimming. A few domestic cat breeds also like swimming, such as the Turkish Van. In an unpublished research carried out 2002 at the University of Bern (Switzerland), Bender & Hirt showed that the Turkish Van has less inhibition to enter in shallow water compared to another breed, the Russian Blue. This behavior can be partially explained by the character of the Turkish Van, who seems to be more curious and enterprising than other cat breeds (see Widmer 1990).

Horses, moose, and elk are very powerful swimmers, and can travel long distances in the water. Elephants are also capable of swimming, even in deep waters. Eyewitnesses have confirmed that camels, including Dromedary and Bactrian camels, can swim,^[10] despite the fact that there is little deep water in their natural habitats.

A Labrador Retriever swimming as seen from below the surface of the water.

Both domestic and wild rabbits can swim. Domestic rabbits are sometimes trained to swim as a circus attraction. A wild rabbit famously swam in an apparent attack on U.S. President Jimmy Carter's boat when it was threatened in its natural habitat.^[11]

The Guinea pig (or cavy) is noted as having an excellent swimming ability.^[12] Mice can swim quite well. They do panic when placed in water, but many lab mice are used in the Morris water maze, a test to measure learning. When mice swim, they use their tails like flagella and kick with their legs.

Many snakes are excellent swimmers as well. Large adult anacondas spend the majority of their time in the water, and have difficulty moving on land.

Humans do not swim instinctively, but nonetheless often feel attracted to water, showing a broader range of swimming movements than other non-aquatic animals.^[13] In contrast, many monkeys can naturally swim and some, like the proboscis monkey, crab-eating macaque, and Rhesus macaque swim regularly.

Large primates other than humans generally do not like to swim. Wild chimpanzees and some gorillas will wade in very shallow water but will make no attempt to cross larger bodies of water. Orangutans don't swim instinctively but will attempt it under pressure or if learned.

Among invertebrates, a number of insect species have adaptations for aquatic life and locomotion. Examples of aquatic insects include dragonfly larvae, water boatmen, and diving beetles. There are also aquatic spiders, although they tend to prefer other modes of locomotion under water than swimming proper.

Human swimming

Main articles: Human swimming and History of swimming

Swimming has been known amongst humans since prehistoric times; the earliest record of swimming dates back to Stone Age paintings from around 7,000 years ago. Competitive swimming started in Europe around 1800 and was part of the first modern 1896 Summer Olympics in Athens, though not in a form comparable to the contemporary events. It was not until 1908 that regulations were implemented by the International Swimming Federation to produce competitive swimming.^[14]

References

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5. Marion Nixon and J.Z. Young. (2003). The brains and lives of cephalopods. New York: Oxford University Press. ISBN 0-19-852761-6.
6. By Daniel L. Gilbert, William J. Adelman, John M. Arnold Contributor Daniel L. Gilbert, John M. Arnold (1990). Squid as Experimental Animals (illustrated ed.). Springer,. ISBN 9780306435133. {{cite book}}: |author= has generic name (help); line feed character in |author= at position 57 (help)
7. Campbell, Reece, & Mitchell, p.612
8. Attention: This template ({{cite doi}}) is deprecated. To cite the publication identified by doi:10.1111/j.1469-185X.1972.tb00975.x, please use {{cite journal}} (if it was published in a bona fide academic journal, otherwise {{cite report}} with |doi=10.1111/j.1469-185X.1972.tb00975.x instead.
9. SWIMMING DOG VIDEOS Swimming Background
10. The Straight Dope Mailbag: The Straight Dope Mailbag: Is the camel the only animal that can't swim?
11. News of the Odd - Jimmy Carter Attacked by Killer Rabbit (April 20, 1979)
12. Harkness, John E.; Wagner, Joseph E. (1995). The Biology and Medicine of Rabbits and Rodents. Williams & Wilkins. pp. 30–39. ISBN 0-683-03919-9.
13. Bender, Renato. 1999a. Die evolutionsbiologische Grundlage des menschlichen Schwimmens, Tauchens und Watens: Konvergenzforschung in den Terrestrisierungshypothesen und in der Aquatic Ape Theory. Institut für Sport und Sportwissenschaft, Universität Bern.
14. Kehm, G (2007). Olympic Swimming and Diving:Great Moments in Olympic History. The Rosen Publishing Group. pp. 14. ISBN 1404209700.