Sea turtle migration

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The green sea turtle migrates between its nesting sites and its coastal foraging areas. Total internal reflection of Chelonia mydas.jpg
The green sea turtle migrates between its nesting sites and its coastal foraging areas.

Sea turtle migration is the long-distance movements of sea turtles (superfamily Chelonioidea) notably the long-distance movement of adults to their breeding beaches, but also the offshore migration of hatchings. Sea turtle hatchings emerge from underground nests and crawl across the beach towards the sea. They then maintain an offshore heading until they reach the open sea. [1] The feeding and nesting sites of adult sea turtles are often distantly separated meaning some must migrate hundreds or even thousands of kilometres. [2]

Contents

Several main patterns of adult migration have been identified. [3] Some such as the green sea turtle shuttle between nesting sites and coastal foraging areas. The loggerhead sea turtle uses a series of foraging sites. Others such as the leatherback sea turtle and olive ridley sea turtle do not show fidelity to any specific coastal foraging site. Instead, they forage in the open sea in complex movements apparently not towards any goal. Although the foraging movements of leatherbacks seem to be determined to a large part by passive drift with the currents, they are still able to return to specific sites to breed. The ability of adult sea turtles to travel to precise targets has led many to wonder about the navigational mechanisms. Some have suggested that juvenile and adult turtles might use the Earth's magnetic field to determine their position. There is evidence for this ability in juvenile green sea turtles. [4]

Physiological and Behavioral Aspects of Sea Turtle Migration

Sea turtles are known to migrate long distances up to 10,000 miles or more per year. [5] During this time of travel, there is movement between breeding, foraging, and overwintering sites. Migration begins at the time of hatching. Hatchlings begin to migrate to open waters after emerging from their nest. Juvenile and adult sea turtles engage in seasonal migration, likely due to finding other thermal habitats and seeking areas with sufficient food availability. [6] Sea turtles will move north during spring and summer seasons to more nutrient rich bodies of water. In fall and winter seasons, they will migrate back in a southward direction. [5]

Loggerhead Sea Turtle Loggerhead sea turtle.jpg
Loggerhead Sea Turtle

Sea turtles are considered ectothermic non-avian reptiles. Temperature plays a major affect on both metabolic and physiological process of the turtle. [7] During sea turtle migration, it has been shown that there is a correlation between activity levels and VO2 within the turtles. Previous research concludes that VO2 levels are higher when in migration rather than in rest. [6] The size of the turtles also have an effect on aerobic metabolism levels. A previous study indicated that as body size of the sea turtles increased, so did the capacity for aerobic activity. [8] The higher capacity of aerobic activity is effective when traveling long distances. The research team concluded that the migrations done by the sea turtles are helpful in regulating temperatures, which overall increases their aerobic metabolic activity.

The following navigational methods of sea turtle migration help to increase the fitness benefits of the sea turtle. The turtles use these cues to travel into deeper waters for more a higher abundance of food and a lower risk of predation. For sea turtles who are endangered, finding an area of lower predation helps to maximize their overall fitness and keep them as an existent species. [9] For female sea turtles, traveling back to their natal beach in order to lay their offspring has been hypothesized to have an advantage towards parasitic resistance and disease. [10] This advantage also increases the fitness of the sea turtle along with its offspring.

Hatchling migration

Hatchling Loggerhead Sea Turtles migrating towards the ocean Hatchling Loggerhead Sea Turtles near Atlit Israel.jpg
Hatchling Loggerhead Sea Turtles migrating towards the ocean

Efficient movement of hatchlings away from the beach and shallow coastal waters is important in reducing the length of time that they are vulnerable to predators, which target the hatchlings on the beach or in shallow waters. [1] Therefore, sea turtle hatchlings move offshore as an innate behaviour. The first part of the hatchling migration is called the 'frenzy period' which involves almost continuous swimming for the first 24–36 hours. [11]

Orientation and navigation

Studies of loggerhead and leatherback hatchlings have shown that moonlight reflected from the sea is an important visual cue in guiding movement from the beach to the sea. [1] This navigational mechanism becomes a handicap if nesting sites are affected by artificial lighting since this can mean that hatchlings head towards the artificial lights rather than offshore towards the moonlit sea. [12] Hence, the use of moonlight by turtle hatchings as a navigational cue can be considered an 'evolutionary trap'. Loggerhead and green turtles can detect the orbital movement of waves and use this information to swim perpendicular to the waves crests. This means they swim offshore, since close to the shore, wave crests run parallel to the beach. Further offshore the Earth's magnetic field is used to maintain an offshore direction and therefore head towards the open sea. [1]

The ability to head in a given direction without reference to landmarks, is called a compass mechanism and where magnetic cues are used to achieve this it is called a 'magnetic compass'. [13] Hatchling loggerheads mature within the North Atlantic Gyre and it is important that they stay within this current system since here water temperatures are benign. It has been shown that loggerheads use the magnetic field to stay within the gyre. For example, when exposed to fields characteristic of a region at the edge of the gyre they responded by orienting in a direction which would keep them within the gyre. [14] These responses are inherited rather than learned since the hatchlings tested were captured before reaching the ocean. Adult turtles may learn aspects of the magnetic field and use this to navigate in a learned rather than innate way. [15]

Post-hatchling migration

Juveniles often reside in coastal feeding grounds, as with green sea turtles and loggerheads. Adult sea turtles can be divided into 3 categories according to their movements. [2] Leatherbacks and olive ridley turtles roam widely and unpredictably before returning to specific breeding sites. Satellite tracking of leatherbacks showed that they tended to stay within relatively food-rich areas of the ocean during their migration. [16] Kemp's ridley sea turtles, loggerheads and flatback sea turtles migrate between breeding areas and a series of coastal foraging areas. Green sea turtles and hawksbill sea turtles shuttle between fixed foraging and nesting sites. Both species of ridley sea turtle nest in large aggregations, arribadas. [17] This is thought to be an anti-predator adaptation — there are simply too many eggs for the predators to consume. One unifying aspect of sea turtle migrations is their ability to return to specific nesting sites over vast areas of ocean year after year. They may return to the beach where they hatched, an ability called natal philopatry; this has been demonstrated in green turtles using mitochondrial DNA analysis. [2]

The precision migration of adults across featureless and dynamic oceans requires more than a compass mechanism, something Darwin pointed out in 1873: [18] "Even if we grant animals a sense of the points of the compass ... how can we account for [green sea turtles] finding their way to that speck of land in the midst of the great Atlantic Ocean" [of the migration of green sea turtles from the coast of Brazil to Ascension Island, a journey of 2200 km to an island only 20 km in diameter]. An error in heading of only a few degrees would lead a turtle to miss the island by almost 100 km and animal compass analogues are not thought to be this precise. Moreover, a compass mechanism does not correct for current displacement since there is no position-fix. [19]

Some have suggested that turtles use aspects of the Earth's magnetic field to gauge their position and in this way they could correct for displacement by currents or by an experimenter. [20]

Green sea turtles

Green Sea Turtle grazing seagrass Green Sea Turtle grazing seagrass.jpg
Green Sea Turtle grazing seagrass

The post-nesting migration of adult female green sea turtles from Ascension Island to Brazil has been recorded using satellite transmitters as part of an experiment into their navigation. [21] In addition to the transmitters, some turtles were fitted with magnets which were expected to disrupt any ability to use the Earth's field for navigation. There was no difference in migratory performance between these turtles and turtles which were not carrying magnets, but the experimental design has been criticised. [22] There is strong evidence that green turtles are sensitive to magnetic cues. For example, juvenile green turtles exposed to fields north and south of a capture site (i.e. displaced in geomagnetic but not geographical space) oriented in a direction that would have led them back to the capture site, suggesting that they can use the earth's magnetic field to acquire positional information. Adult turtles also use magnetic cues. [23] Whilst geomagnetic cues may guide navigation over long distances, close to the goal, it is thought that turtles use wind-borne cues emanating from the goal to home in on their target. [24] Juvenile greens can orient using a 'sun compass'. [25] In other words, they can use directional information to determine their headings.

[9] Turtle navigational skills for migrations remain unknown. There are several hypotheses including astronomical cues and the Earth's magnetic field. [26] There is evidence that sea turtles do use a navigational compass such as bicoordinate mapping or geomagnetic imprinting when making long migrations. The following navigational methods of sea turtle migration help to increase the fitness benefits of the sea turtle. The turtles use these cues to travel into deeper waters for more a higher abundance of food and a lower risk of predation. For sea turtles who are endangered, finding an area of lower predation helps to maximize their overall fitness and keep them as an existent species.

The astronomical cue hypothesis is unsupported by scientific evidence. These cues would include light from the Sun, Moon, and stars. [21] If sea turtles used astronomical cues, they would not be able to navigate in waters where light does not attenuate well, on cloudy days or when the Moon is blocked by clouds. [21] The Moon is not a good astronomical cue because there is a new moon every 28 days. Narrowing out the astronomical hypothesis, the use of Earth's magnetic fields can be viewed as the navigational tool for long-migration patterns of sea turtles.

Earth's magnetic field is used for migration for a wide variety of species including bacteria, mollusks, arthropods, mammals, birds, reptiles, and amphibians. [27] In order to understand the Earth's magnetic fields, the Earth can be viewed as a large magnet. As a typical magnet has a north and south end, so does the Earth. The north pole magnet is located at the Earth's north pole and the south pole magnet is located at the Earth's south pole. From this north and south pole span magnetic fields. The magnetic field leaves the poles and curves around the Earth until it reaches the opposite pole. [28]

Earths magnetic field schematic Earth's magnetic field, schematic.png
Earths magnetic field schematic

In regards to the magnetic field hypothesis, there are three main concepts. The concepts include electromagnetic induction, magnetic field chemical reactions, and magnetite. In regards to electromagnetic induction, it is assumed that the sea turtles have electroreceptors. Although evidence has been found in other species such as rays and sharks, no evidence has shown that there are electroreceptors in sea turtles making this hypothesis invalid. A second concept from the experimentation by Irwin involves chemical reactions commonly found in newts and birds. The strength of the magnetic field affects the chemical reactions within the bodies of the newts and birds. The final concept includes the magnetic crystals that form during the magnetic pulses from the Earth's magnetic fields. These magnetic crystals formed by magnetite give the turtles directional information and guides in migration. The magnetite affects the cells of the nervous system of the sea turtle by producing a signal that references the forces of the magnetic field and the direction and magnitude that is applied. [29] If this magnetite is used in the migration, when the Earth's magnetic poles reverse at the dipole moment, the signal that the sea turtle nervous system receives will change the migration direction. [29] Regardless of the hypothesis, hatchling turtles have the ability to determine the direction and inclination angle of which they are swimming with aide from magnetic fields. [14]

Bicoordinate Mapping

Bicoordinate mapping has also been hypothesized as a method of travel for sea turtles along with longitudinal direction. [30] Bicoordinate mapping is defined as a geomagnetic map that depends on both the intensity and inclination of the magnetic field. [31] Changes within the intensity or inclination of the Earth's magnetic field can deter a sea turtles direction of travel, so it is important for geographical coordinates to play a role in open-sea migration. It has been shown that when placed into areas with the same latitudinal but different longitudinal coordinates, sea turtles are able to continue traveling in the same magnetic direction they began in. [31] The conclusion is formed that sea turtles may inherit a bicoordinate map to follow that does not coordinate with specific latitudinal or longitudinal points, but helps for the turtle to maintain a constant direction of travel. [30]

Geomagnetic Imprinting

Sea Turtle laying eggs at designated natal beach Green sea turtle laying eggs (4202525004).jpg
Sea Turtle laying eggs at designated natal beach

Geomagnetic imprinting is done by the use of inclination angle and field intensity to imprint onto the magnetic fields of the sea turtles natal homes. Imprinting is an innate learning process that is inherited within species to recognize important landmarks and resources. The use of geomagnetic imprinting helps the sea turtles to navigate back in later timelines. This process is not only used in sea turtles, but can also be seen in fish such as Salmo Salar (Atlantic salmon) and Bird migration. This method of navigation is important for female sea turtles, as it has been proven that they will return to their natal beaches to lay their own eggs. [32] Intensity and inclination of the magnetic field depend on latitude, which is helpful in navigating the turtles north or south. [33] This makes it easier for the turtles to follow along the coastline that is most related to their natal beach, [32] ultimately guiding them back. Previous research concluded that returning to the natal beach in order to lay offspring is an advantage towards parasitic resistance and disease, which overall increases the fitness of the turtles. [10]

Related Research Articles

<span class="mw-page-title-main">Turtle</span> Order of reptiles characterized by a shell

Turtles are reptiles of the order Testudines, characterized by a special shell developed mainly from their ribs. Modern turtles are divided into two major groups, the Pleurodira and Cryptodira, which differ in the way the head retracts. There are 360 living and recently extinct species of turtles, including land-dwelling tortoises and freshwater terrapins. They are found on most continents, some islands and, in the case of sea turtles, much of the ocean. Like other amniotes they breathe air and do not lay eggs underwater, although many species live in or around water.

<span class="mw-page-title-main">Sea turtle</span> Reptiles of the superfamily Chelonioidea

Sea turtles, sometimes called marine turtles, are reptiles of the order Testudines and of the suborder Cryptodira. The seven existing species of sea turtles are the flatback, green, hawksbill, leatherback, loggerhead, Kemp's ridley, and olive ridley. Six of the seven sea turtle species, all but the flatback, are present in U.S. waters, and are listed as endangered and/or threatened under the Endangered Species Act. All but the flatback turtle are listed as threatened with extinction globally on the IUCN Red List of Threatened Species. The flatback turtle is found only in the waters of Australia, Papua New Guinea, and Indonesia.

<span class="mw-page-title-main">Earth's magnetic field</span> Magnetic field that extends from the Earths outer and inner core to where it meets the solar wind

Earth's magnetic field, also known as the geomagnetic field, is the magnetic field that extends from Earth's interior out into space, where it interacts with the solar wind, a stream of charged particles emanating from the Sun. The magnetic field is generated by electric currents due to the motion of convection currents of a mixture of molten iron and nickel in Earth's outer core: these convection currents are caused by heat escaping from the core, a natural process called a geodynamo.

<span class="mw-page-title-main">Leatherback sea turtle</span> Species of marine reptile in the family Chelonioidea

The leatherback sea turtle, sometimes called the lute turtle, leathery turtle or simply the luth, is the largest of all living turtles and the heaviest non-crocodilian reptile, reaching lengths of up to 2.7 metres and weights of 500 kilograms (1,100 lb). It is the only living species in the genus Dermochelys and family Dermochelyidae. It can easily be differentiated from other modern sea turtles by its lack of a bony shell; instead, its carapace is covered by oily flesh and flexible, leather-like skin, for which it is named. Leatherback turtles have a global range, although there are multiple distinct subpopulations. The species as a whole is considered vulnerable, and some of its subpopulations are critically endangered.

<span class="mw-page-title-main">Salmon run</span> Annual migration of salmon

A salmon run is an annual fish migration event where many salmonid species, which are typically hatched in fresh water and live most of the adult life downstream in the ocean, swim back against the stream to the upper reaches of rivers to spawn on the gravel beds of small creeks. After spawning, all species of Pacific salmon and most Atlantic salmon die, and the salmon life cycle starts over again with the new generation of hatchlings.

<span class="mw-page-title-main">Magnetoreception</span> Biological ability to perceive magnetic fields

Magnetoreception is a sense which allows an organism to detect the Earth's magnetic field. Animals with this sense include some arthropods, molluscs, and vertebrates. The sense is mainly used for orientation and navigation, but it may help some animals to form regional maps. Experiments on migratory birds provide evidence that they make use of a cryptochrome protein in the eye, relying on the quantum radical pair mechanism to perceive magnetic fields. This effect is extremely sensitive to weak magnetic fields, and readily disturbed by radio-frequency interference, unlike a conventional iron compass.

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

In oviparous biology, a hatchling is a newly hatched fish, amphibian, reptile, or bird. A group of mammals called monotremes lay eggs, and their young are hatchlings as well.

<span class="mw-page-title-main">Loggerhead sea turtle</span> Species of marine reptile distributed throughout the world

The loggerhead sea turtle is a species of oceanic turtle distributed throughout the world. It is a marine reptile, belonging to the family Cheloniidae. The average loggerhead measures around 90 cm (35 in) in carapace length when fully grown. The adult loggerhead sea turtle weighs approximately 135 kg (298 lb), with the largest specimens weighing in at more than 450 kg (1,000 lb). The skin ranges from yellow to brown in color, and the shell is typically reddish brown. No external differences in sex are seen until the turtle becomes an adult, the most obvious difference being the adult males have thicker tails and shorter plastrons than the females.

<span class="mw-page-title-main">Green sea turtle</span> Species of large sea reptile

The green sea turtle, also known as the green turtle, black (sea) turtle or Pacific green turtle, is a species of large sea turtle of the family Cheloniidae. It is the only species in the genus Chelonia. Its range extends throughout tropical and subtropical seas around the world, with two distinct populations in the Atlantic and Pacific Oceans, but it is also found in the Indian Ocean. The common name refers to the usually green fat found beneath its carapace, not to the color of its carapace, which is olive to black.

A geomagnetic reversal is a change in a planet's magnetic field such that the positions of magnetic north and magnetic south are interchanged. The Earth's field has alternated between periods of normal polarity, in which the predominant direction of the field was the same as the present direction, and reverse polarity, in which it was the opposite. These periods are called chrons.

<span class="mw-page-title-main">Animal migration</span> Periodic large-scale movement of animals, usually seasonal

Animal migration is the relatively long-distance movement of individual animals, usually on a seasonal basis. It is the most common form of migration in ecology. It is found in all major animal groups, including birds, mammals, fish, reptiles, amphibians, insects, and crustaceans. The cause of migration may be local climate, local availability of food, the season of the year or for mating.

Natal homing, or natal philopatry, is the homing process by which some adult animals that have migrated away from their juvenile habitats return back to their birthplace to reproduce. This process is primarily used by aquatic animals such as sea turtles and salmon, although some migratory birds and mammals also practice similar reproductive behaviors. Scientists believe that the main cues used by the animals are geomagnetic imprinting and olfactory cues. The benefits of returning to the precise location of an animal's birth may be largely associated with its safety and suitability as a breeding ground. When seabirds like the Atlantic puffin return to their natal breeding colony, which are mostly on islands, they are assured of a suitable climate and a sufficient lack of land-based predators.

<span class="mw-page-title-main">Homing (biology)</span> Ability of an animal to navigate towards an original location

Homing is the inherent ability of an animal to navigate towards an original location through unfamiliar areas. This location may be either a home territory, or a breeding spot.

<span class="mw-page-title-main">Fin and flipper locomotion</span>

Fin and flipper locomotion occurs mostly in aquatic locomotion, and rarely in terrestrial locomotion. From the three common states of matter — gas, liquid and solid, these appendages are adapted for liquids, mostly fresh or saltwater and used in locomotion, steering and balancing of the body. Locomotion is important in order to escape predators, acquire food, find mates and bury for shelter, nest or food. Aquatic locomotion consists of swimming, whereas terrestrial locomotion encompasses walking, 'crutching', jumping, digging as well as covering. Some animals such as sea turtles and mudskippers use these two environments for different purposes, for example using the land for nesting, and the sea to hunt for food.

<span class="mw-page-title-main">Olfactory navigation</span>

Olfactory navigation is a hypothesis that proposes the usage of the sense of smell by pigeons, in particular the mail pigeon, in navigation and homing.

<span class="mw-page-title-main">Threats to sea turtles</span>

Threats to sea turtles are numerous and have caused many sea turtle species to be endangered. Of the seven extant species of sea turtles, six in the family Cheloniidae and one in the family Dermochelyidae, all are listed on the IUCN Red List of Endangered Species. The list classifies six species of sea turtle as "threatened", two of them as "critically endangered", one as "endangered" and three as "vulnerable". The flatback sea turtle is classified as "data deficient" which means that there is insufficient information available for a proper assessment of conservation status. Although sea turtles usually lay around one hundred eggs at a time, on average only one of the eggs from the nest will survive to adulthood. While many of the things that endanger these hatchlings are natural, such as predators including sharks, raccoons, foxes, and seagulls, many new threats to the sea turtle species are anthropogenic.

<span class="mw-page-title-main">Animal navigation</span> Ability of many animals to find their way accurately without maps or instruments

Animal navigation is the ability of many animals to find their way accurately without maps or instruments. Birds such as the Arctic tern, insects such as the monarch butterfly and fish such as the salmon regularly migrate thousands of miles to and from their breeding grounds, and many other species navigate effectively over shorter distances.

Most fish possess highly developed sense organs. Nearly all daylight fish have color vision that is at least as good as a human's. Many fish also have chemoreceptors that are responsible for extraordinary senses of taste and smell. Although they have ears, many fish may not hear very well. Most fish have sensitive receptors that form the lateral line system, which detects gentle currents and vibrations, and senses the motion of nearby fish and prey. Sharks can sense frequencies in the range of 25 to 50 Hz through their lateral line.

Many animals are able to navigate using the Sun as a compass. Orientation cues from the position of the Sun in the sky are combined with an indication of time from the animal's internal clock.

<span class="mw-page-title-main">Graeme Hays</span> British marine ecologist (born 1966)

Graeme C. Hays is a British and Australian marine ecologist known for his work with sea turtles and plankton. He is the Alfred Deakin Professor of Marine Science at Deakin University, Australia.

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