Asterias amurensis

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Geographic Range

Northern Pacific sea stars are found throughout parts of the Pacific Ocean near Japan, Russia, Northern China, and Korea as a native species. However, this species has also been introduced to oceanic habitats near parts of the southern Australian coast (especially Tasmania), Alaska and the Aleutian Islands, Europe, and the state of Maine. ("Asterias amurensis (Japanese seastar)", 2012; "Ocean Biogeographic Information System", 2012; Byrne, et al., 1997; Stevens, 2012)

Habitat

Northern Pacific sea stars live in estuarine, intertidal, and coastal zones and prey on other marine inhabitants in or on the substrate. They are found near protected areas of coasts, far away from areas of the ocean with high wave action, at depths up to 220 meters. They prefer a slightly cold environment of about 7-10ºC; however, this species has adapted to the warmer waters of the Australian coast, which average about 22ºC. It can survive in a temperature range of 0–25ºC. Due to their presence in estuarine habitats, these sea stars are able to tolerate a large range of salinities, from 18.7-41.0 ppt. ("Asterias amurensis (Japanese seastar)", 2012; Stevens, 2012)

  • Range depth
    220 (high) m
    721.78 (high) ft

Physical Description

Northern Pacific sea stars have five arms, all ending in small, upward-turned tips. Each of these arms joins in the center of the organism to form a central disc. This species shows a wide range of colors, from orange to yellow, and sometimes purple on their dorsal side. Irregularly arranged spines run down the length of each arm. A row of spines from each arm come together near the mouth area, creating a fan-like appearance. Spines also line the ventral groove of each arm, where the tube feet are found. This species can grow to be up to 50 cm in diameter. ("Asterias amurensis (Japanese seastar)", 2012; Stevens, 2012)

  • Sexual Dimorphism
  • sexes alike
  • Range length
    50 (high) cm
    19.69 (high) in

Development

Male and female sea stars release their respective gametes in to the aquatic environment. The gametes come together to form a fertilized egg, which undergoes holoblastic and radial cleavage followed by gastrulation, completing the beginning stages of larval development. The larva begins to feed once the gastrovascular canals are formed, and at this stage is called a bipinnaria. This stage later develops brachiolar arms, with three of them combining with a central adhesive disk to form the brachiolar complex. This marks the transition of the larva into the brachiolaria state. A brachiolarian larva can remain in the water column for about 120 days before it finally settles and undergoes metamorphosis into the adult sea star. Metamorphosis is induced by the detection of metamorphic inducing factors by the adhesive papillae on the brachiolar arms, such as chemical cues from adult sea stars in the environment. It takes a larva as little as 41 days to about 120 days, from the time of fertilization, to develop into an adult sea star. This process is all dependent upon the temperature of the water in which the sea star is developing; the warmer the water, the faster the rate of development. (Byrne, et al., 1997; Paik, et al., 2005; Stevens, 2012)

Reproduction

Female Northern Pacific sea stars release their eggs into the surrounding marine environment; they are then externally fertilized by sperm released by male sea stars. This species reproduces seasonally and spawns during the months of January to April in Japan and during the months of June to October in Russia and Australia. ("Asterias amurensis (Japanese seastar)", 2012; Stevens, 2012)

Sexual maturity occurs in both males and females when they are 3.6-5.5 cm in length. Females can be identified for 5-6 months of the year due to the presence of their maturing ovaries. Mature ovaries are characterized by the constant release of eggs as well as their orange color. Females are capable of carrying about 10-25 million eggs. Males are also reproductively mature for about 6 months of the year, with maturity being characterized by the yellowish-brown color of the testes. These sea stars have ectosomatic organs, meaning that the pores for gamete expulsion are in direct contact with the marine environment. As gametes are released, they are replaced by constantly ongoing gametogenesis within the gonads. Spawning usually occurs in the late winter and early spring months, continuing into the summer. ("Asterias amurensis (Japanese seastar)", 2012; Byrne, et al., 1997; Paik, et al., 2005; Stevens, 2012)

  • Breeding interval
    This species has an annual breeding season, during which individuals may spawn several times.
  • Breeding season
    Spawning usually occurs in the late winter to early spring.
  • Range number of offspring
    10,000,000 to 25,000,000

Gametes are released freely into the environment, and offspring develop independently of the parents. (Murabe, et al., 2007; Stevens, 2012)

  • Parental Investment
  • no parental involvement

Lifespan/Longevity

The average lifespan of a sea star is around 10 years, although many sea star species are able to live to about the age of 50. There is no specific information available regarding the lifespan of Northern Pacific sea stars. (Uscian, 2006)

Behavior

These sea stars exhibit positive phototactic behavior, moving toward light. In situations where part of the organism is shaded and part is illuminated, it has been seen that the animal moves towards the illuminated area. As they move, the animals exhibit what is known as a “typical advancing posture". This means that the sea star moves with a particular ray of its body in a certain direction and the rest of the organism slowly follows. The adult and juvenile forms of these sea stars both have limited motility. When they do move, they step using their tube feet. However, larval stages are free-swimming and are known to travel using water currents. (Stevens, 2012; Yoshida and Ohtsuki, 1968)

Home Range

There is no home range information available for Northern Pacific sea stars.

Communication and Perception

Northern Pacific sea stars are able to perceive light stimuli and are positively phototactic. As previously mentioned, when four of five arms are shaded, a sea star will move with its illuminated ray forward. All other documented information about the communication and perception abilities of these sea stars regards sensory interactions between larval and adult forms. Larvae are capable of sensing metamorphosis inducing factors expelled by adults via use of neural cells that are held within the adhesive papillae on the external surface of the brachiolar arms. (Murabe, et al., 2007; Yoshida and Ohtsuki, 1968)

Food Habits

Northern Pacific sea stars are known to be voracious predators with a varied diet, essentially eating any type of animal that they encounter. Bivalves, such as mussels, scallops and clams compromise the largest part of this species' diet. They are known to pull apart the shell of these organisms with their arms, and then evert their stomachs into the shell cavity to digest their prey. This species also preys on gastropods, crabs, and barnacles. Occasionally, they have been seen exhibiting cannibalistic behavior when food sources are particularly low. This species has also been observed digging out buried prey from under the substrate, and feeding on algae. ("Introduced Marine Aquatic Invaders - A Feld Guide", 2012)

  • Animal Foods
  • mollusks
  • aquatic crustaceans
  • echinoderms
  • Plant Foods
  • algae

Predation

Northern Pacific sea stars are not generally preyed upon by other organisms. However, they may occasionally be eaten by Japanese sun stars (Solaster paxillatus). In Alaska, king crabs are known to feed on this species, and in laboratory settings, snails in the genus Charonia (tritons) have shown a preference for this species, as opposed to feeding on other marine life. ("Asterias amurensis Feeding and Predators", 2012)

Ecosystem Roles

Northern Pacific sea stars are an invasive species in some areas and an obligate predator whose presence has a great impact on benthic infauna, including mollusks, crustaceans, echinoderms, and other organisms that are preyed upon by this sea star. This species is known to host the bacterium Colwellia asteriadis, although negative effects on the sea star due to the presence of this microbe have not been described. ("National Control Plan for the Northern Pacific Seastar Asterias amurensis", 2008; Choi, et al., 2010)

Commensal/Parasitic Species
  • Colwellia asteriadis (Class Gammaproteobacteria, Phylum Proteobacteria)

Economic Importance for Humans: Positive

There are no known positive economic effects of Asterias amurensis on humans.

Economic Importance for Humans: Negative

The negative economic effects of Northern Pacific sea stars are extensive. In their native Japan, they have devastated the shellfish industry. In Australia, the economic effects of the species are still being fully evaluated, but it is thought that if their spread continues, the soft sediment communities along the coast of Australia may be compromised. It is evident that several fisheries have been negatively impacted – there has been an estimated one billion dollar loss in the industry in Tasmania. Because these fishing industries are important to the economy of the region, several “sea star hunting days” have been organized in which several thousand sea stars have been removed from the coasts. Northern Pacific sea stars are also on the Global Invasive Species Database's list of the 100 Worst Invasive Species. ("National Control Plan for the Northern Pacific Seastar Asterias amurensis", 2008; Stevens, 2012)

Conservation Status

This species hs no special conservation status.

Contributors

Foram Shah (author), The College of New Jersey, Shikha Surati (author), The College of New Jersey, Keith Pecor (editor), The College of New Jersey, Jeremy Wright (editor), University of Michigan-Ann Arbor.

Glossary

Atlantic Ocean

the body of water between Africa, Europe, the southern ocean (above 60 degrees south latitude), and the western hemisphere. It is the second largest ocean in the world after the Pacific Ocean.

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Australian

Living in Australia, New Zealand, Tasmania, New Guinea and associated islands.

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Nearctic

living in the Nearctic biogeographic province, the northern part of the New World. This includes Greenland, the Canadian Arctic islands, and all of the North American as far south as the highlands of central Mexico.

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Pacific Ocean

body of water between the southern ocean (above 60 degrees south latitude), Australia, Asia, and the western hemisphere. This is the world's largest ocean, covering about 28% of the world's surface.

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Palearctic

living in the northern part of the Old World. In otherwords, Europe and Asia and northern Africa.

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asexual

reproduction that is not sexual; that is, reproduction that does not include recombining the genotypes of two parents

benthic

Referring to an animal that lives on or near the bottom of a body of water. Also an aquatic biome consisting of the ocean bottom below the pelagic and coastal zones. Bottom habitats in the very deepest oceans (below 9000 m) are sometimes referred to as the abyssal zone. see also oceanic vent.

bilateral symmetry

having body symmetry such that the animal can be divided in one plane into two mirror-image halves. Animals with bilateral symmetry have dorsal and ventral sides, as well as anterior and posterior ends. Synapomorphy of the Bilateria.

brackish water

areas with salty water, usually in coastal marshes and estuaries.

carnivore

an animal that mainly eats meat

chemical

uses smells or other chemicals to communicate

coastal

the nearshore aquatic habitats near a coast, or shoreline.

ectothermic

animals which must use heat acquired from the environment and behavioral adaptations to regulate body temperature

estuarine

an area where a freshwater river meets the ocean and tidal influences result in fluctuations in salinity.

external fertilization

fertilization takes place outside the female's body

fertilization

union of egg and spermatozoan

heterothermic

having a body temperature that fluctuates with that of the immediate environment; having no mechanism or a poorly developed mechanism for regulating internal body temperature.

intertidal or littoral

the area of shoreline influenced mainly by the tides, between the highest and lowest reaches of the tide. An aquatic habitat.

introduced

referring to animal species that have been transported to and established populations in regions outside of their natural range, usually through human action.

iteroparous

offspring are produced in more than one group (litters, clutches, etc.) and across multiple seasons (or other periods hospitable to reproduction). Iteroparous animals must, by definition, survive over multiple seasons (or periodic condition changes).

metamorphosis

A large change in the shape or structure of an animal that happens as the animal grows. In insects, "incomplete metamorphosis" is when young animals are similar to adults and change gradually into the adult form, and "complete metamorphosis" is when there is a profound change between larval and adult forms. Butterflies have complete metamorphosis, grasshoppers have incomplete metamorphosis.

molluscivore

eats mollusks, members of Phylum Mollusca

motile

having the capacity to move from one place to another.

native range

the area in which the animal is naturally found, the region in which it is endemic.

oviparous

reproduction in which eggs are released by the female; development of offspring occurs outside the mother's body.

polygynandrous

the kind of polygamy in which a female pairs with several males, each of which also pairs with several different females.

radial symmetry

a form of body symmetry in which the parts of an animal are arranged concentrically around a central oral/aboral axis and more than one imaginary plane through this axis results in halves that are mirror-images of each other. Examples are cnidarians (Phylum Cnidaria, jellyfish, anemones, and corals).

saltwater or marine

mainly lives in oceans, seas, or other bodies of salt water.

seasonal breeding

breeding is confined to a particular season

sedentary

remains in the same area

sexual

reproduction that includes combining the genetic contribution of two individuals, a male and a female

tactile

uses touch to communicate

temperate

that region of the Earth between 23.5 degrees North and 60 degrees North (between the Tropic of Cancer and the Arctic Circle) and between 23.5 degrees South and 60 degrees South (between the Tropic of Capricorn and the Antarctic Circle).

visual

uses sight to communicate

References

2012. "Asterias amurensis (Japanese seastar)" (On-line). The National Introduced Marine Pest Information System- NIMPIS. Accessed March 18, 2012 at http://adl.brs.gov.au/marinepests/index.cfm?fa=main.spDetailsDB&sp=6000005721#generalInfo.

2012. "Asterias amurensis Feeding and Predators" (On-line). The National Introduced Marine Pest Information System. Accessed March 20, 2012 at http://adl.brs.gov.au/marinepests/index.cfm?fa=main.spDetailsDB&sp=6000005721#feedingPredators.

2012. "Introduced Marine Aquatic Invaders - A Feld Guide" (On-line). Department of Fisheries, Western Australia. Accessed March 20, 2012 at http://www.fish.wa.gov.au/docs/pub/IMPMarine/IMPMarinePage06a.php#03.

The National System for the Prevention and Management of Marine Pest Incursions. National Control Plan for the Northern Pacific Seastar Asterias amurensis. Australia: Commonwealth of Australia. 2008. Accessed March 20, 2012 at http://www.marinepests.gov.au/__data/assets/pdf_file/0010/952489/Asterias-ncp-08.pdf.

2012. "Ocean Biogeographic Information System" (On-line). OBIS. Accessed March 20, 2012 at http://www.iobis.org/.

Byrne, M., M. Morrice, B. Wolf. 1997. Introduction of the Northern Pacific asteroid Asterias amurensis to Tasmania: reproduction and current distribution. Marine Biology, 127(4): 673-685.

Choi, E., H. Kwon, H. Koh, Y. Kim, H. Yang. 2010. Colwellia asteriadis sp. nov., a marine bacterium isolated from the starfish Asterias amurensis. International Journal of Systematic and Evolutionary Microbiology, 60/8: 1952-1957.

McEdward, L., K. Morgan. 2001. Interspecific relationships between egg size and the level of parental investment per offspring in echinoderms. The Biological Bulletin, 200(1): 33-50.

Murabe, N., H. Hatoyama, K. Mieko, H. Kaneko, Y. Nakajima. 2007. Adhesive papillae on the brachiolar arms of brachiolaria larvae in two starfishes, Asterina pectinifera and Asterias amurensis, are sensors for metamorphic inducing factors(s). Development, Growth, and Differentiation, 49(8): 647-656.

Paik, S., H. Park, S. Yi, S. Yun. 2005. Developmental duration and morphology of the sea star Asterias amurensis in Tongyeong, Korea. Ocean Science Journal, 40(3): 65-70.

Ross, D., C. Johnson, C. Hewitt. 2002. Impact of introduced seastars Asterias amurensis on survivorship of juvenile commercial bivalves Fulvia tenuicostata. Marine Ecology Progress Series, 241: 99-112.

Stevens, C. 2012. "ISSG Database: Ecology of Asterias amurensis" (On-line). Global Invasive Species Database. Accessed March 18, 2012 at http://www.issg.org/database/species/ecology.asp?si=82&fr=1&sts=&lang=EN.

Uscian, J. 2006. Alaska SeaLife Center Guide to Marine Life For Visitors, Staff, and all Marine Life Enthusiasts. Seward, Alaska: The Alaska SeaLife Center. Accessed November 26, 2012 at http://ir.library.oregonstate.edu/xmlui/handle/1957/19568.

Yoshida, M., H. Ohtsuki. 1968. The phototactic behavior of the starfish, Asterias amurensis. The Biological Bulletin, 134: 516-532.