California sea hare

The California sea hare (Aplysia californica) is a species of sea slug in the sea hare family, Aplysiidae.^[2] It is found in the Pacific Ocean, off the coast of California in the United States and northwestern Mexico.

California sea hare
Releasing ink after being disturbed
Scientific classification
Domain:	Eukaryota
Kingdom:	Animalia
Phylum:	Mollusca
Class:	Gastropoda
Clade:	Euopisthobranchia
Clade:	Anaspidea
Superfamily:	Aplysioidea
Family:	Aplysiidae
Genus:	Aplysia
Species:	A. californica
Binomial name
Aplysia californica (James Graham Cooper, 1863)
Occurrence is sparse in the northern portion of this range[1]
Synonyms[2]
Aplysia nettiae Winkler, 1959

Distribution

A. californica is found along the coast of California, United States, and northwestern Mexico (including the Gulf of California). Aplysia species inhabit the photic zone to graze on algae, mainly the intertidal, usually not deeper than 18–20 m (59–66 ft).^[3]

Description

The maximum length recorded for the California sea hare is 75 cm (30 in) when crawling, thus fully extended, although most adult specimens are half this size or smaller. Adult animals can weigh up to 7 kg (15 lb).^[4][5] A closely related species, Aplysia vaccaria, the black sea hare, can grow larger still.

A California sea hare is typically reddish-brown to greenish-brown, but the color varies based on the algae it ingests. Each sea hare houses four tentacles, with two on the head sheltering the eyes, and two on the face surrounding the mouth. The body has two folds, called parapodia, which envelop the gills for protection but enable water to get by. Below the body is a muscle that allows mobility, almost like a foot. The California sea hare also has an internal shell to protect its organs.^[6]

Lifecycle

Like all sea hares, the California sea hare is hermaphroditic, simultaneously acting as male and female during mating. A. californica is known to form mating chains with up to 20 animals. The eggs are yellow-green, and change after 8–9 days into a brown color before larvae hatch. Mating is most prominent during the summer following water temperature rise to 17°C.

A. californica has a generation time of 19 weeks: Days 1-37 after hatching from the egg comprise the planktonic stage, days 34-37 are the metamorphic stage, and days 45-80 are the juvenile stage. At about day 30, the larvae move on from the planktonic stage and begin to roost on algae, typically red algae. The larvae eat enough to double their weight every 10 days for the following 3 months while they undergo metamorphosis.^[7] Reproductive maturity is reached 85 days after hatching (133 days after deposition of the fertilized eggs). The development of the nervous system lasts for 140 days.^[8] Often, the California sea hare dies shortly after laying eggs.^[9] Cooler temperatures (14-25°C, or 57-77°F) delay spawning and have been shown to extend the lifespan.

• 
  Out of water at low tide near Morro Bay
• 
  Juvenile on display at Birch Aquarium in San Diego, California
• 
  A. californica rhinophore
• A. californica at Monterey Bay Aquarium. Video clip

Sexual reproduction

At the base of the right anterior tentacle is the aperture from which the penis can protrude. The genital aperture lies at the anterior end of the mantle cavity, a seminal grove arises from it and runs forward to the penis, at the base of the anterior tentacle.

Coupling lasts for hours or sometimes for days, although the actual passage of the sperm may take only a few minutes. Egg laying normally has to be triggered by copulation, but it occurs spontaneously in individuals kept in isolation for up to 3–4 months (typically these eggs are unfertilized).^[8] Copulation occurs most frequently in the early morning, and rarely after 12:30 pm.^[10] An individual animal weighing 2,600g was recorded to have laid about 500 million eggs at 27 separate times during less than five months.

Feeding habits

Like all Aplysia species, the California sea hare is herbivorous. Its diet consists primarily of red algae such as Laurencia pacifica, Plocamium pacificum, and Ceramium eatonianum, which give the animal its typically reddish or pinkish coloration. Some California sea hares will appear more brown, which helps them blend into their surroundings.^[11] A. californica resembles the food on which it grazes, and cannot be distinguished easily from the seaweed unless the animal is moving.^[8] When the sea hares eat algae, they consume toxins, which they store in themselves to repel predators.^[11] They can also release these toxins as a purple ink, which will also discourage predators from attacking them.^[11]

Predators

Close-up showing the rhinophores of Aplysia californica

Because of the toxins in its body that come from consuming algae, the California sea hare has very few predators. Predators include starfish, lobsters,^[12] and the ophistobranch Navanax inermis which will take juveniles.^[13]

When it is considerably disturbed, the sea hare is capable of releasing two different kinds of ink from different locations within its mantle cavity, much in the way an octopus does. One ink is reddish-purple and comes from what is called the purple ink gland, while the other is milky white, comes from what is called the opaline gland, and contains the aversive chemical opaline.^[14]

Protective mechanisms

Inking provides protection from spiny lobsters, a major predator of sea hares, by means of three mechanisms:^[14] chemical deterrence, sensory disruption, and phagomimicry.

The typical defence response of the sea hare to a predator is the release of chemicals such as free amino acids, ink from the ink gland, and opaline from the opaline gland. Chemical deterrence involves the release of toxic chemicals that are noxious to predators and rapidly dissuades them from feeding. Ink creates a dark, diffuse cloud in the water that disrupts the sensory perception of the predator by acting as a screen or decoy. The opaline, which affects the senses dealing with feeding, causes the predator to instinctively attack the cloud of chemicals as if it were indeed food.^[14][15]

Laboratory use

A. californica has become a valuable laboratory animal, used in studies of the neurobiology of learning and memory, and is especially associated with the work of Nobel laureate Eric Kandel.^[16]

Its ubiquity in synaptic plasticity studies can be attributed to its simple nervous system, consisting of just 20,000 large, easily identified neurons with cell bodies up to 1 mm in size.^[17] Despite its seemingly simple nervous system, though, A. californica is capable of a variety of nonassociative and associative learning tasks, including sensitization, habituation, and classical and operant conditioning. Study typically involves a reduced preparation of the gill and siphon withdrawal reflex.^[18]

Sequencing of its whole genome was approved as a priority by National Human Genome Research Institute in March 2005.^[19][20] The draft genome is available on the UCSC Genome browser.^[21]

References

1. Robert Hugh Morris; Eugene Clinton Haderlie (1980). Intertidal Invertebrates of California. Stanford University Press. p. 348. ISBN 978-0-8047-1045-9. Retrieved 26 July 2013.
2. Rosenberg, G.; Bouchet, P. (2011). Aplysia californica J. G. Cooper, 1863. Accessed through: World Register of Marine Species at http://www.marinespecies.org/aphia.php?p=taxdetails&id=240765 on 2012-03-31
3. Kandel, Eric. R. (1979). Behavioral Biology of Aplysia: Contribution to the Comparative Study of Opisthobranch Molluscs. San Francisco: W. H. Freeman and Company.
4. MacFarland, F.M. (1966). Studies of the opisthobranchiate mollusks of the Pacific coast of North America. Mem. Calif. Acad. Sc. VI, p. 1-596
5. Aplysia californica from the Sea Slug Forum
6. Dice, Samantha. "Aplysia californica". Animal Diversity Web. Retrieved 2022-10-20.
7. Pacific, Aquarium of the. "California Brown Sea Hare". www.aquariumofpacific.org. Retrieved 2022-10-20.
8. Kandel, Eric Behavioral biology of Aplysia. W.H. Freeman and Co., San Francisco.
9. Pacific, Aquarium of the. "California Brown Sea Hare". www.aquariumofpacific.org. Retrieved 2022-10-20.
10. Newby 1972
11. "Insided Look: California Sea Hare". Catalina Island Marine Institute. 2021-06-03. Retrieved 2022-10-20.
12. Watkins et al. Lobster attack induces sensitization in the sea hare, Aplysia californica. J Neurosci. 2010 Aug 18;30(33):11028-31.
13. Janet L. Leonard and Ken Lukowiak. The Behavior of Aplysia californica Cooper (Gastropoda; Opisthobranchia): I. Ethogram. Behaviour Vol. 98, No. 1/4 (Aug., 1986), pp. 320-360
14. Derby, Charles D.; Kicklighter, Cynthia E.; Johnson, P. M. & Xu Zhang (29 March 2007). "Chemical Composition of Inks of Diverse Marine Molluscs Suggests Convergent Chemical Defenses" (PDF). Journal of Chemical Ecology. 2007 (33): 1105–1113. Bibcode:2007JCEco..33.1105D. doi:10.1007/s10886-007-9279-0. PMID 17393278. S2CID 92064. Archived from the original (PDF) on 15 November 2009. Retrieved 9 May 2015.
15. Inman, Mason (29 March 2005). "Sea Hares Lose Their Lunch". Sciencemag.org. Retrieved 10 May 2015.
16. Edythe McNamee and Jacque Wilson (14 May 2013). "A Nobel Prize with help from sea slugs". CNN. Retrieved 2020-10-31.
17. Redish, Edward F. (2003). Teaching physics : with the physics suite. Hoboken, NJ: John Wiley & Sons. ISBN 0-471-39378-9. OCLC 53287676.
18. December 2011, Joseph Castro 30 (30 December 2011). "Sea Slug Offers Clues to Improving Long-Term Memory". livescience.com. Retrieved 2020-10-31.{{cite web}}: CS1 maint: numeric names: authors list (link)
19. Approved Sequencing Targets Archived 2012-07-27 at the Wayback Machine. Last updated 14 September 2009. Accessed 24 November 2009
20. National Human Genome Research Institute (1 March 2005) "NHGRI Targets 12 More Organisms for Genome Sequencing". NIH new Releases, Last Updated: 12 June 2009.
21. aplCal1 at UCSC Genome Browser Gateway

• Beeman R.D. (1963) Notes on the California species of Aplysia (Gastropoda: Opisthobranchia). The Veliger 5(4): 145–147.
• Bebbington A. (1977) Aplysiid species from Eastern Australia with notes on the Pacific Ocean Aplysiomorpha (Gastropoda, Opisthobranchia). Transactions of the Zoological Society of London 34: 87-147
• Turgeon, D.D.; Quinn, J.F.; Bogan, A.E.; Coan, E.V.; Hochberg, F.G.; Lyons, W.G.; Mikkelsen, P.M.; Neves, R.J.; Roper, C.F.E.; Rosenberg, G.; Roth, B.; Scheltema, A.; Thompson, F.G.; Vecchione, M.; Williams, J.D. (1998). Common and scientific names of aquatic invertebrates from the United States and Canada: mollusks. 2nd ed. American Fisheries Society Special Publication, 26. American Fisheries Society: Bethesda, MD (USA). ISBN 1-888569-01-8. IX, 526 + cd-rom pp.
• NIH/University of Miami National Resource for Aplysia Facility

Further reading

• Cummins Scott F, Erpenbeck Dirk, Zou Zhihua, Claudianos Charles, Moroz Leonid L, Nagle Gregg T, Degnan Bernard M (2009). "Candidate chemoreceptor subfamilies differentially expressed in the chemosensory organs of the mollusc Aplysia". BMC Biology. 2009 (7): 28. doi:10.1186/1741-7007-7-28. PMC 2700072. PMID 19493360.{{cite journal}}: CS1 maint: multiple names: authors list (link)
• Moroz L. L., Ju J., Russo J. J., Puthanveetti S., Kohn A., Medina M., Walsh P. J., Birren B., Lander E. S. & Kandel E. R. (2004) "Sequencing the Aplysia Genome: a model for single cell, real-time and comparative genomics". National Human Genome Research Institute. online at http://www.genome.gov/Pages/Research/Sequencing/SeqProposals/AplysiaSeq.pdf Accessed 20 November 2009
• Proekt A., Wong J., Zhurov Y., Kozlova N., Weiss K. R., Brezina V. (2008). "Predicting Adaptive Behavior in the Environment from Central Nervous System Dynamics". PLoS ONE. 3 (11): e3678. Bibcode:2008PLoSO...3.3678P. doi:10.1371/journal.pone.0003678. PMC 2576442. PMID 18989362.{{cite journal}}: CS1 maint: multiple names: authors list (link)
• Wayne N. L., Block G. D. (1992). "Effect of Photoperiod and Temperature on Egg-Laying Behavior in a Marine Mollusk, Aplysia californica". The Biological Bulletin. 182 (1): 8–14. doi:10.2307/1542176. JSTOR 1542176. PMID 29304714.