Sepia tuberculata grows to a mantle length of 82 mm.[5] The upper surface of the body is rough with variably extending bumps. The lower body surface has two glandular patches. Like all cuttlefish, this species has ten arms, of which two are elongated tentacles used for catching prey. It has narrow fins which extend the length of the body.[7]
Ecology
Sepia tuberculata is capable of changing colour rapidly. It feeds on shrimps. It uses its glandular patches to cling to rocks.
Threats
It is the prey of the Cape Clawless Otter – an opportunistic mammal that is adept at capturing available prey. It is often caught in the Tsitsikama Coastal National Park in South Africa.[8] It is part of the IUCN Red List of Threatened Species however it is considered “data deficient” since there is very little published information on the species and thus cannot be put into a Red List Category.[9] A huge threat to Sepia tuberculata, as well as many other Cephalopods, is ocean acidification due to anthropogenic carbon dioxide emissions. Changes in the 33chemistry of seawater has been found to increase calcification rates in a relative of S. tuberculata, S. officinalis. Increased calcification in the cuttlebone has a negative impact in that it affects the cuttlebone’s function as a lightweight, buoyancy structure in cuttlefish.[10]
Cuttlefish have made a lot of the earnings for several fisheries in the English Channel however it is unknown if S. tuberculata is of interest to fisheries in South Africa.[11]
Prey
Not much is known about specific prey preference S. tuberculata, but the common cuttlefish is known to feed on shrimp. This exhibition of food preference is shown very early in life for cuttlefish and suggests that choosing to prey on shrimp is an innate behavior.[12]
Adaptations
Much of the research published about Sepia tuberculata has been concerning the topic of adhesion. Adhesion is a common occurrence that is used by many plants and animals including Cephalopods, the class to which all Cuttlefish belong.[4] It is effectively bonding, or how plants and animals hold onto substrates. Adhesion, for Cephalopods, typically happens by means of a pressure system that includes use of the suckers on their and tentacles.[13]Sepia are one taxa of cephalopods that produce a chemical substance to be used for adhesion; the use of this secretion varies depending on each specific animal. In addition, S. tuberculata is one of at least four Sepia species that actually possesses an adhesive structure.[14]
No information has been published on whether or not S. tuberculata has the ability to change colors/produce patterns on its body, but the common cuttlefish, S. officinalis, possesses the ability to produce 13 different body patterns composed of a number of different chromatic, textural, postural and locomotor components in its body. The changing of body patterns is primarily used for concealment, and specific patterns are chosen depending on the strategy the cuttlefish intends to use be that disruptive coloration or general color resemblance .[15]
^Julian Finn (2016). "Sepia tuberculata Lamarck, 1798". World Register of Marine Species. Flanders Marine Institute. Retrieved 20 February 2018.
^Jereb, P.; Roper, Clyde F. E., eds. (2005). Cephalopods of the world : an annotated and illustrated catalogue of cephalopod species known to date. Rome: Food and Agriculture Organization of the United Nations. ISBN978-9251053836. OCLC71193186.
^ abvon Byern, Janek; Scott, Robyn; Griffiths, Charles; Micossi, Andrea; Grunwald, Ingo; Cyran, Norbert (2011-10-01). "Characterization of the adhesive areas in Sepia tuberculata (Mollusca, Cephalopoda)". Journal of Morphology. 272 (10): 1245–1258. doi:10.1002/jmor.10980. ISSN1097-4687. PMID21688295. S2CID5894947.
^ abReid, A., P. Jereb, & C.F.E. Roper 2005. Family Sepiidae. In: P. Jereb & C.F.E. Roper, eds. Cephalopods of the world. An annotated and illustrated catalogue of species known to date. Volume 1. Chambered nautiluses and sepioids (Nautilidae, Sepiidae, Sepiolidae, Sepiadariidae, Idiosepiidae and Spirulidae). FAO Species Catalogue for Fishery Purposes. No. 4, Vol. 1. Rome, FAO. pp. 57–152.
^Roeleveld, M.A. 1972. A review of the Sepiidae (Cephalopoda) of southern Africa. Ann. S. Afr. Mus.59(10): 193–313.
^Van Der Zee, D. (1981). "Prey of the Cape clawless otter (Aonyx capensis) n the Tsitsikama Coastal National Park, South Africa". Journal of Zoology. 194 (4): 467–483. doi:10.1111/j.1469-7998.1981.tb04595.x.
^Dunn, M.R. (1999). "Aspects of the stock dynamics and exploitation of cuttlefish, Sepia officinalis, in the English Channel". Fisheries Research. 40: 277–293. doi:10.1016/s0165-7836(98)00223-9.
^Darmaillacq, Anne-Sophie; Chichery, Raymond; Poirier, Roseline; Dickel, Ludovic (2004-12-01). "Effect of early feeding experience on subsequent prey preference by cuttlefish, Sepia officinalis". Developmental Psychobiology. 45 (4): 239–244. doi:10.1002/dev.20034. ISSN1098-2302. PMID15549683.
^Hanlon, R. T.; Messenger, J. B. (1988-08-12). "Adaptive coloration in young cuttlefish (Sepia officinalis L.): the morphology and development of body patterns and their relation to behaviour". Phil. Trans. R. Soc. Lond. B. 320 (1200): 437–487. Bibcode:1988RSPTB.320..437H. doi:10.1098/rstb.1988.0087. ISSN0080-4622.