Ciona intestinalis
System : Marine
Kingdom
Phylum
Class
Order
Family
Animalia
Chordata
Ascidiacea
Enterogona
Cionidae
- General
- Distribution
- Impact
- Management
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Common name
cione (French), doorschijnende zakpijp (Dutch), gelbe seescheide (German), vase tunicate (English), sea vase (English), yellow sea squirt (English), ascidie jaune (French)
Synonym
Ascidia viridiscens , (Brugiere, 1792)
Ciona canina , (Mueller, 1776)
Ciona diaphanea , (Quoy & Gaimard, 1834)
Ciona ocellata , (Agassiz, 1850)
Ciona pulchella , (Alder, 1863)
Ciona robusta , (Hoshino & Tokioka, 1967)
Ciona sociabilis , (Gunnerus, 1765)
Ciona tenella , (Stimpson, 1852)
Phallusia intestinalis , (Linnaeus, 1767)
Tethyum sociabile , (Gunnerus, 1765)
Ciona canina , (Mueller, 1776)
Ciona diaphanea , (Quoy & Gaimard, 1834)
Ciona ocellata , (Agassiz, 1850)
Ciona pulchella , (Alder, 1863)
Ciona robusta , (Hoshino & Tokioka, 1967)
Ciona sociabilis , (Gunnerus, 1765)
Ciona tenella , (Stimpson, 1852)
Phallusia intestinalis , (Linnaeus, 1767)
Tethyum sociabile , (Gunnerus, 1765)
Similar species
Summary
The sea vase, Ciona intestinalis, is a tunicate that has such widespread distribution that its natural range continues to be a source of constant debate. A major pest on shellfish aquaculture production, C. intestinalis is a highly competitive species. There is evidence of C. intestinalis displacing native species, reducing biodiversity, and altering community properties in some invaded habitats. Control of C. intestinalis is difficult due to its rapid recolonisation, difficulty of containment and proximity to valuable aquaculture production that limits the control options able to be used.
Species Description
Like all Ciona spp. Ciona intestinalis has a sessile adult stage which lives attached to submerged hard substrates (Holland, 2002). C. intestinalis usually adheres vertically to these substrates, with its siphons pointing downward (Marins et al, 2009). The body of C. intestinalis is cylindrical, reaching to 100 - 150 mm in length, with its two siphons at the anterior end (Marins et al, 2009). All Ciona spp. are encased in a soft leathery tunic, which in the case of C. intestinalis, it is thin, soft, gelatinous, translucent, and clear to greenish coloured, making the internal organs visible (McDonald, 2004; Jackson, 2008; in Marins et al, 2009).
The inhalant anterior opening into the gut is larger and terminal with eight lobes while the atrial siphon is smaller and shorter with six lobes (McDonald, 2004). Larvae are free swimming and tadpole-like in appearance, with a dorsal nerve cord, a rudimentary brain and a notochord (Holland, 2002). After dispersal, larvae attach to a surface with their head after which the tail is reabsorbed and metamorphosis into a sessile filter-feeding adult occurs (Holland, 2002).
Once settled, C. intestinalis provide a poor substrate for other settlers, producing strong anti-microbial compounds that may restrict epibiosis and therefore limit recruitment of other species (Finslay & Smith, 1995; in Blum et al, 2007). The maximum reported lifespan of individuals is 2 years, but a more typical lifespan is 1 year (Jackson, 2000; in Blum et al, 2007).
Notes
The origin of Ciona intestinalis populations in Canada is a source of debate. Locke (2009) describes populations in sourthern Nova Scotia as cryptogenic while populations in Atlantic Canadian waters are non-indigenous. In contrast, Therriault & Herborg (2008a) describe populations in Atlantic Canadian waters as cryptogenic and populations in Pacific Canadian waters as non-indigenous.
Lifecycle Stages
Larvae are free swimming and tadpole-like in appearance, with a dorsal nerve cord, a rudimentary brain and a notochord (Holland, 2002). After dispersal over a period of 1 - 5 days (Dybern, 1965; in Howes et al, 2007), larvae attach to a surface with their head after which the tail is reabsorbed and metamorphosis into a sessile filter-feeding adult occurs (Holland, 2002).
Uses
Species of sea squirt, including Ciona spp., were popular models for embryological research in the early part of the twentieth century. Ciona spp. were instrumental in the discovery of cytoplasmic determinants, and were one of the first animals to have a cell lineage mapped (Holland, 2002). More recently, numerous developmentally expressed genes have been cloned from Ciona spp., hundreds of gene expression patterns are published, and there are powerful methods for introducing gene constructs into Ciona spp. embryos using electroporation (Holland, 2002).
Habitat Description
Ciona intestinalis lives attached to submerged rocks or other hard surfaces, such as ropes, chains and boat hulls (Holland, 2002). C. intestinalis has a cosmopolitan distribution, tolerates organic pollution and a wide range of enviornmental conditions. It is abundant in ports and marinas all over the world (Meliane, 2003; in Marins et al, 2009; Therriault & Herborg, 2008a).
Reproduction
As with all Ascidians, Ciona intestinalis is hermaphroditic and potentially capable of self-fertilisation (Silva & Smith, 2008). It is also a solitary (opposed to colonial) Ascidian which undergoes broadcast spawning (Silva & Smith, 2008). Each mature individual can potentially spawn once per day over the spawning period, releasing appproximately 500 eggs per day (Carver et al, 2003). Eggs are negatively buoyant and released in mucus strings that tangle and attach to nearby adults, contributing to the dense aggregations of adults (MarLIN, 2004; in McDonald, 2004).
Nutrition
Ciona intestinalis is a filter feeding organism, feeding on particles in the water column (Daigle & Herbinger, 2009). Clearance rates increase in an approximately linear relationship with increasing temperature with rates ranging from 4.6 ml per min per individual at 4 °C to about 29 ml per min per individual at 19 °C (Daigle & Herbinger, 2009).
Principal source:
Compiler: IUCN SSC Invasive Species Specialist Group (ISSG) with support from the Overseas Territories Environmental Programme (OTEP) project XOT603, a joint project with the Cayman Islands Government - Department of Environment
Review: Under expert review
Publication date: 2007-05-07
Recommended citation: Global Invasive Species Database (2024) Species profile: Ciona intestinalis. Downloaded from http://iucngisd.org/gisd/speciesname/Ciona+intestinalis on 21-11-2024.
General Impacts
The most severe impacts of Ciona intestinalis worldwide have been on aquaculture production, causing substantial economic losses to the shellfish industry in particular (Robinson et al, 2005). Higher C. intestinalis densities are generally linked to lower mussel size and condition, with heavy fouling resulting in up to 50 % mussel mortality (Daigle & Herbinger, 2009). This is due mainly to inhibited growth and yield through food and space competition (Daigle & Herbinger, 2009; Rocha et al 2009) as well as increasing weight of gear, leading to difficulties in handling and processing (Locke et al., 2009b).
Additionally, as a highly competitive species within subtidal, epibenthic communities, C. intestinalis has also displaced native species, lowered biodiversity, and altered community properties in some invaded habitats (Blum et al 2007; Therriault & Herborg, 2008b).
Management Info
Please follow this link for detailed information on the management of Ciona intestinalis. A brief summary can by found below.
Preventative measures: A risk assessment carried out by Hayes et al (2005) in Australia determined that C. intestinalis was one of top ten species in both its likelihood to be spread to uninfected bioregions by shipping and its damage potential. Preventative requirements on Prince Edward Island, Canada failed to stop the spread of C. intestinalis (Locke et al., 2009b). The only regulated vector in Canada is ballast water coming in from commercial shipping (Locke et al., 2009a)
Monitoring: Tunicate collectors were created and used to detect the presence and distribution of exotic tunicate species in the Bay of Fundy, including Ciona intestinalis (LeGresley et al, 2008).
Physical control: Aquaculture farmers surveyed by Clancey & Hinton (2003) revealed that physical removal methods such as hand scrubbing, scraping or high pressure spraying were the most common treatments used to remove tunicates that had become established on gear, however C. intestinalis quickly re-established populations within short periods.
Chemical control: A number of chemical treatments to control C. intestinalis have been trialed (Carver et al, 2003). While some like acetic acid and calcium hydroxide have shown promising results, chemicals have the potential to alter estuarine pH are and have been shown to be biocidal to a variety of non-target organisms such as species of bacteria, shrimp and fish (Locke et al, (2009b).
Biological control: Potential biological control agents include the rock crab, Cancer irroratus and green crab, Carcinus maenas. The use of crab predators for the control of C. intestinalis in aquaculture is limited for a number of reasons (Carver et al, 2003). Grazing species such as Littorina littorea and the shrimp Rhynchocinetes typus have also been trialled, with the shrimp in particular showing promising results (Dumont et al., 2009).
Cultural control: These refer to aquaculture management practices and generally include avoiding times of high C. intestinalis recruitment, changing or rotating the gear used or air drying depending on the species being farmed and the gear being used. More information on C. intestinalis recruitment patterns and population development is necessary to develop more effective management procedures (Ramsay, et al, 2009).
