Association with vessel vectors

Actual evidence of being found in samples in a particular vector from any world region.

Anchor and anchor chains. Organisms found on anchors, anchor chain or within attached sediments, including anchor chain lockers.

Ballast water. Ballast water means water with its suspended matter taken on board a ship to control trim, list, draught, stability or stresses of the ship.

Biofouling. Biofouling means the accumulation of aquatic organisms such as micro-organisms, plants, and animals on surfaces and structures immersed in or exposed to the aquatic environment. Biofouling can include microfouling and macrofouling.

  • Macrofouling means large, distinct multicellular organisms visible to the human eye such as barnacles, tubeworms, or fronds of algae.
  • Microfouling means microscopic organisms including bacteria and diatoms and the slimy substances that they produce.
Biofouling comprised of only microfouling is commonly referred to as a slime layer.

Sea chest. The sea chests are cavities (an opening with protection grid) at the bottom side of the ships’ hull (an opening for pumping in and out water for, e.g., ballasting, firefighting) where aquatic organisms may settle and be transported.

Tank sediments. Matter settled out of ballast water within a ship.

Bioaccumulation association

Natural toxins. An organism that accumulates toxins naturally produced by other organisms, such as phytotoxins, in its tissues.

Anthropogenic chemical compounds. An organism that accumulates human-produced chemicals, such as pharmaceuticals, heavy metals, pesticides, dioxins, in its tissues.

Characteristic feeding method

Chemoautotroph. An organism that obtains metabolic energy by oxidation of inorganic substrates such as sulphur, nitrogen or iron.

Deposit feeder – Subsurface. Synonym: detritivore. An organism feeding on fragmented particulate organic matter in the substratum.

Deposit feeder – Surface. Synonym: detritivore. An organism feeding on fragmented particulate organic matter from the surface of the substratum.

Grazer. An organism feeding on plants (higher aquatic plants, benthic algae and phytoplankton) and/or sessile animals organisms.

Herbivore. An organism feeding on plants (higher aquatic plants, benthic algae and phytoplankton).

Mixotroph. An organism both autotrophic and heterotrophic.

Omnivore. An organism feeding on mixed diet of plant and animal material.

Parasite. Feeding on the tissues, blood or other substances of a host.

Photoautotroph. An organism that obtains metabolic energy from light by photosynthesis (e.g. seaweeds, phytoplankton).

Planktotroph. An organism feeding on plankton.

Predator. An organism that feeds by preying on other organisms, killing them for food.

Scavenger. An organism feeding on dead and decaying organic material.

Suspension feeder – Active. An organism feeding on particulate organic matter, including plankton, suspended in the water column, collecting it actively by sweeping or pumping (creating feeding currents).

Suspension feeder – Passive. An organism feeding on particulate organic matter, including plankton, suspended in the water column, utilizing the natural flow to bring particles in contact with feeding structures.

Symbiont contribution. Where some dietary component(s) are provided by symbiotic organisms (e.g. Anemonia with zooxanthellae).

Developmental trait

Brooding. The incubation of eggs either inside or outside the body. Eggs may be brooded to a variety of developmental stages. Males or females may be responsible for brooding.

Direct development. A life cycle lacking a larval stage.

Spawning. The release of gametes into the water.

Lecithotrophy. Development at the expense of internal resources (i.e. yolk) provided by the female.

Parental care. Any form of parental behaviour that is likely to increase the fitness of offspring.

Planktotrophy. Feeding on plankton.

Resting stages. The quiescent stage in the life cycle (dormancy, diapause).

Viviparous. Producing live offspring from within parental body.

Habitat modifying ability potential

Autogenic ecosystem engineers. Organisms which change the environment via their own physical structures (i.e. their living and dead tissues) such as corals, oysters, kelps, sea grasses, etc.

Allogenic ecosystem engineers. Organisms which modify the environment by causing physical state changes in biotic and abiotic materials that, directly or indirectly, modulate the availability of resources to other species (e.g. excavating deep burrows which other organisms co-occupy, damming the water flow, etc).

Keystone species. A keystone species is crucial in maintaining the organization and diversity of its ecological community, by determining the types and numbers of other species.

Life form

Neuston. Organisms that live on (epineuston) or under (hyponeuston) the surface film of water bodies.

Zoobenthos. Animals living on or in the seabed.

Phytobenthos. Algae and higher plants living on or in the seabed.

Zooplankton. Animals living in the water column, unable to maintain their position independent of water movements.

Phytoplankton. Microscopic plankton algae and cyanobacteria.

Benthopelagos. Synonyms: hyperbenthic, benthopelagic, nektobenthic, demersal. An organism living at, in or near the bottom of the sea, but having the ability to swim.

Nekton. Actively swimming aquatic organisms able to move independently of water currents.

Parasite. An organism intimately associated with and metabolically dependent on another living organism (host) for completion of its life cycle.

Symbiont (nonparasitic). An organism living mutually with another species without harming it. Association of two species (symbionts) may be mutually beneficial.

Mobility

Boring. An organism capable of penetrating a solid substrate by mechanical scraping or chemical dissolution.

Burrowing. An organism capable of digging in sediment.

Crawling. An organism moving slowly along on the substrate.

Drifting. An organism whose movement is dependent on wind or water currents.

Permanent attachment. Non-motile; permanently attached at the base. Also includes permanent attachment to a host.

Swimming. An organism capable of moving through the water by means of fins, limbs or appendages.

Temporary attachment. Temporary / sporadic attachment. Attached to a substratum but capable of movement across (or through) it (e.g. Actinia). Also includes temporary attachment to a host.

Native origin

The region the species originates from.

References



References should follow the standard of Biological invasions:


Journal article
Gamelin FX, Baquet G, Berthoin S, Thevenet D, Nourry C, Nottin S, Bosquet L (2009) Effect of high intensity intermittent training on heart rate variability in prepubescent children. Eur J Appl Physiol 105:731-738. doi: 10.1007/s00421-008-0955-8
Ideally, the names of all authors should be provided, but the usage of “et al” in long author lists will also be accepted:
Smith J, Jones M Jr, Houghton L et al (1999) Future of health insurance. N Engl J Med 965:325–329


Article by DOI


Slifka MK, Whitton JL (2000) Clinical implications of dysregulated cytokine production. J Mol Med. doi:10.1007/s001090000086


Book
South J, Blass B (2001) The future of modern genomics. Blackwell, London


Book chapter
Brown B, Aaron M (2001) The politics of nature. In: Smith J (ed) The rise of modern genomics, 3rd edn. Wiley, New York, pp 230-257


Online document
Cartwright J (2007) Big stars have weather too. IOP Publishing PhysicsWeb. http://physicsweb.org/articles/news/11/6/16/1. Accessed 26 June 2007


Dissertation
Trent JW (1975) Experimental acute renal failure. Dissertation, University of California

Reproductive frequency

Iteroparous. Organisms breeding more than once in their lifetime.

Semelparous. Organisms breeding once in their lifetime.

Reproductive type

Asexual. Budding, Fission, Fragmentaion, including parthenogenesis. A form of asexual multiplication in which:
a) a new individual begins life as an outgrowth from the body of the parent. It may then separate to lead an independent existence or remain connected or otherwise associated to form a colonial organism;
b) the ovum develops into a new individual without fertilization;
c) division of the body into two or more parts each or all of which can grow into new individuals is involved.

Self-fertilization. Selfing or autogamy. The union of a male and female gamete produced by the same individual.

Sexual. Permanent hermaphrodite, Protandrous hermaphrodite, Protogynous hermaphrodite, Gonochoristic.
Capable of producing both ova and spermatozoa either at the same time. A condition of hermaphroditism in plants and animals where male gametes mature and are shed before female gametes mature or vice versa.
Having separate sexes.

Salinity

The exact salinity range if known (psu), else salinity zone(s) according to the Venice system:
1. Limnetic [<0.5psu]
2. β-Oligohaline [0.5-3psu]
3. α-Oligohaline [3-5psu]
4. β-Mesohaline [5-10psu]
5. α-Mesohaline [10-18psu]
6. Polymixohaline [18-30psu]
7. Euhaline [30-40psu]
8. Hypersaline [>40psu]

Sociability

Colonial. Descriptive of organisms produced asexually which remain associated with each other; in many animals, retaining tissue contact with other polyps or zooids as a result of incomplete budding.

Gregarious. Organisms living in groups or communities, growing in clusters.

Solitary. Living alone, not gregarious.

Sub-species level

A geographical subset of a species showing discrete differences in morphology, coloration or other features when compared with other members of the species. Subspecies may also differ in their habitat or behavior, but they can interbreed. Often the lowest taxonomic level within a classification system.

Synonym

Valid synonyms of a species (not all of them).

Toxicity

Poisonous. An organism capable of producing poison that gains entry to another organism body via the gastrointestinal tract, the respiratory tract, or via absorption through intact body layers.

Venomous. An organism capable of producing poison, usually injected through another organism intact skin by bite or sting.

Not relevant. Neither poisonous nor venomous.

Public domain: Species account

 
Species Mytilus galloprovincialis [WoRMS]
Authority Lamarck, 1819
Family Mytilidae  
Order Mytilida  
Class Bivalvia  
Phylum Mollusca  
Synonym (?)
Sub-species level (?) Not entered
Native origin (?) LME: 26. Mediterranean Sea
LME: 62. Black Sea

References (not structured):
Gosling EM (2003) Bivalve Molluscs. Biology, Ecology and Culture. Fishing News Books. Blackwell, Oxford, England.
Life form / Life stage (?)
 AdultJuvenileLarvaeEggsResting stage
Neuston
ZoobenthosXX
Phytobenthos
ZooplanktonXX
Phytoplankton
Benthopelagos
Nekton
Ectoparasite
Endoparasite
Symbiont (non parasitic)


References (not structured):
Beaumont A, Gjedrem T, Moran P (2007) Blue mussel Mytilus edulis, Mediterranean mussel M. galloprovincialis. Genetic impact of aquaculture activities in native populations. Genimpact Final Scientific Report:62-69
Sociability / Life stage (?)
 AdultJuvenileLarvaeEggsResting stage
SolitaryXX
GregariousXX
Colonial


References (not structured):
Ardizzone GD, Belluscio A, Gravina MF, et al. (1996) Colonization and Disappearance ofMytilus galloprovincialisLam. on an Artificial Habitat in the Mediterranean Sea. Estuarine, Coastal and Shelf Science 43:665-676
Reproductive frequency (?) Iteroparous

References (not structured):
Beaumont A, Gjedrem T, Moran P (2007) Blue mussel Mytilus edulis, Mediterranean mussel M. galloprovincialis. Genetic impact of aquaculture activities in native populations. Genimpact Final Scientific Report:62-69
Reproductive type (?) Self-fertilization
Sexual

References:
Beaumont A, Matin-Abdul A (1994) Differences in morphology, survival and size between self-and cross-fertilized larvae of Mytilus galloprovincialis. Journal of the Marine Biological Association of the United Kingdom 74:445-448
Beaumont A, Gjedrem T, Moran P (2007) Blue mussel Mytilus edulis, Mediterranean mussel M. galloprovincialis. Genetic impact of aquaculture activities in native populations. Genimpact Final Scientific Report:62-69

Comments:
Self-fertilization if unusual.
Developmental trait (?) Planktotrophy
Spawning

References:
Beaumont A, Gjedrem T, Moran P (2007) Blue mussel Mytilus edulis, Mediterranean mussel M. galloprovincialis. Genetic impact of aquaculture activities in native populations. Genimpact Final Scientific Report:62-69
Characteristic feeding method / Life stage (?)
 AdultJuvenileLarvaeEggsResting stage
Photoautotroph
Mixotroph
Suspension feeder – ActiveXX
Suspension feeder – Passive
Deposit feeder – Surface
Deposit feeder – Sub-surface
Omnivore
Herbivore
Scavenger
Symbiont contribution
PlanktotrophX
Chemoautotroph
Predator
Grazer


References (not structured):
Beaumont A, Gjedrem T, Moran P (2007) Blue mussel Mytilus edulis, Mediterranean mussel M. galloprovincialis. Genetic impact of aquaculture activities in native populations. Genimpact Final Scientific Report:62-69
Mobility / Life stage (?)
 AdultJuvenileLarvaeEggsResting stage
Swimmer
Crawler
Burrower
DrifterXX
Temporary attachmentXX
Permanent attachment
Borer


References (not structured):
Carl C, Poole AJ, Williams MR, de Nys R (2012) Where to Settle—Settlement Preferences of Mytilus galloprovincialis and Choice of Habitat at a Micro Spatial Scale. PLoS ONE 7(12): e52358. doi: 10.1371/journal.pone.0052358
Salinity tolerance range (?) Exact range: 12 - 38

References:
Bayne BL (1976) Marine mussels, their ecology and physiology. Cambridge University Press

Comments:
The salinity range for M. galloprovincialis as 12-38 (Bayne 1976).
Habitat modifying ability potential (?) Allogenic ecosystem engineers
Autogenic ecosystem engineers

References:
O'Connor NE, Crowe TP, McGrath D (2006) Effects of epibiotic algae on the survival, biomass and recruitment of mussels, Mytilus L. (Bivalvia: Mollusca). Journal of Experimental Marine Biology and Ecology 328:265-276

Comments:
Mussels can be thought of as both “allogenic” and “autogenic” bioengineers.
Toxicity / Life stage (?) Not relevant
Bioaccumulation association (?) Anthropogenic chemical compounds
Natural toxins

References:
D'adamo R, Pelosi S, Trotta P, et al. (1997) Bioaccumulation and biomagnification of polycyclic aromatic hydrocarbons in aquatic organisms. Marine Chemistry 56:45-49
Sakellari A, Karavoltsos S, Theodorou D, et al. (2013) Bioaccumulation of metals (Cd, Cu, Zn) by the marine bivalves M. galloprovincialis, P. radiata, V. verrucosa and C. chione in Mediterranean coastal microenvironments: association with metal bioavailability. Environmental monitoring and assessment 185:3383-3395
Known human health impact? Known

References:
Branch, G.M., Steffani, C.N. (2004) Can we predict the effects of alien species? A case-history of the invasion of South Africa by Mytilus galloprovincialis (Lamarck), Journal of Experimental Marine Biology and Ecology, Volume 300, Issues 1–2,Pages 189-215. https://doi.org/10.1016/j.jembe.2003.12.007.
Carl, C., Poole, A.J., Vucko, M.J., Williams, M.R., Whalan, S., and de Nys, R., 2011. Optimising settlement assays of pediveligers and plantigrades of Mytilus galloprovincialis. Biofouling. 27 (8), 859-868. https://doi.org/10.1080/08927014.2011.605943
Jovic, M., and Stankovic, S., 2014. Human exposure to trace metals and possible public health risks via consumption of mussels Mytilus galloprovincialis from the Adriatic coastal area. Food Chem. Toxicol. 70, 241-251. https://doi.org/10.1016/j.fct.2014.05.012

Comments:
Toxic effects if trace metals in eaten mussels are high (Jovic and Stankovic 2014).
Known economic impact? Not known

Comments:
Not available.
Known measurable environmental impact? Known

References:
Branch, G.M., Steffani, C.N. (2004) Can we predict the effects of alien species? A case-history of the invasion of South Africa by Mytilus galloprovincialis (Lamarck), Journal of Experimental Marine Biology and Ecology, Volume 300, Issues 1–2,Pages 189-215. https://doi.org/10.1016/j.jembe.2003.12.007.
Carl, C., Poole, A.J., Vucko, M.J., Williams, M.R., Whalan, S., and de Nys, R., 2011. Optimising settlement assays of pediveligers and plantigrades of Mytilus galloprovincialis. Biofouling. 27 (8), 859-868. https://doi.org/10.1080/08927014.2011.605943
Jovic, M., and Stankovic, S., 2014. Human exposure to trace metals and possible public health risks via consumption of mussels Mytilus galloprovincialis from the Adriatic coastal area. Food Chem. Toxicol. 70, 241-251. https://doi.org/10.1016/j.fct.2014.05.012

Comments:
Competitive exclusion of limpets (Branch and Steffani 2004).
Included in the Target Species list? No

Comments:
Assessed by the COMPLETE project experts (2021), excluded from the previous target species list.
Association with vessel vectors (?) Anchor and anchor chains
Ballast waters
Biofouling
Sea chest
Tank sediments

References:
Cáceres-Martı́nez J, Figueras A (1998) Long-term survey on wild and cultured mussels (Mytilus galloprovincialis Lmk) reproductive cycles in the Ria de Vigo (NW Spain). Aquaculture 162:141-156

Gollasch S, Macdonald E, Belson S, Botnen H, Christensen JT, Hamer JP, Houvenaghel G, Jelmert A, Lucas I, Masson D, McCollin T, Olenin S, Persson A, Wallentinus I, Wetsteyn LPMJ, Wittling T (2002) Life in Ballast Tanks In: Invasive aquatic species of Europe - distribution, impact and management. Leppäkoski, E., S. Gollasch & S. Olenin (eds). Kluwer Academic Publishers: 217-231 http://www.corpi.ku.lt/nemo/aqua_app_gollasch.pdf

Scardino A, de Nys R (2004) Fouling deterrence on the bivalve shell Mytilus galloprovincialis: a physical phenomenon? Biofouling 20:249-257

Carlton JT (1999) Molluscan invasions in marine and estuarine communities. Malacologia 41:439-454

Briski E, Ghabooli S, Bailey S, et al. (2012) Invasion risk posed by macroinvertebrates transported in ships’ ballast tanks. Biol Invasions 14:1843-1850
Molecular information Available

Toro JE, Ojeda JA, Vergara AM, et al. (2005) Molecular characterization of the Chilean blue mussel (Mytilus chilensis Hupe 1854) demonstrates evidence for the occurrence of Mytilus galloprovincialis in southern Chile. Journal of Shellfish Research 24:1117-1121
Last update byAleksas Narščius, 2019-04-10