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Grateloupia turuturu

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Grateloupia turuturu
File:Single weed of Grateloupia Turuturu.png
Individual
Scientific classification Edit this classification
Clade: Archaeplastida
Division: Rhodophyta
Class: Florideophyceae
Order: Halymeniales
Family: Halymeniaceae
Genus: Grateloupia
Species:
G. turuturu
Binomial name
Grateloupia turuturu
Yamada, 1941

Grateloupia turuturu, known as the devil's tongue weed, is a marine species of the Rhodophyta (red algae) plant, a type of seaweed, native to eastern Asia (China, Japan, Korea) and parts of eastern Russia.[1] Due to global shipping and maritime activities, G. turuturu has become an invasive species that has altered natural communities by out-competing native seaweed species, this has resulted in a loss of habitat in many parts of the world, primarily in Australia, northern Ireland, Great Britain, and the northeastern United States. Other common names for this species are the "red menace" and "red tide".[2]

Description

Grateloupia turuturu is a large species of seaweed that has several shades of coloring such as red, maroon, and burgundy.[3] However, it may also be yellow when dying or deceased. It is soft and gelatinous in texture. The blades of the organism vary in size and shape; typically 1 to 8 blades will stem from a center, attached by a cylindrical holdfast. Each blade can grow to be almost a meter long, 3-15 centimeters wide, and 10-70 cm long.[3]

Distribution

Currently, G. turuturu is found in Asia, Europe, North America, and Oceania. It is native to China, Japan, and South Korea. In Europe, it is found in France, Italy, the Netherlands, Portugal, Russia, Spain, the United Kingdom, and the Channel Islands. In North America, it is found in Mexico and in the United States, specifically in Connecticut, Massachusetts, New York, and Rhode Island. In Oceania, it is found in Australia and New Zealand.[4]

Habitat and ecology

File:Grateloupia Turuturu in water.png
A patch of Grateloupia turuturu

Grateloupia turuturu is a perennial plant living an average of 6-10 years. They grow best in nutrient-rich eutrophic waters and are commonly found on rocky layers near coastal and shallow shores.[5] This species can quickly grow in length and peak in biomass during the late summer and early autumn months; though growth begins to wane in late spring and early summer. It has adapted to live in variable temperatures and levels of salinity(12-52 ppt),[6] being able to continue normal growth in temperatures as low as 3℃ and as high as 29℃. This is advantageous to the plant as it can withstand many environmental changes, making it an increasingly threatening and invasive species. Several small invertebrates live in proximity to G. turuturu populations, including shrimps, snails, adolescent fish and crabs. There is little evidence of herbivory on G. turuturu.

Reproduction

Grateloupia turuturu reproduce sexually, and asexually via spores and through vegetative propagation. Peak reproduction time occurs in the summer, during which time an average of 90% of individuals are fertile.[7] Germination of this species is similar to that of many other naturally occurring seaweed, where large dense masses of non-motile aplanospores are released into the environment; since discharging spores of red algae cannot swim they must rely on water currents to transport them. When spores settle they form small rounded discs that develop via a germ tube, these discs can produce various shoots that have the ability to release thousands of additional spores.[8] Vegetative reproduction occurs when a fragment of the plant breaks off and develops directly into new individuals, all offspring resulting from this asexual reproduction are genetically identical to each other.

Dispersal

A tugboat pumping ballast water into the ocean.

One of the major means of transport for G. turuturu’s that enables its spread is molluscan aquaculture, or shellfish farming, this involves intentional transportation of shellfish that contains juvenile spores and/or fragments of the plant species.[9] Transport of macroscopic spores via “stone-rafting” or drifting of fertile blades on small cobbles/rock may also occur, as well as accidental transfer on boats.[10] Spores may also be transported in ballast water over long distances.[11]

Uses

Grateloupia turuturu is edible.[12]

As an invasive species

Originating from the northwest Pacific, Grateloupia turuturu has become dispersed profoundly being recorded in regions of Australia, New Zealand, Northeastern United States, Western Europe and the Mediterranean.[13] Originally, many reports of G. turuturu in North America and Europe were thought to be a species from the Peruvian waters, G. doryphora. However, close examination regarding molecular and morphological comparisons concluded that the species that have been appearing in North American and Europe were indeed G. turuturu.[13] One experiment, which was conducted in Northern Portugal, examined if G. turuturu was a passenger or driver of ecological change. The results of the experiment suggested that G. turuturu waited for disturbances in the environment that reduced the abundance of competitors, before increasing in population for a particular habitat.[14] This could lead to the possibility that disturbances, due to human contribution, could result in the increased spreading of this invasive species.

The invasive properties of G. turuturu have significant impacts on its environment and the species that inhabit those areas. This impact can be seen by observing native biota such as the five major plant species in the North Atlantic (Chondrus crispus, Mastocarpus stellatus, Palmaria palmata, Saccharina latissima, and S. longicruris) which all occur within low shallow subtidal zones—the same environment in which G. turuturu thrives. Due in part to its size, it is able to block the amount of sunlight its understory vegetation receives,[10] this is why enhanced growth of Grateloupia could cause a shift or reduced diversity of neighboring organisms such as, other native seaweeds, marine life, and bacteria.

Control

There are not many records about controlling the spread of this species successfully. However, in 2017, to control an invasion of G. turuturu on the coast of Maine, researchers tested how the seaweed reacted to methods commonly used in invasive species and pathogen control. Such methods include heat treatment and addition of bleach to sea water (chlorination) at levels that could not harm the environment. Blades of G. turuturu were observed for weeks in petri dishes that either contained bleach + salt water solutions or heated salt water (60-75 degrees Celsius). The results indicated that G.turuturu had resistances to bleach due to sugars on the cell wall that are reactive to bleach. Heat treatment was successful and rapidly killed the seaweed. Based on this experiment, extended drying periods and heat treatment could serve as environmentally friendly countermeasures to G. turuturu invasion.[15]

References

  1. ^ Mathieson, Arthur C.; Dawes, Clinton J.; Pederson, Judith; Gladych, Rebecca A.; Carlton, James T. (27 September 2007). "The Asian red seaweed Grateloupia turuturu (Rhodophyta) invades the Gulf of Maine". Biological Invasions. 10 (7): 985-988. doi:10.1007/s10530-007-9176-z. S2CID 26387504.
  2. ^ Patten MP van, 2006. Beware of the red menace. Wrack Lines Magazine, 6:8-10.
  3. ^ a b "Marine Invasive Species - NYS Dept. of Environmental Conservation". www.dec.ny.gov. Retrieved 2020-10-30.
  4. ^ Mathieson, Arthur. "Grateloupia turuturu". Invasive Species Compendium. Retrieved 28 October 2020.
  5. ^ Harlin MM, Villalard-Bohnsack M, 1999. A large red seaweed invades Narragansett bay. Maritimes, 41:6-9.
  6. ^ Simon C, Gall EA, Levavasseur G, Deslandes E, 1999. Effects of short-term variations of salinity and temperature on the photosynthetic response to the red alga Grateloupia doryphora from Brittany (France). Botanica Marina, 42:437-440.
  7. ^ Irvine LM, 1983. Seaweeds of the British Isles, volume 1, Rhodophyta; Part 2A: Cryptonemiales (sensu stricto) Palmariales, Rhodymeniales. London, UK: British Museum (Natural History), 113 pp.
  8. ^ Harlin MM, Villalard-Bohnsack M, 2001. Seasonal dynamics and recruitment strategies of the invasive seaweed Grateloupia doryphora (Halymeniaceae, Rhodophyta) in Narragansett Bay and Rhode Island Sound, Rhode Island, USA. Phycologia, 40:468-474.
  9. ^ Ribera A, Boudouresque CF, 1995. Introduced marine plants, with special reference to macroalgae: mechanisms and impact. In: Progress in Phycological Research, Vol. 11 [ed. by Round, F. E.\Chapman, D. J.]. Amsterdam: Biopress Ltd., 187-268.
  10. ^ a b Simon C, Gall EA, Deslandes E, 2001. Expansion of the red alga Grateloupia doryphora along the coast of Brittany, France. Hydrobiologia, 443:23-29.
  11. ^ Marston M, Villalard-Bohnsack M, 2002. Molecular variability and potential sources of Grateloupia doryphora (Halymeniacae), an invasive species in Rhode Island waters (USA). Journal of Phycology, 38:649-658.
  12. ^ Kendel, Melha; Couzinet-Mossion, Aurélie; Viau, Michèle; Fleurence, Joël; Barnathan, Gilles; Wielgosz-Collin, Gaëtane (April 2013). "Seasonal composition of lipids, fatty acids, and sterols in the edible red alga Grateloupia turuturu". Journal of Applied Phycology. 25 (2): 425–432. doi:10.1007/s10811-012-9876-3. ISSN 0921-8971. S2CID 9727967.
  13. ^ a b D'Archino, R.; Nelson, W. A.; Zuccarello, G. C. (March 2007). "Invasive marine red alga introduced to New Zealand waters: First record of Grateloupia turuturu (Halymeniaceae, Rhodophyta)". New Zealand Journal of Marine and Freshwater Research. 41 (1): 35–42. doi:10.1080/00288330709509894. ISSN 0028-8330. S2CID 84556486.
  14. ^ Mulas, Martina; Bertocci, Iacopo (July 2016). "Devil's tongue weed (Grateloupia turuturu Yamada) in northern Portugal: Passenger or driver of change in native biodiversity?". Marine Environmental Research. 118: 1–9. doi:10.1016/j.marenvres.2016.04.007. PMID 27110653.
  15. ^ Capistrant-Fossa, Kyle; Brawley, Susan H. (24 April 2019). "Unexpected reproductive traits of Grateloupia turuturu revealed by its resistance to bleach-based biosecurity protocols". Botanica Marina. 62 (2): 83–96. doi:10.1515/bot-2018-0104. ISSN 1437-4323. S2CID 92555080.