Halodule wrightii

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Halodule wrightii
Halodule wrightii.jpg
Scientific classification OOjs UI icon edit-ltr.svg
Kingdom: Plantae
Clade: Tracheophytes
Clade: Angiosperms
Clade: Monocots
Order: Alismatales
Family: Cymodoceaceae
Genus: Halodule
Species:
H. wrightii
Binomial name
Halodule wrightii
Asch 1868
Synonyms [2]
  • Diplanthera beaudetteiHartog
  • Diplanthera dawsoniiHartog
  • Diplanthera wrightii(Asch.) Asch.
  • Halodule beaudettei(Hartog) Hartog
  • Halodule brasiliensisLipkin

Halodule wrightii is an aquatic plant in the Cymodoceaceae family. [3] It is referred to by the common names shoal grass or shoalweed, and is a plant species native to seacoasts of some of the warmer oceans of the world.

Contents

H. wrightii is an herb growing in salt-water marshes in intertidal regions, often submerged at high tide but emergent at low tide. [4]

Taxonomy

This plant was named after Charles Wright, who was an American botanist and collector. In 1853 and 1856 Wright participated in a surveying expedition and discovered Halodule wrightii. [5] [6] [7]

Some publications cite US specimens by the synonym, Halodule beaudettei, [8] [9] but the two names represent the same species. [10] [11] [12] [13]

Description

Seagrass is a marine angiosperm that possesses conductive tissue, shoot systems, rhizomes and flowers. [14] It has flat leaves up to 20 cm long, dark reddish-brown, with a few teeth on the margins. The fruits are spherical to egg-shaped, about 2 mm across. [10] [4] [15]

Distribution

This plant is mainly found in muddy coastal marsh waters and off the coast of many Caribbean islands. [14] It has been reported from Texas, [16] Florida, Louisiana, Mississippi, Alabama, North Carolina, Maryland, [10] [17] Yucatán, Quintana Roo, Tabasco, [18] [19] [20] Costa Rica, [21] Belize, [22] Panamá, Cuba, Trinidad & Tobago, Venezuela, Brazil and Cape Verde. [23]

In California, it was intentionally introduced into the Salton Sea from Texas almost a century ago, but died out a long time ago. [24]

Ecology

These aquatic plants form sea beds and increase habitat stabilization through constant shoot and rhizome production. The string-like structure of the seagrass decrease water turbidity and movement of substrate whether it is sand or mud. [25] Seagrass beds function as an incubator for young juvenile fishes. They provide shelter from predators and reduce competition with other species. Halodule wrightii also supplies food resources to several species of fish, invertebrate marine life and manatees. [26] This species of plant has the ability to adapt to various levels of salinity and temperatures.

H. wrightii is able to reproduce sexually and asexually, however, flowering in this species is rare.

Conservation

Recreational activities, like jet skiing and boating, damage and uproot seagrass beds with ease in shallow coastal waters. Studies such as the one performed in Brazil's Abrolhos Marine National Park tested the direct effects of anchor damage caused by intense boating activity, and found that H. wrightii abundance was deeply impacted. [27]

Restoration

Restoration of seagrass beds has been experimentally tested many times. [28] One such experiment in Florida attempted to use H. wrightii as a pioneer species to stimulate natural succession to the eventual climax vegetation dominated by Thalassia testudinum . The experiment found that the application of fertilizer to transplants greatly increased their growth rate. [29]

Related Research Articles

<span class="mw-page-title-main">Seagrass</span> Plants that grow in marine environments

Seagrasses are the only flowering plants which grow in marine environments. There are about 60 species of fully marine seagrasses which belong to four families, all in the order Alismatales. Seagrasses evolved from terrestrial plants which recolonised the ocean 70 to 100 million years ago.

<i>Zostera</i> Genus of aquatic plants

Zostera is a small genus of widely distributed seagrasses, commonly called marine eelgrass, or simply seagrass or eelgrass, and also known as seaweed by some fishermen and recreational boaters including yachtsmen. The genus Zostera contains 15 species.

<span class="mw-page-title-main">Zosteraceae</span> Family of aquatic plants

Zosteraceae is a family of marine perennial flowering plants found in temperate and subtropical coastal waters, with the highest diversity located around Korea and Japan. Most seagrasses complete their entire life cycle under water, having filamentous pollen especially adapted to dispersion in an aquatic environment and ribbon-like leaves that lack stomata. Seagrasses are herbaceous and have prominent creeping rhizomes. A distinctive characteristic of the family is the presence of characteristic retinacules, which are present in all species except members of Zostera subgenus Zostera.

<i>Garcia</i> (plant) Genus of flowering plants

Garcia is a plant genus of the family Euphorbiaceae and of the monotypic subtribe Garciinae, first described as a genus in 1792. It is native to Central America, Mexico, Colombia, and Venezuela, and also naturalized in some of the West Indies.

  1. Garcia nutansVahl ex Rohr - Mexico from Sinaloa and San Luis Potosí to Chiapas + Yucatán, Central America, Colombia, Venezuela
  2. Garcia parvifloraLundell - Chiapas, Tabasco, Veracruz
<span class="mw-page-title-main">Seagrass meadow</span> Underwater ecosystem

A seagrass meadow or seagrass bed is an underwater ecosystem formed by seagrasses. Seagrasses are marine (saltwater) plants found in shallow coastal waters and in the brackish waters of estuaries. Seagrasses are flowering plants with stems and long green, grass-like leaves. They produce seeds and pollen and have roots and rhizomes which anchor them in seafloor sand.

<span class="mw-page-title-main">Cymodoceaceae</span> Family of aquatic plants

Cymodoceaceae is a family of flowering plants, sometimes known as the "manatee-grass family", which includes only marine species.

The flora of Belize is highly diverse by regional standards, given the country's small geographical extent. Situated on the Caribbean coast of northern Central America the flora and vegetation have been intimately intertwined with Belize's history. The nation itself grew out of British timber extraction activities from the 17th century onwards, at first for logwood and later for mahogany, fondly called "red gold" because of its high cost and was much sought after by European aristocracy. Central America generally is thought to have gained much of it characteristic flora during the "Great American interchange" during which time South American elements migrated north after the geological closure of the isthmus of Panama. Few Amazonian elements penetrate as far north as Belize and in species composition the forests of Belize are most similar to the forests of the Petén (Guatemala) and the Yucatán (Mexico).

<i>Halodule</i> Genus of aquatic plants

Halodule is a genus of plants in the family Cymodoceaceae described as a genus in 1841. It is widespread on tropical and semi-tropical ocean shores of all continents except Europe and Antarctica.

Amphibolis antarctica is a species of flowering plant in the family Cymodoceaceae. It is referred to by the common names wire weed or sea nymph, and is a seagrass found in coastal waters of southern and western Australia.

<i>Posidonia</i> Genus of aquatic plants

Posidonia is a genus of flowering plants. It contains nine species of marine plants ("seagrass"), found in the seas of the Mediterranean and around the south coast of Australia.

The Seagrasses of Western Australia are submerged flowering plants found along the coast, around islands, and in Estuaries of Western Australia. The region contains some of the largest seagrass meadows in the world, and is the most diverse in the number of species. The variety of habitats along its western and southern coasts is often soft sands in shallow subtropical waters, ideal for these plants.

Goldmanella is a genus of flowering plants in the daisy family.

<i>Smaragdia viridis</i> Species of gastropod

Smaragdia viridis. common name the "emerald nerite" is a species of small, green sea snail, a marine gastropod mollusk in the family Neritidae, the nerites.

<i>Thalassia testudinum</i> Species of aquatic plant

Thalassia testudinum, commonly known as turtlegrass, is a species of marine seagrass. It forms meadows in shallow sandy or muddy locations in the Caribbean Sea and the Gulf of Mexico. Turtle grass and other seagrasses form meadows which are important habitats and feeding grounds. The grass is eaten by turtles and herbivorous fish, supports many epiphytes, and provides habitat for juvenile fish and many invertebrate taxa.

<i>Cymodocea nodosa</i> Species of plant in the family Cymodoceaceae

Cymodocea nodosa is a species of seagrass in the family Cymodoceaceae and is sometimes known as little Neptune grass. As a seagrass, it is restricted to growing underwater and is found in shallow parts of the Mediterranean Sea and certain adjoining areas of the Atlantic Ocean.

<span class="mw-page-title-main">Gulf flounder</span> Species of fish

The Gulf flounder is a species of saltwater flounder.

<i>Halodule uninervis</i> Species of plant in the family Cymodoceaceae

Halodule uninervis is a species of seagrass in the family Cymodoceaceae. It is native to the western Pacific and Indian Oceans. Common names include narrowleaf seagrass in English and a'shab bahriya in Arabic.

<i>Zostera muelleri</i> Species of plant in the family Zosteraceae

Zostera muelleri is a southern hemisphere temperate species of seagrass native to the seacoasts of South Australia, Victoria and Tasmania. and New Zealand. Today, Zostera muelleri can be found in regions of Australia, New Zealand, and Papua New Guinea, as well as areas of the eastern Indian Ocean, and the southwest and western central Pacific Ocean. Zostera muelleri is a marine angiosperm, and is commonly referred to as eelgrass or garweed. It is a fast growing and readily colonizing species that serves as a feeding ground for wading birds and aquatic animals, and a breeding ground for juvenile fish and shrimp species.

Spermacoce glabra, smooth false buttonweed, is a New World species of plants in the coffee family.

Halophila baillonis is a species of aquatic plant in the family Hydrocharitaceae. It is referred to by the common name clover grass. It is native to Brazil, Cayman Islands, Colombia, Costa Rica, Jamaica, Leeward Islands, Netherlands Antilles, Panama, Puerto Rico, Trinidad and Tobago, and Venezuela. It is listed on the IUCN Red List as "vulnerable" due to its naturally rare occurrence and fragmented populations.

References

  1. Short, F.T.; Carruthers, T.J.R.; van Tussenbroek, B.; Zieman, J. (2010). "Halodule wrightii". IUCN Red List of Threatened Species . 2010: e.T173372A7001725. doi: 10.2305/IUCN.UK.2010-3.RLTS.T173372A7001725.en . Retrieved 12 November 2021.
  2. The Plant List Halodule wrightii
  3. "Halodule wrightii Asch". Plants of the World Online. The Trustees of the Royal Botanic Gardens, Kew. n.d. Retrieved September 26, 2020.
  4. 1 2 Godfrey, R. K. & J. W. Wooten. 1979. Aquatic and Wetland Plants of Southeastern United States Monocotyledons 1–712. The University of Georgia Press, Athens.
  5. "Indian River Lagoon Species Inventory". Smithsonian Marine Station at Fort Pierce.
  6. Berlin., Gesellschaft Naturforschender Freunde zu (1868-01-01). "Sitzungsberichte der Gesellschaft Naturforschender Freunde zu Berlin". Sitzungsberichte der Gesellschaft Naturforschender Freunde zu Berlin. 1868. ISSN   0433-8731.
  7. Ascherson, Paul Friedrich August. 1897. Die Natürlichen Pflanzenfamilien 2: 37.
  8. Hartog, Cornelis den. 1964. Blumea 12: 303.
  9. Hartog, Cornelis den. 1960. Pacific Naturalist 1(15): 4–5, f. 2a–c.
  10. 1 2 3 "Halodule wrightii in Flora of North America @ efloras.org". www.efloras.org. Retrieved 2017-02-03.
  11. Phillips, Ronald C. (1 July 1967). "On Species of the Seagrass, Halodule, in Florida". Bulletin of Marine Science. 17 (3): 672–676.
  12. McMmillan, C. 1991. Isozyme patterning in marine spermatophytes. In: L. Triest, ed. 1988+. Isozymes In Water Plants. Opera Botanica Belgica 1+ vols. Belgium, Meise. Vol. 4,: pp. 193--200.
  13. "Image". www.tropicos.org. Retrieved 2017-02-03.
  14. 1 2 Gallegos, Me; Merino, M; Rodriguez, A; Marba, N; Duarte, Cm (1994). "Growth patterns and demography of pioneer Caribbean seagrasses Halodule wrightii and Syringodium filiforme". Marine Ecology Progress Series. 109: 99–104. Bibcode:1994MEPS..109...99G. doi: 10.3354/meps109099 .
  15. Novelo, A. & L. Ramos. 2005. Vegetación acuática. Cap. 5: 111–144. In J. Bueno, F Álvarez & S. Santiago, Biodiversidad del Estado de Tabasco. CONABIO-UNAM, México.
  16. Correll, D. S. & M. C. Johnston. 1970. Manual of the Vascular Plants of Texas i–xv, 1–1881. The University of Texas at Dallas, Richardson
  17. BONAP (Biota of North America Project) floristic synthesis, Halodule wrightii Image
  18. Cowan, C. P. 1983. Flora de Tabasco. Listados Florísticos de México 1: 1–123.
  19. Sousa Sánchez, M. & E. F. Cabrera Cano. 1983. Flora de Quintana Roo. Listados Florísticos de México 2: 1–100.
  20. Novelo R., A. & A. L. H. 1994. 239. Cymodoceaeceae. 6: 15–16. In G. Davidse, M. Sousa Sánchez & A.O. Chater (eds.) Flora Mesoamericana. Universidad Nacional Autónoma de México, México, D. F.
  21. Hammel, B. E. 2003. Cymodoceaceae. In: Manual de Plantas de Costa Rica, B.E. Hammel, M.H. Grayum, C. Herrera & N. Zamora (eds.). Monographs in systematic botany from the Missouri Botanical Garden 92: 456–457.
  22. Balick, M. J., M. H. Nee & D.E. Atha. 2000. Checklist of the vascular plants of Belize. Memoirs of The New York Botanical Garden 85: i–ix, 1–246.
  23. Creed, Joel C.; Engelen, Aschwin H.; D´Oliveira, Emanuel C.; Bandeira, Salomão; Serrão, Ester A. (December 2016). "First record of seagrass in Cape Verde, eastern Atlantic". Marine Biodiversity Records. 9 (1): 57. doi: 10.1186/s41200-016-0067-9 . S2CID   7494405.
  24. Hickman, J. C. 1993. The Jepson Manual: Higher Plants of California 1–1400. University of California Press, Berkeley.
  25. Hall, Lauren M.; Hanisak, M. Dennis; Virnstein, Robert W. (3 April 2006). "Fragments of the seagrasses Halodule wrightii and Halophila johnsonii as potential recruits in Indian River Lagoon, Florida". Marine Ecology Progress Series. 310: 109–117. Bibcode:2006MEPS..310..109H. doi: 10.3354/meps310109 . JSTOR   24870011.
  26. Pereira, Pedro H.C.; Ferreira, Beatrice P.; Rezende, Sérgio M. (September 2010). "Community structure of the ichthyofauna associated with seagrass beds (Halodule wrightii) in Formoso River estuary - Pernambuco, Brazil". Anais da Academia Brasileira de Ciências. 82 (3): 617–628. doi: 10.1590/S0001-37652010000300009 . PMID   21562690.
  27. Creed, Joel C; Amado Filho, Gilberto M (March 1999). "Disturbance and recovery of the macroflora of a seagrass (Halodule wrightii Ascherson) meadow in the Abrolhos Marine National Park, Brazil: an experimental evaluation of anchor damage". Journal of Experimental Marine Biology and Ecology. 235 (2): 285–306. doi:10.1016/S0022-0981(98)00188-9.
  28. van Katwijk, Marieke M.; Thorhaug, Anitra; Marbà, Núria; Orth, Robert J.; Duarte, Carlos M.; Kendrick, Gary A.; Althuizen, Inge H. J.; Balestri, Elena; Bernard, Guillaume; Cambridge, Marion L.; Cunha, Alexandra; Durance, Cynthia; Giesen, Wim; Han, Qiuying; Hosokawa, Shinya; Kiswara, Wawan; Komatsu, Teruhisa; Lardicci, Claudio; Lee, Kun-Seop; Meinesz, Alexandre; Nakaoka, Masahiro; O'Brien, Katherine R.; Paling, Erik I.; Pickerell, Chris; Ransijn, Aryan M. A.; Verduin, Jennifer J. (April 2016). "Global analysis of seagrass restoration: the importance of large-scale planting". Journal of Applied Ecology. 53 (2): 567–578. doi: 10.1111/1365-2664.12562 . hdl: 11568/759969 .
  29. Kenworthy, W. Judson; Hall, Margaret O.; Hammerstrom, Kamille K.; Merello, Manuel; Schwartzschild, Arthur (March 2018). "Restoration of tropical seagrass beds using wild bird fertilization and sediment regrading". Ecological Engineering. 112: 72–81. doi: 10.1016/j.ecoleng.2017.12.008 .
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