Fucus Explained

Fucus is a genus of brown algae found in the intertidal zones of rocky seashores almost throughout the world.

Description and life cycle

The thallus is perennial with an irregular or disc-shaped holdfast or with haptera.[1] The erect portion of the thallus is dichotomous or subpinnately branched, flattened and with a distinct midrib. Gas-filled pneumatocysts (air-vesicles) are present in pairs in some species, one on either side of the midrib. The erect portion of the thallus bears cryptostomata and caecostomata (sterile surface cavities). The base of the thallus is stipe-like due to abrasion of the tissue lateral to the midrib and it is attached to the rock by a holdfast. The gametangia develop in conceptacles embedded in receptacles in the apices of the final branches. They may be monoecious or dioecious.[2]

These algae have a relatively simple life cycle and produce only one type of thallus which grows to a maximum size of 2 m. Fertile cavities, the conceptacles, containing the reproductive cells are immersed in the receptacles near the ends of the branches. After meiosis oogonia and antheridia, the female and male reproductive organs, produce egg cells and sperm respectively that are released into the sea where fertilisation takes place. The resulting zygote develops directly into the diploid plant. This contrasts with the life cycle of the flowering plant,[3] where the egg cells and sperm are produced by a haploid multicellular generation, albeit very strongly reduced, and the egg cells are fertilised within the ovules of the parent plant and then released as seeds.

Distribution and ecology

Species of Fucus are recorded almost worldwide. They are dominant on the shores of the British Isles,[4] the northeastern coast of North America[5] and California.[6]

In the British Isles these larger brown algae occur on sheltered shores in fairly well defined zones along the shore from high-water mark to below low water mark. On the more exposed shores not all of these species can be found and on very exposed shores few, if any, occur. Pelvetia canaliculata forms a zone at the top of the shore. Just below this Fucus spiralis, Fucus vesiculosus, Fucus serratus and Laminaria form clear zones, one below the other, along the shore down to low water mark. On sheltered shores Ascophyllum nodosum usually forms a broad and dominating zone along the shore at the mid-littoral. Other brown algae can be found at the low-littoral such as Himanthalia, Laminaria saxatilis and Alaria esculenta. Small green and red algae and animals occur, protected under these large brown algae.[7] When washed up on beaches, kelp flies such as Coelopa pilipes feed and breed on Fucus algae.

Uses

In Scotland and Norway, up until the mid-19th century, several seaweed species from Fucus and other genera were harvested, dried, burned to ash, and further processed to become "kelp", which was a type of soda ash that was less costly in Britain than the barilla imported from Spain. It has an alkali content of about 2.5%–5% that was mainly sodium carbonate (Na2CO3), used in soapmaking, glassmaking, and other industries. The purest barilla had a sodium carbonate concentration of about 30%. The seaweed was also used as fertilizer for crop land in the same areas in which it was harvested.[8]

Fucus species can also be used for thalassotherapy, along with other species such as Turkish towel (Chondracanthus exasperatus), feather boa (Egregia menziesii), and finger kelp (Laminaria digitata).[9]

In 2005, it was announced that bacteria grown on Fucus have the ability to attack and kill the MRSA superbacterium.[10]

Because of their easily accessible apolar eggs and free-floating zygotes, several Fucus species have been used as model organisms to study cell polarity, the development of growth axes, and the role of the cell wall in establishing and maintaining cell identity.[11] [12] [13] [14] [15]

Predator

The seaweed fly, Coelopa frigida, together with other species of Coelopa, are known to feed, mate, and create habitats out of different species of Fucus. This is of particular notice when the Fucus is stranded on the beach and not when it is submerged under seawater. With increasing amounts of seaweed washing up on shores, there is an increasing recognition of Fucus and their close pairing with Coelopa.

Taxonomy

This list of species of Fucus excludes names of uncertain status:[16] [17]

* Species recorded around the coast of Britain.[4]

Fucus distichus

See main article: Fucus distichus. F. distichus is up to 10 cm long with a short stout cylindrical stipe, branching dichotomous, flat and with a mid-rib.[18] F. distichus subsp. edentatus was first described from Shetland by Börgesen in 1903. Powell found F. distichus subsp. anceps on the north coast of Caithness. It had also been recorded from: Orkney, Fair Isle, St Kilda and the Outer Hebrides in Scotland; in Ireland it had been recorded from Counties Clare, Donegal and Kerry.[19] [20] Two subspecies of F. distichus (subsp. anceps and subsp. edentatus) have been described from the British Isles.[19]

Fucus distichus is the organism used as a model to study the development of cell polarity, since it forms an apolar zygote that can develop polarity given a varying number of gradients.

Fucus serratus

See main article: Fucus serratus. F. serratus, toothed wrack, is the most distinctive of all the Fucus species. It clearly shows a distinctive serrated edge to the frond not shown by the other species of the genus.[21]

Fucus spiralis

See main article: Fucus spiralis. F. spiralis is one of the three most common algae on the shores of the British Isles. It grows to about 40 cm long and does not show air bladders as found on F.vesiculosus or toothed edges as found on F. serratus. It forms a zone near the top of the shore above the zones of F. vesiculosus and F. serratus.

Fucus vesiculosus

See main article: Fucus vesiculosus. This is one of the most common species of Fucus, common on most shores in the mid-littoral. It has the common name "bladder wrack", and is readily identified by a distinct mid-rib and air vesicles in pairs on either side of the mid-rib.[22]

Notes and References

  1. Book: H. Stegenga, J. J. Bolton & R. J. Anderson . 1997 . Seaweeds of the South African West Coast. Contributions from the Bolus Herbarium Volume 18 . 978-0-7992-1793-3 . Bolus Herbarium, University of Cape Town . Rondebosch.
  2. Web site: Fucus . Michael Guiry . 2007-04-28 . . https://web.archive.org/web/20070304122548/http://www.seaweed.ie/algae/fucus.lasso . 2007-03-04 . dead .
  3. Book: C. van den Hoek, D. G. Mann & H. M. Jahns . 1995 . Algae: An Introduction to Phycology . Cambridge University Press, Cambridge . 978-0-521-30419-1.
  4. Book: F. G. Hardy & M. D. Guiry . 2006 . A Checklist and Atlas of the Seaweeds of Britain and Ireland . British Phycological Society, London . 978-3-906166-35-3.
  5. Book: W. R. Taylor . 1972 . Marine Algae of the Northeastern Coast of North America . Ann Arbor, MI . . 978-0-472-04904-2.
  6. Book: I. A. Abbott & G. J. Hollenberg . 1976 . Marine Algae of California . . 978-0-8047-0867-8.
  7. Book: J. R. Lewis . 1964 . The Ecology of Rocky Shores . The English Universities Press Ltd, London.
  8. Book: A. Clow & N. L. Clow . 1952 . Chemical Revolution . Ayer Co Pub -->,Books for Libraries Press . 65–90 . 978-0-8369-1909-7 . Freeport, N.Y. .
  9. Book: Lewallen. Eleanor. Lewallen. John. Sea Vegetable Gourmet Cookbook and Wildcrafter's Guide. 21 March 1996. Mendocino sea Vegetable Company. Mendocino, CA. 978-0964764378. 62–63. 1st. en. Bathing with Seaweed.
  10. News: Sponge puzzles superbug experts . . December 26, 2005.
  11. Kropf . Darryl L . Bisgrove . Sherryl R . Hable . Whitney E . Establishing a growth axis in fucoid algae . Trends in Plant Science . Elsevier BV . 4 . 12 . 1999 . 1360-1385 . 10.1016/s1360-1385(99)01509-5 . 490–494. 10562734 .
  12. Kropf . D. . Kloareg . B . Quatrano . R. . Cell wall is required for fixation of the embryonic axis in Fucus zygotes . Science . American Association for the Advancement of Science (AAAS) . 239 . 4836 . 1988-01-08 . 0036-8075 . 10.1126/science.3336780 . 187–190. 3336780 . 1988Sci...239..187K .
  13. Quatrano . Ralph S. . Shaw . Sidney L. . Role of the cell wall in the determination of cell polarity and the plane of cell division in Fucus embryos . Trends in Plant Science . Elsevier BV . 2 . 1 . 1997 . 1360-1385 . 10.1016/s1360-1385(96)10049-2 . 15–21.
  14. Shaw . S.L. . Quatrano . R.S. . The role of targeted secretion in the establishment of cell polarity and the orientation of the division plane in Fucus zygotes . Development . The Company of Biologists . 122 . 9 . 1996-09-01 . 1477-9129 . 10.1242/dev.122.9.2623 . 2623–2630. 8787737 . free .
  15. Berger . F. . Taylor . A. . Brownlee . C. . Cell Fate Determination by the Cell Wall in Early Fucus Development . Science . American Association for the Advancement of Science (AAAS) . 263 . 5152 . 1994-03-11 . 0036-8075 . 10.1126/science.263.5152.1421 . 1421–1423. 17776514 . 1994Sci...263.1421B . 41196632 .
  16. Web site: . Fucus Linnaeus 1753: 1158 . August 21, 2006 . M. D. Guiry . 2006.
  17. Guiry, M.D. . 2011 . Fucus Linnaeus, 1753 . 144129 . 2012-02-29 .
  18. Book: G. Russell . 1978 . D. E. G. Irvine & J. H. Price . Modern Approaches to the Taxonomy of Red and Brown Algae . 339–369 . Systematics Association.
  19. H. T. Powell . 1957 . Studies in the genus Fucus L. II. Distribution and ecology of forms of Fucus distichus L. emend. Powell in Britain and Ireland . . 36 . 663–693 . 10.1017/S0025315400025923 . 3. 56433449 .
  20. H. T. Powell . 1957 . Studies in the genus Fucus L. I. Fucus distichus L. emend. Powell . . 36 . 407–432 . 10.1017/S002531540001688X . 2. 85774776 .
  21. Book: H. T. Powell . 1963 . Speciation in the genus Fucus L., and related genera . Systematics Association Publications . 5 . 63–77 . J. P. Harding & N. Tebble . Speciation in the Sea.
  22. Book: Lily Newton . 1931 . A Handbook of the British Seaweeds . . London.