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Algae (singular alga) encompass several groups of relatively simple living aquatic organisms that capture light energy through photosynthesis, using it to convert inorganic substances into organic matter.
Algae are photosynthetic organisms that occur in most habitats. Algae varies from small, single-celled species to complex multicellular species, such as the Giant kelps that grow to 65 meters in length. [1]
Although algae have conventionally been regarded as simple plants, they actually span more than one domain, including both Eukaryota and Bacteria (see Blue-green algae), as well as more than one kingdom, including plants and protists, the latter being traditionally considered more animal-like (see Protozoa). Thus algae do not represent a single evolutionary direction or line but a level of organization that may have developed several times in the early history of life on Earth.
Algae range from single-cell organisms to multicellular organisms, some with fairly complex differentiated form and (if marine) called seaweeds. All lack leaves, roots, flowers, seeds and other organ structures that characterize higher plants (vascular plants). They are distinguished from other protozoa in that they are photoautotrophic although this is not a hard and fast distinction as some groups contain members that are mixotrophic, deriving energy both from photosynthesis and uptake of organic carbon either by osmotrophy, myzotrophy, or phagotrophy. Some unicellular species rely entirely on external energy sources and have reduced or lost their photosynthetic apparatus.
All algae have photosynthetic machinery ultimately derived from the cyanobacteria, and so produce oxygen as a byproduct of photosynthesis, unlike non-cyanobacterial photosynthetic bacteria. It is estimated that algae produce about 73 to 87 percent of the net global production of oxygen[1] - which is available to humans and other terrestrial animals for respiration.
Algae are usually found in damp places or bodies of water and thus are common in terrestrial as well as aquatic environments. However, terrestrial algae are usually rather inconspicuous and far more common in moist, tropical regions than dry ones, because algae lack vascular tissues and other adaptations to live on land. Algae can, however, endure dryness and other conditions in symbiosis with a fungus as lichen.
The various sorts of algae play significant roles in aquatic ecology. Microscopic forms that live suspended in the water column — called phytoplankton — provide the food base for most marine food chains. In very high densities (so-called algal blooms) these algae may discolor the water and outcompete or poison other life forms. Seaweeds grow mostly in shallow marine waters. Some are used as human food or harvested for useful substances such as agar or fertilizer.
The study of marine and freshwater algae is called phycology or algology.
The US Algal Collection is represented by almost 300,000 accessioned and inventoried herbarium specimens.[2]
Cyanobacteria have been included among the algae, referred to as the cyanophytes or Blue-green algae, (the term "algae" refers to any aquatic organisms capable of photosynthesis)[2] though some recent treatises on algae specifically exclude them. Cyanobacteria are some of the oldest organisms to appear in the fossil record dating back to the Precambrian, possibly as far as about 3.5 billion years.[3] Ancient cyanobacteria likely produced much of the oxygen in the Earth's atmosphere.
Cyanobacteria can be unicellular, colonial, or filamentous. They have a cockprokaryotic cell structure typical of bacteria and conduct photosynthesis on specialized cytoplasmic membranes called thylakoid membranes, rather than in organelles. Some filamentous blue-green algae have specialized cells, termed heterocysts, in which nitrogen fixation occurs.[4]
All other algae are eukaryotes and conduct photosynthesis within membrane-bound structures (organelles) called chloroplasts. Chloroplasts contain DNA and are similar in structure to cyanobacteria, presumably representing reduced cyanobacterial endosymbionts. The exact nature of the chloroplasts is different among the different lines of algae, reflecting different endosymbiotic events. The table below lists the three major groups of eukaryotic algae and their lineage relationship is shown in the figure on the left. Note many of these groups contain some members that are no longer photosynthetic. Some retain plastids, but not chloroplasts, while others have lost them entirely.
It was W.H.Harvey (1811 — 1866) who first divided the algae into four divisions based on their pigmentation. This is the first use of a biochemical criterion in plant systematics. Harvey's four divisions were: red algae (Rhodophyta), brown algae (Heteromontophyta), green algae (Chlorophyta) and Diatomaceae (Dixon, 1973 p.232).[5]
Most of the simpler algae are unicellular flagellates or amoeboids, but colonial and non-motile forms have developed independently among several of the groups. Some of the more common organizational levels, more than one of which may occur in the life cycle of a species, are:
In three — lines even higher levels of organization have been reached, leading to organisms with full tissue differentiation. These are the brown algae [3] — some of which may reach 50 m in length (kelps)[6] — the red algae [4], and the green algae [5]. The most complex forms are found among the green algae (see Charales and Charophyta), in a lineage that eventually led to the higher land plants. The point where these non-algal plants begin and algae stop is usually taken to be the presence of reproductive organs with protective cell layers, a characteristic not found in the other alga groups.
The first plants on earth were algae and these still thrive in a range of aquatic habitats today. The land plants evolved from the algae, more specifically green algae. Some 400 million years ago freshwater, green, filamentous algae invaded the land. These probably had an isomorphic alternation of generations and were probably heterotrichous. Fossils of isolated land plant spores suggest land plants may have been around as long as 475 million years ago.
Some species of algae form symbiotic relationships with other organisms. In these symbioses, the algae supply photosynthates (organic substances) to the host organism providing protection to the algal cells. The host organism derives some or all of its energy requirements from the algae. Examples include:
Rhodophyta, Chlorophyta and Heterokontophyta, the three main algal Phyla, have life-cycles which show tremendous variation with considerable complexity. In general there is an asexual phase where the seaweed's cells are diploid, a sexual phase where the cells are haploid followed by fusion of the male and female gametes. Asexual reproduction is advantageous in that it permits efficient population increases, but less variation is possible. Sexual reproduction allows more variation but is more costly because of the waste of gametes that fail to mate, among other things. Often there is no strict alternation between the sporophyte and gametophyte phases and also because there is often an asexual phase, which could include the fragmentation of the thallus.[8][9][6]
In the British Isles the UK Biodiversity Steering Group Report estimated there to be 20,000 algal species in the UK, freshwater and marine, about 650 of these are seaweeds. Another checklist of freshwater algae reported only about 5000 species. It seems therefore that the 20,000 is an overestimate or an error (John, 2002 p.1).[10]
World-wide it is thought that there are over 5,000 species of red algae, 1,500 — 2,000 of brown algae and 8,000 of green algae. In Australia it is estimated that there are over 1,300 species of red algae, 350 species of brown algae and approximately 2,000 species of green algae totalling 3,650 species of algae in Australia.[11]
Around 400 species appear to be an average figure for the coastline of South African west coast.[12]
669 marine species have been described from California (U.S.A.).[13]
642 entities are listed in the check-list of Britain and Ireland (Hardy and Guiry, 2006).[14]
No publication has been found which attempts to discuss the general distribution of algae in the seas of the world. However some comments have been made by some authors.
Hardy, F.G. and Guiry, M.D. 2006. A Check-list and Atlas of the Seaweeds of Britain and Ireland. British Phycological Society, London. ISBN 3 906166 35 X
Hardy, F.G. and Aspinall, R.J. 1988. An Atlas of the Seaweeds of Northumberland and Durham. Northumberland Biological Records Centre. The Hancock Museum. The University Newcastle upon Tyne. Special publication: 3. ISBN 0 9509680 5 6
Morton, O. 1994. Marine Algae of Northern Ireland. Ulster Museum, Belfast. ISBN 0 900761 28 8
Morton, O. The marine macroalgae of County Donegal, Ireland. Bull. Ir. biogeog. Soc. 27:3 - 164.
Knight, M. and Park, M.W. 1931. Manx algae. An algal survey of the south end of the Isle of Man. L.M.B.C. Mem. Typ. Br. Mar. Pl. 390: 1 - 155.
Lund, S. 1959. The Marine Algae of East Greenland. I. Taxonomical part. Meddr. Grønland 156: 1 - 247.
Borgesen, F. 1903. Marine Algae, pp.339 - 532. In, Warming, E. (Ed.), Botany of the Faröes Based Upon Danish Investigations. Part II. Copenhagen. [reprint 1970]
Cabioc'h,J., Floc'h,J-Y., Le Toquin, A., Boudouresque, C-F., Meinesz, A. & Verlaque, M. 1992. Guide des algues des mers d'Europe. Delachaux et Niestlé, Switzerland. Gayral, P. 1958 Algues de la Côte Atlantique Marocaine. Rabat. Gayral, P. 1966. Algues des Côtes Françaises. Paris.
Borgesen,F. 1925. Marine algae from the Canary Islands, especially from Teneriffe and Gran Canaria. I. Chlorophyceae. Biol. Meddr 5: 1 - 113.
Borgesen,F. 1926. Marine algae from the Canary Islands especially from Teneriffe and Gran Canaria. II. Phaeophyceae. Biol. Meddr 6: 1 - 112.
Borgesen,F. 1927. Marine algae from the Canary Islands. III. Rhodophyceae. Part I, Bangiales and Nemalionales. Biol. Meddr 6: 1 - 97.
Borgesen,F. 1929. Marine algae from the Canary Islands. III Rhodophyceae. Part II. Cryptonemiales, Gigartinales and Rhodymeniales. Biol. Meddr 8: 1 - 97.
Borgesen,F. 1930. Marine algae from the Canary Islands. III Rhodophyceae. Part II. Cryptonemiales, Gigartinales and Rhodymeniales. Biol. Meddr 9: 1 - 159.
Taylor, W.R. 1957. Marine Algae of the Northeastern Coast of North America. University of Michigan Press, Ann Arbor.
Abbott, I.A. and Hollenberg, G.J. 1976. Marine Algae of California. Stanford University Press, California.
Stegenga, H. Bolton, J.J. and Anderson, R.J. 1997. Seaweeds of the South African West Coast. Bolus Herbarium Number 18, Publication jointly financed by the Fourcade Bequest and the Research Committee of the University of Cape Town and the Foundation for Research Development.
Huisman, J.M. 2000. Marine Plants of Australia. University of Western Australia Press, Nedlands, Western Australia 6907.
Lindauer, V.W., Chapman, V.J. and Aiken, M. 1961. The Marine Algae of New Zealamnd. Part II. Phaeophyta. Nova Hedwigia 3: 129 - 350. Chapman, V.J. 1969. The Marine Algae of New Zealand. Part III issues 1. Lehre: J.Cramer, 1 - 113. Chapman, V.J. and Dromgoole, F.I. 1970. The Marine Algae of New Zealand. Part III issues 2.Lehre: J.Cramer, 115 - 154. Chapman, V.J. and Parkinson, P.G. 1974 The Marine Algae of New Zealand. Part III issues 3.Lehre: J.Cramer,155 - 278. Chapman, V.J. 1979 The Marine Algae of New Zealand.Part III issues 4. Lehre: J.Cramer, 279 - 420.
For centuries seaweed has been used as fertilizer; Orwell writing in the 16th Century referring to drift weed in South Wales: "This kind of ore they often gather and lay in heaps where it heteth and rotteth, and will have a strong and loathsome smell; when being so rotten they cast it on the land, as they do their muck, and thereof springeth good corn, especially barley" and "After spring tides or great rigs of the sea, they fetch it in sacks on horse brackets, and carry the same three, four, or five miles, and cast it on the lande, which doth very much better the ground for corn and grass" (Chapman p.35).[15]
There are also commercial uses of algae as agar.[16]
Maerl is commonly used as a soil conditioner, it is dredged from the sea floor and crushed to form a powder. [17] It is still harvested around the coasts of Brittany in France and off Falmouth (also extensively in western Ireland) and is a popular fertilizer in these days of organic gardening investigated Falmouth maerl and found that L. corallioides predominated down to 6 m and P. calcareum from 6-10 m (Blunden et al., 1981).[18][19]
Chemical analysis of maerl showed that it contained 32.1% CaCO<sub>3</sub> and 3.1% MgCO<sub>3</sub> (dry weight).
Algae are used by humans in many ways. They are used as fertilizers, soil conditioners and are a source of livestock feed.[20] Because many species are aquatic and microscopic, they are cultured in clear tanks or ponds and either harvested or used to treat effluents pumped through the ponds. Algaculture on a large scale is an important type of aquaculture in some places.
Human food. Seaweeds are an important source of food, especially in Asia; They are excellent sources of many vitamins including: A, B1, B2, B6, niacin and C. They are rich in iodine, potassium, iron, magnesium and calcium.[21]
Algae is commercially cultivated as a nutritional supplement. One of the most popular microalgal species is Spirulina (Arthrospira platensis), which is a Cyanobacteria (known as blue-green algae), and has been hailed by some as a superfood.[12] Other algal species cultivated for their nutritional value include; Chlorella (a green algae), and Dunaliella (Dunaliella salina), which is high in beta-carotene and is used in vitamin C supplements.
In China at least 70 species of algae are eaten as is the Chinese "vegetable" known as fat choy (which is actually a cyanobacterium). Roughly 20 species of algae are used in everyday cooking in Japan.[22]
Certain species are edible; the best known, especially in Ireland is Palmaria palmata (Linnaeus) O. Kuntze (Rhodymenia palmata (Linnaeus) Kuntze, common name: dulse). [13] This is a red alga which is dried and may be bought in the shops in Ireland. It is eaten raw, fresh or dried, or cooked like spinach. Similarly, Durvillaea antarctica [14] is eaten in Chile, common name: cochayuyo. [15]
Porphyra (common name: purple laver), is also collected and used in a variety of ways (e.g. "laver bread" in the British Isles). In Ireland it is collected and made into a jelly by stewing or boiling. Preparation also involves frying with fat or converting to a pinkish jelly by heating the fronds in a saucepan with a little water and beating with a fork. It is also collected and used by people parts of Asia, specifically China and Japan as nori and along most of the coast from California to British Columbia. The Hawaiians and the Maoris of New Zealand also use it. Chondrus crispus, (probably confused with Mastocarpus stellatus, common name: Irish moss), is also used as "carrageen" for the stiffening of milk and dairy products, such as ice-cream. One particular use is in "instant" puddings, sauces and creams. Ulva lactuca (common name: sea lettuce), is used locally in Scotland where it is added to soups or used in salads. Alaria esculenta (common name: dabberlocks), is used either fresh or cooked, in Greenland, Iceland, Scotland and Ireland.
The natural pigments produced by algae can be used as an alternative to chemical dyes and coloring agents.[18] Many of the paper products used today are not recyclable because of the chemical inks that they use, paper recyclers have found that inks made from algae are much easier to break down. There is also much interest in the food industry into replacing the coloring agents that are currently used with coloring derived from algal pigments. In Israel, a spicies of green algae is grown in water tanks, then exposed to direct sunlight and heat which causes it to become bright red in color. It is then harvested and used as a natural pigment for foods such as Salmon. [19]
Between 100,000 and 170,000 wet tons of Macrocystis are harvested annually in California for alginate extraction and abalone feed.[20] [21]
Seaweed specimens are collected, preserved for research. Such preserved specimens will keep for two or three hundred years. Those of Carl von Linné (1707 — 1778) are still available for reference, and are used. Specimens may be collected from the shore; those below low tide must be collected by diving or dredging. The whole algal specimen should be collected, that is the holdfast, stipe and lamina. Specimens of algae reproducing will be the more useful for identification and research. When collected the details of the location and site should be noted. They can then be preserved pressed on paper or in a preserving liquid such as alcohol or solution of 5 per cent formalin/seawater. However formalin is reported to be carcinogenic.[23]
The ecology of the shores of the British Isles including a discussion of the different shores from sheltered to exposed along with an exposure scale is given by Lewis (1964).[24] An exposure scale of five stages is given:- Very Exposed Shores; Expose Shores; Semi-exposed Shores; Sheltered Shores and Very Sheltered Shores. Factors indicating the differences between these exposure scales are detailed. Very Exposed Shores have a wide Verrucaria zone entirely above the upper tide level, a Porphyra zone zone above the barnacle level and Lichina pygmaea is locally abundant. The eulittoral zone is dominated by barnacles and limpets with a coralline belt in the very low littoral along with other Rhodophyta and Alaria in the upper sublittoral. Exposed shores show a Verrucaria belt mainly above the high tide, with Porphyra and Lichina pygmaea. The mid shore is dominated by barnacles, limpets and some Fucus. Some Rhodophyta. Himanthalia and some Rhodophyta such as Mastocarpus and Corallina are found in the low littorral with Himanthalia, Alaria and [Laminaria digitata]] dominant in the upper sublittoral. The semi-exposed shores show a Verrucaria belt just above high tide with clear Pelvetia in the upper-littoral and Fucus serratus in the lower-littoral. Limpets, barnacles and short Fucus vesiculosus midshore. Fucus serratus with Rhodophyta, (Laurencia, Mastocarpus, Rhodymenia and Lomentaria). Laminaria and Saccorhiza polyschides and small algae common in the sublittoral. The sheltered shores show a narrow Verrucaria zone at high water and a full sequence of fucoids: Pelvetia, Fucus spiralis, Fucus vesiculosus, Fucus serratus Ascophyllum nodosum. Laminaria digitata is dominant the upper sublittoral. The very sheltered shores show a very narrow zone of Verrucaria, the dominance of the littoral by a full sequence of the fucoids and Ascophyllum covering the rocks. Laminaria saccharina, Halidrys, Chondrus and or Furcellaria.[25]
Atractophora hypnoides P.L.Crouan and H.M.Crouan (red algae)
Ascophyllum nodosum
Charales (green algae)
Chondrus crispus
Codium
Fucus
Ulva lactuca
Laminaria
Lemanea
Macrocystis
Mastocarpus stellatus
Pelvetia canaliculata
Palmaria palmata
Porphyra
A student, having collected some beautiful Algae on the shore, showed the contents of his vasculum to the Professor of Botany whose lectures he attended, expressing a wish to get some information respecting them. The Professor looked at them, and putting on his spectacles, again looked at them, when, pushing them from him, he exclaimed: "Pooh! a parcel of Seaweeds, Sir; a parcel of Seaweeds!"[26]
Algae is also known as "Pond Scum."
This has also been published as:-
Call us not weeds, we are flowers of the Sea,
For lovely and bright and gay tinted are we,
And quite independent of sun's fire or showers-
Then call us not weeds! We are ocean's bright flowers,
Not nursed like the plants of a summer parterre,
Where gales are but sighs of an evening air,
Our exquisite, fragile and delicate forms
Are nursed by the Ocean and rocked by the Storms. from: Historia naturalis bulgarica 4: 10 - 15.
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