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Algae Algae

Links

Higher taxa:  Life   Algae   IDnature guides: Groups_Algae, North_American_Invasives IDnature guide Phylogeny Overview Links to other sites Diatom We parsed the following live from the Web into this page. Such content is managed by its original site and not cached on Discover Life. Please send feedback and corrections directly to the source. See original regarding copyrights and terms of use. University of Western Cape, South Africa University of Maryland

Kinds

Charophytes Chlorophyta Dinophyta -- Dinoflagellates, Red tides, Pyrrophycophyta Euglenophyta -- Euglenophytes, Euglenophyte algae Ochrophyta -- Yellow-green algae, Golden algae, Xanthophyta Streptophyta -- Green algae, Stoneworts, Brittleworts, Chlorophyta, Charophyta

Overview

Algae are mainly found in marine or freshwater environments but also occupy such extreme environments as deserts, boiling springs, ice, and snow. Algae survive by capturing light energy which is used to convert inorganic substances into simple sugars, this process is commonly known as Photosynthesis. As a by-product of photosynthesis, Algae produce oxygen which other aquatic life uses. Algae can be found in a variety of forms ranging from single-celled to complex multicellular forms, such as the Kelp which grow to be over sixty meters in length. Algae are vital in many food chains acting as the primary producer of organic matter. Algae are important to humans in the form of food and medicine. Algae are also important in the make up of coral reefs, coralline algae engage in a symbiotic relationship with coral to form large coral reefs.

Phylogeny

Tree of Life Scientific name -- Common name Algae -- Algae Alveolates Ciliates Colponema Dinoflagellates Colpodella Perkinsus Euapicomplexa Chlorarachniophytes Lotharella globosa Lotharella amoeboformis Gymnochlora stellata Chlorarachnion reptans Strain BC52 Flagellated strains Cryptochlora perforans Cryptomonads Euglenids Glaucophytes Haptophytes Rhodophyta -- Red algae Cyanidium Porphyridiales Compsopogonales Bangiales Florideophyceae Stramenopiles Viridaeplantae -- Green plants

Links to other sites

Algaebase -- Information database for algae. Charophycean Green Algae -- Information on charophycean green algae. Berkeley -- Introduction to green algae.

Acknowledgements

Richard McCourt Acadamy of Natural Sciences, Philadelphia Rex Lowe Bowling Green State University John Pickering University of Georgia, Athens David Porter Department of Botany University of Georgia, Athens

Following modified from University of Western Cape, South Africa

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How many Kingdoms? The concept of Kingdom, as well as most other taxonomic levels predate the realisation that living organisms have undergone evolution and that phylogenies can be traced through a combination of morphology, anatomy, ultrastructure and (more recently) molecular sequences. Rather than modifying our taxonomic systems, we have rather attempted to mould phylogenies so that they fit into the Kingdom-Division-Class-Order-Family-Genus-Species series. Therefore, the squeezing of organisms into these categories is somewhat arbitrary. For example, the evolutionary distance between divisions varies enormously from seed plants to red algae, showing that the concept of "division" is not used consistently in different groups. The classification of organisms into Kingdoms carries the implicit assumption that once lineages diverge, genetic information does not cross back again from other lineages. We now know that there are a number of ways that genetic material has crossed lineages, the most obvious one being the endosymbiosis of chloroplasts and mitochondria. Therefore, the concept of Kingdom is an imperfect concept, and one that biologists are still trying to figure out how to deal with in the light of our current and steadily advancing knowledge. It has long been recognized that the 2-Kingdom system was inadequate. In 1969, Robert H Whittaker proposed a five-kingdom system as an alternative to the 2-Kingdom System. The Archaebacteria and the Eubacteria are treated as subkingdoms under this system. Various authors have used either Protista or Protoctista for the kingdom that includes most eukaryotic algae. Under this system, photosynthetic organisms occur in three kingdoms: Monera, Protista, and Plantae. In most treatments that use this system, the Chlorophyta are included in the Protista and not the plant kingdom, something which is clearly not supported by the current evidence. Two Kingdoms Five Kingdoms Eight Kingdoms Animalia Monera Eubacteria Plantae Protista (Protoctista in some treatments) Archaebacteria    Plantae Archaezoa    Animalia Protozoa    Fungi Chromista       Plantae       Animalia       Fungi The Monera were eventually split into the Kingdoms: Eubacteria and Archaebacteria. A further Kingdom, the Chromista was proposed at the same time for the heterokontic organisms, although this was and remains controversial. The kingdom Archaezoa was proposed for three phyla (Archaemoebae, Metamonada, Microsporidia) which differ from all other eukaryotes in lacking mitochondria, peroxosomes, Golgi dictyosomes and cisternae, and probably also in having 70S rather than 80S ribosomes. Modern studies show that even the eight kingdom system is not adequate. Some groups are paraphyletic, others are polyphyletic. Current evidence is pointing towards the idea that there is a single eukaryotic kingdom, if indeed the concept of "Kingdom" has any fundamental meaning at all in evolutionary phylogeny. However, there is no consensus in this regard, and you are still likely to see photosynthetic organisms treated according to any of the above systems, or without regard to their position within Kingdoms at all.

Following modified from University of Maryland

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Photosynthetic Life Syllabus -Fall 1998 I: Introduction to Photosynthesis Week 1: 8/31 Review of the biochemistry of photosynthesis The shape of the Tree of Life as measured by SSU rRNA Part I - Eukaryotes Part II - Prokaryotes II: Anoxygenic Photosynthetetic Bacteria Week 2: 9/7 Holiday: Monday 9/7/98 Tree of Life (continued) Proteobacteria The relationship between physiology and ecological niche Week 3: 9/14 First homework assignement due Monday 9/14 Green Sulfur Bacteria Green Nonsulfur Bacteria Heliobacteria III: Cyanobacteria and Plastids Week 4: 9/21 Anoxygenic photosynthesis in nature Phototroph layering in stratified lakes Life on a mud flat Phototrophs in extreme environments Cyanobacteria "Prochlorophytes" and variation in cyanobacterial pigmentation. Week 5: 9/28 Carbon fixation in prokaryotes Eutrophication and nuisance organisms in the freshwater environment IV: Eukaryotes - Glaucocystophyta and Rhodophyta Week 6: 10/5 Second homework assignment due Monday, 10/5 The Endosymbiotic Origin of Plastids Three major lineages of primary plastids Glaucocystophyta, Rhodophyta, Chlorophyta How many symbiotic events? Week 7: 10/12 The Endosymbiotic Origin of Plastids (continued) Exam Review Midterm Exam: Friday October 16 V: Eukaryotes - Taxa with secondary plastids derived from red algae Week 8: 10/19 Glaucocystophyta Plastids with cell wall Rhodophyta Alternation of generations as a response to the loss of flagella Parasitism in red algae -- cytosolic hijacking Week 9: 10/26 Cryptomonads The ultrastructure of secondary endosymbiosis Photosynthetic organisms in the fossil record The early evolution of life The transition to an oxidizing atmosphere Week 10: 11/2 Haptophyta (prymnesiophytes) Heterokonts Chrysophyceae and kin Week 11: 11/9 Third homework assignment due Monday 11/9 Heterokonts (continued) Xanthophyceae Eustigmatophyceae Bacillariophyta (Diatoms) Phaeophyta (Brown Algae) Adaptation to the intertidal environment   Week 12: 11/16 Heterokonts (continued) Bacillariophyta (Diatoms) Phaeophyta (Brown Algae) Adaptation to the intertidal environment Week 13: 11/23 Fourth homework assignment due 11/23 Thanksgiving Holiday 11/27 Phytoplankton Ecology Algae in the open ocean Week 14: 11/30 Dinoflagellates Apicomplexa - nonphotosynthetic plastids in parasites Toxin-forming algae (including Pfiesteria) Feeding mechanisms in mixotrophic organism VI: Eukaryotes - Taxa with green plastids Chlorophyta Micromonadophyceae Ulvophyceae Pleurastrophyceae Chlorophyceae Charophyceae The evolution of cell division Algae as model systems Algae in biotechnology Week 15: 12/7 Taxa with secondary plastids from green algae Chlorarachniophyta Euglenophyta The molecular biology of secondary endosymbiosis Molecular traffic within the cell Molecular systematics of the eukaryotes revisited Major Crown Group tax VII: Land Plants: the Drier Algae Charophyceae sensu Mattox and Stewart The transition to a terrestrial flora Embryophytes - green algae adapted to life on land Alternation of generations Structural adaptations Biochemical adaptations Final Exam: 12/17