DOCSLIB.ORG

Limits of Life on Earth Some Archaea and Bacteria

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Limits of Life on Earth Some Archaea and Bacteria Limits of life on Earth Thermophiles Temperatures up to ~55C are common, but T > 55C is Some archaea and bacteria (extremophiles) can live in associated usually with geothermal features (hot springs, environments that we would consider inhospitable to volcanic activity etc) life (heat, cold, acidity, high pressure etc) Thermophiles are organisms that can successfully live Distinguish between growth and survival: many organisms can survive intervals of harsh conditions but could not at high temperatures live permanently in such conditions (e.g. seeds, spores) Best studied extremophiles: may be relevant to the Interest: origin of life. Very hot environments tolerable for life do not seem to exist elsewhere in the Solar System • analogs for extraterrestrial environments • `extreme’ conditions may have been more common on the early Earth - origin of life? • some unusual environments (e.g. subterranean) are very widespread Extraterrestrial Life: Spring 2008 Extraterrestrial Life: Spring 2008 Grand Prismatic Spring, Yellowstone National Park Hydrothermal vents: high pressure in the deep ocean allows liquid water Colors on the edge of the at T >> 100C spring are caused by different colonies of thermophilic Vents emit superheated water (300C or cyanobacteria and algae more) that is rich in minerals Hottest water is lifeless, but `cooler’ ~50 species of such thermophiles - mostly archae with some margins support array of thermophiles: cyanobacteria and anaerobic photosynthetic bacteria oxidize sulphur, manganese, grow on methane + carbon monoxide etc… Sulfolobus: optimum T ~ 80C, minimum 60C, maximum 90C, also prefer a moderately acidic pH. Live by oxidizing sulfur Known examples can grow (i.e. multiply) at temperatures which is abundant near hot springs. as high as 110-120C… but can also survive at much lower temperatures Extraterrestrial Life: Spring 2008 Extraterrestrial Life: Spring 2008 Adaptations of thermophiles Low temperatures: growth below the freezing point is very difficult, but some liquid water exists below 0C in Generally, thermophiles are very similar to `ordinary’ thin films or in water under high pressure archaea and bacteria (DNA, same amino acids etc) Series of quite subtle differences, e.g.: Slow multiplication of bacteria living in permafrost has been seen at temperatures as low as -20C • cell membranes are made up of lipids that are more stable to high temperature • additional enzyme (reverse DNA gyrase) causes the DNA to fold up in a way that is more stable against heat Thought that the absolute maximum temperature is around 150C - above this DNA breaks up very readily Extraterrestrial Life: Spring 2008 Extraterrestrial Life: Spring 2008 1 Lake Vostok Atacama desert in Chile is one of the driest locations Large sub-glacial lake on Earth (14,000 km2) at a depth of ~3750m under Average annual rainfall Antarctica in parts of the Atacama is < 1mm / yr Water is not frozen, probably very oxygen rich May have been isolated for around a million years from No plants have lived for more than one million years any other environment Difficult location to find life - the NASA Viking experiments Terrestrial analog for an ocean on Europa? would fail. Microbes can be grown from shallow subsurface layers successfully. Extraterrestrial Life: Spring 2008 Extraterrestrial Life: Spring 2008 Other extremes Radiation High pressures: 10m of water adds 1 atmosphere of Radiation exposure is measured in Gray (Gy): pressure. Viable organisms have been recovered from the Mariana trench (10,900m, ~1100 atm). • 5-10 Gray is fatal for humans Main adaptations are in the cell membranes. • some microbes can survive 30,000 Gray Saline environments: haloarchaea thrive in waters with Adaptation: efficient repair mechanisms for DNA that is near saturation levels of salt (e.g. Dead Sea), and damaged by the radiation flux are found in rock salt deposits. Adapted to make use of very little water. Puzzle: such high levels of radiation are not found naturally on Earth - may be that radiation tolerance is Subterranean environments: microbes appear to exist a byproduct of adaptation to very dry environments in dry, hot subterranean environments (several km depth). Properties and origin unclear… Extraterrestrial Life: Spring 2008 Extraterrestrial Life: Spring 2008 Travel time from Mars to Earth is typically 1-10 Myr - all the known specimens probably came from a handful of impact events Ejection events likely produced large (30km) craters - but pressures and temperatures in some of the ejecta would have been low enough to allow survival Microbes within the rock would be shielded from ultraviolet radiation and cosmic rays… Interest: some meteorites from Mars have been recovered, many from Antarctica Extraterrestrial Life: Spring 2008 Extraterrestrial Life: Spring 2008 2 Sterilization of space missions to Mars, Europa Implications for extraterrestrial life Galileo orbiter was crashed into Jupiter to avoid any Life can flourish in environments well beyond those that are obviously `habitable’ chance that it might collide with and contaminate Europa Need liquid water, but -20C < T < 120C OK - modest Astrobiology missions to Mars, Europa need to be sterilized to very high standards: expansion of traditional habitable zone requirement • assembly in clean room conditions Subterranean organisms seem of greatest interest for • irradiation with gamma-rays Mars, Lake Vostok may be similar to Europa • heated to 105-124C for several hours • hydrogen peroxide plasma sterlilization… Can only speculate as to whether life on Earth started in an extreme environment… Extraterrestrial Life: Spring 2008 Extraterrestrial Life: Spring 2008 3.
Load more

Recommended publications
  • Anoxygenic Photosynthesis in Photolithotrophic Sulfur Bacteria and Their Role in Detoxication of Hydrogen Sulfide
    antioxidants Review Anoxygenic Photosynthesis in Photolithotrophic Sulfur Bacteria and Their Role in Detoxication of Hydrogen Sulfide Ivan Kushkevych 1,* , Veronika Bosáková 1,2 , Monika Vítˇezová 1 and Simon K.-M. R. Rittmann 3,* 1 Department of Experimental Biology, Faculty of Science, Masaryk University, 62500 Brno, Czech Republic; [email protected] (V.B.); [email protected] (M.V.) 2 Department of Biology, Faculty of Medicine, Masaryk University, 62500 Brno, Czech Republic 3 Archaea Physiology & Biotechnology Group, Department of Functional and Evolutionary Ecology, Universität Wien, 1090 Vienna, Austria * Correspondence: [email protected] (I.K.); [email protected] (S.K.-M.R.R.); Tel.: +420-549-495-315 (I.K.); +431-427-776-513 (S.K.-M.R.R.) Abstract: Hydrogen sulfide is a toxic compound that can affect various groups of water microorgan- isms. Photolithotrophic sulfur bacteria including Chromatiaceae and Chlorobiaceae are able to convert inorganic substrate (hydrogen sulfide and carbon dioxide) into organic matter deriving energy from photosynthesis. This process takes place in the absence of molecular oxygen and is referred to as anoxygenic photosynthesis, in which exogenous electron donors are needed. These donors may be reduced sulfur compounds such as hydrogen sulfide. This paper deals with the description of this metabolic process, representatives of the above-mentioned families, and discusses the possibility using anoxygenic phototrophic microorganisms for the detoxification of toxic hydrogen sulfide. Moreover, their general characteristics, morphology, metabolism, and taxonomy are described as Citation: Kushkevych, I.; Bosáková, well as the conditions for isolation and cultivation of these microorganisms will be presented. V.; Vítˇezová,M.; Rittmann, S.K.-M.R.
    [Show full text]
  • PROTISTS Shore and the Waves Are Large, Often the Largest of a Storm Event, and with a Long Period
    (seas), and these waves can mobilize boulders. During this phase of the storm the rapid changes in current direction caused by these large, short-period waves generate high accelerative forces, and it is these forces that ultimately can move even large boulders. Traditionally, most rocky-intertidal ecological stud- ies have been conducted on rocky platforms where the substrate is composed of stable basement rock. Projec- tiles tend to be uncommon in these types of habitats, and damage from projectiles is usually light. Perhaps for this reason the role of projectiles in intertidal ecology has received little attention. Boulder-fi eld intertidal zones are as common as, if not more common than, rock plat- forms. In boulder fi elds, projectiles are abundant, and the evidence of damage due to projectiles is obvious. Here projectiles may be one of the most important defi ning physical forces in the habitat. SEE ALSO THE FOLLOWING ARTICLES Geology, Coastal / Habitat Alteration / Hydrodynamic Forces / Wave Exposure FURTHER READING Carstens. T. 1968. Wave forces on boundaries and submerged bodies. Sarsia FIGURE 6 The intertidal zone on the north side of Cape Blanco, 34: 37–60. Oregon. The large, smooth boulders are made of serpentine, while Dayton, P. K. 1971. Competition, disturbance, and community organi- the surrounding rock from which the intertidal platform is formed zation: the provision and subsequent utilization of space in a rocky is sandstone. The smooth boulders are from a source outside the intertidal community. Ecological Monographs 45: 137–159. intertidal zone and were carried into the intertidal zone by waves. Levin, S. A., and R.
    [Show full text]
  • Algae and Cyanobacteria in Coastal and Estuarine Waters
    CHAPTER 7 Algae and cyanobacteria in coastal and estuarine waters n coastal and estuarine waters, algae range from single-celled forms to the seaweeds. ICyanobacteria are organisms with some characteristics of bacteria and some of algae. They are similar in size to the unicellular algae and, unlike other bacteria, contain blue-green or green pigments and are able to perform photosynthesis; thus, they are also termed blue-green algae. Algal blooms in the sea have occurred throughout recorded history but have been increasing during recent decades (Anderson, 1989; Smayda, 1989a; Hallegraeff, 1993). In several areas (e.g., the Baltic and North seas, the Adriatic Sea, Japanese coastal waters and the Gulf of Mexico), algal blooms are a recurring phe- nomenon. The increased frequency of occurrence has accompanied nutrient enrich- ment of coastal waters on a global scale (Smayda, 1989b). Blooms of non-toxic phytoplankton species and mass occurrences of macro-algae can affect the amenity value of recreational waters due to reduced transparency, dis- coloured water and scum formation. Furthermore, bloom degradation can be accom- panied by unpleasant odours, resulting in aesthetic problems (see chapter 9). Several human diseases have been reported to be associated with many toxic species of dinoflagellates, diatoms, nanoflagellates and cyanobacteria that occur in the marine environment (CDC, 1997). The effects of these algae on humans are due to some of their constituents, principally algal toxins. Marine algal toxins become a problem primarily because they may concentrate in shellfish and fish that are subsequently eaten by humans (CDR, 1991; Lehane, 2000), causing syndromes known as para- lytic shellfish poisoning (PSP), diarrhetic shellfish poisoning (DSP), amnesic shellfish poisoning (ASP), neurotoxic shellfish poisoning (NSP) and ciguatera fish poisoning (CFP).
    [Show full text]
  • The Unicellular and Colonial Organisms Prokaryotic And
    The Unicellular and Colonial Organisms Prokaryotic and Eukaryotic Cells As you know, the building blocks of life are cells. Prokaryotic cells are those cells that do NOT have a nucleus. They mostly include bacteria and archaea. These cells do not have membrane-bound organelles. Eukaryotic cells are those that have a true nucleus. That would include plant, animal, algae, and fungal cells. As you can see, to the left, eukaryotic cells are typically larger than prokaryotic cells. Today in lab, we will look at examples of both prokaryotic and eukaryotic unicellular organisms that are commonly found in pond water. When examining pond water under a microscope… The unpigmented, moving microbes will usually be protozoans. Greenish or golden-brown organisms will typically be algae. Microorganisms that are blue-green will be cyanobacteria. As you can see below, living things are divided into 3 domains based upon shared characteristics. Domain Eukarya is further divided into 4 Kingdoms. Domain Kingdom Cell type Organization Nutrition Organisms Absorb, Unicellular-small; Prokaryotic Photsyn., Archaeacteria Archaea Archaebacteria Lacking peptidoglycan Chemosyn. Unicellular-small; Absorb, Bacteria, Prokaryotic Peptidoglycan in cell Photsyn., Bacteria Eubacteria Cyanobacteria wall Chemosyn. Ingestion, Eukaryotic Unicellular or colonial Protozoa, Algae Protista Photosynthesis Fungi, yeast, Fungi Eukaryotic Multicellular Absorption Eukarya molds Plantae Eukaryotic Multicellular Photosynthesis Plants Animalia Eukaryotic Multicellular Ingestion Animals Prokaryotic Organisms – the archaea, non-photosynthetic bacteria, and cyanobacteria Archaea - Microorganisms that resemble bacteria, but are different from them in certain aspects. Archaea cell walls do not include the macromolecule peptidoglycan, which is always found in the cell walls of bacteria. Archaea usually live in extreme, often very hot or salty environments, such as hot mineral springs or deep-sea hydrothermal vents.
    [Show full text]
  • Archaeal Distribution and Abundance in Water Masses of the Arctic Ocean, Pacific Sector
    Vol. 69: 101–112, 2013 AQUATIC MICROBIAL ECOLOGY Published online April 30 doi: 10.3354/ame01624 Aquat Microb Ecol FREEREE ACCESSCCESS Archaeal distribution and abundance in water masses of the Arctic Ocean, Pacific sector Chie Amano-Sato1, Shohei Akiyama1, Masao Uchida2, Koji Shimada3, Motoo Utsumi1,* 1University of Tsukuba, Tennodai, Tsukuba, Ibaraki 305-8572, Japan 2National Institute for Environmental Studies, Onogawa, Tsukuba, Ibaraki 305-8506, Japan 3Tokyo University of Marine Science and Technology, Konan, Minato-ku, Tokyo 108-8477, Japan ABSTRACT: Marine planktonic Archaea have been recently recognized as an ecologically impor- tant component of marine prokaryotic biomass in the world’s oceans. Their abundance and meta- bolism are closely connected with marine geochemical cycling. We evaluated the distribution of planktonic Archaea in the Pacific sector of the Arctic Ocean using fluorescence in situ hybridiza- tion (FISH) with catalyzed reporter deposition (CARD-FISH) and performed statistical analyses using data for archaeal abundance and geochemical variables. The relative abundance of Thaum - archaeota generally increased with depth, and euryarchaeal abundance was the lowest of all planktonic prokaryotes. Multiple regression analysis showed that the thaumarchaeal relative abundance was negatively correlated with ammonium and dissolved oxygen concentrations and chlorophyll fluorescence. Canonical correspondence analysis showed that archaeal distributions differed with oceanographic water masses; in particular, Thaumarchaeota were abundant from the halocline layer to deep water, where salinity was higher and most nutrients were depleted. However, at several stations on the East Siberian Sea side of the study area and along the North- wind Ridge, Thaumarchaeota and Bacteria were proportionally very abundant at the bottom in association with higher nutrient conditions.
    [Show full text]
  • About Cyanobacteria BACKGROUND Cyanobacteria Are Single-Celled Organisms That Live in Fresh, Brackish, and Marine Water
    About Cyanobacteria BACKGROUND Cyanobacteria are single-celled organisms that live in fresh, brackish, and marine water. They use sunlight to make their own food. In warm, nutrient-rich environments, microscopic cyanobacteria can grow quickly, creating blooms that spread across the water’s surface and may become visible. Because of the color, texture, and location of these blooms, the common name for cyanobacteria is blue-green algae. However, cyanobacteria are related more closely to bacteria than to algae. Cyanobacteria are found worldwide, from Brazil to China, Australia to the United States. In warmer climates, these organisms can grow year-round. Scientists have called cyanobacteria the origin of plants, and have credited cyanobacteria with providing nitrogen fertilizer for rice and beans. But blooms of cyanobacteria are not always helpful. When these blooms become harmful to the environment, animals, and humans, scientists call them cyanobacterial harmful algal blooms (CyanoHABs). Freshwater CyanoHABs can use up the oxygen and block the sunlight that other organisms need to live. They also can produce powerful toxins that affect the brain and liver of animals and humans. Because of concerns about CyanoHABs, which can grow in drinking water and recreational water, the U.S. Environmental Protection Agency (EPA) has added cyanobacteria to its Drinking Water Contaminant Candidate List. This list identifies organisms and toxins that EPA considers to be priorities for investigation. ASSESSING THE IMPACT ON PUBLIC HEALTH Reports of poisonings associated with CyanoHABs date back to the late 1800s. Anecdotal evidence and data from laboratory animal research suggest that cyanobacterial toxins can cause a range of adverse human health effects, yet few studies have explored the links between CyanoHABs and human health.
    [Show full text]
  • Oceans of Archaea Abundant Oceanic Crenarchaeota Appear to Derive from Thermophilic Ancestors That Invaded Low-Temperature Marine Environments
    Oceans of Archaea Abundant oceanic Crenarchaeota appear to derive from thermophilic ancestors that invaded low-temperature marine environments Edward F. DeLong arth’s microbiota is remarkably per- karyotes), Archaea, and Bacteria. Although al- vasive, thriving at extremely high ternative taxonomic schemes have been recently temperature, low and high pH, high proposed, whole-genome and other analyses E salinity, and low water availability. tend to support Woese’s three-domain concept. One lineage of microbial life in par- Well-known and cultivated archaea generally ticular, the Archaea, is especially adept at ex- fall into several major phenotypic groupings: ploiting environmental extremes. Despite their these include extreme halophiles, methanogens, success in these challenging habitats, the Ar- and extreme thermophiles and thermoacido- chaea may now also be viewed as a philes. Early on, extremely halo- cosmopolitan lot. These microbes philic archaea (haloarchaea) were exist in a wide variety of terres- first noticed as bright-red colonies trial, freshwater, and marine habi- Archaea exist in growing on salted fish or hides. tats, sometimes in very high abun- a wide variety For many years, halophilic isolates dance. The oceanic Marine Group of terrestrial, from salterns, salt deposits, and I Crenarchaeota, for example, ri- freshwater, and landlocked seas provided excellent val total bacterial biomass in wa- marine habitats, model systems for studying adap- ters below 100 m. These wide- tations to high salinity. It was only spread Archaea appear to derive sometimes in much later, however, that it was from thermophilic ancestors that very high realized that these salt-loving invaded diverse low-temperature abundance “bacteria” are actually members environments.
    [Show full text]
  • Rhythmicity of Coastal Marine Picoeukaryotes, Bacteria and Archaea Despite Irregular Environmental Perturbations
    Rhythmicity of coastal marine picoeukaryotes, bacteria and archaea despite irregular environmental perturbations Stefan Lambert, Margot Tragin, Jean-Claude Lozano, Jean-François Ghiglione, Daniel Vaulot, François-Yves Bouget, Pierre Galand To cite this version: Stefan Lambert, Margot Tragin, Jean-Claude Lozano, Jean-François Ghiglione, Daniel Vaulot, et al.. Rhythmicity of coastal marine picoeukaryotes, bacteria and archaea despite irregular environmental perturbations. ISME Journal, Nature Publishing Group, 2019, 13 (2), pp.388-401. 10.1038/s41396- 018-0281-z. hal-02326251 HAL Id: hal-02326251 https://hal.archives-ouvertes.fr/hal-02326251 Submitted on 19 Nov 2020 HAL is a multi-disciplinary open access L’archive ouverte pluridisciplinaire HAL, est archive for the deposit and dissemination of sci- destinée au dépôt et à la diffusion de documents entific research documents, whether they are pub- scientifiques de niveau recherche, publiés ou non, lished or not. The documents may come from émanant des établissements d’enseignement et de teaching and research institutions in France or recherche français ou étrangers, des laboratoires abroad, or from public or private research centers. publics ou privés. Rhythmicity of coastal marine picoeukaryotes, bacteria and archaea despite irregular environmental perturbations Stefan Lambert, Margot Tragin, Jean-Claude Lozano, Jean-François Ghiglione, Daniel Vaulot, François-Yves Bouget, Pierre Galand To cite this version: Stefan Lambert, Margot Tragin, Jean-Claude Lozano, Jean-François Ghiglione, Daniel
    [Show full text]
  • CYANOBACTERIA (BLUE-GREEN ALGAE) BLOOMS When in Doubt, It’S Best to Keep Out!
    Cyanobacteria Blooms FAQs CYANOBACTERIA (BLUE-GREEN ALGAE) BLOOMS When in doubt, it’s best to keep out! What are cyanobacteria? Cyanobacteria, also called blue-green algae, are microscopic organisms found naturally in all types of water. These single-celled organisms live in fresh, brackish (combined salt and fresh water), and marine water. These organisms use sunlight to make their own food. In warm, nutrient-rich (high in phosphorus and nitrogen) environments, cyanobacteria can multiply quickly, creating blooms that spread across the water’s surface. The blooms might become visible. How are cyanobacteria blooms formed? Cyanobacteria blooms form when cyanobacteria, which are normally found in the water, start to multiply very quickly. Blooms can form in warm, slow-moving waters that are rich in nutrients from sources such as fertilizer runoff or septic tank overflows. Cyanobacteria blooms need nutrients to survive. The blooms can form at any time, but most often form in late summer or early fall. What does a cyanobacteria bloom look like? You might or might not be able to see cyanobacteria blooms. They sometimes stay below the water’s surface, they sometimes float to the surface. Some cyanobacteria blooms can look like foam, scum, or mats, particularly when the wind blows them toward a shoreline. The blooms can be blue, bright green, brown, or red. Blooms sometimes look like paint floating on the water’s surface. As cyanobacteria in a bloom die, the water may smell bad, similar to rotting plants. Why are some cyanbacteria blooms harmful? Cyanobacteria blooms that harm people, animals, or the environment are called cyanobacteria harmful algal blooms.
    [Show full text]
  • Archaea and the Origin of Eukaryotes
    REVIEWS Archaea and the origin of eukaryotes Laura Eme, Anja Spang, Jonathan Lombard, Courtney W. Stairs and Thijs J. G. Ettema Abstract | Woese and Fox’s 1977 paper on the discovery of the Archaea triggered a revolution in the field of evolutionary biology by showing that life was divided into not only prokaryotes and eukaryotes. Rather, they revealed that prokaryotes comprise two distinct types of organisms, the Bacteria and the Archaea. In subsequent years, molecular phylogenetic analyses indicated that eukaryotes and the Archaea represent sister groups in the tree of life. During the genomic era, it became evident that eukaryotic cells possess a mixture of archaeal and bacterial features in addition to eukaryotic-specific features. Although it has been generally accepted for some time that mitochondria descend from endosymbiotic alphaproteobacteria, the precise evolutionary relationship between eukaryotes and archaea has continued to be a subject of debate. In this Review, we outline a brief history of the changing shape of the tree of life and examine how the recent discovery of a myriad of diverse archaeal lineages has changed our understanding of the evolutionary relationships between the three domains of life and the origin of eukaryotes. Furthermore, we revisit central questions regarding the process of eukaryogenesis and discuss what can currently be inferred about the evolutionary transition from the first to the last eukaryotic common ancestor. Sister groups Two descendants that split The pioneering work by Carl Woese and colleagues In this Review, we discuss how culture- independent from the same node; the revealed that all cellular life could be divided into three genomics has transformed our understanding of descendants are each other’s major evolutionary lines (also called domains): the archaeal diversity and how this has influenced our closest relative.
    [Show full text]
  • The Cells That Changed the World (Adapted from the 2003 Windows to the Sea Expedition)
    Thunder Bay Sinkholes 2008 The Cells That Changed the World (adapted from the 2003 Windows to the Sea Expedition) FOCUS SEATIN G ARRAN G E M ENT Cyanobacteria Classroom style or groups of three to four students GRADE LEVE L MAXI M U M NU M BER O F STUDENTS 9-12 (LIfe Science) 30 FOCUS QUESTION KEY WORDS What are cyanobacteria, and how have they Cold seeps been important to life on Earth? Cyanobacteria Photosynthesis LEARNIN G OBJECTIVES Chemosynthesis Students will compare and contrast cyanobacteria with eukaryotic algae. BAC kg ROUND IN F OR M ATION In June, 2001, the Ocean Explorer Thunder Bay Students will discuss differences in photosynthesis ECHO Expedition was searching for shipwrecks by cyanobacteria and green algae. in the deep waters of the Thunder Bay National Marine Sanctuary and Underwater Preserve in Students will discuss the role of cyanobacteria in Lake Huron. But the explorers discovered more the development of life on Earth. than shipwrecks: dozens of underwater sinkholes in the limestone bedrock, some of which were MATERIA L S several hundred meters across and 20 meters Copies of “Cyanobacteria Discovery deep. The following year, an expedition to sur- Worksheet,” one copy for each student or stu- vey the sinkholes found that some of them were dent group releasing fluids that produced a visible cloudy (Optional) Cultures of live cyanobacteria and layer above the lake bottom, and the lake floor materials for microscopic examination near some of the sinkholes was covered by con- spicuous green, purple, white, and brown mats. AUDIOVISUA L MATERIA L S None Preliminary studies of the mats have found that where water is shallow (≤ 1.0 m) the mats are TEACHIN G TI M E composed of green algae.
    [Show full text]
  • Factors Controlling the Community Structure of Picoplankton in Contrasting Marine Environments
    Biogeosciences, 15, 6199–6220, 2018 https://doi.org/10.5194/bg-15-6199-2018 © Author(s) 2018. This work is distributed under the Creative Commons Attribution 4.0 License. Factors controlling the community structure of picoplankton in contrasting marine environments Jose Luis Otero-Ferrer1, Pedro Cermeño2, Antonio Bode6, Bieito Fernández-Castro1,3, Josep M. Gasol2,5, Xosé Anxelu G. Morán4, Emilio Marañon1, Victor Moreira-Coello1, Marta M. Varela6, Marina Villamaña1, and Beatriz Mouriño-Carballido1 1Departamento de Ecoloxía e Bioloxía Animal, Universidade de Vigo, Vigo, Spain 2Institut de Ciències del Mar, Consejo Superior de Investigaciones Científicas, Barcelona, Spain 3Departamento de Oceanografía, Instituto de investigacións Mariñas (IIM-CSIC), Vigo, Spain 4King Abdullah University of Science and Technology (KAUST), Read Sea Research Center, Biological and Environmental Sciences and Engineering Division, Thuwal, Saudi Arabia 5Centre for Marine Ecosystem Research, School of Sciences, Edith Cowan University, WA, Perth, Australia 6Centro Oceanográfico de A Coruña, Instituto Español de Oceanografía (IEO), A Coruña, Spain Correspondence: Jose Luis Otero-Ferrer ([email protected]) Received: 27 April 2018 – Discussion started: 4 June 2018 Revised: 4 October 2018 – Accepted: 10 October 2018 – Published: 26 October 2018 Abstract. The effect of inorganic nutrients on planktonic as- played a significant role. Nitrate supply was the only fac- semblages has traditionally relied on concentrations rather tor that allowed the distinction among the ecological
    [Show full text]