DOCSLIB.ORG

Trophic Interactions in the Pelagic

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Trophic Interactions in the Pelagic Trophic interactions in the pelagic Dissertation zur Erlangung des Doktorgrades der Mathematisch-Naturwissenschaftlichen Fakultät der Christian-Albrechts-Universität zu Kiel vorgelegt von Susanna Knotz Kiel 2006 Referent: Professor Dr. U. Sommer Koreferent: PD Dr. M. Boersma Tag der mündlichen Prüfung: 6. Juli 2006 Zum Druck genehmigt: 4. Januar 2007 der Dekan: gez. J. Grotemeyer 2 Content Chapter 1: Community structure of marine pelagic food webs and trophic interactions................................................................................................................ 5 1.1. Introductory remarks................................................................................................... 5 1.2. The North Sea plankton communities off Helgoland ...............................................6 Phytoplankton................................................................................................................................ 6 Zooplankton................................................................................................................................... 7 Ichthyoplankton.............................................................................................................................. 8 Microbial food web......................................................................................................................... 9 1.3. Factors influencing plankton communities.............................................................10 Hydrography of the German Bight (Otto et al. 1990).................................................................... 10 Irradiance, temperature and salinity............................................................................................. 11 Nutrients and nutrient limitation – food quantity and quality......................................................... 11 Algal toxins and chemical defence............................................................................................... 14 Anthropogenic impacts – excess nutrients, toxins, fishing, climate change................................. 15 1.4. Internal factors influencing zooplankton communities ........................................ 16 1.5. Overview of the following chapters..........................................................................17 Chapter 2: Microassays for a set of enzymes in individual small marine copepods ................................................................................................................. 19 2.1. Introduction................................................................................................................ 19 2.2. Materials and methods.............................................................................................. 20 2.3. Results and discussion............................................................................................. 24 Chapter 3: Sublethal physiological effects of food limitation in copepods ...... 28 3.1. Introduction................................................................................................................ 28 3.2. Material and Methods................................................................................................ 30 Laboratory experiments............................................................................................................... 30 Digestive enzyme activities.......................................................................................................... 30 Water soluble protein content of individuals................................................................................. 30 Protease zymograms................................................................................................................... 31 Statistics ...................................................................................................................................... 32 3.3. Results........................................................................................................................ 32 Mortality and survival after starvation........................................................................................... 32 Hunger experiments – digestive enzyme activities and protein contents..................................... 33 Hunger experiments – protease zymograms................................................................................ 34 Species comparison – protease zymograms ............................................................................... 35 3.4. Discussion.................................................................................................................. 36 Time scales of reactions.............................................................................................................. 37 Role of enzymes.......................................................................................................................... 39 Zymograms.................................................................................................................................. 40 Species specificity........................................................................................................................ 41 Sexual differences........................................................................................................................ 41 Conclusion .................................................................................................................................. 41 Chapter 4: Influence of food quality and quantity on egg production of Acartia clausi and Temora longicornis during a spring phytoplankton bloom.............. 43 4.1. Introduction................................................................................................................ 43 4.2. Material and Methods................................................................................................ 45 Sampling – animals and surface seawater................................................................................... 45 3 Abiotic environmental data........................................................................................................... 46 Phytoplankton determination........................................................................................................ 46 Dry mass, C, N and P determination............................................................................................ 46 Copepod egg production.............................................................................................................. 47 Copepod grazing selectivity......................................................................................................... 48 Statistics....................................................................................................................................... 50 4.3. Results........................................................................................................................ 50 Abiotic factors............................................................................................................................... 50 Prey community structure influencing egg production.................................................................. 51 Stoichiometric factors influencing egg production........................................................................ 57 Grazing behaviour........................................................................................................................ 58 4.4. Discussion.................................................................................................................. 64 Conclusion................................................................................................................................... 68 Chapter 5: Stable isotopes as predictors of copepod reproductive success....69 5.1. Introduction ............................................................................................................... 69 5.2. Material and Methods................................................................................................ 71 Seasonal Study............................................................................................................................ 71 Sampling – animals and surface seawater................................................................................... 71 Copepod egg production ............................................................................................................. 72 Stable isotope determination........................................................................................................ 72 Protein content and enzyme activities.......................................................................................... 72 Spatial study................................................................................................................................. 73 C, N and P determination............................................................................................................. 74 5.3. Results........................................................................................................................ 74 Seasonal Study............................................................................................................................ 74 Protein and digestive enzyme activities....................................................................................... 81 Spatial study................................................................................................................................
Load more

Recommended publications
  • Development of a Quantitative PCR Assay for the Detection And
    bioRxiv preprint doi: https://doi.org/10.1101/544247; this version posted February 8, 2019. The copyright holder for this preprint (which was not certified by peer review) is the author/funder, who has granted bioRxiv a license to display the preprint in perpetuity. It is made available under aCC-BY-NC-ND 4.0 International license. Development of a quantitative PCR assay for the detection and enumeration of a potentially ciguatoxin-producing dinoflagellate, Gambierdiscus lapillus (Gonyaulacales, Dinophyceae). Key words:Ciguatera fish poisoning, Gambierdiscus lapillus, Quantitative PCR assay, Great Barrier Reef Kretzschmar, A.L.1,2, Verma, A.1, Kohli, G.S.1,3, Murray, S.A.1 1Climate Change Cluster (C3), University of Technology Sydney, Ultimo, 2007 NSW, Australia 2ithree institute (i3), University of Technology Sydney, Ultimo, 2007 NSW, Australia, [email protected] 3Alfred Wegener-Institut Helmholtz-Zentrum fr Polar- und Meeresforschung, Am Handelshafen 12, 27570, Bremerhaven, Germany Abstract Ciguatera fish poisoning is an illness contracted through the ingestion of seafood containing ciguatoxins. It is prevalent in tropical regions worldwide, including in Australia. Ciguatoxins are produced by some species of Gambierdiscus. Therefore, screening of Gambierdiscus species identification through quantitative PCR (qPCR), along with the determination of species toxicity, can be useful in monitoring potential ciguatera risk in these regions. In Australia, the identity, distribution and abundance of ciguatoxin producing Gambierdiscus spp. is largely unknown. In this study we developed a rapid qPCR assay to quantify the presence and abundance of Gambierdiscus lapillus, a likely ciguatoxic species. We assessed the specificity and efficiency of the qPCR assay. The assay was tested on 25 environmental samples from the Heron Island reef in the southern Great Barrier Reef, a ciguatera endemic region, in triplicate to determine the presence and patchiness of these species across samples from Chnoospora sp., Padina sp.
    [Show full text]
  • Environmental Quality Standards for Barium in Surface Water Proposal for an Update According to the Methodology of the Water Framework Directive
    Environmental quality standards for barium in surface water Proposal for an update according to the methodology of the Water Framework Directive This report contains an erratum d.d. 29-01-2021 on page 111 RIVM letter report 2020-0024 E.M.J. Verbruggen | C.E. Smit | P.L.A. van Vlaardingen Environmental quality standards for barium in surface water Proposal for an update according to the methodology of the Water Framework Directive This report contains an erratum d.d. 29-01-2021 on page 111 RIVM letter report 2020-0024 E.M.J. Verbruggen | C.E. Smit | P.L.A. van Vlaardingen RIVM letter report 2020-0024 Colophon © RIVM 2020 Parts of this publication may be reproduced, provided acknowledgement is given to: National Institute for Public Health and the Environment, along with the title and year of publication. DOI 10.21945/RIVM-2020-0024 E.M.J. Verbruggen (author), RIVM C.E. Smit (author), RIVM P.L.A. van Vlaardingen. (author), RIVM Contact: Els Smit Centre for Safety of Substances and Products [email protected] This investigation has been performed by order and for the account of Ministry of Infrastructure and Water Management, within the framework of the project ‘Chemical substances, standard setting and Priority Substances Directive’. Published by: National Institute for Public Health and the Environment, RIVM P.O. Box1 | 3720 BA Bilthoven The Netherlands www.rivm.nl/en Page 2 of 111 RIVM letter report 2020-0024 Synopsis Environmental quality standards for barium in surface water Proposal for an update according to the methodology of the Water Framework Directive RIVM is proposing new water quality standards for barium in surface water.
    [Show full text]
  • Estuarine Response to Nutrient Enrichment, a Counterpart of Eutrophication
    ESTUARINE RESPONSE TO NUTRIENT ENRICHMENT, A COUNTERPART OF EUTROPHICATION: AN ANNOTATED BIBLIOGRAPHY K. L. WEBB D. M. HAYWARD J. M. BAKER B. MURRAY VIRGINIA INSTITUTE OF MARINE SCIENCE AND SCHOOL OF MARINE SCIENCE COLLEGE OF WILLIAM AND MARY GLOUCESTER POINT, VA 23062 THIS RESEARCH WAS SUPPORTED BY GRANT NUMBER: R 806 189 010 FROM THE US ENVIRONMENTAL PROTECTION AGENCY TO THE CHESAPEAKE RESEARCH CONSORTIUM, INC. 1419 FOREST DRIVE, SUITE 207 ANNAPOLIS, MD 21403 MAY 1979 CRC PUBLICATION NUMBER: 67 SPECIAL SCIENTIFIC REPORT NUMBER: 94 VIRGINIA INSTITUTE OF MARINE SCIENCE PREFACE This work is a result of our efforts to compile the literature related to the results of nutrient enrichment of estuaries. It consists of two related publications, a bibliography and an annotated bibliography; both works are accompanied by an index which applies to either bibliography. An attempt has been made to include some key papers related to various processes, eg. nutrient uptake by phytoplankton, which influence or participate in the response process. Items included are wide ranging from articles in scientific journals, chapters in books, and manuscripts for such publications to the grey literature of project reports, theses and the like. They have been accumulated by a variety of methods including the use of the DIALOG Information Retrieval Service (Lockheed Information Systems), manual search of various abstracting publications and the original contemporary literature as well as direct input from authors responding to direct and indirect solicitation. Science Citation Index (Institute of Scientific Information) was also utilized as a source. Annotations rely heavily on abstracts from authors or abstracting services. Copies of all the original documents are being acquired and will be available for personal use at the CRC headquarters and the four Consortium member institutions.
    [Show full text]
  • Dry Weight and Cell Density of Individual Algal and Cyanobacterial Cells for Algae
    Dry Weight and Cell Density of Individual Algal and Cyanobacterial Cells for Algae Research and Development _______________________________________ A Thesis presented to the Faculty of the Graduate School at the University of Missouri-Columbia _______________________________________________________ In Partial Fulfillment of the Requirements for the Degree Master of Science _____________________________________________________ by WENNA HU Dr. Zhiqiang Hu, Thesis Supervisor July 2014 The undersigned, appointed by the Dean of the Graduate School, have examined the thesis entitled Dry Weight and Cell Density of Individual Algal and Cyanobacterial Cells for Algae Research and Development presented by Wenna Hu, a candidate for the degree of Master of Science, and hereby certify that, in their opinion, it is worthy of acceptance. Professor Zhiqiang Hu Professor Enos C. Inniss Professor Pamela Brown DEDICATION I dedicate this thesis to my beloved parents, whose moral encouragement and support help me earn my Master’s degree. Acknowledgements Foremost, I would like to express my sincere gratitude to my advisor and mentor Dr. Zhiqiang Hu for the continuous support of my graduate studies, for his patience, motivation, enthusiasm, and immense knowledge. His guidance helped me in all the time of research and writing of this thesis. Without his guidance and persistent help this thesis would not have been possible. I would like to thank my committee members, Dr. Enos Inniss and Dr. Pamela Brown for being my graduation thesis committee. Their guidance and enthusiasm of my graduate research is greatly appreciated. Thanks to Daniel Jackson in immunology core for the flow cytometer operation training, and Arpine Mikayelyan in life science center for fluorescent images acquisition.
    [Show full text]
  • Investigation of the Microbial Communities Associated with the Octocorals Erythropodium
    Investigation of the Microbial Communities Associated with the Octocorals Erythropodium caribaeorum and Antillogorgia elisabethae, and Identification of Secondary Metabolites Produced by Octocoral Associated Cultivated Bacteria. By Erin Patricia Barbara McCauley A Thesis Submitted to the Graduate Faculty in Partial Fulfillment of the Requirements for a Degree of • Doctor of Philosophy Department of Biomedical Sciences Faculty of Veterinary Medicine University of Prince Edward Island Charlottetown, P.E.I. April 2017 © 2017, McCauley THESIS/DISSERTATION NON-EXCLUSIVE LICENSE Family Name: McCauley . Given Name, Middle Name (if applicable): Erin Patricia Barbara Full Name of University: University of Prince Edward Island . Faculty, Department, School: Department of Biomedical Sciences, Atlantic Veterinary College Degree for which Date Degree Awarded: , thesis/dissertation was presented: April 3rd, 2017 Doctor of Philosophy Thesis/dissertation Title: Investigation of the Microbial Communities Associated with the Octocorals Erythropodium caribaeorum and Antillogorgia elisabethae, and Identification of Secondary Metabolites Produced by Octocoral Associated Cultivated Bacteria. *Date of Birth. May 4th, 1983 In consideration of my University making my thesis/dissertation available to interested persons, I, :Erin Patricia McCauley hereby grant a non-exclusive, for the full term of copyright protection, license to my University, The University of Prince Edward Island: to archive, preserve, produce, reproduce, publish, communicate, convert into a,riv format, and to make available in print or online by telecommunication to the public for non-commercial purposes; to sub-license to Library and Archives Canada any of the acts mentioned in paragraph (a). I undertake to submit my thesis/dissertation, through my University, to Library and Archives Canada. Any abstract submitted with the .
    [Show full text]
  • Use of Algae and Aquatic Macrophytes As Feed in Small-Scale Aquaculture a Review Use of Algae and Aquatic Macrophytes As Feed in Small-Scale Aquaculture – a Review
    FAO ISSN 2070-7010 FISHERIES AND 531 AQUACULTURE TECHNICAL PAPER 531 Use of algae and aquatic macrophytes as feed in small-scale aquaculture A review Use of algae and aquatic macrophytes as feed in small-scale aquaculture – A review While the contribution of small-scale aquaculture (SSA) to rural development is generally recognized, until now there has been no systematic assessment to clearly measures its contribution. The FAO Expert Workshop on Methods and Indicators for Evaluating the Contribution of Small-scale Aquaculture to Sustainable Rural Development held in Nha Trang, Viet Nam, from 24 to 28 November 2009, attempted to develop an indicator system to measure the contribution of SSA. The workshop used a number of processes and steps in the developping the indicator system, including: (i) understanding the subject of measurements; (ii) identifying an analytical framework and ratting criteria (iii) developing a list of SSA contributions; (iv) categorizing the contributions; (v) devising and organizing the indicators of contribution; and (vi) measuring the indicators. The major outcome was the development, through an iterative process, of an indicator system which can provide a good measure of the contribution of SSA based on agreed criteria (accuracy, measurability and efficiency) and the sustainable livelihood approach analytical framework which consists of five capital assets (human, financial, physical, social and natural) and can be used for various livelihoods options. F AO Cover photographs: Left: Woman collecting water chestnut fruits from a floodplain, Rangpur, Bangladesh (courtesy of Mohammad R. Hasan). Right top to bottom: Sale of water spinach leaves, Ho Chi Minh City, Viet Nam (courtesy of William Leschen).
    [Show full text]
  • Phytoplankton Culture for Aquaculture Feed
    Southern regional SRAC Publication No. 5004 aquaculture center September 2010 VI PR Phytoplankton Culture for Aquaculture Feed LeRoy Creswell1 Phytoplankton consists of one-celled marine and digestibility, culture characteristics, and nutritional value freshwater microalgae and other plant-like organisms. (Muller-Feuga et al., 2003). They are used in the production of pharmaceuticals, diet supplements, pigments, and biofuels, and also used as Table 1: Cell volume, organic weight, and gross lipid content of feeds in aquaculture. Phytoplankton are cultured to feed some commonly cultured phytoplankton species used in bivalve mollusc and fish hatcheries (Helm et al., 2004). bivalve molluscs (all life stages), the early larval stages of Species Median cell Organic Lipid crustaceans, and the zooplankton (e.g., rotifers, cope- volume weight content (%) pods) that are used as live food in fish hatcheries. (μm3) (pg) Flagellates and diatoms are two important types of FLAGELLATES phytoplankton at the base of the food chain. They manu- Tetraselmis suecica 300 200 6 facture cellular components through the process of pho- Dunaliella tertiolecta* 170 85 21 tosynthesis, taking up carbon dioxide and nutrients from Isochrysis galbana (T-ISO) 40 – 50 19 – 24 20 - 24 the water and using light as an energy source. DIATOMS The microalgae used as feed in hatcheries vary in size, environmental requirements, growth rate, and nutrition- Chaetoceros calcitrans 35 7 17 al value (Fig. 1, Tables 1 and 2) (Helm et al., 2004). When Chaetoceros gracilis 80 30 19 selecting a species for culture, it is important to take all Thalassiosira pseudonana 45 22 24 of these parameters into consideration. Most hatcher- Skeletonema costatum 85 29 12 ies grow a variety of species that serve different needs Phaeodactylum tricornutum* 40 23 12 throughout the production cycle with respect to size, * Species considered to be of poor nutritional value.
    [Show full text]
  • Harmful Algae News
    1 The Intergovernmental Oceanographic Commission of UNESCO May 2008 HARMFUL ALGAE NEWS An IOC Newsletter on toxic algae and algal blooms http://ioc.unesco.org/hab/news.htm No. 36 • Turkey Mucilage event associated with diatoms and dinoflagellates in Sea of Marmara, Turkey The massive presence of consisting of white gelatinous material mid-autumn 2007 along the north- mucilaginous organic matter, resulting initially suspended at the surface and in eastern part of Marmara Sea with from planktonic and benthic algal the water column was noticed along the temperatures 18.4±1.0oC. It extended blooms, has become more frequent in Turkish coast of the Marmara Sea from Izmit Bay to the Dardanelles during many coastal waters around Europe, (especially Izmit Bay). Marmara Sea the calm weather period; it was denser especially in the Adriatic. The has a rather complex hydrological and of longer duration in Izmit Bay, appearance of mucilage in the Adriatic system, in a zone of transition between which is affected by intense industrial Sea has been reported periodically since dense (salinity 37- 38.5 ‰) and warmer activity, and which has a weaker 1800, with major mucus blooms during waters originating in the Mediterranean circulation compared to Marmara Sea. the 1990s [1]. The mucilage Sea, and cold, lower-salinity water (20- To identify phytoplankton species phenomenon of the Adriatic Sea had 22 ‰) coming from the Black Sea. The responsible for the mucilage, water usually been related to extracellular pycnocline lies at 10 to 30 m depth and samples were collected from surface organic matter of phytoplanktonic origin. varies seasonally [2].
    [Show full text]
  • Phytoplankton Vertical Distributions and Composition in Baltic Sea
    Harmful Algae 6 (2007) 189–205 www.elsevier.com/locate/hal Phytoplankton vertical distributions and composition in Baltic Sea cyanobacterial blooms Susanna Hajdu *, Helena Ho¨glander, Ulf Larsson Department of Systems Ecology, Marine and Brackish Water Ecology, Stockholm University, SE-106 91 Stockholm, Sweden Received 17 January 2006; received in revised form 27 July 2006; accepted 31 July 2006 Abstract We studied the vertical structure of the phytoplankton community in two toxic cyanobacterial blooms in the offshore Baltic Sea. In 1994, vertically separated potentially toxic, diazotrophic and mixotrophic species (belonging to Cyanophyceae, Dinophyceae and Prymnesiophyceae) dominated. In 1997, picocyanobacteria, mainly in colonies, made up 40–50% of the total phytoplankton carbon biomass in the top 20 m both day and night. Colony-forming species of picocyanobacteria seem to be occasionally important and hitherto underestimated in the Baltic Sea. We found species-specific depth distribution patterns. Nodularia spumigena and Anabaena spp. were observed mainly above 10 m depth, while Aphanizomenon sp. was mostly found deeper, especially at night. Dinophysis norvegica was only abundant near the seasonal pycnocline and showed very limited diurnal migration. Other flagellates, including small Cryptophyceae and 10 identified Chrysochromulina species, occurred down to 40 m depth. Their vertical migration may help to retrieve nutrients from below the summer pycnocline. We conclude that considerable differences in dominating functional groups may occur between years/bloom stages, and that the vertical distribution pattern of many species is recurring at similar environmental conditions, suggesting species-specific niche- separation. # 2006 Elsevier B.V. All rights reserved. Keywords: Baltic Sea; Chrysochromulina; Picocyanobacteria; Phytoplankton; Vertical distribution 1.
    [Show full text]
  • Computer Simulation of Phytoplankton and Nutrient Dynamics
    COMPUTER SIMULATION OF PHYTOPLANKTON AND NUTRIENT DYNAMICS IN AN ENCLOSED MARINE ECOSYSTEM by ALAN BOYD CARRUTHERS B.Sc. University of Calgary 1976 A THESIS SUBMITTED IN PARTIAL FULFILLMENT OF THE REQUIREMENTS FOR THE DEGREE OF MASTER OF SCIENCE in THE FACULTY OF GRADUATE STUDIES (Departments of Zoology and Oceanography) We accept this thesis as conforming to the required standard THE UNIVERSITY OF BRITISH COLUMBIA 19 May 1981 © Alan Boyd Carruthers, 1981 In presenting this thesis in partial fulfilment of the requirements for an advanced degree at the University of British Columbia, I agree that the Library shall make it freely available for reference and study. I further agree that permission for extensive copying of this thesis for scholarly purposes may be granted by the head of my department or by his or her representatives. It is understood that copying or publication of this thesis for financial gain shall not be allowed without my written permission. Department of ^—00/0 The University of British Columbia 2075 Wesbrook Place Vancouver, Canada V6T 1W5 Date tn+r n, /rrt DE-6 (2/79). i i ABSTRACT This thesis presents a quantitative model of interactions among phytoplankton, nutrients, bacteria and grazers in an enclosed marine ecosystem. The enclosed system was a 23 m deep, 9.6 m diameter column of surface water in Saanich Inlet, British Columbia. Dynamics of large- and small-celled diatoms and flagellates in response to observed irradiance and zooplankton numbers and observed or simulated nitrogen and silicon concentrations were modelled over a simulated 76-day period between July 12 and September 26.
    [Show full text]
  • Proposed Methodology for the Assessment of Protective Numeric Nutrient Criteria for South Florida Estuaries and Coastal Waters
    Proposed Methodology for the Assessment of Protective Numeric Nutrient Criteria for South Florida Estuaries and Coastal Waters Prepared by: Henry Briceño, Joseph Boyer and Peter Harlem Florida International University Southeast Environmental Research Center Miami, Florida Delivered to: U. S. Environmental Protection Agency Miami December 6th, 2010 This report is contribution # T-501 of the Southeast Environmental Research Center at Florida International University OE #148, Florida International University, Miami, Florida 33199 305‐348‐3095; 305‐348‐4096 fax; http://serc.fiu.edu Ms Stephanie Sanzone Designated Federal Officer(DFO) EPA Science Advisory Board Staff Office (1400R) U.S. Environmental Protection Agency 1200 Pennsylvania Avenue, NW Washington, DC 20460 Re: EPA SAB Nutrient Criteria Review Panel Dear Ms. Sanzone We would like to provide the attached document entitled “Proposed Methodology for the Assessment of Protective Nutrient Criteria for South Florida Estuaries and Coastal Waters” to the EPA Science Advisory Board, Nutrient Criteria Review Panel. We speak as members of South Florida scientific community, principal investigators for many years of a large marine water quality monitoring network, contributors of statistical and modeling approaches to the above document, and member (Boyer) of Florida’s Marine Numeric Nutrient Criteria Technical Advisory Committee (MTAC) Sincerely, Dr. Henry O. Briceño, Research Faculty Southeast Environmental Research Center Florida International University Dr. Joseph N. Boyer, Director and
    [Show full text]
  • Ecologigal Conseouence of Acidig and Heaw-Metal
    Canadian Minzralogist Vol. 14, pp.47-57 (1976) ECOLOGIGALCONSEOUENCE OF ACIDIG AND HEAW-METAL DISCHARGESFROM THE SUDBURVSMELTERS L. M. WHITBY, P. M. STOKES, T. C. HUTCHINSON eNo G. MYSLIK Institute for Environmental Studies and. Department of Botany, University of Toronto, Toron:to, Ontarto. ABSTRACT trds vastes r6gions forestibres, par facidification du sol et les 6rosions terrestres majeures subs6quetrtes. Studies have been made of the effects on temes- De plus, les m6taux lourds fondus se sont accumu- trial and aquatic ecosysiemg of heavy-oetal emis- l6s jusqu'i de trds fortes concentrations sur une sions, sulfur dioxide, and acidic rain-induced grando 6tendue, et surtout dans les sols superficiels. problems, caused by smelting activities in the Sud- Ces niveaux 6taient toxiques, meme en fabsence de bury region. The effects have been profound. Phyto- dioxyde sulfurique, i une grande vari6t6 d'espdces plankton populations have been reduced from 2,000 solutions i 'negligible' 6tudi6es dans des extraits ou dans des cells,/ml to in many of the lakes close m6tal unique. 13s am6liorations du sol avec la to the Coniston smelter, alrd around both Falcon- chaux ont eu des effets dramatiques sur 1a crois- bridge and Copper Cliff. Levels of nickel (up to sance et la survie des plantes. La proportion de m6' 6.5 ppm) and colper (up to 0.2 ppm) occur in these tal s'est trouv6e r6duite, par la meme occasion, i lakes, and these, combinetl with increased acidity, comparer i etle des sols notr-amaiores. are major obstacles to survival of primary produc- Cfraduit Par le journal) ers.
    [Show full text]