Details

Title

Cyanobacterial and algal diversity in the vicinity of two different seabird colonies in Spitsbergen

Journal title

Polish Polar Research

Yearbook

2016

Volume

vol. 37

Issue

No 2

Authors

Keywords

Arctic ; Cyanobacterial and algal assembalges ; Influence of seabirds ; Spitsbergen ; Trophy

Divisions of PAS

Nauki o Ziemi

Coverage

269-288

Publisher

Polish Academy of Sciences ; Committee on Polar Research

Date

2016

Type

Artykuły / Articles

Identifier

DOI: 10.1515/popore-2016-0015 ; ISSN 0138-0338 ; eISSN 2081-8262

Source

Polish Polar Research; 2016; vol. 37; No 2; 269-288

References

StempniewiczL (2007), Impact of climate change on zooplankton communities seabird populations and Arctic terrestrial ecosystem a scenario II :, Deep Sea Research Part Topical Studies in Oceanography, 54, 2934, doi.org/10.1016/j.dsr2.2007.08.012 ; HolzingerA (2006), Ultrastructure and photosynthesis in the supralittoral green macroalgaPrasiola crispafrom Spitsbergen ( Norway ) under UV exposure, Phycologia, 45, 168, doi.org/10.2216/05-20.1 ; Zmudczyńska (2015), Is ornithogenic fertilisation important for collembolan communities in Arctic terrestrial ecosystems http dx doi org, Polar Research, 34, doi.org/10.3402/polar.v34.25629 ; RyanP (1989), The influence of physical factors and ornithogenic products on plant and arthropod abundance at an inland nunatak group in Antarctica, Polar Biology, 10, 151. ; StempniewiczL (2005), Keystone species and ecosystem functioning Seabirds in polar ecosystems, Ecology Quest, 6, 111. ; EllisJ (2011), Effects of seabirds on plant communities In and Bellingham eds ) Seabird islands invasion and restoration Oxford University Press New York, Ecology, 135. ; Zmudczyńska (2015), An assessment of seabird influence on Arctic coastal benthic communities, Journal of Marine Systems, 144, 48, doi.org/10.1016/j.jmarsys.2014.11.013 ; HuangT (2014), Transport of nutrients and contaminants from ocean to island by emperor penguins from Amanda Bay East Antarctic of the, Science Total Environment, 468, 578, doi.org/10.1016/j.scitotenv.2013.08.082 ; ElsterJ (2008), Freezing and desiccation injury resistance in the filamentous green algaKlebsormidiumfrom the Antarctic Arctic and Slovakia, Biologia, 63, 843. ; ZmudczyńskaK (2009), and StempniewiczL Spectral characteristics of the Arctic ornithogenic tundra vegetation in Hornsund area SW Spitsbergen, Polish Polar Research, 30, 249, doi.org/10.4202/ppres.2009.12 ; MulderC (2011), Impacts of seabirds on plant and soil properties In Bellingham eds ) Seabird islands invasion and restoration Oxford University Press New York, Ecology, 135. ; SzymańskiW (2013), Distribution genesis and properties of Arctic soils : a case study from the Fuglebekken catchment, Polish Polar Research, 34, 289. ; ZwolickiA (2013), Guano deposition and nutrient enrichment in the vicinity of planktivorous and piscivorous seabird colonies in Spitsbergen, Polar Biology, 36, 363, doi.org/10.1007/s00300-012-1265-5 ; ZwolickiA (2015), Seabird colony effects on soil properties and vegetation zonation patterns on King George Island Maritime Antarctic, Polar Biology, 38, 1645, doi.org/10.1007/s00300-015-1730-z ; HoggE (1983), The effects of nesting gulls on the vegetation and soil of islands in the Great Lakes, Canadian Journal of Botany, 61, 3240, doi.org/10.1139/b83-361 ; KolbG (2010), Effects of seabird nesting colonies on algae and aquatic invertebrates in coastal waters, Marine Ecology Progress Series, 417, 287, doi.org/10.3354/meps08791 ; BrasellK (2015), Successional Change in Microbial Communities of BenthicPhormidium Dominated Biofilms, Microbial Ecology, 69, 254, doi.org/10.1007/s00248-014-0538-7 ; ZiółekM (2014), The impact of seabirds on the content of various forms of phosphorus in organic soils of the Bellsund coast western Spitsbergen http dx doi org, Polar Research, 33, doi.org/10.3402/polar.v33.19986 ; ElvebakkA (1994), A survey of plant associations and alliances from Svalbard, Journal of Vegetation Science, 5, 791, doi.org/10.2307/3236194 ; WojtuńB (2013), Metals in some dominant vascular plants mosses lichens algae and the biological soil crust in various types of terrestrial tundra SW Spitsbergen Norway, Polar Biology, 36, 1799, doi.org/10.1007/s00300-013-1399-0 ; GodzikB (1991), Heavy metals and macroelements in the tundra of southern Spitsbergen : the effect of little auk ( Alle alle ) colonies, Polar Research, 9, 121, doi.org/10.1111/j.1751-8369.1991.tb00608.x ; OdaszA (1994), Nitrate reductase activity in vegetation below an arctic bird cliff Svalbard Norway, Journal of Vegetation Science, 5, 913, doi.org/10.2307/3236203 ; SmilV (2000), Phosphorus in the environment : natural flows and human interferences of Energy and the Environment, Annual Review, 25, 53. ; ElserJ (2007), Global analysis of nitrogen and phosphorus limitation of primary producers in freshwater marine and terrestrial ecosystems, Ecology Letters, 10, 1135, doi.org/10.1111/j.1461-0248.2007.01113.x ; LanS (2013), Assessing Level of Development and Successional Stages in Biological Soil Crusts with Biological Indicators, Microbial Ecology, 66, 394, doi.org/10.1007/s00248-013-0191-6 ; StempniewiczL (2006), Impact of plankton - and fish - eating seabird colonies on the Arctic tundra ecosystem a comparison, Journal of Ornithology, 147, 257. ; ErskineP (1998), Subantarctic Macquarie Island a model ecosystem for studying animal - derived nitrogen sources using N natural abundance, Oecologia, 117, 187, doi.org/10.1007/s004420050647 ; MatułaJ (2007), Cyanobacteria and algae of Arctic terrestrial ecosystems in the Hornsund area, Polish Polar Research, 28, 283. ; KaštovskaK (2005), Microbial Assemblages in Soil Microbial Succession After Glacial Retreat in Svalbard ( High Arctic, Microbial Ecology, 50, 396, doi.org/10.1007/s00248-005-0246-4 ; PenningsS (2005), Do individual plant species show predictable responses to nitrogen addition across multiple experiments, Oikos, 110, 547, doi.org/10.1111/j.0030-1299.2005.13792.x ; TheodoseT (1997), Nutrient availability plant abundance and species diversity in two alpine tundra communities, Ecology, 78, 1861, doi.org/10.1890/0012-9658(1997)078[1861:NAPAAS]2.0.CO;2 ; AndersonW (1999), Nutrient fluxes from water to land : seabirds affect plant nutrient status on Gulf of California islands, Oecologia, 118, 324, doi.org/10.1007/s004420050733 ; KomárekJ (2008), Diversity of cyanobacterial microflora of the northern part of James Ross Island NW Weddell Sea, Polar Biology, 31, 853, doi.org/10.1007/s00300-008-0424-1 ; LindeboomH (1984), The nitrogen pathway in a penguin rookery, Ecology, 65, 269, doi.org/10.2307/1939479 ; Breuning (2008), The impact of perennial cormorant colonies on soil phosphorus status, Geoderma, 148, 51, doi.org/10.1016/j.geoderma.2008.09.002 ; KomárekJ (2008), Ecological background of cyanobacterial assemblages of the northern part of James Ross Island, Polish Polar Research, 29, 17. ; BokhorsS (2007), External nutrient inputs into terrestrial ecosystems of the Falkland Islands and the Maritime Antarctic region, Polar Biology, 30, 1315, doi.org/10.1007/s00300-007-0292-0 ; DaveyM (1992), Factors causing the limitation of growth of terrestrial algae in maritime Antarctica during late summer, Polar Biology, 12, 595. ; LigęzaS (2003), Accumulation of nutrients in soils affected by perennial colonies of piscivorous birds with reference to biogeochemical cycles of elements, Chemosphere, 52, 595, doi.org/10.1016/S0045-6535(03)00241-8 ; StempniewiczL (1990), Biomass of dovekie excreta in the vicinity of a breeding colony, Colonial Waterbird, 13, 62, doi.org/10.2307/1521421 ; MyrchaA (1991), Ecological role of the current and abandoned penguin rookeries in the land environment of the maritime Antarctic, Polish Polar Research, 12, 3. ; CavaciniP (2001), Soil algae from northern Victoria land Antarctica, Polar Bioscience, 14, 45. ; SmyklaJ (2007), Zonation of vegetation related to penguin rookeries on King George Island Maritime Antarctic Antarctic and, Arctic Alpine Research, 39, 143, doi.org/10.1657/1523-0430(2007)39[143:ZOVRTP]2.0.CO;2 ; RichterD (2015), Relationship of cyanobacteral and algal assemblages with vegetation in the high Arctic tundra ( West Spitsbergen Svalbard Archipelago ), Polish Polar Research, 36, 239. ; GraeveM (2002), Fatty acid composition of Arctic and Antarctic macroalgae : indicator of phylogenetic and trophic relationships, Marine Ecology Progress Series, 231, 67, doi.org/10.3354/meps231067 ; StruneckýO (2010), Phylogenetic relationships between geographically separatePhormidiumcyanobacteria : is there a link between north and south polar regions, Polar Biology, 33, 1419, doi.org/10.1007/s00300-010-0834-8 ; JakubasD (2008), Faeces deposition and numbers of vertebrate herbivores in the vicinity of planktivorous and piscivorous seabird colonies in Hornsund, Polish Polar Research, 29, 45. ; ZelenskayaL (2006), Growth of the nesting colony of slaty - backed gulls ( Larus schistisagus ) and plant cover degradation on Shelikan Island ( Taui Inlet the Sea of Okhotsk ), Russian Journal of Ecology, 37, 126, doi.org/10.1134/S106741360602010X ; HodkinsonI (2002), Primary community assembly on land the missing stages : why are the heterotrophic organisms always there first, Journal of Ecology, 90, 569, doi.org/10.1046/j.1365-2745.2002.00696.x ; LudD (2001), dePollW DNA damage and photosynthetic performance in the Antarctic terrestrial algaPrasiola crispaspp antarctica ( Chlorophyta ) under manipulated UV - B radiation, Journal of Phycology, 34, 459, doi.org/10.1046/j.1529-8817.2001.037004459.x ; KomárekJ (2016), Review of the cyanobacterial genera implying planktic species after recent taxonomic revisions according to polyphasic methods : state as of, Hydrobiologia, 764. ; MadanN (2007), Greater nitrogen and / or phosphorus availability increase plant species cover and diversity at a High Arctic polar semidesert, Polar Biology, 30, 559, doi.org/10.1007/s00300-006-0213-7 ; WojciechowskaA (2015), The structure ofCochlearia groenlandicapopulation along the bird colony influence gradient ( Hornsund, Polar Biology, 38, 1919, doi.org/10.1007/s00300-015-1755-3 ; PizzaroH (1996), Epilithic algae from a freshwater stream at Hope Bay, Antarctic Science, 8, 161. ; HeathM (2014), Development of habitat suitability criteria and in - stream habitat assessment for the benthic cyanobacteriaPhormidium, River Research and Applications, 31, 98, doi.org/10.1002/rra.2722 ; HawkeD (2004), Inventories and elemental accumulation in peat soils of forested seabird breeding islands southern New Zealand, Soil Research, 42, 45, doi.org/10.1071/SR03107 ; GamaJr (2014), How diverse are coccoid cyanobacteria ? A case study of terrestrial habitats from the Atlantic Rainforest ( Sao Paulo, Phytotaxa, 178, 61, doi.org/10.11646/phytotaxa.178.2.1 ; ZmudczyńskaK (2012), Influence of allochtonous nutrients delivered by colonial seabirds on soil collembolan communities on Spitsbergen, Polar Biology, 35, 1233, doi.org/10.1007/s00300-012-1169-4

Editorial Board


Editorial Advisory Board


Angelika BRANDT (Hamburg),

Claude DE BROYER (Bruxelles),

Peter CONVEY (Cambridge, UK),

J. Alistair CRAME (Cambridge, UK),

Rodney M. FELDMANN (Kent, OH),

Jane E. FRANCIS (Cambridge, UK),

Andrzej GAŹDZICKI (Warszawa)

Aleksander GUTERCH (Warszawa),

Jacek JANIA (Sosnowiec),

Jiří KOMÁREK (Třeboň),

Wiesława KRAWCZYK (Sosnowiec),

German L. LEITCHENKOV (Sankt Petersburg),

Jerónimo LÓPEZ-MARTINEZ (Madrid),

Sergio A. MARENSSI (Buenos Aires),

Jerzy NAWROCKI (Warszawa),

Ryszard OCHYRA (Kraków),

Maria OLECH (Kraków)

Sandra PASSCHIER (Montclair, NJ),

Jan PAWŁOWSKI (Genève),

Gerhard SCHMIEDL (Hamburg),

Jacek SICIŃSKI (Łódź),

Michael STODDART (Hobart),

Witold SZCZUCIŃSKI (Poznań),

Andrzej TATUR (Warszawa),

Wim VADER (Tromsø),

Tony R. WALKER (Halifax, Nova Scotia),

Jan Marcin WĘSŁAWSKI (Sopot) - President.

Abstracting & Indexing

Abstracting & Indexing


Polish Polar Research is covered by the following services:

  • AGRICOLA (National Agricultural Library)
  • AGRO
  • Arianta
  • Baidu Scholar
  • Cabell's Directory
  • CABI (over 50 subsections)
  • Celdes
  • CNKI Scholar (China National Knowledge Infrastructure)
  • CNPIEC
  • Cold Regions Bibliography
  • Current Antarctic Literature
  • DOAJ (Directory of Open Access Journals)
  • EBSCO (relevant databases)
  • EBSCO Discovery Service
  • Elsevier - Geobase
  • Elsevier - Reaxys
  • Elsevier - SCOPUS
  • Genamics JournalSeek
  • Google Scholar
  • J-Gate
  • JournalTOCs
  • Naviga (Softweco)
  • Polish Scientific Journals Contents
  • Primo Central (ExLibris)
  • ProQuest (relevant databases)
  • ReadCube
  • ResearchGate
  • SCImago (SJR)
  • Summon (Serials Solutions/ProQuest)
  • TDOne (TDNet)
  • Thomson Reuters - Biological Abstracts
  • Thomson Reuters - BIOSIS Previews
  • Thomson Reuters - Journal Citation Reports/Science Edition
  • Thomson Reuters - Science Citation Index Expanded
  • Thomson Reuters - Zoological Record
  • Ulrich's Periodicals Directory/ulrichsweb
  • WorldCat (OCLC)
×