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| Comparison of the oxidative stress response of two Antarctic fungi to different growth temperatures

Kostadinova, Nedelina; Solveig Tosi; Spassova, Boryana; Angelova, Maria

Details

Title

Comparison of the oxidative stress response of two Antarctic fungi to different growth temperatures

Journal title

Polish Polar Research

Yearbook

2017

Volume

vol. 38

Issue

No 3

Authors

Kostadinova, Nedelina ; Solveig Tosi ; Spassova, Boryana ; Angelova, Maria

Keywords

Antarctic ; antioxidant enzymes ; fungi ; glycogen ; Livingston Island ; physiological cell response ; trehalose

Divisions of PAS

Nauki o Ziemi

Coverage

393-408

Publisher

Polish Academy of Sciences ; Committee on Polar Research

Date

2017.09.01

Type

Artykuły / Articles

Identifier

DOI: 10.1515/popore-2017-0015 ; ISSN 0138-0338 ; eISSN 2081-8262

Source

Polish Polar Research; 2017; vol. 38; No 3; 393-408

References

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ParkC (null), Algal and fungal diversity in Antarctic lichens The of, Journal Eukaryotic Microbiology, 2015. ; SomogyM (1952), on sugar determination The of, Notes Journal Biological Chemistry, 195. ; ZhangT (null), and distribution of lichen associated fungi in the Region High as revealed by pyrosequencing Scientific Reports, Diversity Arctic, 2015. ; NonzomS (2014), Fate of mitosporic soil fungi in cold deserts reviewAmerican of Research in Formal Natural, International Journal Applied Sciences, 9, 01. ; RaoS (2012), Low diversity fungal assemblage in an Antarctic Dry Valleys soil, Polar Biology, 567. ; ArenzB (2006), diversity in soils and historic wood from the Ross Sea region of Soil Biology, Fungal Biochemistry, 3057. ; ShilovaN (1989), The effect of aeration on the activity of alcohol oxidase and enzymes utilising hydrogen peroxide in the course ofCandida maltosagrowth on paraffin in, null, 430. ; FeniceM (2016), The psychrotolerant Antarctic fungusLecanicillium muscariumCCFEE a powerful producer of cold tolerant chitinolytic enzymes, Molecules, 21, 5003. ; OnofriS (2005), and The of continental Reports, null, 11. ; SofoA (null), peroxidase and catalase activities and their genetic regulation in plants subjected to drought and salinity stresses, International Journal of Molecular Sciences, 16, 2015. ; AngelovaM (1995), Effect of glucose on the superoxide dismutase production in fungal strainHumicola lutea of, Canadian Journal Microbiology, 978. ; NimseS (null), Free radicals natural antioxidants and their reaction mechanismsRSC Advances, null, 2015. ; FellerG (2006), Enzymes from psychrophilic organisms, FEMS Microbiology Reviews, 18, 189. ; AguileraJ (2007), Cold response inSaccharomyces cerevisiae : new functions for old mechanisms, FEMS Microbiology Reviews, 31, 327. ; ZhangL (2003), Growth temperature downshift induces antioxidant response inSaccharomyces cerevisiae and, Biochemical Biophysical Research Communications, 307. ; KostadinovaN (2011), Cold stress in Antarctic fungi targets enzymes of the glycolytic pathway and tricarboxylic acid cycle Biotechnology, Biotechnological Equipment, 25. ; GonçalvesV (2012), and distribution of fungal communities in lakes of, Diversity FEMS Microbiology Ecology, 459. ; MatsumotoM (2016), Molds The Battle Under Snow Between Fungal Pathogens and Their Plant Hosts Media, Science Business, 136. ; KostadinovaN (2012), Transient cold shock induces oxidative stress events in Antarctic fungi In ed Oxidative Stress, InTech, 1. ; RussellN (2006), microorganisms coming in from the cold Culture, null, 27, 1. ; IordachescuM (2011), and abiotic stress in biological systems In eds Stress in Plants Mechanisms and Adaptations, InTech, 215. ; MargesinR (2009), Effect of temperature on growth parameters of psychrophilic bacteria and yeasts, Extremophiles, 13, 257. ; ChuX (2016), Effect of arbuscular mycorrhizal fungi inoculation on cold stress induced oxidative damage in leaves ofElymus nutansGriseb, South African Journal of Botany, 21. ; FeofilovaE (2000), Different mechanisms of the biochemical adaptation of mycelial fungi to temperature stress : Changes in the cytosol carbohydrate composition, Microbiology, 69. ; FridovichI (1998), Oxygen toxicity a radical explanation of, Journal Experimental Biology, 201. ; SterflingerK (2006), yeast meristematic fungi diversity identification In eds The Handbook Ecophysiology of Yeasts, ecology Yeast Biodiversity, 501. ; LowryO (1951), Protein measurement with the Folin phenol reagent The of, Journal Biological Chemistry, 193. ; GochevaY (2009), Temperature downshift induces antioxidant response in fungi isolated from Antarctica, Extremophiles, 13, 273. ; OnofriS (2008), Resistance of Antarctic black fungi and cryptoendolithic communities to simulated space and Martian conditions in, Studies Mycology, 61. ; FukunagaN (1990), Membrane lipid composition and glucose uptake in two psychrotolerant bacteria from Antarctica of, Journal General Microbiology, 136. ; CantrellS (2011), Unusual fungal niches, Mycologia, 103. ; NewshamK (2009), and dark septate root endophytes in polar regions, Fungal Ecology, 10. ; WillekensH (1997), Catalase is a sink for and is indispensable for stress defense in plants Organisation, European Molecular Biology, 16, 4806. ; 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Editorial Board

Editorial Advisory Board

Robert BIALIK (Warszawa, Poland)

Magda BŁAŻEWICZ (Łódź, Poland)

Alistair CRAME (Cambridge, UK)

Josef ELSTER (České Budějovice, Czechia)

Jacek JANIA (Sosnowiec, Poland)

Cezary KABAŁA (Wrocław, Poland)

Jerónimo LÓPEZ-MARTINEZ (Madrid, Spain)

Krzysztof MIGAŁA (Wrocław, Poland)

Jerzy NAWROCKI (Warszawa, Poland)

Maria OLECH (Kraków, Poland)

Sergej OLENIN (Klaipeda, Litva)

Sandra PASSCHIER (Montclair, USA)

Jan PAWŁOWSKI (Sopot, Poland)

Żaneta POLKOWSKA (Gdańsk, Poland)

Gerhard SCHMIEDL (Hamburg, Germany)

Peter SCHWEITZER (Vienna, Austria)

Janne SOREIDE (UNIS, Svalbard)

Lech STEMPNIEWICZ (Gdańsk, Poland)

Mateusz STRZELECKI (Wrocław, Poland)

Witold SZCZUCIŃSKI (Poznań, Poland)

Slawek TULACZYK (Santa Cruz, USA)

Jan Marcin WĘSŁAWSKI (Sopot, Poland) - President

Abstracting & Indexing

Abstracting & Indexing

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