Fructans of the saline world

Saline and hypersaline environments make up the largest ecosystem on earth and the organisms living in such water-restricted environments have developed unique ways to cope with high salinity. As such these organisms not only carry significant industrial potential in a world where freshwater supplie...

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Veröffentlicht in:	Biotechnology advances 2018-09, Vol.36 (5), p.1524-1539
Hauptverfasser:	Kırtel, Onur, Versluys, Maxime, Van den Ende, Wim, Toksoy Öner, Ebru
Format:	Artikel
Sprache:	eng
Schlagworte:	Adaptation Archaea Biosynthesis Carbohydrates Domains Enzymes Fructan Fructans Fructans - chemistry Fructans - metabolism Fructose Fructosyltransferase Halobacteriales - chemistry Halobacteriales - enzymology Halobacteriales - physiology Halophile Halophyte Hexosyltransferases Marine ecology Microorganisms Organisms Prokaryotes Salinity Salt Tolerance Salt-Tolerant Plants - chemistry Salt-Tolerant Plants - enzymology Salt-Tolerant Plants - physiology Sodium Chloride Virulence
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container_title	Biotechnology advances
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creator	Kırtel, Onur Versluys, Maxime Van den Ende, Wim Toksoy Öner, Ebru
description	Saline and hypersaline environments make up the largest ecosystem on earth and the organisms living in such water-restricted environments have developed unique ways to cope with high salinity. As such these organisms not only carry significant industrial potential in a world where freshwater supplies are rapidly diminishing, but they also shed light upon the origins and extremes of life. One largely overlooked and potentially important feature of many salt-loving organisms is their ability to produce fructans, fructose polymers widely found in various mesophilic Eubacteria and plants, with potential functions as storage carbohydrates, aiding stress tolerance, and acting as virulence factors or signaling molecules. Intriguingly, within the whole archaeal domain of life, Archaea possessing putative fructan biosynthetic enzymes were found to belong to the extremely halophilic class of Halobacteria only, indicating a strong, yet unexplored link between the fructan syndrome and salinity. In fact, this link may indeed lead to novel strategies in fighting the global salinization problem. Hence this review explores the unknown world of fructanogenic salt-loving organisms, where water scarcity is the main stress factor for life. Within this scope, prokaryotes and plants of the saline world are discussed in detail, with special emphasis on their salt adaptation mechanisms, the potential roles of fructans and fructosyltransferase enzymes in adaptation and survival as well as future aspects for all fructanogenic salt-loving domains of life.
doi_str_mv	10.1016/j.biotechadv.2018.06.009
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Hence this review explores the unknown world of fructanogenic salt-loving organisms, where water scarcity is the main stress factor for life. Within this scope, prokaryotes and plants of the saline world are discussed in detail, with special emphasis on their salt adaptation mechanisms, the potential roles of fructans and fructosyltransferase enzymes in adaptation and survival as well as future aspects for all fructanogenic salt-loving domains of life.</description><identifier>ISSN: 0734-9750</identifier><identifier>EISSN: 1873-1899</identifier><identifier>DOI: 10.1016/j.biotechadv.2018.06.009</identifier><identifier>PMID: 29935267</identifier><language>eng</language><publisher>England: Elsevier Inc</publisher><subject>Adaptation ; Archaea ; Biosynthesis ; Carbohydrates ; Domains ; Enzymes ; Fructan ; Fructans ; Fructans - chemistry ; Fructans - metabolism ; Fructose ; Fructosyltransferase ; Halobacteriales - chemistry ; Halobacteriales - enzymology ; Halobacteriales - physiology ; Halophile ; Halophyte ; Hexosyltransferases ; Marine ecology ; Microorganisms ; Organisms ; Prokaryotes ; Salinity ; Salt Tolerance ; Salt-Tolerant Plants - chemistry ; Salt-Tolerant Plants - enzymology ; Salt-Tolerant Plants - physiology ; Sodium Chloride ; Virulence</subject><ispartof>Biotechnology advances, 2018-09, Vol.36 (5), p.1524-1539</ispartof><rights>2018 Elsevier Inc.</rights><rights>Copyright © 2018 Elsevier Inc. 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As such these organisms not only carry significant industrial potential in a world where freshwater supplies are rapidly diminishing, but they also shed light upon the origins and extremes of life. One largely overlooked and potentially important feature of many salt-loving organisms is their ability to produce fructans, fructose polymers widely found in various mesophilic Eubacteria and plants, with potential functions as storage carbohydrates, aiding stress tolerance, and acting as virulence factors or signaling molecules. Intriguingly, within the whole archaeal domain of life, Archaea possessing putative fructan biosynthetic enzymes were found to belong to the extremely halophilic class of Halobacteria only, indicating a strong, yet unexplored link between the fructan syndrome and salinity. In fact, this link may indeed lead to novel strategies in fighting the global salinization problem. 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subjects	Adaptation Archaea Biosynthesis Carbohydrates Domains Enzymes Fructan Fructans Fructans - chemistry Fructans - metabolism Fructose Fructosyltransferase Halobacteriales - chemistry Halobacteriales - enzymology Halobacteriales - physiology Halophile Halophyte Hexosyltransferases Marine ecology Microorganisms Organisms Prokaryotes Salinity Salt Tolerance Salt-Tolerant Plants - chemistry Salt-Tolerant Plants - enzymology Salt-Tolerant Plants - physiology Sodium Chloride Virulence
title	Fructans of the saline world
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