Lichen as Micro-Ecosystem: Extremophilic Behavior with Astrobiotechnological Applications

This work demonstrates the tolerance of lichen Pleurosticta acetabulum under extreme conditions similar to those encountered in extraterrestrial environments. Specifically, the impact of three extreme Mars-like conditions-complete dehydration, extremely low temperature (-196°C/77K), and oxygen deple...

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Veröffentlicht in:	Astrobiology 2018-12, Vol.18 (12), p.1528-1542
Hauptverfasser:	Parasyri, Athina, Papazi, Aikaterini, Stamatis, Nikolaos, Zerveas, Sotirios, Avramidou, Evangelia V, Doulis, Andreas G, Pirintsos, Stergios, Kotzabasis, Kiriakos
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Schlagworte:	Acetabulum Carbohydrates Chlorophyll Cultivation Dehydration Deoxyribonucleic acid Depletion Desiccation DNA DNA methylation Drying Ecosystem integrity Ecosystems Efflux Environmental changes Environmental conditions Environmental impact Ergosterol Extraterrestrial environments Extraterrestrial materials Fatty acids Hydrogen production Lichens Low temperature Mars Molecular structure Oxygen depletion Panspermia Photosynthesis Photosynthetic apparatus Polyamines Structure-function relationships Symbionts Symbiosis Viability
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container_title	Astrobiology
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creator	Parasyri, Athina Papazi, Aikaterini Stamatis, Nikolaos Zerveas, Sotirios Avramidou, Evangelia V Doulis, Andreas G Pirintsos, Stergios Kotzabasis, Kiriakos
description	This work demonstrates the tolerance of lichen Pleurosticta acetabulum under extreme conditions similar to those encountered in extraterrestrial environments. Specifically, the impact of three extreme Mars-like conditions-complete dehydration, extremely low temperature (-196°C/77K), and oxygen depletion-on lichens was investigated. The symbiosis of mycobiont and photobiont partners creates a micro-ecosystem that ensures viability of both symbiotic partners under prolonged desiccation and extremely low temperatures without any cultivation care. Changes in the molecular structure and function of the photosynthetic apparatus, in the level of chlorophylls, polyamines, fatty acids, carbohydrates, ergosterol, efflux of K , and DNA methylation ensure the ecological integrity of the system and offer resistance of lichens to above-mentioned extreme environmental conditions. For the first time, we also demonstrate that the unprecedented polyextremophilic characteristic of lichens could be linked to biotechnological applications, following exposure to these extreme conditions, such that their ability to produce a high yield of hydrogen was unchanged. All these support that lichens are (a) ideal model systems for a space mission to inhabit other planets, supporting also the aspect that the panspermia theory could be extended to incorporate in the traveling entities not only single organisms but micro-ecosystems like lichens, and (b) ideal model systems for astrobiotechnological applications (hydrogen production), such as in the development of bioregeneration systems for extraterrestrial environments.
doi_str_mv	10.1089/ast.2017.1789
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Specifically, the impact of three extreme Mars-like conditions-complete dehydration, extremely low temperature (-196°C/77K), and oxygen depletion-on lichens was investigated. The symbiosis of mycobiont and photobiont partners creates a micro-ecosystem that ensures viability of both symbiotic partners under prolonged desiccation and extremely low temperatures without any cultivation care. Changes in the molecular structure and function of the photosynthetic apparatus, in the level of chlorophylls, polyamines, fatty acids, carbohydrates, ergosterol, efflux of K , and DNA methylation ensure the ecological integrity of the system and offer resistance of lichens to above-mentioned extreme environmental conditions. For the first time, we also demonstrate that the unprecedented polyextremophilic characteristic of lichens could be linked to biotechnological applications, following exposure to these extreme conditions, such that their ability to produce a high yield of hydrogen was unchanged. All these support that lichens are (a) ideal model systems for a space mission to inhabit other planets, supporting also the aspect that the panspermia theory could be extended to incorporate in the traveling entities not only single organisms but micro-ecosystems like lichens, and (b) ideal model systems for astrobiotechnological applications (hydrogen production), such as in the development of bioregeneration systems for extraterrestrial environments.</description><identifier>ISSN: 1531-1074</identifier><identifier>EISSN: 1557-8070</identifier><identifier>DOI: 10.1089/ast.2017.1789</identifier><identifier>PMID: 30383392</identifier><language>eng</language><publisher>United States: Mary Ann Liebert, Inc</publisher><subject>Acetabulum ; Carbohydrates ; Chlorophyll ; Cultivation ; Dehydration ; Deoxyribonucleic acid ; Depletion ; Desiccation ; DNA ; DNA methylation ; Drying ; Ecosystem integrity ; Ecosystems ; Efflux ; Environmental changes ; Environmental conditions ; Environmental impact ; Ergosterol ; Extraterrestrial environments ; Extraterrestrial materials ; Fatty acids ; Hydrogen production ; Lichens ; Low temperature ; Mars ; Molecular structure ; Oxygen depletion ; Panspermia ; Photosynthesis ; Photosynthetic apparatus ; Polyamines ; Structure-function relationships ; Symbionts ; Symbiosis ; Viability</subject><ispartof>Astrobiology, 2018-12, Vol.18 (12), p.1528-1542</ispartof><rights>Copyright Mary Ann Liebert, Inc. 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subjects	Acetabulum Carbohydrates Chlorophyll Cultivation Dehydration Deoxyribonucleic acid Depletion Desiccation DNA DNA methylation Drying Ecosystem integrity Ecosystems Efflux Environmental changes Environmental conditions Environmental impact Ergosterol Extraterrestrial environments Extraterrestrial materials Fatty acids Hydrogen production Lichens Low temperature Mars Molecular structure Oxygen depletion Panspermia Photosynthesis Photosynthetic apparatus Polyamines Structure-function relationships Symbionts Symbiosis Viability
title	Lichen as Micro-Ecosystem: Extremophilic Behavior with Astrobiotechnological Applications
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