Permafrost meta-omics and climate change

Rachel Mackelprang; Scott R. Saleska; Carsten Suhr Jacobsen; Janet K. Jansson; Neslihan Taş

doi:10.1146/annurev-earth-060614-105126

Permafrost meta-omics and climate change

Rachel Mackelprang, Scott R. Saleska, Carsten Suhr Jacobsen, Janet K. Jansson, Neslihan Taş

Geography

35 Citations (Scopus)

194 Downloads (Pure)

Abstract

Permanently frozen soil, or permafrost, covers a large portion of the Earth's terrestrial surface and represents a unique environment for cold-adapted microorganisms. As permafrost thaws, previously protected organic matter becomes available for microbial degradation. Microbes that decompose soil carbon produce carbon dioxide and other greenhouse gases, contributing substantially to climate change. Next-generation sequencing and other -omics technologies offer opportunities to discover the mechanisms by which microbial communities regulate the loss of carbon and the emission of greenhouse gases from thawing permafrost regions. Analysis of nucleic acids and proteins taken directly from permafrost-associated soils has provided new insights into microbial communities and their functions in Arctic environments that are increasingly impacted by climate change. In this article we review current information from various molecular -omics studies on permafrost microbial ecology and explore the relevance of these insights to our current understanding of the dynamics of permafrost loss due to climate change.

Original language	English
Journal	Annual Review of Earth and Planetary Sciences
Volume	44
Pages (from-to)	439-462
Number of pages	27
ISSN	0084-6597
DOIs	https://doi.org/10.1146/annurev-earth-060614-105126
Publication status	Published - 2016

Keywords

Arctic
Bioinformatics
Global warming
Metagenomics
Microbiology
Next-generation sequencing

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1146/annurev-earth-060614-105126Licence: CC BY

Permafrost Meta-Omics and Climate ChangeFinal published version, 367 KBLicence: CC BY

Cite this

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title = "Permafrost meta-omics and climate change",

abstract = "Permanently frozen soil, or permafrost, covers a large portion of the Earth's terrestrial surface and represents a unique environment for cold-adapted microorganisms. As permafrost thaws, previously protected organic matter becomes available for microbial degradation. Microbes that decompose soil carbon produce carbon dioxide and other greenhouse gases, contributing substantially to climate change. Next-generation sequencing and other -omics technologies offer opportunities to discover the mechanisms by which microbial communities regulate the loss of carbon and the emission of greenhouse gases from thawing permafrost regions. Analysis of nucleic acids and proteins taken directly from permafrost-associated soils has provided new insights into microbial communities and their functions in Arctic environments that are increasingly impacted by climate change. In this article we review current information from various molecular -omics studies on permafrost microbial ecology and explore the relevance of these insights to our current understanding of the dynamics of permafrost loss due to climate change.",

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AU - Mackelprang, Rachel

AU - Saleska, Scott R.

AU - Jacobsen, Carsten Suhr

AU - Jansson, Janet K.

AU - Taş, Neslihan

N1 - CENPERMOA[2016]

PY - 2016

Y1 - 2016

N2 - Permanently frozen soil, or permafrost, covers a large portion of the Earth's terrestrial surface and represents a unique environment for cold-adapted microorganisms. As permafrost thaws, previously protected organic matter becomes available for microbial degradation. Microbes that decompose soil carbon produce carbon dioxide and other greenhouse gases, contributing substantially to climate change. Next-generation sequencing and other -omics technologies offer opportunities to discover the mechanisms by which microbial communities regulate the loss of carbon and the emission of greenhouse gases from thawing permafrost regions. Analysis of nucleic acids and proteins taken directly from permafrost-associated soils has provided new insights into microbial communities and their functions in Arctic environments that are increasingly impacted by climate change. In this article we review current information from various molecular -omics studies on permafrost microbial ecology and explore the relevance of these insights to our current understanding of the dynamics of permafrost loss due to climate change.

AB - Permanently frozen soil, or permafrost, covers a large portion of the Earth's terrestrial surface and represents a unique environment for cold-adapted microorganisms. As permafrost thaws, previously protected organic matter becomes available for microbial degradation. Microbes that decompose soil carbon produce carbon dioxide and other greenhouse gases, contributing substantially to climate change. Next-generation sequencing and other -omics technologies offer opportunities to discover the mechanisms by which microbial communities regulate the loss of carbon and the emission of greenhouse gases from thawing permafrost regions. Analysis of nucleic acids and proteins taken directly from permafrost-associated soils has provided new insights into microbial communities and their functions in Arctic environments that are increasingly impacted by climate change. In this article we review current information from various molecular -omics studies on permafrost microbial ecology and explore the relevance of these insights to our current understanding of the dynamics of permafrost loss due to climate change.

KW - Arctic

KW - Bioinformatics

KW - Global warming

KW - Metagenomics

KW - Microbiology

KW - Next-generation sequencing

U2 - 10.1146/annurev-earth-060614-105126

DO - 10.1146/annurev-earth-060614-105126

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SN - 0084-6597

VL - 44

SP - 439

EP - 462

JO - Annual Review of Earth and Planetary Sciences

JF - Annual Review of Earth and Planetary Sciences

ER -

Permafrost meta-omics and climate change

Abstract

Keywords

UN SDGs

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