Changes of the Bacterial Abundance and Communities in Shallow Ice Cores from Dunde and Muztagata Glaciers, Western China

Chen, Yong; Li, Xiang-Kai; Si, Jing; Wu, Guangjian; Tian, Lide; Xiang, Song

doi:10.3389/fmicb.2016.01716

Cited by 21 publications

(14 citation statements)

References 64 publications

(114 reference statements)

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“…Members belonging to the genus Methylobacterium were also reported to dominate the microbial community in ancient ice cores from many previous studies ( Miteva, 2008 ; Segawa et al, 2010 ; Antony et al, 2012 ; Miteva et al, 2015 , 2016 ), including several microbial investigations of the Guliya ice cap ice cores using culture-dependent methods ( Christner et al, 2000 , 2001 ; Christner, 2003 ). Five other genera with relative abundances of 0.1–4.5%, which had recognized names, were also previously reported to be abundant in glacier ice cores, including the genera Flavobacterium ( Liu et al, 2015 ; Chen et al, 2016 ), Janthinobacterium ( Christner, 2003 ; Miteva, 2008 ), Polaromonas ( Liu et al, 2009 ; An et al, 2010 ; Chen et al, 2016 ), Sphingomonas ( An et al, 2010 ; Miteva et al, 2016 ), and Rhodobacter ( Liu et al, 2015 ). The detection of bacterial sequences belonging to similar genera in ice core samples from different glaciers located around the world can be explained by the ubiquitous distribution of certain species in geographically distant environments ( Baas Becking, 1934 ; Martiny et al, 2006 ).…”

Section: Resultsmentioning

confidence: 77%

“…Thus, microorganisms immured in ice cores represent those in the atmosphere at the time of deposition and hence reflect environmental conditions during the same time period ( Priscu et al, 2007 ; Xiang et al, 2009 ). Previous investigations of the microbial community in polar glaciers (e.g., Miteva et al, 2009 , 2015 ; Santibanez-Avila, 2016 ) and low-latitude glaciers (e.g., Yao et al, 2008 ; Chen et al, 2016 ) have suggested that microbial diversity and abundance preserved in deep ice cores are correlated with dust particle concentrations, local climate conditions, and global atmospheric circulation. Usually the biomass is very low in most glacier ice samples, with the estimated number of microbial cells ranging from 10 2 to 10 4 cells ml -1 ( Miteva, 2008 ).…”

Section: Introductionmentioning

confidence: 99%

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Clean Low-Biomass Procedures and Their Application to Ancient Ice Core Microorganisms

et al. 2018

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Microorganisms in glacier ice provide tens to hundreds of thousands of years archive for a changing climate and microbial responses to it. Analyzing ancient ice is impeded by technical issues, including limited ice, low biomass, and contamination. While many approaches have been evaluated and advanced to remove contaminants on ice core surfaces, few studies leverage modern sequencing to establish in silico decontamination protocols for glacier ice. Here we sought to apply such “clean” sampling techniques with in silico decontamination approaches used elsewhere to investigate microorganisms archived in ice at ∼41 (D41, ∼20,000 years) and ∼49 m (D49, ∼30,000 years) depth in an ice core (GS3) from the summit of the Guliya ice cap in the northwestern Tibetan Plateau. Four “background” controls were established – a co-processed sterile water artificial ice core, two air samples collected from the ice processing laboratories, and a blank, sterile water sample – and used to assess contaminant microbial diversity and abundances. Amplicon sequencing revealed 29 microbial genera in these controls, but quantitative PCR showed that the controls contained about 50–100-times less 16S DNA than the glacial ice samples. As in prior work, we interpreted these low-abundance taxa in controls as “contaminants” and proportionally removed them in silico from the GS3 ice amplicon data. Because of the low biomass in the controls, we also compared prokaryotic 16S DNA amplicons from pre-amplified (by re-conditioning PCR) and standard amplicon sequencing, and found the resulting microbial profiles to be repeatable and nearly identical. Ecologically, the contaminant-controlled ice microbial profiles revealed significantly different microorganisms across the two depths in the GS3 ice core, which is consistent with changing climate, as reported for other glacier ice samples. Many GS3 ice core genera, including Methylobacterium, Sphingomonas, Flavobacterium, Janthinobacterium, Polaromonas, and Rhodobacter, were also abundant in previously studied ice cores, which suggests wide distribution across glacier environments. Together these findings help further establish “clean” procedures for studying low-biomass ice microbial communities and contribute to a baseline understanding of microorganisms archived in glacier ice.

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Section: Resultsmentioning

confidence: 77%

Section: Introductionmentioning

confidence: 99%

Clean Low-Biomass Procedures and Their Application to Ancient Ice Core Microorganisms

et al. 2018

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“…Antarctic permafrost (brown crosses) and subglacial sediments (brown-filled triangles) exhibit cell concentrations that are also greater than those of the adjacent and overlying ice sheets (open triangles). In general, cell concentrations in ice sheets (open squares, triangles, and circles) do not diminish as a function of depth and age as rapidly as observed for permafrost sediments and likely reflect a combination of airborne input flux and in situ metabolism (Chen et al, 2016). Cell concentrations are higher near rock-ice interfaces and in dust-rich ice, pointing to the importance of chemical and physical gradients.…”

Section: Modern Rock-hosted Life On Earthmentioning

confidence: 83%

Paleo-Rock-Hosted Life on Earth and the Search on Mars: A Review and Strategy for Exploration

et al. 2019

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Here we review published studies on the abundance and diversity of terrestrial rock-hosted life, the environments it inhabits, the evolution of its metabolisms, and its fossil biomarkers to provide guidance in the search for life on Mars. Key findings are (1) much terrestrial deep subsurface metabolic activity relies on abiotic energy-yielding fluxes and in situ abiotic and biotic recycling of metabolic waste products rather than on buried organic products of photosynthesis; (2) subsurface microbial cell concentrations are highest at interfaces with pronounced chemical redox gradients or permeability variations and do not correlate with bulk host rock organic carbon; (3) metabolic pathways for chemolithoautotrophic microorganisms evolved earlier in Earth's history than those of surface-dwelling phototrophic microorganisms; (4) the emergence of the former occurred at a time when Mars was habitable, whereas the emergence of the latter occurred at a time when the martian surface was not continually habitable; (5) the terrestrial rock record has biomarkers of subsurface life at least back hundreds of millions of years and likely to 3.45 Ga with several examples of excellent preservation in rock types that are quite different from those preserving the photosphere-supported biosphere. These findings suggest that rock-hosted life would have been more likely to emerge and be preserved in a martian context. Consequently, we outline a Mars exploration strategy that targets subsurface life and scales spatially, focusing initially on identifying rocks with evidence for groundwater flow and low-temperature mineralization, then identifying redox and permeability interfaces preserved within rock outcrops, and finally focusing on finding minerals associated with redox reactions and associated traces of carbon and diagnostic chemical and isotopic biosignatures. Using this strategy on Earth yields ancient rock-hosted life, preserved in the fossil record and confirmable via a suite of morphologic, organic, mineralogical, and isotopic fingerprints at micrometer scale. We expect an emphasis on rock-hosted life and this scale-dependent strategy to be crucial in the search for life on Mars.

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“…Cryobacterium strains, within the family Microbacteriaceae , are Gram‐positive, non‐spore‐forming, irregular rod‐shaped, aerobic bacteria (Liu et al ., ). Cryobacterium strains were commonly discovered in cold environments, such as in ice core, surface soil and ice of mountain glaciers (Reddy et al ., ; Liu et al ., ; Chen et al ., ); the Antarctic, Arctic and Siberian permafrost soils (Suzuki et al ., ; Bajerski et al ., ; Schuerger and Nicholson, ); Antarctic sandy intertidal sediments (Yu et al ., ), surface seawater along the Victoria Land coast of Antarctica (Giudice et al ., ) and glacier cryoconite holes in the High Arctic (Singh et al ., ). Although the genus Cryobacterium is widespread in the cryosphere, it may be a rare taxon (Liu et al ., ).…”

Section: Introductionmentioning

confidence: 99%

Phenotypic divergence of thermotolerance: Molecular basis and cold adaptive evolution related to intrinsic DNA flexibility of glacier‐inhabitingCryobacteriumstrains

Liu

Song

Zhou

et al. 2020

Environmental Microbiology

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Summary The link between guanine–cytosine (GC) content and thermal adaptation is controversial. Here, we compared maximum growth temperature (TMGT) and genomics of 78 Cryobacterium strains to avoid unreliable conclusions resulting from distantly phylogenetic groups. Phylogenomic analysis revealed this taxon had much higher diversification than we knew. Interestingly, these strains showed thermotolerance divergence with phylogenetic cohesion. A significant difference was found between TMGT ≤ 20°C strains and TMGT > 20°C strains in genomic GC content which mainly caused by variation of GC3. TMGT ≤ 20°C strains tended to use synonymous codons ended with A/U, but TMGT > 20°C strains tended to use G/C. Lower GC content at synonymous sites (≈GC3) of TMGT ≤ 20°C strains could provide lower intrinsic DNA flexibility which strongly associated with optimal molecular dynamics, and then guarantee DNA function at lower growth temperatures. This analysis of codon bias revealed close relationships for thermal adaptation, GC content at synonymous sites (≈GC3), intrinsic DNA flexibility and optimal DNA dynamics. Natural selection was main force driving this codon bias; strains with lower TMGT endured stronger natural selection. Therefore, this study provided molecular basis for bacterial adaptive evolution from moderate temperature to low temperature.

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Changes of the Bacterial Abundance and Communities in Shallow Ice Cores from Dunde and Muztagata Glaciers, Western China

Cited by 21 publications

References 64 publications

Clean Low-Biomass Procedures and Their Application to Ancient Ice Core Microorganisms

Clean Low-Biomass Procedures and Their Application to Ancient Ice Core Microorganisms

Paleo-Rock-Hosted Life on Earth and the Search on Mars: A Review and Strategy for Exploration

Phenotypic divergence of thermotolerance: Molecular basis and cold adaptive evolution related to intrinsic DNA flexibility of glacier‐inhabitingCryobacteriumstrains

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