Cold adaptation in the marine bacterium, <i>Sphingopyxis alaskensis</i>, assessed using quantitative proteomics

Ting, Lily; Williams, Timothy J.; Cowley, Mark J.; Lauro, Federico M.; Guilhaus, Michael; Raftery, Mark J.; Cavicchioli, Ricardo

doi:10.1111/j.1462-2920.2010.02235.x

Cited by 123 publications

(111 citation statements)

References 93 publications

(128 reference statements)

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“…The heat shock protein genes present in the metagenomic data set probably do not reflect heat shock responses in the permanently cold LH Spring, since these genes were more related to the general chaperone protein DnaK (640 hits) and its interacting protein, DnaJ (31 hits); these proteins are prevalent in microorganisms in cold environments and assist with protein folding (75,76).…”

Section: Resultsmentioning

confidence: 99%

Defining the Functional Potential and Active Community Members of a Sediment Microbial Community in a High-Arctic Hypersaline Subzero Spring

Lay

Mykytczuk

Yergeau

et al. 2013

Appl Environ Microbiol

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bThe Lost Hammer (LH) Spring is the coldest and saltiest terrestrial spring discovered to date and is characterized by perennial discharges at subzero temperatures (؊5°C), hypersalinity (salinity, 24%), and reducing (Ϸ؊165 mV), microoxic, and oligotrophic conditions. It is rich in sulfates (10.0%, wt/wt), dissolved H 2 S/sulfides (up to 25 ppm), ammonia (Ϸ381 M), and methane (11.1 g day ؊1 ). To determine its total functional and genetic potential and to identify its active microbial components, we performed metagenomic analyses of the LH Spring outlet microbial community and pyrosequencing analyses of the cDNA of its 16S rRNA genes. Reads related to Cyanobacteria (19.7%), Bacteroidetes (13.3%), and Proteobacteria (6.6%) represented the dominant phyla identified among the classified sequences. Reconstruction of the enzyme pathways responsible for bacterial nitrification/denitrification/ammonification and sulfate reduction appeared nearly complete in the metagenomic data set. In the cDNA profile of the LH Spring active community, ammonia oxidizers (Thaumarchaeota), denitrifiers (Pseudomonas spp.), sulfate reducers (Desulfobulbus spp.), and other sulfur oxidizers (Thermoprotei) were present, highlighting their involvement in nitrogen and sulfur cycling. Stress response genes for adapting to cold, osmotic stress, and oxidative stress were also abundant in the metagenome. Comparison of the composition of the functional community of the LH Spring to metagenomes from other saline/ subzero environments revealed a close association between the LH Spring and another Canadian high-Arctic permafrost environment, particularly in genes related to sulfur metabolism and dormancy. Overall, this study provides insights into the metabolic potential and the active microbial populations that exist in this hypersaline cryoenvironment and contributes to our understanding of microbial ecology in extreme environments. Cryoenvironments are defined as permanently subzero or frozen environments, such as permafrost, glaciers, ice sheets, multiyear sea ice, high-elevation Antarctic dry valleys, and some cold saline springs (1-6). Microorganisms inhabiting cryoenvironments must face the challenges of subzero temperatures, low water activity, and, often, high solute concentrations to sustain their viability. The cold saline springs on Axel Heiberg Island (AHI) in the Canadian high Arctic discharge through 500 to 600 m of thick permafrost, maintain a liquid state at subzero temperatures, and offer a unique opportunity to assess microbial adaptations to extremes of both high salinity and subzero temperatures (3, 4, 7-9). These springs occur in an area with an average annual air temperature of Ϫ15°C, reaching below Ϫ40°C during the winter months, and probably originate from subpermafrost groundwater flow through carboniferous evaporites in areas of diapiric uplift on AHI (10, 11). Other Arctic cold springs, on Ellesmere Island in the Canadian high Arctic and on the Norwegian highArctic Svalbard archipelago, have been reported (12-14), although t...

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Section: Resultsmentioning

confidence: 99%

Defining the Functional Potential and Active Community Members of a Sediment Microbial Community in a High-Arctic Hypersaline Subzero Spring

Lay

Mykytczuk

Yergeau

et al. 2013

Appl Environ Microbiol

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“…It is noteworthy in this connection that a combined transcriptome and proteome study of continuously chill-stressed B. subtilis cells revealed a major contribution of posttranscriptional regulatory phenomena in shaping the proteome in the cold (15). Compatible solutes might also help make translation more efficient since the initiation and efficiency of protein biosynthesis and folding are a major hurdle in cold-stressed microbial cells (58,60,62).…”

Section: Vol 193 2011 Protection Against Cold Stress By Compatible mentioning

confidence: 99%

Protection ofBacillus subtilisagainst Cold Stress via Compatible-Solute Acquisition

2011

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Accumulation of compatible solutes is a strategy widely employed by bacteria to achieve cellular protection against high osmolarity. These compounds are also used in some microorganisms as thermostress protectants. We found that Bacillus subtilis uses the compatible solute glycine betaine as an effective cold stress protectant. Glycine betaine strongly stimulated growth at 15°C and permitted cell proliferation at the growth-inhibiting temperature of 13°C. Initial uptake of glycine betaine at 15°C was low but led eventually to the buildup of an intracellular pool whose size was double that found in cells grown at 35°C. Each of the three glycine betaine transporters (OpuA, OpuC, and OpuD) contributed to glycine betaine accumulation in the cold. Protection against cold stress was also accomplished when glycine betaine was synthesized from its precursor choline. Growth of a mutant defective in the osmoadaptive biosynthesis for the compatible solute proline was not impaired at low temperature (15°C). In addition to glycine betaine, the compatible solutes and osmoprotectants L-carnitine, crotonobetaine, butyrobetaine, homobetaine, dimethylsulfonioactetate, and proline betaine all served as cold stress protectants as well and were accumulated via known Opu transport systems. In contrast, the compatible solutes and osmoprotectants choline-O-sulfate, ectoine, proline, and glutamate were not cold protective. Our data highlight an underappreciated facet of the acclimatization of B. subtilis to cold environments and allow a comparison of the characteristics of compatible solutes with respect to their osmotic, heat, and cold stress-protective properties for B. subtilis cells.

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“…As a result of such microbial adaptation to low temperature, the rate and efficiency of organic carbon mineralization in the cold may be as high as in temperate and warm habitats (Kostka et al, 1999). However, bacteria that grow at temperatures extending into the mesophilic range and that do not show cold adaptations were also isolated from the cold deep seafloor (Rüger,temperatures and cold-adapted proteins (Ting et al, 2011;Casanueva et al, 2010). Phenotypically these molecular adaptations are expressed as different cardinal temperatures of growth or respiration, i.e.…”

Section: Introductionmentioning

confidence: 99%

Temperature characteristics of bacterial sulfate reduction in continental shelf and slope sediments

2012

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Abstract. The temperature responses of sulfate-reducing microbial communities were used as community temperature characteristics for their in situ temperature adaptation, their origin, and dispersal in the deep sea. Sediments were collected from a suite of coastal, continental shelf, and slope sediments from the southwest and southeast Atlantic and permanently cold Arctic fjords from water depths ranging from the intertidal zone to 4327 m. In situ temperatures ranged from 8 • C on the shelf to −1 • C in the Arctic. Temperature characteristics of the active sulfate-reducing community were determined in short-term incubations with 35 S-sulfate in a temperature gradient block spanning a temperature range from 0 to 40 • C. An optimum temperature (T opt ) between 27 • C and 30 • C for the South Atlantic shelf sediments and for the intertidal flat sediment from Svalbard was indicative of a psychrotolerant/mesophilic sulfate-reducing community, whereas T opt ≤ 20 • C in South Atlantic slope and Arctic shelf sediments suggested a predominantly psychrophilic community. High sulfate reduction rates (20-50 %) at in situ temperatures compared to those at T opt further support this interpretation and point to the importance of the ambient temperature regime for regulating the short-term temperature response of sulfate-reducing communities. A number of cold (< 4 • C) continental slope sediments showed broad temperature optima reaching as high as 30 • C, suggesting the additional presence of apparently mesophilic sulfate-reducing bacteria. Since the temperature characteristics of these mesophiles do not fit with the permanently cold deep-sea environment, we suggest that these mesophilic microorganisms are of allochthonous origin and transported to this site. It is likely that they were deposited along with the mass-flow movement of warmer shelf-derived sediment. These data therefore suggest that temperature response profiles of bacterial carbon mineralization processes can be used as community temperature characteristics, and that mixing of bacterial communities originating from diverse locations carrying different temperature characteristics needs to be taken into account to explain temperature response profiles of bacterial carbon mineralization processes in sediments.

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Cold adaptation in the marine bacterium, Sphingopyxis alaskensis, assessed using quantitative proteomics

Cited by 123 publications

References 93 publications

Defining the Functional Potential and Active Community Members of a Sediment Microbial Community in a High-Arctic Hypersaline Subzero Spring

Defining the Functional Potential and Active Community Members of a Sediment Microbial Community in a High-Arctic Hypersaline Subzero Spring

Protection ofBacillus subtilisagainst Cold Stress via Compatible-Solute Acquisition

Temperature characteristics of bacterial sulfate reduction in continental shelf and slope sediments

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