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Inicio Brazilian Journal of Microbiology Draft genome sequence of sulfur-reducing archaeon Thermococcus thioreducens DSM ...
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Vol. 48. Núm. 1.
Páginas 3-4 (enero - marzo 2017)
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Vol. 48. Núm. 1.
Páginas 3-4 (enero - marzo 2017)
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Draft genome sequence of sulfur-reducing archaeon Thermococcus thioreducens DSM 14981T
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Sung-Jun Hong, Chang Eon Park, Gun-Seok Park, Min-Chul Kim, Byung Kwon Jung, Jae-Ho Shin
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jhshin@knu.ac.kr

Corresponding author.
Kyungpook National University, College of Agriculture and Life Sciences, School of Applied Biosciences, Daegu, Republic of Korea
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Abstract

Thermococcus thioreducens DSM 14981T, a sulfur-reducing archaeon, was isolated from the rainbow hydrothermal vent site on the Mid-Atlantic Ridge. Herein, we report the draft genome sequence of T. thioreducens DSM 14981T; we obtained 41 contigs with a genome size of 2,052,483bp and G+C content of 53.5%. This genome sequence will not only help understand how the archaeon adapts to the deep-sea hydrothermal environment but also aid the development of enzymes that are highly stable under extreme conditions for industrial applications.

Keywords:
Archaea
Hyperthermophile
Thermococcus thioreducens
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Introduction

Thermococcus taxonomically belongs to the family Flavobacteriaceae and phylum Euryarchaeota.1 Members of this genus are characterized by thermophilic anaerobiosis with sulfur-type respiration and sulfur stimulation for fermentation.2 A decrease in S levels in the growth medium leads to the enhanced production of ethanol, butanol, H2, and formate at the expense of H2S and acetate production.3 The minimal growth temperature for most species is approximately 50°C and the maximum is approximately 95–100°C. Therefore, these microorganisms are generally good sources of enzymes for application in various biotechnological processes in the food, chemical, and pharmaceutical industries.4

A strain DSM 14981T was isolated from “black smoker” chimney material from the rainbow hydrothermal vent site on the Mid-Atlantic Ridge. It is a hyperthermophilic, heterotrophic, sulfur-dependent, coccoid archaeon inhabiting a deep-sea hydrothermal system in the Mid-Atlantic Ridge (36.2°N, 33.9°W). The optimal growth conditions include a pH of 5.0–8.5, NaCl concentration of 1–5% (w/v), and temperature of 55–94°C. A strain DSM 14981T was identified by 16S rRNA gene sequence, was named as Thermococcus thioreducens. And, this strain is an obligate anaerobe and completely dependent upon elemental sulfur as the electron acceptor, but it does not reduce sulfate, sulfite, thiosulfate, Fe (III), or nitrate.5 In this communication, we present the draft genome sequence of T. thioreducens DSM 14981T, with the aim to study the extreme adaptation of this archaeon in a hydrothermal environment.

T. thioreducens DSM 14981T was cultured in Bacto Marine broth with 0.5% (w/v) sulfur powder and incubated at 80°C for 48h. Genomic DNA was then extracted using the method reported by Ramakrishnan.6 Whole-genome sequencing of the strain was performed using the Ion Torrent PGM sequencer (400-bp library) and 316™ chip v2, according to the manufacturer's instructions (ThermoFisher Scientific, Germany).7 Sequencing generated 755,986 reads with an average read length of 290bp. De novo assembly was performed using the MIRA assembler v4.0.2 and CLC Genomics Workbench v7.0 software. Forty-one contigs with N50 contig length of 151,544bp and a maximum contig size of 253,877bp were obtained. The draft genome size was 2,052,483bp, with a G+C content of 53.5% and no plasmids.

We used the Rapid Annotation using Subsystem Technology8 and National Centre for Biotechnology Information's Prokaryotic Genomes Annotation Pipeline v2.6 (http://www.ncbi.nlm.nih.gov/genome/annotation_prok) for gene prediction and annotation. Genes were predicted using the Glimmer 3.02 software.9 Forty-two tRNA genes were identified using tRNAscan-SE,10 and 5 rRNAs were identified using the RNAmmer 1.2 software.11

Apart from encoding the archaeal-modified Embden–Meyerhof (EM) glycolysis pathway and protein and carbohydrate metabolism pathways,12 the T. thioreducens DSM 14981 draft genome also encodes the archaeal RuBisCo to facilitate carbon fixation.13 In addition, this genome encodes genes involved in energy synthesis including a V-type ATP synthase gene cluster and NADH – ubiquinone oxidoreductase on the cell membrane. The genome also has a gene cluster for respiration, including membrane bound hydrogenase, sulfurhydrogenase II complex, and formate dehydrogenase H. In order to survive extreme conditions such as high temperature, pressure, and pH, the strain contains heat shock protein 60, a prefoldin protein, and a small heat shock protein.14,15 The important enzyme-encoding genes for potential use in commercial enzyme production,16 such as those encoding amylase, protease, pullulanase, glycosyltransferase, and alcohol dehydrogenase, were also found in its genome sequence. Further insights into the genome sequence of this archaeon should facilitate studying extreme environments in hydrothermal vents and aid the development of enzymes that are highly stable under extreme conditions for industrial applications.

Nucleotide sequence accession numbers

The whole genome sequence of T. thioreducens DSM 14981 has been deposited at DDBJ/EMBL/GenBank under the accession number LIXN00000000. The first version (LIXN00000000.1) has been described in this paper.

Conflicts of interest

The authors declare no conflicts of interest.

Acknowledgements

This research was supported by the Basic Science Research Program through the National Research Foundation of Korea (NRF), funded by the Ministry of Education (NRF-2015R1D1A1A01057187).

References
[1]
G. Garrity, D.R. Boone, R.W. Castenholz.
The archaea and the deeply branching and phototrophic.
Springer Science & Business Media, (2012),
[2]
W. Zillig, I. Holz, D. Janekovic, et al.
Hyperthermus butylicus, a hyperthermophilic sulfur-reducing archaebacterium that ferments peptides.
J Bacteriol, 172 (1990), pp. 3959-3965
[3]
K. Ma, H. Loessner, J. Heider, M.K. Johnson, M. Adams.
Effects of elemental sulfur on the metabolism of the deep-sea hyperthermophilic archaeon Thermococcus strain ES-1: characterization of a sulfur-regulated, non-heme iron alcohol dehydrogenase.
J Bacteriol, 177 (1995), pp. 4748-4756
[4]
J.A. Littlechild.
Archaeal enzymes and applications in industrial biocatalysts.
Archaea, 2015 (2015), pp. 10
[5]
E.V. Pikuta, D. Marsic, T. Itoh, et al.
Thermococcus thioreducens sp. nov., a novel hyperthermophilic, obligately sulfur-reducing archaeon from a deep-sea hydrothermal vent.
Int J Syst Evol Microbiol, 57 (2007), pp. 1612-1618
[6]
V. Ramakrishnan, M. Adams.
Preparation of Genomic DNA from Sulfur-Dependent Hyperthermophilic Archaea. Archaea: A Laboratory Manual.
Cold Spring Harbor Laboratory Press, (1995),
[7]
J.M. Rothberg, W. Hinz, T.M. Rearick, et al.
An integrated semiconductor device enabling non-optical genome sequencing.
Nature, 475 (2011), pp. 348-352
[8]
R.K. Aziz, D. Bartels, A.A. Best, et al.
The RAST server: rapid annotations using subsystems technology.
BMC Genomics, 9 (2008), pp. 75
[9]
A.L. Delcher, D. Harmon, S. Kasif, O. White, S.L. Salzberg.
Improved microbial gene identification with GLIMMER.
Nucleic Acids Res, 27 (1999), pp. 4636-4641
[10]
T.M. Lowe, S.R. Eddy.
tRNAscan-SE: a program for improved detection of transfer RNA genes in genomic sequence.
Nucleic Acids Res, 25 (1997), pp. 0955-0964
[11]
K. Lagesen, P. Hallin, E.A. Rødland, H.-H. Stærfeldt, T. Rognes, D.W. Ussery.
RNAmmer: consistent and rapid annotation of ribosomal RNA genes.
Nucleic Acids Res, 35 (2007), pp. 3100-3108
[12]
C.H. Verhees, S.W.M. Kengen, J.E. Tuininga, et al.
The unique features of glycolytic pathways in Archaea.
Biochem J, 375 (2003), pp. 231-246
[13]
T. Sato, H. Atomi, T. Imanaka.
Archaeal type III RuBisCOs function in a pathway for AMP metabolism.
Science, 315 (2007), pp. 1003-1006
[14]
K.R. Shockley, D.E. Ward, S.R. Chhabra, S.B. Conners, C.I. Montero, R.M. Kelly.
Heat shock response by the hyperthermophilic archaeon Pyrococcus furiosus.
Appl Environ Microbiol, 69 (2003), pp. 2365-2371
[15]
P. Laksanalamai, F.T. Robb.
Small heat shock proteins from extremophiles: a review.
Extremophiles, 8 (2004), pp. 1-11
[16]
J. Gomes, W. Steiner.
The biocatalytic potential of extremophiles and extremozymes.
Food Technol Biotech, 42 (2004), pp. 223-235
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