Literature DB >> 28104654

Draft Genome Sequence of the Acidophilic, Halotolerant, and Iron/Sulfur-Oxidizing Acidihalobacter prosperus DSM 14174 (Strain V6).

Himel Nahreen Khaleque¹, Joshua P Ramsay¹, Riley J T Murphy¹, Anna H Kaksonen², Naomi J Boxall², Elizabeth L J Watkin³.

Abstract

The principal genomic features of Acidihalobacter prosperus DSM 14174 (strain V6) are presented here. This is a mesophilic, halotolerant, and iron/sulfur-oxidizing acidophile that was isolated from seawater at Vulcano, Italy. It has potential for use in biomining applications in regions where high salinity exists in the source water and ores.

Entities: Chemical Disease Species

Year: 2017 PMID： 28104654 PMCID： PMC5255921 DOI： 10.1128/genomeA.01469-16

Source DB: PubMed Journal: Genome Announc

GENOME ANNOUNCEMENT

Acidihalobacter prosperus (previously known as Thiobacillus prosperus) is a Gram-negative, halotolerant, acidophilic, mesophilic, and chemolitho-autotrophic bacterium capable of oxidizing both iron and reduced sulfur compounds (1). The type strain, A. prosperus DSM 5130, was isolated from a marine geothermal field in Italy. It requires a minimum of 0.04 M Cl- for growth and tolerates up to 0.6 M Cl- (1). A. prosperus DSM 14174 was isolated from a shallow acidic pool by the shore of Baia de Levant, Aelion Islands of Vulcano, Italy (2). Like A. prosperus DSM 5130, it does not grow in the absence of salt (3). It has been used in salt-rich systems for the active biomining of metal sulfide ores (4). Total DNA extracted from A. prosperus DSM 14174 was sequenced using Illumina MiSeq (204,485 paired-end 300 bp × 2 reads) and PacBio RS single-molecule real-time (SMRT) sequencing technologies (96,369 reads postfilter, 11,756 bp mean length). De novo hybrid assembly using SPAdes 3.9.0 (5) produced a circular 162,484-bp plasmid (~32-fold coverage) and two chromosome fragments of 2,607,071 bp and 752,753 bp (~18-fold coverage). The two chromosome fragments were scaffolded using SSPACE-LongRead version 1.1 (6), producing a circular chromosome of 3,363,634 bp (with one gap). The genome has a G+C content of 62.2%. The NCBI Prokaryotic Genome Annotation Pipeline version 3.3 and GeneMarkS+ were used for annotation. The genome contains 46 tRNA sequences, one rRNA operon, and 3,194 protein-coding genes. Genome analysis of A. prosperus DSM 14174 confirmed the presence of the previously reported rus operon known to be involved in iron oxidation (3). Also present were genes coding for subunits SoxAX, SoxB, and SoxYZ of the sulfur oxidation system (7), as well as those for sulfur metabolism through hydrogen sulfide biosynthesis (8). Furthermore, there were genes encoding proteins involved in various catalytic reactions for oxidation/reduction of sulfur as well as the transport of sulfate/sulfonate (8). Similar to the genome of the type strain A. prosperus DSM 5130, the genome of A. prosperus DSM 14174 contains a complete set of genes for carbon dioxide fixation via the Calvin-Benson-Bassham cycle, as well as those for the Nif complex for nitrogen fixation, chemotaxis, and formation of a polar flagellum (9). The synthesis of compatible solutes, such as ectoine, sucrose, and glycine betaine, assists in the survival of bacteria under high osmotic stress (10). The genome of A. prosperus DSM 14174 contains genes that encode diaminobutyrate aminotransferases, diaminobutyrate acetyltransferase, ectoine synthase, and sucrose synthase. These have potential roles in ectoine and sucrose biosynthesis pathways. Genes for ABC transporters for ectoine and glycine betaine uptake were also detected. A. prosperus DSM 14174 contains a single plasmid, pABPV6, which is unique to this strain. The plasmid pABPV6 contains an array of genes coding for replication and transfer proteins, transposases, DNA methyltransferases, recombinases, hydrolases, and DNA binding proteins.

Accession number(s).

The whole-genome sequence has been deposited at DDBJ/EMBL/GenBank under the GenBank accession no. CP017448. The plasmid pABPV6 has been deposited under the GenBank accession no. CP017449. The versions described in this paper are CP017448.1 and CP017449.1, respectively.

8 in total

1. Acidophiles of saline water at thermal vents of Vulcano, Italy.

Authors: Susan Simmons; R Norris
Journal: Extremophiles Date: 2002-01-22 Impact factor: 2.395

Review 2. Prokaryotic sulfur oxidation.

Authors: Cornelius G Friedrich; Frank Bardischewsky; Dagmar Rother; Armin Quentmeier; Jörg Fischer
Journal: Curr Opin Microbiol Date: 2005-06 Impact factor: 7.934

3. Assembling single-cell genomes and mini-metagenomes from chimeric MDA products.

Authors: Sergey Nurk; Anton Bankevich; Dmitry Antipov; Alexey A Gurevich; Anton Korobeynikov; Alla Lapidus; Andrey D Prjibelski; Alexey Pyshkin; Alexander Sirotkin; Yakov Sirotkin; Ramunas Stepanauskas; Scott R Clingenpeel; Tanja Woyke; Jeffrey S McLean; Roger Lasken; Glenn Tesler; Max A Alekseyev; Pavel A Pevzner
Journal: J Comput Biol Date: 2013-10 Impact factor: 1.479

Review 4. Osmoadaptation mechanisms in prokaryotes: distribution of compatible solutes.

Authors: Nuno Empadinhas; Milton S da Costa
Journal: Int Microbiol Date: 2008-09 Impact factor: 2.479

5. Ferrous iron oxidation and rusticyanin in halotolerant, acidophilic 'Thiobacillus prosperus'.

Authors: James Le C Nicolle; Susan Simmons; Stephan Bathe; Paul R Norris
Journal: Microbiology Date: 2009-04 Impact factor: 2.777

6. Insights from the metagenome of an acid salt lake: the role of biology in an extreme depositional environment.

Authors: Sarah Stewart Johnson; Marc Gerard Chevrette; Bethany L Ehlmann; Kathleen Counter Benison
Journal: PLoS One Date: 2015-04-29 Impact factor: 3.240

7. SSPACE-LongRead: scaffolding bacterial draft genomes using long read sequence information.

Authors: Marten Boetzer; Walter Pirovano
Journal: BMC Bioinformatics Date: 2014-06-20 Impact factor: 3.169

8. Draft Genome Sequence of the Iron-Oxidizing, Acidophilic, and Halotolerant "Thiobacillus prosperus" Type Strain DSM 5130.

Authors: Francisco J Ossandon; Juan Pablo Cárdenas; Melissa Corbett; Raquel Quatrini; David S Holmes; Elizabeth Watkin
Journal: Genome Announc Date: 2014-10-23

8 in total

10 in total

Review 1. The effect of H₃O⁺ on the membrane morphology and hydrogen bonding of a phospholipid bilayer.

Authors: Evelyne Deplazes; David Poger; Bruce Cornell; Charles G Cranfield
Journal: Biophys Rev Date: 2018-09-15

Review 2. In a quest for engineering acidophiles for biomining applications: challenges and opportunities.

Authors: Yosephine Gumulya; Naomi J Boxall; Himel N Khaleque; Ville Santala; Ross P Carlson; Anna H Kaksonen
Journal: Genes (Basel) Date: 2018-02-21 Impact factor: 4.096

3. Draft Genome Sequence of Acidihalobacter ferrooxidans DSM 14175 (Strain V8), a New Iron- and Sulfur-Oxidizing, Halotolerant, Acidophilic Species.

Authors: Himel N Khaleque; Joshua P Ramsay; Riley J T Murphy; Anna H Kaksonen; Naomi J Boxall; Elizabeth L J Watkin
Journal: Genome Announc Date: 2017-05-25

4. Draft Genome Sequence of Acidithiobacillus sp. Strain SH, a Marine Acidophilic Sulfur-Oxidizing Bacterium.

Authors: Kazuo Kamimura; Sultana Sharmin; Eriko Yoshino; Mirai Tokuhisa; Tadayoshi Kanao
Journal: Genome Announc Date: 2018-02-08

5. Uncovering the Mechanisms of Halotolerance in the Extremely Acidophilic Members of the Acidihalobacter Genus Through Comparative Genome Analysis.

Authors: Himel N Khaleque; Carolina González; Raihan Shafique; Anna H Kaksonen; David S Holmes; Elizabeth L J Watkin
Journal: Front Microbiol Date: 2019-02-08 Impact factor: 5.640

6. Bioprospecting Reveals Class III ω-Transaminases Converting Bulky Ketones and Environmentally Relevant Polyamines.

Authors: Cristina Coscolín; Nadine Katzke; Antonio García-Moyano; José Navarro-Fernández; David Almendral; Mónica Martínez-Martínez; Alexander Bollinger; Rafael Bargiela; Christoph Gertler; Tatyana N Chernikova; David Rojo; Coral Barbas; Hai Tran; Olga V Golyshina; Rainhard Koch; Michail M Yakimov; Gro E K Bjerga; Peter N Golyshin; Karl-Erich Jaeger; Manuel Ferrer
Journal: Appl Environ Microbiol Date: 2019-01-09 Impact factor: 4.792

7. Prediction and Inferred Evolution of Acid Tolerance Genes in the Biotechnologically Important Acidihalobacter Genus.

Authors: Katelyn Boase; Carolina González; Eva Vergara; Gonzalo Neira; David Holmes; Elizabeth Watkin
Journal: Front Microbiol Date: 2022-04-18 Impact factor: 6.064

8. Genomic Characterization and Probiotic Potency of Bacillus sp. DU-106, a Highly Effective Producer of L-Lactic Acid Isolated From Fermented Yogurt.

Authors: Pan Li; Wenni Tian; Zhuo Jiang; Zuanhao Liang; Xueyin Wu; Bing Du
Journal: Front Microbiol Date: 2018-09-20 Impact factor: 5.640

9. Genome-based classification of Acidihalobacter prosperus F5 (=DSM 105917=JCM 32255) as Acidihalobacter yilgarnensis sp. nov.

Authors: Himel Nahreen Khaleque; Carolina González; D Barrie Johnson; Anna H Kaksonen; David S Holmes; Elizabeth L J Watkin
Journal: Int J Syst Evol Microbiol Date: 2020-12 Impact factor: 2.747

10. Examining the Osmotic Response of Acidihalobacter aeolianus after Exposure to Salt Stress.

Authors: Melissa K Corbett; Liam Anstiss; April Gifford; Ross M Graham; Elizabeth L J Watkin
Journal: Microorganisms Date: 2021-12-23