Complete Genome Sequence of the Methanogen Methanoculleus bourgensis BA1 Isolated from a Biogas Reactor

Irena Maus; Daniel Wibberg; Anika Winkler; Alfred Pühler; Anna Schnürer; Andreas Schlüter

doi:10.1128/genomeA.00568-16

DOI: 10.1128/genomeA.00568-16

ABSTRACT

Methanoculleus bourgensis BA1, a hydrogenotrophic methanogen, was isolated from a laboratory-scale biogas reactor operating under an elevated ammonium concentration. Here, the complete genome sequence of M. bourgensis BA1 is reported. The availability of the BA1 genome sequence enables detailed comparative analyses involving other Methanoculleus spp. representing important members of microbial biogas communities.

GENOME ANNOUNCEMENT

Frequently, members of the genus Methanoculleus were described as playing an important role in different biogas reactor systems (1, 2). In particular, the species Methanoculleus bourgensis was found to be dominant in several biogas systems. Moreover, different studies described the prevalence of M. bourgensis in reactors performing syntrophic acetate oxidation (SAO) under high ammonium concentrations (3 –5), indicating the importance of this methanogen in corresponding communities. Isolation and/or cocultivation of M. bourgensis, together with acetate-oxidizing bacteria (4, 6) such as Clostridium ultunense (7), led to the assumption that syntrophic association may play an important role for members of the genus Methanoculleus. Bioaugmentation involving Methanoculleus spp. in coculture with SAO bacteria was discussed as a feasible approach to shorten the adaptation period of digesters operating under high ammonium/ammonia concentrations (3, 8).

The objective of this work was to sequence the methanogen M. bourgensis BA1 (9) originating from a Swedish lab-scale continuous stirred tank reactor (37°C) operating under an elevated ammonium concentration (6.4 g 1⁻¹ NH₄+ N) and utilizing alfalfa silage for methane production. Furthermore, the availability of the M. bourgensis BA1 genome sequence and insights into its predicted metabolic capabilities provide reference points for comparative analyses comprising other methanogenic species of Archaea from biogas communities.

Strain BA1 was isolated as described previously (9, 10). The 16S rRNA gene sequence analysis classified the isolate as a member of the species M. bourgensis with 99% sequence identity to the 16S rRNA gene of strain MS2^T (11). Genomic DNA of strain BA1 was isolated using the Qiagen blood and tissue kit and sequenced applying the paired-end protocol on an Illumina MiSeq system. The 2,155,212 reads obtained, accounting for 565,780,211 bp of sequence information, were de novo assembled using the GS de novo assembler version 2.8 software. The assembly resulted in 14 scaffolds comprising 48 contigs. An in silico gap closure approach (12) was applied to close all gaps between contigs and circularize the genome. The complete BA1 chromosome has a size of 2,551,189 bp, featuring a GC content of 60.89%. Annotation of the genome sequence was performed within the annotation system GenDB version 2.0 (13) and resulted in the detection of 2,528 protein-coding sequences, 45 tRNA genes, and one rrn operon.

Interpretation of the M. bourgensis BA1 genome sequence revealed that all genes required for hydrogenotrophic methanogenesis were identified. Moreover, genes encoding a formate transporter (fdhC) and a formate dehydrogenase operon (fdhA-B) for growth on formate as an alternative methanogenic substrate were found. Since strain BA1 was isolated from a habitat rich in ammonium/ammonia, genes involved in nitrogen metabolism were analyzed. Similar to the type strain M. bourgensis MS2^T (11, 14), the BA1 genome encodes neither a methylammonium permease nor the putative archaeal ammonium uptake system Amt predicted to transport NH₄+. The missing ammonium transporter may indicate an adaptation of the strain to environments rich in ammonium/ammonia. Furthermore, strain BA1 harbors genes encoding different potassium transporters and a glycine betaine/proline transport system that may contribute to compatible solute accumulation as response to high osmolarity.

Nucleotide sequence accession number.This whole-genome shotgun project has been deposited in the EMBL/GenBank database (EBI, NCBI) under the accession number LT549891 (Study ID: PRJEB13327).

ACKNOWLEDGMENTS

The bioinformatics support of the BMBF-funded project “Bielefeld-Gießen Center for Microbial Bioinformatics”—BiGi (grant 031A533) within the German Network for Bioinformatics Infrastructure (de.NBI) is gratefully acknowledged. I.M. and D.W. acknowledge the receipt of a scholarship from the CLIB Graduate Cluster “Industrial Biotechnology,” cofinanced by the Ministry of Innovation of North Rhine-Westphalia. Moreover, we acknowledge funding by the German Federal Ministry of Food and Agriculture (BMEL, grant 22006712), and the German Federal Ministry of Education and Research (BMBF, grant 03SF0440C).

FOOTNOTES

Received 4 May 2016.
Accepted 10 May 2016.
Published 23 June 2016.

This is an open-access article distributed under the terms of the Creative Commons Attribution 4.0 International license.

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1. Wibberg D,
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6. Scharf B,
7. Schneiker-Bekel S,
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10. Setubal JC,
11. Schmitt R,
12. Pühler A,
13. Schlüter A
. 2011. Complete genome sequencing of Agrobacterium sp. H13-3, the former Rhizobium lupini H13-3, reveals a tripartite genome consisting of a circular and a linear chromosome and an accessory plasmid but lacking a tumor-inducing Ti-plasmid. J Biotechnol 155:50–62. doi:10.1016/j.jbiotec.2011.01.010.
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13.↵
1. Meyer F,
2. Goesmann A,
3. McHardy AC,
4. Bartels D,
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6. Clausen J,
7. Kalinowski J,
8. Linke B,
9. Rupp O,
10. Giegerich R,
11. Pühler A
. 2003. GenDB—an open source genome annotation system for prokaryote genomes. Nucleic Acids Res 31:2187–2195. doi:10.1093/nar/gkg312.
OpenUrl CrossRef PubMed Web of Science
14.↵
1. Maus I,
2. Wibberg D,
3. Stantscheff R,
4. Eikmeyer FG,
5. Seffner A,
6. Boelter J,
7. Szczepanowski R,
8. Blom J,
9. Jaenicke S,
10. König H,
11. Pühler A,
12. Schlüter A
. 2012. Complete genome sequence of the hydrogenotrophic, methanogenic archaeon Methanoculleus bourgensis strain MS2(T), isolated from a sewage sludge digester. J Bacteriol 194:5487–5488. doi:10.1128/JB.01292-12.
OpenUrl Abstract/FREE Full Text

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Cited By...

[1] 1.↵
Jaenicke S,
Ander C,
Bekel T,
Bisdorf R,
Dröge M,
Gartemann KH,
Jünemann S,
Kaiser O,
Krause L,
Tille F,
Zakrzewski M,
Pühler A,
Schlüter A,
Goesmann A
. 2011. Comparative and joint analysis of two metagenomic datasets from a biogas fermenter obtained by 454-pyrosequencing. PLoS One 6:e14519. doi:10.1371/journal.pone.0014519.
OpenUrl CrossRef PubMed

[2] Jaenicke S,

[3] Ander C,

[4] Bekel T,

[5] Bisdorf R,

[6] Dröge M,

[7] Gartemann KH,

[8] Jünemann S,

[9] Kaiser O,

[10] Krause L,

[11] Tille F,

[12] Zakrzewski M,

[13] Pühler A,

[14] Schlüter A,

[15] Goesmann A

[16] 2.↵
Stolze Y,
Zakrzewski M,
Maus I,
Eikmeyer F,
Jaenicke S,
Rottmann N,
Siebner C,
Pühler A,
Schlüter A
. 2015. Comparative metagenomics of biogas-producing microbial communities from production-scale biogas plants operating under wet or dry fermentation conditions. Biotechnol Biofuels 8:14. doi:10.1186/s13068-014-0193-8.
OpenUrl CrossRef

[17] Stolze Y,

[18] Zakrzewski M,

[19] Maus I,

[20] Eikmeyer F,

[21] Jaenicke S,

[22] Rottmann N,

[23] Siebner C,

[24] Pühler A,

[25] Schlüter A

[26] 3.↵
Westerholm M,
Levén L,
Schnürer A
. 2012. Bioaugmentation of syntrophic acetate-oxidizing culture in biogas reactors exposed to increasing levels of ammonia. Appl Environ Microbiol 78:7619–7625. doi:10.1128/AEM.01637-12.
OpenUrl Abstract/FREE Full Text

[27] Westerholm M,

[28] Levén L,

[29] Schnürer A

[30] 4.↵
Moestedt J,
Müller B,
Westerholm M,
Schnürer A
. 2016. Ammonia threshold for inhibition of anaerobic digestion of thin stillage and the importance of organic loading rate. Microb Biotechnol 9:180–194. doi:10.1111/1751-7915.12330.
OpenUrl CrossRef

[31] Moestedt J,

[32] Müller B,

[33] Westerholm M,

[34] Schnürer A

[35] 5.↵
Westerholm M,
Müller B,
Isaksson S,
Schnürer A
. 2015. Trace element and temperature effects on microbial communities and links to biogas digester performance at high ammonia levels. Biotechnol Biofuels 8:154. doi:10.1186/s13068-015-0328-6.
OpenUrl CrossRef

[36] Westerholm M,

[37] Müller B,

[38] Isaksson S,

[39] Schnürer A

[40] 6.↵
Fotidis IA,
Karakashev D,
Angelidaki I
. 2013. Bioaugmentation with an acetate-oxidising consortium as a tool to tackle ammonia inhibition of anaerobic digestion. Bioresour Technol 146:57–62. doi:10.1016/j.biortech.2013.07.041.
OpenUrl CrossRef

[41] Fotidis IA,

[42] Karakashev D,

[43] Angelidaki I

[44] 7.↵
Schnürer A,
Schink BH,
Svensson BH
. 1996. Clostridium ultunense sp. nov., a mesophilic bacterium oxidizing acetate in syntrophic association with a hydrogenotrophic methanogenic bacterium. Int J Syst Bacteriol 46:1145–1152. doi:10.1099/00207713-46-4-1145.
OpenUrl CrossRef PubMed

[45] Schnürer A,

[46] Schink BH,

[47] Svensson BH

[48] 8.↵
Fotidis IA,
Wang H,
Fiedel NR,
Luo G,
Karakashev DB,
Angelidaki I
. 2014. Bioaugmentation as a solution to increase methane production from an ammonia-rich substrate. Environ Sci Technol 48:7669–7676. doi:10.1021/es5017075.
OpenUrl CrossRef

[49] Fotidis IA,

[50] Wang H,

[51] Fiedel NR,

[52] Luo G,

[53] Karakashev DB,

[54] Angelidaki I

[55] 9.↵
Schnürer A,
Zellner G,
Svensson BH
. 1999. Mesophilic syntrophic acetate oxidation during methane formation in biogas reactors. FEMS Microbiol Ecol 29:249–261.
OpenUrl CrossRef Web of Science

[56] Schnürer A,

[57] Zellner G,

[58] Svensson BH

[59] 10.↵
Zehnder AJ,
Huser BA,
Brock TD,
Wuhrmann K
. 1980. Characterization of an acetate-decarboxylating, non-hydrogen-oxidizing methane bacterium. Arch Microbiol 124:1–11. doi:10.1007/BF00407022.
OpenUrl CrossRef PubMed Web of Science

[60] Zehnder AJ,

[61] Huser BA,

[62] Brock TD,

[63] Wuhrmann K

[64] 11.↵
Maus I,
Wibberg D,
Stantscheff R,
Stolze Y,
Blom J,
Eikmeyer FG,
Fracowiak J,
König H,
Pühler A,
Schlüter A
. 2014. Insights into the annotated genome sequence of Methanoculleus bourgensis MS2(T), related to dominant methanogens in biogas-producing plants. J Biotechnol 201:43–53. doi:10.1016/j.jbiotec.2014.11.020.
OpenUrl CrossRef

[65] Maus I,

[66] Wibberg D,

[67] Stantscheff R,

[68] Stolze Y,

[69] Blom J,

[70] Eikmeyer FG,

[71] Fracowiak J,

[72] König H,

[73] Pühler A,

[74] Schlüter A

[75] 12.↵
Wibberg D,
Blom J,
Jaenicke S,
Kollin F,
Rupp O,
Scharf B,
Schneiker-Bekel S,
Sczcepanowski R,
Goesmann A,
Setubal JC,
Schmitt R,
Pühler A,
Schlüter A
. 2011. Complete genome sequencing of Agrobacterium sp. H13-3, the former Rhizobium lupini H13-3, reveals a tripartite genome consisting of a circular and a linear chromosome and an accessory plasmid but lacking a tumor-inducing Ti-plasmid. J Biotechnol 155:50–62. doi:10.1016/j.jbiotec.2011.01.010.
OpenUrl CrossRef PubMed Web of Science

[76] Wibberg D,

[77] Blom J,

[78] Jaenicke S,

[79] Kollin F,

[80] Rupp O,

[81] Scharf B,

[82] Schneiker-Bekel S,

[83] Sczcepanowski R,

[84] Goesmann A,

[85] Setubal JC,

[86] Schmitt R,

[87] Pühler A,

[88] Schlüter A

[89] 13.↵
Meyer F,
Goesmann A,
McHardy AC,
Bartels D,
Bekel T,
Clausen J,
Kalinowski J,
Linke B,
Rupp O,
Giegerich R,
Pühler A
. 2003. GenDB—an open source genome annotation system for prokaryote genomes. Nucleic Acids Res 31:2187–2195. doi:10.1093/nar/gkg312.
OpenUrl CrossRef PubMed Web of Science

[90] Meyer F,

[91] Goesmann A,

[92] McHardy AC,

[93] Bartels D,

[94] Bekel T,

[95] Clausen J,

[96] Kalinowski J,

[97] Linke B,

[98] Rupp O,

[99] Giegerich R,

[100] Pühler A

[101] 14.↵
Maus I,
Wibberg D,
Stantscheff R,
Eikmeyer FG,
Seffner A,
Boelter J,
Szczepanowski R,
Blom J,
Jaenicke S,
König H,
Pühler A,
Schlüter A
. 2012. Complete genome sequence of the hydrogenotrophic, methanogenic archaeon Methanoculleus bourgensis strain MS2(T), isolated from a sewage sludge digester. J Bacteriol 194:5487–5488. doi:10.1128/JB.01292-12.
OpenUrl Abstract/FREE Full Text

[102] Maus I,

[103] Wibberg D,

[104] Stantscheff R,

[105] Eikmeyer FG,

[106] Seffner A,

[107] Boelter J,

[108] Szczepanowski R,

[109] Blom J,

[110] Jaenicke S,

[111] König H,

[112] Pühler A,

[113] Schlüter A

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