Claudia Ehlers

Deep sequencing analysis of the Methanosarcina mazei Gö1 transcriptome in response to nitrogen availability

Methanosarcina mazei and related mesophilic archaea are the only organisms fermenting acetate, methylamines, and methanol to methane and carbon dioxide, contributing significantly to greenhouse gas production. The biochemistry of these metabolic processes is well studied, and genome sequences are available, yet little is known about the overall transcriptional organization and the noncoding regions representing 25% of the 4.01-Mb genome of M. mazei. We present a genome-wide analysis of transcription start sites (TSS) in M. mazei grown under different nitrogen availabilities. Pyrosequencing-based differential analysis of primary vs. processed 5′ ends of transcripts discovered 876 TSS across the M. mazei genome. Unlike in other archaea, in which leaderless mRNAs are prevalent, the majority of the detected mRNAs in M. mazei carry long untranslated 5′ regions. Our experimental data predict a total of 208 small RNA (sRNA) candidates, mostly from intergenic regions but also antisense to 5′ and 3′ regions of mRNAs. In addition, 40 new small mRNAs with ORFs of ≤30 aa were identified, some of which might have dual functions as mRNA and regulatory sRNA. We confirmed differential expression of several sRNA genes in response to nitrogen availability. Inspection of their promoter regions revealed a unique conserved sequence motif associated with nitrogen-responsive regulation, which might serve as a regulator binding site upstream of the common IIB recognition element. Strikingly, several sRNAs antisense to mRNAs encoding transposases indicate nitrogen-dependent transposition events. This global TSS map in archaea will facilitate a better understanding of transcriptional and posttranscriptional control in the third domain of life.

Effects of Nitrogen and Carbon Sources on Transcription of Soluble Methyltransferases in Methanosarcina mazei Strain Gö1

The methanogenic archaeon Methanosarcina mazei strain Gö1 uses versatile carbon sources and is able to fix molecular nitrogen with methanol as carbon and energy sources. Here, we demonstrate that when growing on trimethylamine (TMA), nitrogen fixation does not occur, indicating that ammonium released during TMA degradation is sufficient to serve as a nitrogen source and represses nif gene induction. We further report on the transcriptional regulation of soluble methyltransferases, which catalyze the initial step of methylamine consumption by methanogenesis, in response to different carbon and nitrogen sources. Unexpectedly, we obtained conclusive evidence that transcription of the mtmB2C2 operon, encoding a monomethylamine (MMA) methyltransferase and its corresponding corrinoid protein, is highly increased under nitrogen limitation when methanol serves as a carbon source. In contrast, transcription of the homologous mtmB1C1 operon is not affected by the nitrogen source but appears to be increased when TMA is the sole carbon and energy source. In general, transcription of operons encoding dimethylamine (DMA) and TMA methyltransferases and methylcobalamine:coenzyme M methyltransferases is not regulated in response to the nitrogen source. However, in all cases transcription of one of the homologous operons or genes is increased by TMA or its degradation products DMA and MMA.

Deletion of the archaeal histone in Methanosarcina mazei Gö1 results in reduced growth and genomic transcription

HMm is the only archaeal histone in Methanosarcina mazei Göl and recombinant HMm, synthesized by expression of MM1825 in Escherichia coli, has been purified and confirmed to have the DNA binding and compaction properties characteristic of an archaeal histone. Insertion of a puromycin resistance conferring cassette (pac) into MM1825 was not lethal but resulted in mutants (M. mazei MM1825::pac) that have impaired ability to grow on methanol and trimethylamine. Loss of HMm also resulted in increased sensitivity to UV light and decreased transcript levels for ∼25% of all M. mazei genes. For most genes, the transcript decrease was 3‐ to 10‐fold, but transcripts of MM483 (small heat‐shock protein), MM1688 (trimethylamine:corrinoid methyl transferase) and MM3195 (transcription regulator), were reduced 100‐, 100‐ and 25‐fold, respectively, in M. mazei MM1825::pac cells. Transcripts of only five adjacent genes that appear to constitute an aromatic amino acid biosynthetic operon were elevated in M. mazei MM1825::pac cells. Complementary synthesis of HMm from a plasmid transformed into M. mazei MM1825::pac restored wild‐type growth and transcript levels.

Functional organization of a single nif cluster in the mesophilic archaeon Methanosarcina mazei strain Gö1

The mesophilic methanogenic archaeon Methanosarcina mazei strain Gö1 is able to utilize molecular nitrogen (N2) as its sole nitrogen source. We have identified and characterized a single nitrogen fixation (nif) gene cluster in M. mazei Gö1 with an approximate length of 9 kbp. Sequence analysis revealed seven genes with sequence similarities to nifH, nifI1, nifI2, nifD, nifK, nifE and nifN, similar to other diazotrophic methanogens and certain bacteria such as Clostridium acetobutylicum, with the two glnB-like genes (nifI1 and nifI2) located between nifH and nifD. Phylogenetic analysis of deduced amino acid sequences for the nitrogenase structural genes of M. mazei Gö1 showed that they are most closely related to Methanosarcina barkeri nif2 genes, and also closely resemble those for the corresponding nif products of the gram-positive bacterium C. acetobutylicum. Northern blot analysis and reverse transcription PCR analysis demonstrated that the M. mazei nif genes constitute an operon transcribed only under nitrogen starvation as a single 8 kb transcript. Sequence analysis revealed a palindromic sequence at the transcriptional start site in front of the M. mazei nifH gene, which may have a function in transcriptional regulation of the nif operon.

Insights into the NrpR regulon in Methanosarcina mazei Gö1

The methanogenic archaeon Methanosarcina mazei strain Gö1 contains two homologues of NrpR, the transcriptional repressor of nitrogen assimilation genes recently discovered and characterized in Methanococcus maripaludis. Insertion of a puromycin-resistance conferring cassette into MM1085 encoding a single NrpR domain with an N-terminal helix–turn–helix domain (NrpRI) lead to a significant reduction of the lag-phase after a shift from nitrogen sufficiency to nitrogen limitation. Consistent with this finding, loss of NrpRI resulted in significantly increased transcript levels of genes involved in nitrogen fixation or nitrogen assimilation though growing under nitrogen sufficiency as demonstrated by quantitative reverse transcriptional PCR analysis. Genome-wide analysis using DNA-microarrays confirmed that transcript levels of 27 ORFs were significantly elevated in the M. mazei MM1085::pac mutant under nitrogen sufficiency, including genes known to be up-regulated under nitrogen limitation (e.g., nifH, glnA1, glnK1), and 17 additional genes involved in metabolism (4), encoding a flagella related protein (1) and genes encoding hypothetical proteins (12). Using cell extracts of Escherichia coli expressing MM1085 fused to the maltose binding protein (MBP–NrpRI) and employing promoter binding studies by DNA-affinity chromatography demonstrated that MBP–NrpRI binds specifically to the nifH-promoter. Deletion of various bases in the promoter region of nifH confirmed that the regulatory element ACC-N7-GGT is required for specific binding of NrpRI to the promoter.

Establishing a Markerless Genetic Exchange System for Methanosarcina mazei Strain Gö1 for Constructing Chromosomal Mutants of Small RNA Genes

A markerless genetic exchange system was successfully established in Methanosarcina mazei strain Gö1 using the hpt gene coding for hypoxanthine phosphoribosyltransferase. First, a chromosomal deletion mutant of the hpt gene was generated conferring resistance to the purine analog 8-aza-2,6-diaminopurine (8-ADP). The nonreplicating allelic exchange vector (pRS345) carrying the pac-resistance cassette for direct selection of chromosomal integration, and the hpt gene for counterselection was introduced into this strain. By a pop-in and ultimately pop-out event of the plasmid from the chromosome, allelic exchange is enabled. Using this system, we successfully generated a M. mazei deletion mutant of the gene encoding the regulatory non-coding RNA sRNA154. Characterizing M. mazeiΔsRNA 154 under nitrogen limiting conditions demonstrated differential expression of at least three cytoplasmic proteins and reduced growth strongly arguing for a prominent role of sRNA154 in regulation of nitrogen fixation by posttranscriptional regulation.

NrpRII mediates contacts between NrpRI and general transcription factors in the archaeon Methanosarcina mazei Gö1

We report here on the formation of a complex between the two NrpR homologs present in Methanosarcina mazei Gö1 and their binding properties to the nifH and glnK1 promoters. Reciprocal co‐chromatography demonstrated that NrpRI forms stable complexes with NrpRII (at an NrpRI : NrpRII molar ratio of ∼ 1 : 3), which are not affected by 2‐oxoglutarate. Promoter‐binding, analyses using DNA‐affinity chromatography and electrophoretic gel mobility shift assays, verified that NrpRII is not able to bind to either the nifH promoter or the glnK1 promoter except when in complex with NrpRI. Specific binding of NrpRI to the nifH and glnK1 promoters was shown to be highly sensitive to 2‐oxoglutarate, regardless of whether only NrpRI, or NrpRI in complex with NrpRII, bound to the promoter. Finally, strong interactions between NrpRII and the general transcription factors TATA‐binding proteins (TBP) 1–3 and the general transcription factor TFIIB (TFB) were demonstrated, interactions which are also sensitive to 2‐oxoglutarate. On the basis of these findings we propose the following: under nitrogen sufficiency NrpRII binds from solution to either the nifH promoter or the glnK1 promoter by simultaneously contacting NrpRI and TBP plus TFB, resulting in full repression of transcription; whereas, under nitrogen limitation, increasing 2‐oxoglutarate concentrations significantly decrease the binding of NrpRI to the operator as well as the binding of NrpRII to TBP and TFB, ultimately allowing recruitment of RNA polymerase to the promoter.

Biofilm formation of mucosa-associated methanoarchaeal strains

Although in nature most microorganisms are known to occur predominantly in consortia or biofilms, data on archaeal biofilm formation are in general scarce. Here, the ability of three methanoarchaeal strains, Methanobrevibacter smithii and Methanosphaera stadtmanae, which form part of the human gut microbiota, and the Methanosarcina mazei strain Gö1 to grow on different surfaces and form biofilms was investigated. All three strains adhered to the substrate mica and grew predominantly as bilayers on its surface as demonstrated by confocal laser scanning microscopy analyses, though the formation of multi-layered biofilms of Methanosphaera stadtmanae and Methanobrevibacter smithii was observed as well. Stable biofilm formation was further confirmed by scanning electron microscopy analysis. Methanosarcina mazei and Methanobrevibacter smithii also formed multi-layered biofilms in uncoated plastic μ-dishesTM, which were very similar in morphology and reached a height of up to 40 μm. In contrast, biofilms formed by Methanosphaera stadtmanae reached only a height of 2 μm. Staining with the two lectins ConA and IB4 indicated that all three strains produced relatively low amounts of extracellular polysaccharides most likely containing glucose, mannose, and galactose. Taken together, this study provides the first evidence that methanoarchaea can develop and form biofilms on different substrates and thus, will contribute to our knowledge on the appearance and physiological role of Methanobrevibacter smithii and Methanosphaera stadtmanae in the human intestine.

The transcriptional activator NrpA is crucial for inducing nitrogen fixation in Methanosarcina mazei Gö1 under nitrogen‐limited conditions

With the aim of unraveling their potential involvement in the regulation of nitrogen metabolism in Methanosarcina mazei strain Gö1, we characterized five genes that are differentially transcribed in response to changing nitrogen availability and encoding putative transcriptional regulators. Study of the respective mutant strains under nitrogen‐limited conditions revealed a growth delay for M. mazei MM0444::pac and MM1708::pac, and strongly reduced diazotrophic growth for MM0872::pac, whereas the absence of MM2441 or MM2525 did not affect growth behaviour. Transcriptome analyses further demonstrated that only MM1708 – encoding a CxxCG zinc finger protein – plays a regulatory role in nitrogen metabolism, most likely by specifically enhancing transcription of the N2 fixation (nif) operon under nitrogen‐limited conditions. In agreement with this, a palindromic binding motif was predicted in silico in the nifH promoter region, nine nucleotides upstream of the BRE box, and confirmed to bind purified maltose‐binding protein–MM1708 by electromobility shift assays. As MM1708 itself is under the control of the global nitrogen repressor NrpR, this adds a secondary level to the transcriptional regulation of the nif genes, and is most likely crucial for maximal nif induction under nitrogen‐limited conditions. This is in accordance with the finding that protein expression of NifH is highly reduced in the absence of MM1708 under nitrogen‐limited conditions. On the basis of our findings, we hypothesize that, in M. mazei, nitrogen fixation is controlled by a hierarchical network of two transcriptional regulators, the global nitrogen repressor NrpR, and the newly identified activator NrpA (MM1708), thereby providing tight control of N2 fixation.