Genetics in methanogens: transposon insertion mutagenesis of a Methanococcus maripaludis nifH gene.

We designed a transposon insertion mutagenesis system for Methanococcus species and used it to make mutations in and around a nifH gene in Methanococcus maripaludis. The transposon Mudpur was constructed with a gene for puromycin resistance that is expressed and selectable in Methanococcus species. A 15.6-kb nifH region from M. maripaludis cloned in a lambda vector was used as a target for mutagenesis. A series of 19 independent Mudpur insertions spanning the cloned region were produced. Four mutagenized clones in and around nifH were introduced by transformation into M. maripaludis, where each was found to replace wild-type genomic DNA with the corresponding transposon-mutagenized DNA. Wild-type M. maripaludis and a transformant containing a Mudpur insertion upstream of nifH grew on N2 as a nitrogen source. Two transformants with insertions in nifH and one transformant with an insertion downstream of nifH did not grow on N2. The transposon insertion-gene replacement technique should be generally applicable in the methanococci for studying the effects of genetic manipulations in vivo.     

Functional conservation between the argininosuccinate lyase of the archaeon Methanococcus maripaludis and the corresponding bacterial and eukaryal genes

The argH gene encoding argininosuccinate lyase (ASL) of Methanococcus maripaludis was cloned on a 4.7-kb HindIII genomic fragment. The gene is preceded by a short open reading frame (ORF149), which encodes a polypeptide with an unknown function. The two genes are co-transcribed. The ASL of M. maripaludis shares a high amino acid identity with ASLs from both bacterial and eukaryal origins and was able to complement both an argH Escherichia coli mutant and an arg4 yeast mutant, showing its extraordinary evolutionary conservation. Attempts to create an argH auxotroph of M. maripaludis by disrupting the genomic allele were unsuccessful: although a knockout allele of argH was integrated into the M. maripaludis chromosome by homologous recombination, the intact copy was not excluded, suggesting that the argH gene is essential.     

Characterization of pURB500 from the archaeon Methanococcus maripaludis and construction of a shuttle vector.

The complete sequence of the 8,285-bp plasmid pURB500 from Methanococcus maripaludis C5 was determined. Sequence analysis identified 18 open reading frames as well as two regions of potential iterons and complex secondary structures. The shuttle vector, pDLT44, for M. maripaludis JJ was constructed from the entire pURB500 plasmid and pMEB.2, an Escherichia coli vector containing a methanococcal puromycin-resistance marker (P. Gernhardt, O. Possot, M. Foglino, L. Sibold, and A. Klein, Mol. Gen. Genet. 221:273-279, 1990). By using polyethylene glycol transformation, M. maripaludis JJ was transformed at a frequency of 3.3 x 10(7) transformants per microg of pDLT44. The shuttle vector was stable in E. coli under ampicillin selection but was maintained at a lower copy number than pMEB.2. Based on the inability of various restriction fragments of pURB500 to support maintenance in M. maripaludis JJ, multiple regions of pURB500 were required. pDLT44 did not replicate in Methanococcus voltae.     

Lysine-2,3-aminomutase and beta-lysine acetyltransferase genes of methanogenic archaea are salt induced and are essential for the biosynthesis of Nepsilon-acetyl-beta-lysine and growth at high salinity

The compatible solute N(epsilon)-acetyl-beta-lysine is unique to methanogenic archaea and is produced under salt stress only. However, the molecular basis for the salt-dependent regulation of N(epsilon)-acetyl-beta-lysine formation is unknown. Genes potentially encoding lysine-2,3-aminomutase (ablA) and beta-lysine acetyltransferase (ablB), which are assumed to catalyze N(epsilon)-acetyl-beta-lysine formation from alpha-lysine, were identified on the chromosomes of the methanogenic archaea Methanosarcina mazei G?1, Methanosarcina acetivorans, Methanosarcina barkeri, Methanococcus jannaschii, and Methanococcus maripaludis. The order of the two genes was identical in the five organisms, and the deduced proteins were very similar, indicating a high degree of conservation of structure and function. Northern blot analysis revealed that the two genes are organized in an operon (termed the abl operon) in M. mazei G?1. Expression of the abl operon was strictly salt dependent. The abl operon was deleted in the genetically tractable M. maripaludis. Delta(abl) mutants of M. maripaludis no longer produced N(epsilon)-acetyl-beta-lysine and were incapable of growth at high salt concentrations, indicating that the abl operon is essential for N(epsilon)-acetyl-beta-lysine synthesis. These experiments revealed the first genes involved in the biosynthesis of compatible solutes in methanogens.     

Expression vectors for Methanococcus maripaludis: overexpression of acetohydroxyacid synthase and beta-galactosidase.

A series of integrative and shuttle expression vectors was developed for use in Methanococcus maripaludis. The integrative expression vectors contained the Methanococcus voltae histone promoter and multiple cloning sites designed for efficient cloning of DNA. Upon transformation, they can be used to overexpress specific homologous genes in M. maripaludis. When tested with ilvBN, which encodes the large and small subunits of acetohydroxyacid synthase, transformants possessed specific activity 13-fold higher than that of the wild type. An expression shuttle vector, based on the cryptic plasmid pURB500 and the components of the integrative vector, was also developed for the expression of heterologous genes in M. maripaludis. The beta-galactosidase gene from Escherichia coli was expressed to approximately 1% of the total cellular protein using this vector. During this work, the genes for the acetohydroxyacid synthase (ilvBN) and phosphoenolpyruvate synthase (ppsA) were sequenced from a M. maripaludis genomic library.     

Shuttle vector system for Methanococcus maripaludis with improved transformation efficiency

We have identified an open reading frame and DNA element that are sufficient to maintain shuttle vectors in Methanococcus maripaludis. Strain S0001, containing ORF1 from pURB500 integrated into the M. maripaludis genome, supports a significantly smaller shuttle vector, pAW42, and a 7,000-fold increase in transformation efficiency for pURB500-based vectors.     

Markerless mutagenesis in Methanococcus maripaludis demonstrates roles for alanine dehydrogenase, alanine racemase, and alanine permease

Among the archaea, Methanococcus maripaludis has the unusual ability to use L- or D-alanine as a nitrogen source. To understand how this occurs, we tested the roles of three adjacent genes encoding homologs of alanine dehydrogenase, alanine racemase, and alanine permease. To produce mutations in these genes, we devised a method for markerless mutagenesis that builds on previously established genetic tools for M. maripaludis. The technique uses a negative selection strategy that takes advantage of the ability of the M. maripaludis hpt gene encoding hypoxanthine phosphoribosyltransferase to confer sensitivity to the base analog 8-azahypoxanthine. In addition, we developed a negative selection method to stably incorporate constructs into the genome at the site of the upt gene encoding uracil phosphoribosyltransferase. Mutants with in-frame deletion mutations in the genes for alanine dehydrogenase and alanine permease lost the ability to grow on either isomer of alanine, while a mutant with an in-frame deletion mutation in the gene for alanine racemase lost only the ability to grow on D-alanine. The wild-type gene for alanine dehydrogenase, incorporated into the upt site, complemented the alanine dehydrogenase mutation. Hence, the permease is required for the transport of either isomer, the dehydrogenase is specific for the L isomer, and the racemase converts the D isomer to the L isomer. Phylogenetic analysis indicated that all three genes had been acquired by lateral gene transfer from the low-moles-percent G+C gram-positive bacteria.     

Coenzyme F420-dependent sulfite reductase-enabled sulfite detoxification and use of sulfite as a sole sulfur source by Methanococcus maripaludis

Coenzyme F(420)-dependent sulfite reductase (Fsr) of Methanocaldococcus jannaschii, a sulfite-tolerant methanogen, was expressed with activity in Methanococcus maripaludis, a sulfite-sensitive methanogen. The recombinant organism reduced sulfite to sulfide and grew with sulfite as the sole sulfur source, indicating that Fsr is a sulfite detoxification and assimilation enzyme for methanogens and that M. maripaludis synthesizes siroheme.     

Transformation of Methanococcus maripaludis and identification of a Pst I-like restriction system

Abstract An optimized polyethylene glycol (PEG) method of transformation was developed for Methanococcus maripaludis using the pKAS102 integration vector. The frequency of transformation with 0.8 μg of plasmid and 3×10⁹ cells was 4.8×10⁻⁵ transformants cfu⁻¹, or 1.8×10⁵ transformants μg⁻¹, which was four orders of magnitude greater than with the natural transformation method. A Pst I restriction activity in M. maripaludis was also identified. Methylation of the plasmid with Pst I methylase increased the methanococcal transformation frequency at least four-fold. Also, chromosomal DNA from M. maripaludis was resistant to digestion by the Pst I endonuclease.     

Tryptophan auxotrophs were obtained by random transposon insertions in the Methanococcus maripaludis tryptophan operon

Methanococcus maripaludis is an anaerobic, methane-producing archaeon that utilizes H₂ or formate for the reduction of CO₂ to methane. Tryptophan auxotrophs were constructed by in vitro insertions of the Tn5 transposon into the tryptophan operon, followed by transformation into M. maripaludis . This method could serve for rapid insertions into large cloned DNA regions.     

In vivo requirement of selenophosphate for selenoprotein synthesis in archaea

Biosynthesis of selenocysteine, the 21st proteinogenic amino acid, occurs bound to a dedicated tRNA in all three domains of life, Bacteria, Eukarya and Archaea, but differences exist between the mechanism employed by bacteria and eukaryotes/archaea. The role of selenophosphate and the enzyme providing it, selenophosphate synthetase, in archaeal selenoprotein synthesis was addressed by mutational analysis. Surprisingly, MMP0904, encoding a homologue of eukaryal selenophosphate synthetase in Methanococcus maripaludis S2, could not be deleted unless selD , encoding selenophosphate synthetase of Escherichia coli , was present in trans , demonstrating that the factor is essential for the organism. In contrast, the homologous gene of M. maripaludis JJ could be readily deleted, obviating the strain's ability to synthesize selenoproteins. Complementing with selD restored selenoprotein synthesis, demonstrating that the deleted gene encodes selenophosphate synthetase and that selenophosphate is the in vivo selenium donor for selenoprotein synthesis of this organism. We also showed that this enzyme is a selenoprotein itself and that M. maripaludis contains another, HesB-like selenoprotein previously only predicted from genome analyses. The data highlight the use of genetic methods in archaea for a causal analysis of their physiology and, by comparing two closely related strains of the same species, illustrate the evolution of the selenium-utilizing trait.     

Complete genome sequence of a nonculturable Methanococcus maripaludis strain extracted in a metagenomic survey of petroleum reservoir fluids

Extraction of genome sequences from metagenomic data is crucial for reconstructing the metabolism of microbial communities that cannot be mimicked in the laboratory. A complete Methanococcus maripaludis genome was generated from metagenomic data derived from a thermophilic subsurface oil reservoir. M. maripaludis is a hydrogenotrophic methanogenic species that is common in mesophilic saline environments. Comparison of the genome from the thermophilic, subsurface environment with the genome of the type species will provide insight into the adaptation of a methanogenic genome to an oil reservoir environment.     

Bacterial and eukaryotic systems collide in the three Rs of Methanococcus

Methanococcus maripaludis S2 is a methanogenic archaeon with a well-developed genetic system. Its mesophilic nature offers a simple system in which to perform complementation using bacterial and eukaryotic genes. Although information-processing systems in archaea are generally more similar to those in eukaryotes than those in bacteria, the order Methanococcales has a unique complement of DNA replication proteins, with multiple MCM (minichromosome maintenance) proteins and no obvious originbinding protein. A search for homologues of recombination and repair proteins in M. maripaludis has revealed a mixture of bacterial, eukaryotic and some archaeal-specific homologues. Some repair pathways appear to be completely absent, but it is possible that archaeal-specific proteins could carry out these functions. The replication, recombination and repair systems in M. maripaludis are an interesting mixture of eukaryotic and bacterial homologues and could provide a system for uncovering novel interactions between proteins from different domains of life.     

Biosynthesis of phosphoserine in the Methanococcales

Methanococcus maripaludis and Methanocaldococcus jannaschii produce cysteine for protein synthesis using a tRNA-dependent pathway. These methanogens charge tRNA(Cys) with l-phosphoserine, which is also an intermediate in the predicted pathways for serine and cystathionine biosynthesis. To establish the mode of phosphoserine production in Methanococcales, cell extracts of M. maripaludis were shown to have phosphoglycerate dehydrogenase and phosphoserine aminotransferase activities. The heterologously expressed and purified phosphoglycerate dehydrogenase from M. maripaludis had enzymological properties similar to those of its bacterial homologs but was poorly inhibited by serine. While bacterial enzymes are inhibited by micromolar concentrations of serine bound to an allosteric site, the low sensitivity of the archaeal protein to serine is consistent with phosphoserine's position as a branch point in several pathways. A broad-specificity class V aspartate aminotransferase from M. jannaschii converted the phosphohydroxypyruvate product to phosphoserine. This enzyme catalyzed the transamination of aspartate, glutamate, phosphoserine, alanine, and cysteate. The M. maripaludis homolog complemented a serC mutation in the Escherichia coli phosphoserine aminotransferase. All methanogenic archaea apparently share this pathway, providing sufficient phosphoserine for the tRNA-dependent cysteine biosynthetic pathway.     

Sulfometuron methyl-sensitive and -resistant acetolactate synthases of the archaebacteria Methanococcus spp.

The herbicide sulfometuron methyl (SM) inhibited growth of some methanococci. Of 28 strains tested, the growth of 7 was completely inhibited by 0.55 mM SM. Growth of an additional 14 strains was partially inhibited, and the growth of 7 strains was unaffected by this concentration of SM. In some cases, the branched-chain amino acids protected growth. Growth inhibition was correlated with the Ki for SM of acetolactate synthase (ALS). For the enzymes from bacteria representative of the sensitive, partially resistant, and resistant methanococci (Methanococcus aeolicus, Methanococcus maripaludis, and Methanococcus voltae, respectively), the Ki for SM was 0.0012, 0.34, and greater than 1.0 mM, respectively. Inhibition was uncompetitive with respect to pyruvate. Based on these observations, ALS appeared to be the major if not the sole site of action of SM in the methanococci. The sensitivity of the ALS from these three methanococci to feedback inhibition by branched-chain amino acids was also quite different. Although all three were sensitive to feedback inhibition by valine, the Ki varied 20-fold, from 0.01 to 0.22 mM. Moreover, only the ALS from M. maripaludis was sensitive to inhibition by leucine, and the Ki was 1.8 mM. The Ki for isoleucine for the ALS from both M. maripaludis and M. voltae was about 0.1 mM. The ALS from M. aeolicus was not inhibited by isoleucine. In other respects, the ALSs from the methanococci were very similar. After dialysis, thiamine pyrophosphate but not FAD and Mg2+ was required for maximal activity, and they were all rapidly inactivated by oxygen. Although the methanococcal ALSs exhibited diverse properties, the range of catalytic and regulatory properties closely resembled those of the eubacterial enzymes.     

Inactivation of the selB gene in Methanococcus maripaludis: effect on synthesis of selenoproteins and their sulfur-containing homologs

The genome of Methanococcus maripaludis harbors genes for at least six selenocysteine-containing proteins and also for homologs that contain a cysteine codon in the position of the UGA selenocysteine codon. To investigate the synthesis and function of both the Se and the S forms, a mutant with an inactivated selB gene was constructed and analyzed. The mutant was unable to synthesize any of the selenoproteins, thus proving that the gene product is the archaeal translation factor (aSelB) specialized for selenocysteine insertion. The wild-type form of M. maripaludis repressed the synthesis of the S forms of selenoproteins, i.e., the selenium-independent alternative system, in selenium-enriched medium, but the mutant did not. We concluded that free selenium is not involved in regulation but rather a successional compound such as selenocysteyl-tRNA or some selenoprotein. Apart from the S forms, several enzymes from the general methanogenic route were affected by selenium supplementation of the wild type or by the selB mutation. Although the growth of M. maripaludis on H(2)/CO(2) is only marginally affected by the selB lesion, the gene is indispensable for growth on formate because M. maripaludis possesses only a selenocysteine-containing formate dehydrogenase.