Hybrid Ptr2-like activators of archaeal transcription.

Methanocaldococcus jannaschii Ptr2, a member of the Lrp/AsnC family of bacterial DNA-binding proteins, is an activator of its eukaryal-type core transcription apparatus. In Lrp-family proteins, an N-terminal helix-turn-helix DNA-binding and dimerizing domain is joined to a C-terminal effector and multimerizing domain. A cysteine-scanning surface mutagenesis shows that the C-terminal domain of Ptr2 is responsible for transcriptional activation; two types of DNA binding-positive but activation-defective mutants are found: those unable to recruit the TBP and TFB initiation factors to the promoter, and those failing at a post-recruitment step. Transcriptional activation through the C-terminal Ptr2 effector domain is exploited in a screen of other Lrp effector domains for activation capability by constructing hybrid proteins with the N-terminal DNA-binding domain of Ptr2. Two hybrid proteins are effective activators: Ptr-H10, fusing the effector domain of Pyrococcus furiosus LrpA, and Ptr-H16, fusing the P. furiosus ORF1231 effector domain. Both new activators exhibit distinguishing characteristics: unlike octameric Ptr2, Ptr-H10 is a dimer; unlike Ptr2, the octameric Ptr-H16 poorly recruits TBP to the promoter, but more effectively co-recruits TFB with TBP. In contrast, the effector domain of Ptr1, the M. jannaschii Ptr2 paralogue, yields only very weak activation.

Genetic analysis of the methanol- and methylamine-specific methyltransferase 2 genes of Methanosarcina acetivorans C2A.

The entry of methanol into the methylotrophic pathway of methanogenesis is mediated by the concerted effort of two methyltransferases, namely, methyltransferase 1 (MT1) and methyltransferase 2 (MT2). The mtaA1, mtaA2, and mtbA genes of Methanosarcina acetivorans C2A encode putative methanol- or methylamine-specific MT2 enzymes. To address the in vivo roles of these genes in growth and methanogenesis from known substrates, we constructed and characterized mutants with deletions of each of these genes. The mtaA1 gene is required for growth on methanol, whereas mtaA2 was dispensable. However, the mtaA2 mutant had a reduced rate of methane production from methanol. Surprisingly, deletion of mtaA1 in combination with deletions of the genes encoding three methanol-specific MT1 isozymes led to lack of growth on acetate, suggesting that MT1 and MT2 enzymes might play an important role during growth on this substrate. The mtbA gene was required for dimethylamine and monomethylamine (MMA) utilization and was important, but not required, for trimethylamine utilization. Analysis of reporter gene fusions revealed that both mtaA1 and mtbA were expressed on all methanogenic substrates tested. However, mtaA1 expression was induced on methanol, while mtbA expression was down-regulated on MMA and acetate. mtaA2 was expressed at very low levels on all substrates. The mtaA1 transcript had a large 5' untranslated region (UTR) (275 bp), while the 5' UTR of the mtbA transcript was only 28 bp long.

Differential regulation of the three methanol methyltransferase isozymes in Methanosarcina acetivorans C2A.

Genetic analysis of the three methanol-specific methyltransferase 1 operons (mtaCB1, mtaCB2, and mtaCB3) in Methanosarcina acetivorans led to the suggestion that each of them has a discrete function during growth on methanol, which might be reflected in differential gene regulation (Pritchett and Metcalf, Mol. Microbiol. 56:1183-1194, 2005). To test this suggestion, reporter gene fusions were constructed for each of the three operons, and their expression was examined under various growth conditions. Expression of the mtaCB1 and mtaCB2 fusions was 100-fold and 575-fold higher, respectively, in methanol-grown cells than in trimethylamine (TMA)-grown cells. The mtaCB3 fusion was expressed at low levels on methanol, TMA, and dimethylamine but was significantly upregulated on monomethylamine and acetate. When TMA- or acetate-grown cultures were shifted to methanol, the mtaCB1 fusion was expressed most highly during exponential phase, whereas the mtaCB2 fusion, although strongly induced prior to mtaCB1 expression, did not reach full expression levels until stationary phase. The mtaCB3 fusion was transiently expressed prior to entry into exponential phase during a TMA-to-methanol substrate shift experiment. When acetate-grown cells were shifted to medium containing both TMA and methanol, TMA utilization commenced prior to utilization of methanol; however, these two substrates were consumed simultaneously later in growth. Under these conditions expression of the mtaCB2 and mtaCB3 fusions was delayed, suggesting that methylamines may repress their expression.

Genetic, physiological and biochemical characterization of multiple methanol methyltransferase isozymes in Methanosarcina acetivorans C2A.

Biochemical evidence suggests that methanol catabolism in Methanosarcina species requires the concerted effort of methanol:5-hydroxybenzimidazolylcobamide methyltransferase (MtaB), a corrinoid-containing methyl-accepting protein (MtaC) and Co-methyl-5-hydroxybenzimidazolylcobamide:2-mercapto-ethanesulphonic acid methyltransferase (MtaA). Here we show that Methanosarcina acetivorans possesses three operons encoding putative methanol-specific MtaB and corrinoid proteins: mtaCB1, mtaCB2 and mtaCB3. Deletion mutants lacking the three operons, in all possible combinations, were constructed and characterized. Strains deleted for any two of the operons grew on methanol, whereas strains lacking all three did not. Therefore, each operon encodes a bona fide methanol-utilizing MtaB/corrinoid protein pair. Most of the mutants were similar to the wild-type strain, with the exception of the DeltamtaCB1 DeltamtaCB2 double mutant, which grew more slowly and had reduced cell yields on methanol medium. However, all mutants displayed significantly longer lag times when switching from growth on trimethylamine to growth on methanol. This indicates that all three operons are required for wild-type growth on methanol and suggests that each operon has a distinct role in the metabolism of this substrate. The combined methanol:CoM methyltransferase activity of strains carrying only mtaCB1 was twofold higher than strains carrying only mtaCB2 and fourfold higher than strains carrying only mtaCB3. Interestingly, the presence of the mtaCB2 and mtaCB3 operons, in addition to the mtaCB1 operon, did not increase the overall methyltransferase activity, suggesting that these strains may be limited by MtaA availability. All deletion mutants were unaffected with respect to growth on trimethylamine and acetate corroborating biochemical evidence indicating that each methanogenic substrate has specific methyltransfer enzymes.

Methanol-dependent gene expression demonstrates that methyl-coenzyme M reductase is essential in Methanosarcina acetivorans C2A and allows isolation of mutants with defects in regulation of the methanol utilization pathway.

Methanosarcina acetivorans C2A is able to convert several substrates to methane via at least four distinct methanogenic pathways. A common step in each of these pathways is the reduction of methyl-coenzyme M (CoM) to methane catalyzed by methyl-CoM reductase (MCR). Because this enzyme is used in each of the known pathways, the mcrBDCGA operon, which encodes MCR, is expected to be essential. To validate this prediction, a system for conditional gene inactivation was developed. A heterologous copy of the mcrBDCGA operon was placed under the control of the highly regulated mtaC1 promoter, which directs the expression of genes involved in methanol utilization, and recombined onto the M. acetivorans chromosome. This allowed for disruption of the endogenous mcr operon in the presence of methanol. Because the PmtaC1 promoter is transcribed only during growth on methanol, mcrBDCGA was rendered methanol dependent and the strain was unable to grow in trimethylamine media, strongly suggesting that mcrBDCGA is essential. Upon prolonged incubation, suppressed mutants which expressed mcrBDCGA constitutively could be selected. Expression analysis of PmtaC1::uidA gene fusions in several isolated suppressed mutants suggests that they carry trans-active mutations leading to deregulation of all genes under control of this promoter. Subsequently, proteome analysis of one such suppressed mutant revealed that all known proteins derived from mtaC1 promoter-dependent expression were constitutively expressed in this mutant. This genetic system can therefore be employed for the testing of essential genes and for the identification of genes under a common regulatory mechanism by making regulatory mutations phenotypically selectable.

Development of a markerless genetic exchange method for Methanosarcina acetivorans C2A and its use in construction of new genetic tools for methanogenic archaea.

A new genetic technique for constructing mutants of Methanosarcina acetivorans C2A by using hpt as a counterselectable marker was developed. Mutants with lesions in the hpt gene, encoding hypoxanthine phosphoribosyltransferase, were shown to be >35-fold more resistant to the toxic base analog 8-aza-2,6-diaminopurine (8ADP) than was the wild type. Reintroduction of the hpt gene into a Delta hpt host restored 8ADP sensitivity and provided the basis for a two-step strategy involving plasmid integration and excision for recombination of mutant alleles onto the M. acetivorans chromosome. We have designated this method markerless exchange because, although selectable markers are used during the process, they are removed in the final mutants. Thus, the method can be repeated many times in the same cell line. The method was validated by construction of Delta proC Delta hpt mutants, which were recovered at a frequency of 22%. Additionally, a Methanosarcina-Escherichia shuttle vector, encoding the Escherichia coli proC gene as a new selectable marker, was constructed for use in proC hosts. Finally, the markerless exchange method was used to recombine a series of uidA reporter gene fusions into the M. acetivorans proC locus. In vitro assay of beta-glucuronidase activity in extracts of these recombinants demonstrated, for the first time, the utility of uidA as a reporter gene in Methanosarcina: A >5,000-fold range of promoter activities could be measured by using uidA: the methyl-coenzyme M reductase operon fusion displayed approximately 300-fold-higher activity than did the serC gene fusion, which in turn had 16-fold-higher activity than did a fusion to the unknown orf2 gene.

The genome of M. acetivorans reveals extensive metabolic and physiological diversity.

Methanogenesis, the biological production of methane, plays a pivotal role in the global carbon cycle and contributes significantly to global warming. The majority of methane in nature is derived from acetate. Here we report the complete genome sequence of an acetate-utilizing methanogen, Methanosarcina acetivorans C2A. Methanosarcineae are the most metabolically diverse methanogens, thrive in a broad range of environments, and are unique among the Archaea in forming complex multicellular structures. This diversity is reflected in the genome of M. acetivorans. At 5,751,492 base pairs it is by far the largest known archaeal genome. The 4524 open reading frames code for a strikingly wide and unanticipated variety of metabolic and cellular capabilities. The presence of novel methyltransferases indicates the likelihood of undiscovered natural energy sources for methanogenesis, whereas the presence of single-subunit carbon monoxide dehydrogenases raises the possibility of nonmethanogenic growth. Although motility has not been observed in any Methanosarcineae, a flagellin gene cluster and two complete chemotaxis gene clusters were identified. The availability of genetic methods, coupled with its physiological and metabolic diversity, makes M. acetivorans a powerful model organism for the study of archaeal biology. [Sequence, data, annotations and analyses are available at http://www-genome.wi.mit.edu/.]