Genetic and Phenotypic Comparison of Facultative Methylotrophy between Methylobacterium extorquens Strains PA1 and AM1

Methylobacterium extorquens AM1, a strain serendipitously isolated half a century ago, has become the best-characterized model system for the study of aerobic methylotrophy (the ability to grow on reduced single-carbon compounds). However, with 5 replicons and 174 insertion sequence (IS) elements in the genome as well as a long history of domestication in the laboratory, genetic and genomic analysis of M. extorquens AM1 face several challenges. On the contrary, a recently isolated strain - M. extorquens PA1- is closely related to M. extorquens AM1 (100% 16S rRNA identity) and contains a streamlined genome with a single replicon and only 20 IS elements. With the exception of the methylamine dehydrogenase encoding gene cluster (mau), genes known to be involved in methylotrophy are well conserved between M. extorquens AM1 and M. extorquens PA1. In this paper we report four primary findings regarding methylotrophy in PA1. First, with a few notable exceptions, the repertoire of methylotrophy genes between PA1 and AM1 is extremely similar. Second, PA1 grows faster with higher yields compared to AM1 on C₁ and multi-C substrates in minimal media, but AM1 grows faster in rich medium. Third, deletion mutants in PA1 throughout methylotrophy modules have the same C₁ growth phenotypes observed in AM1. Finally, the precision of our growth assays revealed several unexpected growth phenotypes for various knockout mutants that serve as leads for future work in understanding their basis and generality across Methylobacterium strains.     

Methylotrophic Metabolism Is Advantageous for Methylobacterium extorquens during Colonization of Medicago truncatula under Competitive Conditions

Facultative methylotrophic bacteria of the genus Methylobacterium are commonly found in association with plants. Inoculation experiments were performed to study the importance of methylotrophic metabolism for colonization of the model legume Medicago truncatula. Competition experiments with Methylobacterium extorquens wild-type strain AM1 and methylotrophy mutants revealed that the ability to use methanol as a carbon and energy source provides a selective advantage during colonization of M. truncatula. Differences in the fitness of mutants defective in different stages of methylotrophic metabolism were found; whereas approximately 25% of the mutant incapable of oxidizing methanol to formaldehyde (deficient in methanol dehydrogenase) was recovered, 10% or less of the mutants incapable of oxidizing formaldehyde to CO₂ (defective in biosynthesis of the cofactor tetrahydromethanopterin) was recovered. Interestingly, impaired fitness of the mutant strains compared with the wild type was found on leaves and roots. Single-inoculation experiments showed, however, that mutants with defects in methylotrophy were capable of plant colonization at the wild-type level, indicating that methanol is not the only carbon source that is accessible to Methylobacterium while it is associated with plants. Fluorescence microscopy with a green fluorescent protein-labeled derivative of M. extorquens AM1 revealed that the majority of the bacterial cells on leaves were on the surface and that the cells were most abundant on the lower, abaxial side. However, bacterial cells were also found in the intercellular spaces inside the leaves, especially in the epidermal cell layer and immediately underneath this layer.     

Expressed Genome of Methylobacillus flagellatus as Defined through Comprehensive Proteomics and New Insights into Methylotrophy

In recent years, techniques have been developed and perfected for high-throughput identification of proteins and their accurate partial sequencing by shotgun nano-liquid chromatography-tandem mass spectrometry (nano-LC-MS/MS), making it feasible to assess global protein expression profiles in organisms with sequenced genomes. We implemented comprehensive proteomics to assess the expressed portion of the genome of Methylobacillus flagellatus during methylotrophic growth. We detected a total of 1,671 proteins (64% of the inferred proteome), including all the predicted essential proteins. Nonrandom patterns observed with the nondetectable proteins appeared to correspond to silent genomic islands, as inferred through functional profiling and genome localization. The protein contents in methylamine- and methanol-grown cells showed a significant overlap, confirming the commonality of methylotrophic metabolism downstream of the primary oxidation reactions. The new insights into methylotrophy include detection of proteins for the N-methylglutamate methylamine oxidation pathway that appears to be auxiliary and detection of two alternative enzymes for both the 6-phosphogluconate dehydrogenase reaction (GndA and GndB) and the formate dehydrogenase reaction (FDH1 and FDH4). Mutant analysis revealed that GndA and FDH4 are crucial for the organism''s fitness, while GndB and FDH1 are auxiliary.Methylotrophy is the ability of some microorganisms to grow on compounds containing no carbon-carbon bonds (C₁ compounds) as sole sources of carbon and energy. This type of metabolism requires special enzyme systems and pathways that accomplish three principal metabolic goals: (i) energy-producing primary oxidation of a C₁ substrate to formaldehyde or methyl transfer to produce methyl-tetrahydrofolate (H₄F), (ii) energy-producing oxidation of formaldehyde or methyl-H₄F to CO₂, and (iii) energy-consuming assimilation of formaldehyde, methylene-H₄F, and/or CO₂ into biomass (1, 22). In the course of microbial evolution, multiple pathways for each step have been assembled, and, theoretically, any combination of these should enable methylotrophy (9). Moreover, some organisms possess multiple pathways for certain metabolic tasks. For example, methane can be oxidized to methanol by either soluble or particulate methane monooxygenase, and many methanotrophs possess both enzymes (25). The presence of multiple formate dehydrogenases is typical among methylotrophs (10). Some methylotrophs, such as Methylococcus capsulatus, encode multiple pathways for C₁ assimilation (37). Methylotrophs employing the ribulose monophosphate (RuMP) cycle for formaldehyde assimilation can also oxidize formaldehyde via this pathway by employing a single additional reaction, catalyzed by 6-phosphogluconate dehydrogenase (Gnd) (1, 22). In addition, most RuMP cycle methylotrophs also possess a linear pathway for formaldehyde oxidation employing tetrahydromethanopterin (H₄MPT) as a cofactor (35).Methylobacillus flagellatus is a typical representative of RuMP cycle methylotrophs. It has a very limited substrate repertoire, growing robustly only on methanol or methylamine (16). Genomic analysis has revealed specific lesions in pathways for utilization of multicarbon compounds, confirming that, indeed, this organism must rely exclusively on methylotrophy to sustain its growth (11). At the same time, redundant methylotrophy pathways have been deduced from the genome. For example, in addition to the bona fide methanol dehydrogenase, four homologs of the large subunit are encoded (11). Besides the well-characterized methylamine dehydrogenase, an alternative system for methylamine oxidation is encoded, consisting of N-methylglutamate synthase and N-methylglutamate dehydrogenase (N-methylglutamate pathway) (21). Both cyclic and linear pathways for formaldehyde oxidation are encoded, along with two formate dehydrogenases. In addition, multiple terminal cytochrome oxidases are encoded (11).It has been assumed that metabolism of both methanol and methylamine, with the exception of the respective specific primary oxidation step, is carried out by M. flagellatus (and other methylotrophs) in exactly the same fashion (1, 22). However, this assumption has not been experimentally tested. The relative contributions of each of the redundant pathways encoded in the genome (for example, linear versus cyclic oxidation of formaldehyde) also remained unclear (7). These questions can be assessed through analysis of the expressed portion of the genome under specific growth conditions and especially precisely through a comprehensive analysis of the protein content in the cell (proteome) (3).In recent years, techniques have been developed and perfected for high-throughput identification of proteins and their accurate partial sequencing by shotgun nano-liquid chromatography-tandem mass spectrometry (nanoLC-MS/MS), making it feasible to assess relatively complete global protein expression profiles in prokaryotic organisms with sequenced genomes (2, 17). In this study, we employed comprehensive proteomics of M. flagellatus to determine what portion of the encoded proteome is detectable during methylotrophic growth under defined laboratory conditions and to obtain new insights into the physiology of the organism through this analysis.     

Biosynthesis of polyhydroxyalkanoate copolymers from methanol by Methylobacterium extorquens AM1 and the engineered strains under cobalt-deficient conditions

Methylobacterium extorquens AM1 has been shown to accumulate polyhydroxyalkanoate (PHA) composed solely of (R)-3-hydroxybutyrate (3HB) during methylotrophic growth. The present study demonstrated that the wild-type strain AM1 grown under Co²⁺-deficient conditions accumulated copolyesters of 3HB and a C₅-monomer, (R)-3-hydroxyvalerate (3HV), using methanol as the sole carbon source. The 3HV unit was supposed to be derived from propionyl-CoA, synthesized via the ethylmalonyl-CoA pathway impaired by Co²⁺ limitation. This assumption was strongly supported by the dominant incorporation of the 3HV unit into PHA when a strain lacking propionyl-CoA carboxylase was incubated with methanol. Further genetic engineering of M. extorquens AM1 was employed for the methylotrophic synthesis of PHA copolymers. A recombinant strain of M. extorquens AM1C_Ac in which the original PHA synthase gene phaC _Me had been replaced by phaC _Ac , encoding an enzyme with broad substrate specificity from Aeromonas caviae, produced a PHA terpolymer composed of 3HB, 3HV, and a C₆-monomer, (R)-3-hydroxyhexanoate, from methanol. The cellular content and molecular weight of the PHA accumulated in the strain AM1C_Ac were higher than those of PHA in the wild-type strain. The triple deletion of three PHA depolymerase genes in M. extorquens AM1C_Ac showed no significant effects on growth and PHA biosynthesis properties. Overexpression of the genes encoding β-ketothiolase and NADPH-acetoacetyl-CoA reductase increased the cellular PHA content and 3HV composition in PHA, although the cell growth on methanol was decreased. This study opens up the possibility of producing practical PHA copolymers with methylotrophic bacteria using methanol as a feedstock.     

Two-component system that regulates methanol and formaldehyde oxidation in Paracoccus denitrificans

A chromosomal region encoding a two-component regulatory system, FlhRS, has been isolated from Paracoccus denitrificans. FlhRS-deficient mutants were unable to grow on methanol, methylamine, or choline as the carbon and energy source. Expression of the gene encoding glutathione-dependent formaldehyde dehydrogenase (fhlA) was undetectable in the mutant, and expression of the S-formylglutathione hydrolase gene (fghA) was reduced in the mutant background. In addition, methanol dehydrogenase was immunologically undetectable in cell extracts of FhlRS mutants. These results indicate that the FlhRS sensor-regulator pair is involved in the regulation of formaldehyde, methanol, and methylamine oxidation. The effect that the FlhRS proteins exert on the regulation of C₁ metabolism might be essential to maintain the internal concentration of formaldehyde below toxic levels.     

A Simple Colorimetrie Assay for Aspartate Aminotransferase

γ-Glutamylmethylamide (γ-GMA) synthetase was detected in crude extracts of Methylophaga sp. AA-30, but neither methylamine dehydrogenase nor N-methylglutamate dehydrogenase was observed. A large amount of γ-GMA was accumulated in the cells when the growth on methanol-methylamine was inhibited with iodoacetate, but the accumulation was not observed in the cells grown on methanol-(NH₄)₂SO₄. It is thought that γ-GMA is a metabolic intermediate of the methylamine-dissimilating pathway in the bacterium. In addition, γ-GMA-dissimilating enzymes were found in methylamine-grown cells. The enzymes, which consisted of H protein and L protein, required α-ketoglutaric acid, Mg²⁺ or Mn²⁺, and ammonia as a cofactor. Although the enzyme catalyzed the formation of glutamate from γ-GMA, it did not catalyze the formation of N-methylglutamate. Consequently, in this bacterium, methylamine seems to be metabolized through a different pathway from the N-methylglutamate pathway.     

Alternative Route for Glyoxylate Consumption during Growth on Two-Carbon Compounds by Methylobacterium extorquens AM1

Methylobacterium extorquens AM1 is a facultative methylotroph capable of growth on both single-carbon and multicarbon compounds. Mutants defective in a pathway involved in converting acetyl-coenzyme A (CoA) to glyoxylate (the ethylmalonyl-CoA pathway) are unable to grow on both C₁ and C₂ compounds, showing that both modes of growth have this pathway in common. However, growth on C₂ compounds via the ethylmalonyl-CoA pathway should require glyoxylate consumption via malate synthase, but a mutant lacking malyl-CoA/β-methylmalyl-CoA lyase activity (MclA1) that is assumed to be responsible for malate synthase activity still grows on C₂ compounds. Since glyoxylate is toxic to this bacterium, it seemed likely that a system is in place to keep it from accumulating. In this study, we have addressed this question and have shown by microarray analysis, mutant analysis, metabolite measurements, and ¹³C-labeling experiments that M. extorquens AM1 contains an additional malyl-CoA/β-methylmalyl-CoA lyase (MclA2) that appears to take part in glyoxylate metabolism during growth on C₂ compounds. In addition, an alternative pathway appears to be responsible for consuming part of the glyoxylate, converting it to glycine, methylene-H₄F, and serine. Mutants lacking either pathway have a partial defect for growth on ethylamine, while mutants lacking both pathways are unable to grow appreciably on ethylamine. Our results suggest that the malate synthase reaction is a bottleneck for growth on C₂ compounds by this bacterium, which is partially alleviated by this alternative route for glyoxylate consumption. This strategy of multiple enzymes/pathways for the consumption of a toxic intermediate reflects the metabolic versatility of this facultative methylotroph and is a model for other metabolic networks involving high flux through toxic intermediates.Methylobacterium extorquens AM1 grows on one-carbon (C₁) compounds using the serine cycle for assimilation (25). This metabolism requires the conversion of acetyl-coenzyme A (CoA) to glyoxylate, which occurs via a novel pathway in which acetyl-CoA is converted to methylsuccinyl-CoA via acetoacetyl-CoA, ß-hydroxybutyryl-CoA, and ethylmalonyl-CoA (30-33). Recently, the steps involved in the conversion of methylsuccinyl-CoA to glyoxylate have been elucidated, and the pathway has been termed the ethylmalonyl-CoA (EMC) pathway (1, 19, 20, 40). Careful labeling measurements coupled to measurements of intermediates has confirmed that, during the growth of M. extorquens AM1 on methanol, methylsuccinyl-CoA is converted to glyoxylate and propionyl-CoA via mesaconyl-CoA and ß-methylmalyl-CoA (40).This finding has raised questions regarding how M. extorquens AM1 grows on two-carbon (C₂) compounds. The pathway involved in the conversion of acetyl-CoA to glyoxylate is known to operate during growth on both C₁ and C₂ compounds, as mutants in genes involved in this conversion are unable to grow on either C₁ or C₂ compounds, and in both cases they are rescued by glyoxylate (11, 15-17, 44). If glyoxylate is produced as an end product of this pathway during C₂ growth, then it must be converted to an intermediate of central metabolism, which has been proposed to involve a malate synthase activity (2, 14-17) (Fig. ​(Fig.1).1). In M. extorquens AM1, the apparent malate synthase activity is carried out in two steps, first by converting acetyl-CoA and glyoxylate to malyl-CoA by malyl-CoA lyase and then by converting malyl-CoA to malate by malyl-CoA hydrolase (Fig. ​(Fig.1)1) (14). However, a mutant (PCT57) defective in malyl-CoA lyase (MclA1) (22), which contains no detectable malate synthase activity during growth on methanol, is able to grow on C₂ compounds (43).Open in a separate windowFIG. 1.Enzymes and genes involved in the ethylmalonyol-CoA pathway. The colors of gene names denote a change in gene expression from microarray results comparing wild-type cells grown on ethylamine to those grown on succinate: dark red, >3-fold increase; light red, 1.5- to 3-fold increase; black, no significant change (1.49-fold increase to 1.49-fold decrease); light green, 1.5- to 3-fold decrease; dark green, >3-fold decrease. Parentheses denote a predicted function not confirmed by the mutant phenotype. See Table ​Table11 for enzyme names.Clearly, the finding that glyoxylate is generated as a direct product of the EMC pathway presents a conundrum. Apparently acetyl-CoA is converted to glyoxylate via this pathway, but M. extorquens AM1 lacking malate synthase is able to grow on C₂ compounds. Another apparent conundrum involving the malyl-CoA lyase (mclA1) mutant is that the EMC pathway requires an enzyme that carries out ß-methylmalyl-CoA cleavage, a reaction that homologs of MclA1 are known to carry out (38). The MclA1 enzyme has been purified from M. extorquens AM1 and shown to have activity with glyoxylate and propionyl-CoA (27), which would produce ß-methylmalyl-CoA. These results have led to the suggestion that MclA homologs actually are malyl-CoA/ß-methylmalyl-CoA lyases (38). Since the mclA1 mutant does not contain detectable malyl-CoA lyase activity, and by inference has correspondingly low ß-methylmalyl-CoA lyase activity, it was not clear how M. extorquens AM1 could convert acetyl-CoA to propionyl-CoA and glyoxylate via the EMC pathway in the mclA1 mutant.The purpose of this study was to solve these conundrums and determine how mutants of M. extorquens AM1 grow on C₂ compounds in the absence of malyl-CoA/ß-methylmalyl-CoA lyase or malate synthase activity. Our results show (i) that the known homolog of MclA1 (MclA2) appears to be capable of supporting both ß-methylmalyl-CoA cleavage and condensation between glyoxylate and acetyl-CoA in the mclA1 mutant, and (ii) that an alternative route for glyoxylate consumption occurs in this bacterium, in which it is converted to intermediates of central metabolism via a part of the serine cycle coupled with the glycine cleavage system.     

Development of an Optimized Medium,Strain and High-Throughput Culturing Methods for Methylobacterium extorquens

Methylobacterium extorquens strains are the best-studied methylotrophic model system, and their metabolism of single carbon compounds has been studied for over 50 years. Here we develop a new system for high-throughput batch culture of M. extorquens in microtiter plates by jointly optimizing the properties of the organism, the growth media and the culturing system. After removing cellulose synthase genes in M. extorquens strains AM1 and PA1 to prevent biofilm formation, we found that currently available lab automation equipment, integrated and managed by open source software, makes possible reliable estimates of the exponential growth rate. Using this system, we developed an optimized growth medium for M. extorquens using response surface methodologies. We found that media that used EDTA as a metal chelator inhibited growth and led to inconsistent culture conditions. In contrast, the new medium we developed with a PIPES buffer and metals chelated by citrate allowed for fast and more consistent growth rates. This new Methylobacterium PIPES (‘MP’) medium was also robust to large deviations in its component ingredients which avoided batch effects from experiments that used media prepared at different times. MP medium allows for faster and more consistent growth than other media used for M. extorquens.     

The NADP-Dependent Methylene Tetrahydromethanopterin Dehydrogenase in Methylobacterium extorquens AM1

An NADP-dependent methylene tetrahydromethanopterin (H₄MPT) dehydrogenase has recently been proposed to be involved in formaldehyde oxidation to CO₂ in Methylobacterium extorquens AM1. We report here on the purification of this novel enzyme to apparent homogeneity. Via the N-terminal amino acid sequence, it was identified to be the mtdA gene product. The purified enzyme catalyzed the dehydrogenation of methylene H₄MPT with NADP⁺ rather than with NAD⁺, with a specific activity of approximately 400 U/mg of protein. It also catalyzed the dehydrogenation of methylene tetrahydrofolate (methylene H₄F) with NADP⁺. With methylene H₄F as the substrate, however, the specific activity (26 U/mg) and the catalytic efficiency (V_max/K_m) were approximately 20-fold lower than with methylene H₄MPT. Whereas the dehydrogenation of methylene H₄MPT (E₀ = −390 mV) with NADP⁺ (E₀ = −320 mV) proceeded essentially irreversibly, the dehydrogenation of methylene H₄F (E₀ = −300 mV) was fully reversible. Comparison of the primary structure of the NADP-dependent dehydrogenase from M. extorquens AM1 with those of methylene H₄F dehydrogenases from other bacteria and eucarya and with those of methylene H₄MPT dehydrogenases from methanogenic archaea revealed only marginally significant similarity (<15%).     

Oxidation of C1 compounds by Pseudomonas sp. MS

Pseudomonas sp. MS is capable of growth on a number of compounds containing only C₁ groups. They include trimethylsulphonium salts, methylamine, dimethylamine and trimethylamine. Although formaldehyde and formate will not support growth they are rapidly oxidized by intact cells. Methanol neither supports growth nor is oxidized. A particulate fraction of the cell oxidizes methylamine to carbon dioxide in the absence of any external electron acceptor. Formaldehyde and formate are more slowly oxidized to carbon dioxide by the particulate fraction, although they do not appear to be free intermediates in the oxidation of methylamine. Soluble NAD-linked formaldehyde dehydrogenase and formate dehydrogenase are also present. The particulate methylamine oxidase is induced by growth on methylamine, dimethylamine and trimethylamine, whereas the soluble formaldehyde dehydrogenase and formate dehydrogenase are induced by trimethylsulphonium nitrate as well as the aforementioned amines.     

Thioesterases for ethylmalonyl–CoA pathway derived dicarboxylic acid production in <Emphasis Type="Italic">Methylobacterium extorquens</Emphasis> AM1

The ethylmalonyl–coenzyme A pathway (EMCP) is a recently discovered pathway present in diverse α-proteobacteria such as the well studied methylotroph Methylobacterium extorquens AM1. Its glyoxylate regeneration function is obligatory during growth on C1 carbon sources like methanol. The EMCP contains special CoA esters, of which dicarboxylic acid derivatives are of high interest as building blocks for chemical industry. The possible production of dicarboxylic acids out of the alternative, non-food competing C-source methanol could lead to sustainable and economic processes. In this work we present a testing of functional thioesterases being active towards the EMCP CoA esters including in vitro enzymatic assays and in vivo acid production. Five thioesterases including TesB from Escherichia coli and M. extorquens, YciA from E. coli, Bch from Bacillus subtilis and Acot4 from Mus musculus showed activity towards EMCP CoA esters in vitro at which YciA was most active. Expressing yciA in M. extorquens AM1 led to release of 70 mg/l mesaconic and 60 mg/l methylsuccinic acid into culture supernatant during exponential growth phase. Our data demonstrates the biotechnological applicability of the thioesterase YciA and the possibility of EMCP dicarboxylic acid production from methanol using M. extorquens AM1.     

A Catalytic Role of XoxF1 as La3+-Dependent Methanol Dehydrogenase in Methylobacterium extorquens Strain AM1

In the methylotrophic bacterium Methylobacterium extorquens strain AM1, MxaF, a Ca²⁺-dependent methanol dehydrogenase (MDH), is the main enzyme catalyzing methanol oxidation during growth on methanol. The genome of strain AM1 contains another MDH gene homologue, xoxF1, whose function in methanol metabolism has remained unclear. In this work, we show that XoxF1 also functions as an MDH and is La³⁺-dependent. Despite the absence of Ca²⁺ in the medium strain AM1 was able to grow on methanol in the presence of La³⁺. Addition of La³⁺ increased MDH activity but the addition had no effect on mxaF or xoxF1 expression level. We purified MDH from strain AM1 grown on methanol in the presence of La³⁺, and its N-terminal amino acid sequence corresponded to that of XoxF1. The enzyme contained La³⁺ as a cofactor. The ΔmxaF mutant strain could not grow on methanol in the presence of Ca²⁺, but was able to grow after supplementation with La³⁺. Taken together, these results show that XoxF1 participates in methanol metabolism as a La³⁺-dependent MDH in strain AM1.     

Isolation and characterization of mutants of the facultative methylotroph Arthrobacter P1 blocked in one-carbon metabolism

Among methylamine and/or ethylamine minus mutants of Arthrobacter P1 four different classes were identified, which were blocked either in the methylamine transport system, amine oxidase, hexulose phosphate synthase or acetaldehyde dehydrogenase. The results indicated that a common primary amine oxidase is involved in the metabolism of methylamine and ethylamine. Growth on ethylamine, however, was not dependent on the presence of the methylamine transport system. In mutants lacking amine oxidase, methylamine was unable to induce the synthesis of hexulose phosphate synthase, thus confirming the view that the actual inducer for the latter enzyme is not methylamine, but its oxidation product formaldehyde. Contrary to expectation, when the formaldehyde fixing enzyme hexulose phosphate synthase was deleted (mutant Art 11), accumulation of formaldehyde during growth on choline or on glucose plus methylamine as a nitrogen source did not occur. Evidence was obtained to indicate that under these conditions formaldehyde may be oxidized to carbon dioxide via formate, a sequence in which peroxidative reactions mediated by catalase are involved. In addition, a specific NAD-dependent formaldehyde dehydrogenase was detected in choline-grown cells of wild type Arthrobacter P1 and strain Art 11. This enzyme, however, does not play a role in methylamine or formaldehyde metabolism, apparently because these compounds do not induce its synthesis.Abbreviations RuMP ribulose monophosphate - HPS hexulose phosphate synthase - HPI hexulose phosphate isomerase     

Formaldehyde-detoxifying role of the tetrahydromethanopterin-linked pathway in Methylobacterium extorquens AM1

The facultative methylotroph Methylobacterium extorquens AM1 possesses two pterin-dependent pathways for C(1) transfer between formaldehyde and formate, the tetrahydrofolate (H(4)F)-linked pathway and the tetrahydromethanopterin (H(4)MPT)-linked pathway. Both pathways are required for growth on C(1) substrates; however, mutants defective for the H(4)MPT pathway reveal a unique phenotype of being inhibited by methanol during growth on multicarbon compounds such as succinate. It has been previously proposed that this methanol-sensitive phenotype is due to the inability to effectively detoxify formaldehyde produced from methanol. Here we present a comparative physiological characterization of four mutants defective in the H(4)MPT pathway and place them into three different phenotypic classes that are concordant with the biochemical roles of the respective enzymes. We demonstrate that the analogous H(4)F pathway present in M. extorquens AM1 cannot fulfill the formaldehyde detoxification function, while a heterologously expressed pathway linked to glutathione and NAD(+) can successfully substitute for the H(4)MPT pathway. Additionally, null mutants were generated in genes previously thought to be essential, indicating that the H(4)MPT pathway is not absolutely required during growth on multicarbon compounds. These results define the role of the H(4)MPT pathway as the primary formaldehyde oxidation and detoxification pathway in M. extorquens AM1.     

Mutagenesis of the C1 oxidation pathway in Methanosarcina barkeri: new insights into the Mtr/Mer bypass pathway

A series of Methanosarcina barkeri mutants lacking the genes encoding the enzymes involved in the C1 oxidation/reduction pathway were constructed. Mutants lacking the methyl-tetrahydromethanopterin (H₄MPT):coenzyme M (CoM) methyltransferase-encoding operon (Δmtr), the methylene-H₄MPT reductase-encoding gene (Δmer), the methylene-H₄MPT dehydrogenase-encoding gene (Δmtd), and the formyl-methanofuran:H₄MPT formyl-transferase-encoding gene (Δftr) all failed to grow using either methanol or H₂/CO₂ as a growth substrate, indicating that there is an absolute requirement for the C1 oxidation/reduction pathway for hydrogenotrophic and methylotrophic methanogenesis. The mutants also failed to grow on acetate, and we suggest that this was due to an inability to generate the reducing equivalents needed for biosynthetic reactions. Despite their lack of growth on methanol, the Δmtr and Δmer mutants were capable of producing methane from this substrate, whereas the Δmtd and Δftr mutants were not. Thus, there is an Mtr/Mer bypass pathway that allows oxidation of methanol to the level of methylene-H₄MPT in M. barkeri. The data further suggested that formaldehyde may be an intermediate in this bypass; however, no methanol dehydrogenase activity was found in Δmtr cell extracts, nor was there an obligate role for the formaldehyde-activating enzyme (Fae), which has been shown to catalyze the condensation of formaldehyde and H₄MPT in vitro. Both the Δmer and Δmtr mutants were able to grow on a combination of methanol plus acetate, but they did so by metabolic pathways that are clearly distinct from each other and from previously characterized methanogenic pathways.     

The 380 kb pCMU01 Plasmid Encodes Chloromethane Utilization Genes and Redundant Genes for Vitamin B12- and Tetrahydrofolate-Dependent Chloromethane Metabolism in Methylobacterium extorquens CM4: A Proteomic and Bioinformatics Study

Chloromethane (CH₃Cl) is the most abundant volatile halocarbon in the atmosphere and contributes to the destruction of stratospheric ozone. The only known pathway for bacterial chloromethane utilization (cmu) was characterized in Methylobacterium extorquens CM4, a methylotrophic bacterium able to utilize compounds without carbon-carbon bonds such as methanol and chloromethane as the sole carbon source for growth. Previous work demonstrated that tetrahydrofolate and vitamin B₁₂ are essential cofactors of cmuA- and cmuB-encoded methyltransferases of chloromethane dehalogenase, and that the pathway for chloromethane utilization is distinct from that for methanol. This work reports genomic and proteomic data demonstrating that cognate cmu genes are located on the 380 kb pCMU01 plasmid, which drives the previously defined pathway for tetrahydrofolate-mediated chloromethane dehalogenation. Comparison of complete genome sequences of strain CM4 and that of four other M. extorquens strains unable to grow with chloromethane showed that plasmid pCMU01 harbors unique genes without homologs in the compared genomes (bluB2, btuB, cobA, cbiD), as well as 13 duplicated genes with homologs of chromosome-borne genes involved in vitamin B₁₂-associated biosynthesis and transport, or in tetrahydrofolate-dependent metabolism (folC2). In addition, the presence of both chromosomal and plasmid-borne genes for corrinoid salvaging pathways may ensure corrinoid coenzyme supply in challenging environments. Proteomes of M. extorquens CM4 grown with one-carbon substrates chloromethane and methanol were compared. Of the 49 proteins with differential abundance identified, only five (CmuA, CmuB, PurU, CobH2 and a PaaE-like uncharacterized putative oxidoreductase) are encoded by the pCMU01 plasmid. The mainly chromosome-encoded response to chloromethane involves gene clusters associated with oxidative stress, production of reducing equivalents (PntAA, Nuo complex), conversion of tetrahydrofolate-bound one-carbon units, and central metabolism. The mosaic organization of plasmid pCMU01 and the clustering of genes coding for dehalogenase enzymes and for biosynthesis of associated cofactors suggests a history of gene acquisition related to chloromethane utilization.     

Co-Consumption of Methanol and Succinate by Methylobacterium extorquens AM1

Methylobacterium extorquens AM1 is a facultative methylotrophic Alphaproteobacterium and has been subject to intense study under pure methylotrophic as well as pure heterotrophic growth conditions in the past. Here, we investigated the metabolism of M. extorquens AM1 under mixed substrate conditions, i.e., in the presence of methanol plus succinate. We found that both substrates were co-consumed, and the carbon conversion was two-thirds from succinate and one-third from methanol relative to mol carbon. ¹³C-methanol labeling and liquid chromatography mass spectrometry analyses revealed the different fates of the carbon from the two substrates. Methanol was primarily oxidized to CO₂ for energy generation. However, a portion of the methanol entered biosynthetic reactions via reactions specific to the one-carbon carrier tetrahydrofolate. In contrast, succinate was primarily used to provide precursor metabolites for bulk biomass production. This work opens new perspectives on the role of methylotrophy when substrates are simultaneously available, a situation prevailing under environmental conditions.