Methylamine Utilization via the N-Methylglutamate Pathway in Methylobacterium extorquens PA1 Involves a Novel Flow of Carbon through C1 Assimilation and Dissimilation Pathways

Methylotrophs grow on reduced single-carbon compounds like methylamine as the sole source of carbon and energy. In Methylobacterium extorquens AM1, the best-studied aerobic methylotroph, a periplasmic methylamine dehydrogenase that catalyzes the primary oxidation of methylamine to formaldehyde has been examined in great detail. However, recent metagenomic data from natural ecosystems are revealing the abundance and importance of lesser-known routes, such as the N-methylglutamate pathway, for methylamine oxidation. In this study, we used M. extorquens PA1, a strain that is closely related to M. extorquens AM1 but is lacking methylamine dehydrogenase, to dissect the genetics and physiology of the ecologically relevant N-methylglutamate pathway for methylamine oxidation. Phenotypic analyses of mutants with null mutations in genes encoding enzymes of the N-methylglutamate pathway suggested that γ-glutamylmethylamide synthetase is essential for growth on methylamine as a carbon source but not as a nitrogen source. Furthermore, analysis of M. extorquens PA1 mutants with defects in methylotrophy-specific dissimilatory and assimilatory modules suggested that methylamine use via the N-methylglutamate pathway requires the tetrahydromethanopterin (H₄MPT)-dependent formaldehyde oxidation pathway but not a complete tetrahydrofolate (H₄F)-dependent formate assimilation pathway. Additionally, we present genetic evidence that formaldehyde-activating enzyme (FAE) homologs might be involved in methylotrophy. Null mutants of FAE and homologs revealed that FAE and FAE2 influence the growth rate and FAE3 influences the yield during the growth of M. extorquens PA1 on methylamine.     

Regulation and Physiological Role of the DAS1 Gene, Encoding Dihydroxyacetone Synthase, in the Methylotrophic Yeast Candida boidinii

The physiological role of dihydroxyacetone synthase (DHAS) in Candida boidinii was evaluated at the molecular level. The DAS1 gene, encoding DHAS, was cloned from the host genome, and regulation of its expression by various carbon and nitrogen sources was analyzed. Western and Northern analyses revealed that DAS1 expression was regulated mainly at the mRNA level. The regulatory pattern of DHAS was similar to that of alcohol oxidase but distinct from that of two other enzymes in the formaldehyde dissimilation pathway, glutathione-dependent formaldehyde dehydrogenase and formate dehydrogenase. The DAS1 gene was disrupted in one step in the host genome (das1Δ strain), and the growth of the das1Δ strain in various carbon and nitrogen sources was compared with that of the wild-type strain. The das1Δ strain had completely lost the ability to grow on methanol, while the strain with a disruption of the formate dehydrogenase gene could survive (Y. Sakai et al., J. Bacteriol. 179:4480–4485, 1997). These and other experiments (e.g., those to determine the expression of the gene and the growth ability of the das1Δ strain on media containing methylamine or choline as a nitrogen source) suggested that DAS1 is involved in assimilation rather than dissimilation or detoxification of formaldehyde in the cells.     

A strong nitrogen source-regulated promoter for controlled expression of foreign genes in the yeast Pichia pastoris

In methylotrophic yeasts, glutathione-dependent formaldehyde dehydrogenase (FLD) is a key enzyme required for the metabolism of methanol as a carbon source and certain alkylated amines such as methylamine as nitrogen sources. We describe the isolation and characterization of the FLD1 gene from the yeast Pichia pastoris. The gene contains a single short intron with typical yeast-splicing signals near its 5′ end, the first intron to be demonstrated in this yeast. The predicted FLD1 product (Fld1p) is a protein of 379 amino acids (approx. 40 kDa) with 71% identity to the FLD protein sequence from the n-alkane-assimilating yeast Candida maltosa and 61–65% identity with dehydrogenase class III enzymes from humans and other higher eukaryotes. Using β-lactamase as a reporter, we show that the FLD1 promoter (P_FLD1) is strongly and independently induced by either methanol as sole carbon source (with ammonium sulfate as nitrogen source) or methylamine as sole nitrogen source (with glucose as carbon source). Furthermore, with either methanol or methylamine induction, levels of β-lactamase produced under control of P_FLD1 are comparable to those obtained with the commonly used alcohol oxidase I gene promoter (P_AOX1). Thus, P_FLD1 is an attractive alternative to P_AOX1 for expression of foreign genes in P. pastoris, allowing the investigator a choice of carbon (methanol) or nitrogen source (methylamine) regulation with the same expression strain.     

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.     

Isolation, sequencing, and mutagenesis of the gene encoding NAD- and glutathione-dependent formaldehyde dehydrogenase (GD-FALDH) from Paracoccus denitrificans, in which GD-FALDH is essential for methylotrophic growth.

NAD- and glutathione-dependent formaldehyde dehydrogenase (GD-FALDH) of Paracoccus denitrificans has been purified as a tetramer with a relative molecular mass of 150 kDa. The gene encoding GD-FALDH (flhA) has been isolated, sequenced, and mutated by insertion of a kanamycin resistance gene. The mutant strain is not able to grow on methanol, methylamine, or choline, while heterotrophic growth is not influenced by the mutation. This finding indicates that GD-FALDH of P. denitrificans is essential for the oxidation of formaldehyde produced during methylotrophic growth.     

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.     

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     

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.     

Methanol and methylamine utilization result from mutational events in Thiosphaera pantotropha

With choline as carbon source Thiosphaera pantotropha GB17 grew with a doubling time (t_d) of 6 h. The cellular yield was 55.8 g dry cell weight per mol of choline, indicating that its methyl moieties were used for growth. However, T. pantotropha was unable to grow with methanol or with methylamine as carbon source. Mutants were isolated from liquid or from solid media able to grow with methanol (Mox⁺) as carbon or methylamine as nitrogen source (Mam⁺). The Mox⁺ mutant GB17M grew with a mean t_d of 11.7h and a growth yield of 8.9 g dry cell weight per mol of methanol. Diauxic growth of strain GB17M was observed with mixtures of pyruvate and methanol as substrates in batch culture. Methanol led to the formation of methanol dehydrogenase, formate dehydrogenase, ribulosebisphosphate carboxylase and of a soluble cytochrome c-551.5. Tn5-insertional mutants defective in the thiosulfate oxidizing enzyme system or in hydrogenase acquired the Mox⁺ phenotype. However, Tn5-insertional mutants defective in either a c-type cytochrome or the molybdenum cofactor did not mutate to the Mox⁺ phenotype, indicating common functions in thiosulfate and in methanol metabolism.     

A method for introduction of unmarked mutations in the genome of Paracoccus denitrificans: construction of strains with multiple mutations in the genes encoding periplasmic cytochromes c550, c551i, and c553i.

A new suicide vector, pRVS1, was constructed to facilitate the site-directed introduction of unmarked mutations in the chromosome of Paracoccus denitrificans. The vector was derived from suicide vector pGRPd1, which was equipped with the lacZ gene encoding beta-galactosidase. The reporter gene was found to be a successful screening marker for the discrimination between plasmid integrant strains and mutant strains which had lost the plasmid after homologous recombination. Suicide vectors pGRPd1 and pRVS1 were used in gene replacement techniques for the construction of mutant strains with multiple mutations in the cycA, moxG, and cycB genes encoding the periplasmic cytochromes c550, c551i, and c553i, respectively. Southern analyses of the DNA and protein analyses of the resultant single, double, and triple mutant strains confirmed the correctness of the mutations. The wild type and mutant strains were all able to grow on succinate and choline chloride. In addition, all strains grew on methylamine and displayed wild-type levels of methylamine dehydrogenase activities. cycA mutant strains, however, showed a decreased maximum specific growth rate on the methylamine substrate. The wild-type strain, cycA and cycB mutant strains, and the cycA cycB double mutant strain were able to grow on methanol and showed wild-type levels of methanol dehydrogenase activities. moxG mutant strains failed to grow on methanol and had low levels of methanol dehydrogenase activities. The maximum specific growth rate of the cycA mutant strain on methanol was comparable with that of the wild-type strain. The data indicate the involvement of the soluble cytochromes c in clearly defined electron transport routes.     

Pathways leading to and from serine during growth of Pseudomonas AM1 in C1 compounds or succinate

1. The following enzymes of the phosphorylated pathway of serine biosynthesis have been found in methanol- and succinate-grown Pseudomonas AM1: phosphoglycerate dehydrogenase, phosphoserine-alpha-oxoglutarate aminotransferase and phosphoserine phosphohydrolase. Their specific activities were similar in the organism grown on either substrate. 2. A procedure for preparation of auxotrophic mutants of Pseudomonas AM1 is described involving N-methyl-N'-nitro-N-nitrosoguanidine as mutagen and a penicillin enrichment step. 3. A mutant, M-15A, has been isolated that is unable to grow on methanol and that lacks phenazine methosulphate-linked methanol dehydrogenase. The mutant is able to grow on methylamine, showing that the amine is not oxidized by way of methanol. 4. Loss of methanol dehydrogenase activity in mutant M-15A led to loss of phenazine methosulphate-linked formaldehyde dehydrogenase activity showing that the same enzyme is probably responsible for both activities. 5. A mutant, 20B-L, has been isolated that cannot grow on any C(1) compound tested but can grow on succinate. 6. Mutant 20B-L lacks hydroxypyruvate reductase, and revertants that regained the ability to grow on methanol, methylamine and formate contained hydroxypyruvate reductase activity at specific activities similar to that of the wild-type organism. This shows that hydroxypyruvate reductase is necessary for growth on methanol, methylamine and formate but not for growth on succinate. 7. The results suggest that during growth of Pseudomonas AM1 on C(1) compounds, serine is converted into 3-phosphoglycerate by a non-phosphorylated pathway, whereas during growth on succinate, phosphoglycerate is converted into serine by a phosphorylated pathway.     

Chloromethane Metabolism by Methylobacterium sp. Strain CM4

Methylobacterium sp. strain CM4 metabolized chloromethane quantitatively with a molar yield of 2.8 g of whole-cell protein/mol of C. This value was similar to that observed after growth with methanol (2.9 g of protein/mol of C) and about three times larger than the yield with formate (0.94 g of protein/mol of C). Chloromethane dehalogenation activity was inducible. MiniTn5 transposon insertion mutants with altered growth characteristics with chloromethane and other C₁ compounds were isolated and characterized. Nine of these were unable to grow with chloromethane but were able to grow with methanol, methylamine, or formate. Seventy-three transposon mutants that were defective in the utilization of either methanol, methylamine, methanol plus methylamine, or formate could still grow with chloromethane. Based on the protein yield data and the properties of the transposon mutants, we propose a pathway for chloromethane metabolism that depends on methyltransferase and dehydrogenase activities.     

C1 metabolism inParacoccus denitrificans: Genetics ofParacoccus denitrificans

Paracoccus denitrificans is able to grow on the C₁ compounds methanol and methylamine. These compounds are oxidized to formaldehyde which is subsequently oxidized via formate to carbon dioxide. Biomass is produced by carbon dioxide fixation via the ribulose biphosphate pathway. The first oxidation reaction is catalyzed by the enzymes methanol dehydrogenase and methylamine dehydrogenase, respectively. Both enzymes contain two different subunits in an ₂₂ configuration. The genes encoding the subunits of methanol dehydrogenase (moxF andmoxI) have been isolated and sequenced. They are located in one operon together with two other genes (moxJ andmoxG) in the gene ordermoxFJGI. The function of themoxJ gene product is not yet known.MoxG codes for a cytochromec _551i , which functions as the electron acceptor of methanol dehydrogenase. Both methanol dehydrogenase and methylamine dehydrogenase contain PQQ as a cofactor. These so-called quinoproteins are able to catalyze redox reactions by one-electron steps. The reaction mechanism of this oxidation will be described. Electrons from the oxidation reaction are donated to the electron transport chain at the level of cytochromec. P. denitrificans is able to synthesize at least 10 differentc-type cytochromes. Five could be detected in the periplasm and five have been found in the cytoplasmic membrane. The membrane-bound cytochromec ₁ and cytochromec ₅₅₂ and the periplasmic-located cytochromec ₅₅₀ are present under all tested growth conditions. The cytochromesc _551i andc _553i , present in the periplasm, are only induced in cells grown on methanol, methylamine, or choline. The otherc-type cytochromes are mainly detected either under oxygen limited conditions or under anaerobic conditions with nitrate as electron acceptor or under both conditions. An overview including the induction pattern of allP. denitrificans c-type cytochromes will be given. The genes encoding cytochromec ₁, cytochromec ₅₅₀, cytochromec _551i , and cytochromec _553i have been isolated and sequenced. By using site-directed mutagenesis these genes were mutated in the genome. The mutants thus obtained were used to study electron transport during growth on C₁ compounds. This electron transport has also been studied by determining electron transfer rates inin vitro experiments. The exact pathways, however, are not yet fully understood. Electrons from methanol dehydrogenase are donated to cytochromec _551i . Further electron transport is either via cytochromec ₅₅₀ or cytochromec _553i to cytochromeaa ₃. However, direct electron transport from cytochromec _551i to the terminal oxidase might be possible as well. Electrons from methylamine dehydrogenase are donated to amicyanin and then via cytochromec ₅₅₀ to cytochromeaa ₃, but other routes are used also.P. denitrificans is studied by several groups by using a genetic approach. Several genes have already been cloned and sequenced and a lot of mutants have been isolated. The development of a host/vector system and several techniques for mutation induction that are used inP. denitrificans genetics will be described.     

Identification of a fourth formate dehydrogenase in Methylobacterium extorquens AM1 and confirmation of the essential role of formate oxidation in methylotrophy

A mutant of Methylobacterium extorquens AM1 with lesions in genes for three formate dehydrogenase (FDH) enzymes was previously described by us (L. Chistoserdova, M. Laukel, J.-C. Portais, J. A. Vorholt, and M. E. Lidstrom, J. Bacteriol. 186:22-28, 2004). This mutant had lost its ability to grow on formate but still maintained the ability to grow on methanol. In this work, we further investigated the phenotype of this mutant. Nuclear magnetic resonance experiments with [¹³C]formate, as well as ¹⁴C-labeling experiments, demonstrated production of labeled CO₂ in the mutant, pointing to the presence of an additional enzyme or a pathway for formate oxidation. The tungsten-sensitive phenotype of the mutant suggested the involvement of a molybdenum-dependent enzyme. Whole-genome array experiments were conducted to test for genes overexpressed in the triple-FDH mutant compared to the wild type, and a gene (fdh4A) was identified whose translated product carried similarity to an uncharacterized putative molybdopterin-binding oxidoreductase-like protein sharing relatively low similarity with known formate dehydrogenase alpha subunits. Mutation of this gene in the triple-FDH mutant background resulted in a methanol-negative phenotype. When the gene was deleted in the wild-type background, the mutant revealed diminished growth on methanol with accumulation of high levels of formate in the medium, pointing to an important role of FDH4 in methanol metabolism. The identity of FDH4 as a novel FDH was also confirmed by labeling experiments that revealed strongly reduced CO₂ formation in growing cultures. Mutation of a small open reading frame (fdh4B) downstream of fdh4A resulted in mutant phenotypes similar to the phenotypes of fdh4A mutants, suggesting that fdh4B is also involved in formate oxidation.     

The linear oxidation of formaldehyde to CO2 as the proper energy generating sequence for the assimilation of methanol in Acetobacter methanolicus MB58

Acetobacter methanolicus MB58 can grow on methanol. Since this substrate exhibits to be energy deficient there must be a chance to oxidize methanol to CO₂ merely for purpose of energy generation. For the assimilation of methanol the FBP variant of the RuMP pathway is used. Hence methanol can be oxidized cyclically via 6-phosphogluconate. Since Acetobacter methanolicus MB58 possesses all enzymes for a linear oxidation via formate the question arises which of both sequences is responsible for generation of the energy required. In order to clarify this the linear sequence was blocked by inhibiting the formate dehydrogenase with hypophosphite and by mutagenesis inducing mutants defective in formaldehyde or formate dehydrogenase. It has been shown that the linear dissimilatory sequence is indispensable for methylotrophic growth. Although the cyclic oxidation of formaldehyde to CO₂ has not been influenced by hypophosphite and with mutants both the wild type and the formaldehyde dehydrogenase defect mutants cannot grown on methanol. The cyclic oxidation of formaldehyde does not seem to be coupled to a sufficient energy generation, probably it operates only detoxifying and provides reducing equivalents for syntheses. The regulation between assimilation and dissimilation of formaldehyde in Acetobacter methanolicus MB58 is discussed.Abbreviations ATP Adenosine-5-triphosphate - DCPIP 2,6-dichlorphenolindophenol - DW dry weight - ETP electron transport phosphorylation - FBP fructose-1,6-bisphosphate - MNNG N-methyl-N-nitro-N-nitrosoguanidine - PMS phenazine methosulfate - RuMP ribulose monophosphate - Ru5P ribulose-5-phosphate - SDS sodiumdodecylsulphate - TCA tricarboxylic acid - TYB toluylene blue Dedicated to Prof. Dr. Dr. S. M. Rapoport on occasion of his 75th birthday     

Oxidation of C1-compounds in Pseudomonas C

Extracts of Pseudomonas C grown on methanol as sole carbon and energy source contain a methanol dehydrogenase activity which can be coupled to phenazine methosulfate. This enzyme catalyzes two reactions namely the conversion of methanol to formaldehyde (phenazine methosulfate coupled) and the oxidation of formaldehyde to formate (2,6-dichloroindophenol-coupled). Activities of glutathione-dependent formaldehyde dehydrogenase (NAD⁺) and formate dehydrogenase (NAD⁺) were also detected in the extracts.The addition of d-ribulose 5-phosphate to the reaction mixtures caused a marked increase in the formaldehyde-dependent reduction of NAD⁺ or NADP⁺. In addition, the oxidation of [¹⁴C]formaldehyde to CO₂, by extracts of Pseudomonas C, increased when d-ribulose 5-phosphate was present in the assay mixtures.The amount of radioactivity found in CO₂, was 6.8-times higher when extracts of methanol-grown Pseudomona C were incubated for a short period of time with [1-¹⁴C]glucose 6-phosphate than with [U-¹⁴C]glucose 6-phosphate.These data, and the presence of high specific activities of hexulose phosphate synthase, phosphoglucoisomerase, glucose-6-phosphate dehydrogenase and 6-phosphogluconate dehydrogenase indicate that in methanol-grown Pseudomonas C, formaldehyde carbon is oxidized to CO₂ both via a cyclic pathway which includes the enzymes mentioned and via formate as an oxidation intermediate, with the former predominant.     

The molecular mechanism of menadione resistance in the <Emphasis Type="Italic">Synechocystis</Emphasis> sp. PCC 6803 cyanobacterium

The effect of mutations in the genes encoding dehydrogenases and oxidases on the resistance of the Synechocystis sp. PCC 6803 cyanobacterium to menadione, an oxidative stress inducer, was studied. An enhanced sensitivity to menadione was observed in the mutants carrying inserts in the drgA gene encoding the NAD(P)H:quinone oxidoreductase (NQR) and in the ndhB gene encoding the subunit of NDH-1 complex. The menadione resistance in the mutants lacking oxidases (Ox), succinate dehydrogenase (SDH), and NDH-2 dehydrogenase do not differ from those in wild-type cells. An additional mutation in the drgA gene increased the sensitivity to menadione in the NDH-2 and Ox mutants. The double mutant that lacks both SDH and NQR was not viable. The expression of the drgA gene decreased during cell incubation in the dark but increased in the presence of glucose both in the dark and in light. Under photoautotrophic growth conditions, the dehydrogenase activity of the cells mainly depends on the NQR and NDH-1 functions. The re-reduction rate of the photosystem I reaction center (P700⁺) increased in wild-type and NDH-1 mutants after its oxidation with white light in the presence of DCMU after addition of menadione, and it decreased in the NQR mutant. The reduction of P700⁺ was accelerated in the presence of menadiol in all the strains studied. These results suggest that NQR provides defense of cyanobacterium cells from the toxic effect of menadione via its two-electron reduction to menadiol. An increased sensitivity of the NDH-1 mutant to menadione may result from the inhibition of respiration and the cyclic electron transport in photosystem I.