Characterization of Glycerol Trinitrate Reductase (NerA) and the Catalytic Role of Active-Site Residues

Marshall, Samantha J.; Krause, Doreen; Blencowe, Dayle K.; White, Graham F.

doi:10.1128/jb.186.6.1802-1810.2004

Cited by 19 publications

(15 citation statements)

References 27 publications

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“…Because all nitrogen was accounted for throughout, we conclude that the only nitrogen-containing intermediate compounds are 1,2DNG and 1MNG, which is consistent with previous studies (6,9,20). The fact that most of the nitrogen was released as nitrite is consistent with previous reports of denitration catalyzed by reductase enzymes (4,8,21). The minor amounts of nitrate observed could be from abiotic hydrolysis (5,12) or from oxidation of nitrite.…”

supporting

confidence: 79%

“…Pure cultures capable of completely denitrating NG as a source of nitrogen when provided additional sources of carbon include Bacillus thuringiensis/cereus and Enterobacter agglomerans (11) and a Rhodococcus species (8,9). Cultures capable of incomplete denitration to MNG in the presence of additional carbon sources were identified as Pseudomonas putida, Pseudomonas fluorescens (4), an Arthobacter species, a Klebsiella species (8,9), and Agrobacterium radiobacter (20).…”

mentioning

confidence: 99%

“…The use of NG as a source of nitrogen has been studied in mixed and pure cultures during growth on alternative sources of carbon and energy (3,9,11,20). Under such conditions, NG undergoes a sequential denitration pathway in which NG is transformed to 1,2-dinitroglycerin (1,2DNG) or 1,3DNG followed by 1-mononitroglycerin (1MNG) or 2MNG and then glycerol, under both aerobic and anaerobic conditions (3,6,9,11,20), and the enzymes involved in denitration have been characterized in some detail (4,8,15,21). Pure cultures capable of completely denitrating NG as a source of nitrogen when provided additional sources of carbon include Bacillus thuringiensis/cereus and Enterobacter agglomerans (11) and a Rhodococcus species (8,9).…”

mentioning

confidence: 99%

“…Under such conditions, NG undergoes a sequential denitration pathway in which NG is transformed to 1,2-dinitroglycerin (1,2DNG) or 1,3DNG followed by 1-mononitroglycerin (1MNG) or 2MNG and then glycerol, under both aerobic and anaerobic conditions (3,6,9,11,20), and the enzymes involved in denitration have been characterized in some detail (4,8,15,21). Pure cultures capable of completely denitrating NG as a source of nitrogen when provided additional sources of carbon include Bacillus thuringiensis/cereus and Enterobacter agglomerans (11) and a Rhodococcus species (8,9). Cultures capable of incomplete denitration to MNG in the presence of additional carbon sources were identified as Pseudomonas putida, Pseudomonas fluorescens (4), an Arthobacter species, a Klebsiella species (8,9), and Agrobacterium radiobacter (20).…”

mentioning

confidence: 99%

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Growth of Arthrobacter sp. Strain JBH1 on Nitroglycerin as the Sole Source of Carbon and Nitrogen

Husserl

Spain²,

Hughes

2010

Appl Environ Microbiol

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Arthrobacter sp. strain JBH1 was isolated from nitroglycerin-contaminated soil by selective enrichment. Detection of transient intermediates and simultaneous adaptation studies with potential intermediates indicated that the degradation pathway involves the conversion of nitroglycerin to glycerol via 1,2-dinitroglycerin and 1-mononitroglycerin, with concomitant release of nitrite. Glycerol then serves as the source of carbon and energy.Nitroglycerin (NG) is manufactured widely for use as an explosive and a pharmaceutical vasodilator. It has been found as a contaminant in soil and groundwater (7,9). Due to NG's health effects as well as its highly explosive nature, NG contamination in soils and groundwater poses a concern that requires remedial action (3). Natural attenuation and in situ bioremediation have been used for remediation in soils contaminated with certain other explosives (16), but the mineralization of NG in soil and groundwater has not been reported.To date, no pure cultures able to grow on NG as the sole carbon, energy, and nitrogen source have been isolated. Accashian et al.(1) observed growth associated with the degradation of NG under aerobic conditions by a mixed culture originating from activated sludge. The use of NG as a source of nitrogen has been studied in mixed and pure cultures during growth on alternative sources of carbon and energy (3,9,11,20). Under such conditions, NG undergoes a sequential denitration pathway in which NG is transformed to 1,2-dinitroglycerin (1,2DNG) or 1,3DNG followed by 1-mononitroglycerin (1MNG) or 2MNG and then glycerol, under both aerobic and anaerobic conditions (3,6,9,11,20), and the enzymes involved in denitration have been characterized in some detail (4,8,15,21). Pure cultures capable of completely denitrating NG as a source of nitrogen when provided additional sources of carbon include Bacillus thuringiensis/cereus and Enterobacter agglomerans (11) and a Rhodococcus species (8, 9). Cultures capable of incomplete denitration to MNG in the presence of additional carbon sources were identified as Pseudomonas putida, Pseudomonas fluorescens (4), an Arthobacter species, a Klebsiella species (8, 9), and Agrobacterium radiobacter (20).Here we describe the isolation of bacteria able to degrade NG as the sole source of carbon, nitrogen, and energy. The inoculum for selective enrichment was soil historically contaminated with NG obtained at a facility that formerly manufactured explosives located in the northeastern United States. The enrichment medium consisted of minimal medium prepared as previously described (17) supplemented with NG (0.26 mM), which was synthesized as previously described (18). During enrichment, samples of the inoculum (optical density at 600 nm [OD 600 ] ϳ 0.03) were diluted 1/16 in fresh enrichment medium every 2 to 3 weeks. Isolates were obtained by dilution to extinction in NG-supplemented minimal medium. Cultures were grown under aerobic conditions in minimal medium at pH 7.2 and 23°C or in tryptic soy agar (TSA; 1/4 strength).Early st...

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supporting

confidence: 79%

mentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

See 2 more Smart Citations

Growth of Arthrobacter sp. Strain JBH1 on Nitroglycerin as the Sole Source of Carbon and Nitrogen

Husserl

Spain²,

Hughes

2010

Appl Environ Microbiol

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“…(14), and xenobiotic reductases (XenA and XenB) from Pseudomonas putida and Pseudomonas fluorescens (6). All of the enzymes are members of the old yellow enzyme (OYE) family (23, 33), require flavin mononucleotide (FMN), use NADPH as an electron donor, and catalyze the reductive elimination of nitrate ester groups from NG with concomitant release of nitrite (7,15,23,33). In all cases, both 1,2-and 1,3-DNG are produced, although selectivity for attack at either C1 or C2 has been observed in some cases (7,28).…”

mentioning

confidence: 99%

Key Enzymes Enabling the Growth of Arthrobacter sp. Strain JBH1 with Nitroglycerin as the Sole Source of Carbon and Nitrogen

Husserl¹,

Hughes²,

Spain³

2012

Appl Environ Microbiol

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ABSTRACTFlavoprotein reductases that catalyze the transformation of nitroglycerin (NG) to dinitro- or mononitroglycerols enable bacteria containing such enzymes to use NG as the nitrogen source. The inability to use the resulting mononitroglycerols limits most strains to incomplete denitration of NG. Recently,Arthrobacterstrain JBH1 was isolated for the ability to grow on NG as the sole source of carbon and nitrogen, but the enzymes and mechanisms involved were not established. Here, the enzymes that enable theArthrobacterstrain to incorporate NG into a productive pathway were identified. Enzyme assays indicated that the transformation of nitroglycerin to mononitroglycerol is NADPH dependent and that the subsequent transformation of mononitroglycerol is ATP dependent. Cloning and heterologous expression revealed that a flavoprotein catalyzes selective denitration of NG to 1-mononitroglycerol (1-MNG) and that 1-MNG is transformed to 1-nitro-3-phosphoglycerol by a glycerol kinase homolog. Phosphorylation of the nitroester intermediate enables the subsequent denitration of 1-MNG in a productive pathway that supports the growth of the isolate and mineralization of NG.

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Enzymes, Enolate Reductases “Old Yellow Enzyme”

Hall

Yanto

Bommarius

2010

Encyclopedia of Industrial Biotechnology

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Reported enoate reductase activity is mostly displayed by enzymes belonging to the “Old Yellow Enzyme” family of flavoproteins. They have received increased interest over the last couple of years due to their huge potential in biocatalysis. These FMN‐containing enzymes catalyze the asymmetric reduction of activated C═C bonds at the expense of a nicotinamide cofactor, producing up to two chiral centers. They are also involved in other reductive processes, such as cleavage of nitrate esters, reduction of aromatic nitro groups, and even reduction of alkynes. Increasing knowledge about this family of biocatalysts together with recent advances in biotechnology render the enoate reductases a tool of choice for industrial applications, as catalyzed reactions are usually chemo‐, regio‐ and stereo‐selective, and the enzymes most importantly display a wide substrate spectrum. With enzymatic reactions and mechanisms being generally clearly understood, the efficient production of a number of enantiopure compounds via recycling of the cofactor is now feasible.

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Characterization of Glycerol Trinitrate Reductase (NerA) and the Catalytic Role of Active-Site Residues

Cited by 19 publications

References 27 publications

Growth of Arthrobacter sp. Strain JBH1 on Nitroglycerin as the Sole Source of Carbon and Nitrogen

Growth of Arthrobacter sp. Strain JBH1 on Nitroglycerin as the Sole Source of Carbon and Nitrogen

Key Enzymes Enabling the Growth of Arthrobacter sp. Strain JBH1 with Nitroglycerin as the Sole Source of Carbon and Nitrogen

Enzymes, Enolate Reductases “Old Yellow Enzyme”

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