Finding New Enzymes from Bacterial Physiology: A Successful Approach Illustrated by the Detection of Novel Oxidases in Marinomonas mediterranea

The identification and study of marine microorganisms with unique physiological traits can be a very powerful tool discovering novel enzymes of possible biotechnological interest. This approach can complement the enormous amount of data concerning gene diversity in marine environments offered by metagenomic analysis, and can help to place the activities associated with those sequences in the context of microbial cellular metabolism and physiology. Accordingly, the detection and isolation of microorganisms that may be a good source of enzymes is of great importance. Marinomonas mediterranea, for example, has proven to be one such useful microorganism. This Gram-negative marine bacterium was first selected because of the unusually high amounts of melanins synthesized in media containing the amino acid l-tyrosine. The study of its molecular biology has allowed the cloning of several genes encoding oxidases of biotechnological interest, particularly in white and red biotechnology. Characterization of the operon encoding the tyrosinase responsible for melanin synthesis revealed that a second gene in that operon encodes a protein, PpoB2, which is involved in copper transfer to tyrosinase. This finding made PpoB2 the first protein in the COG5486 group to which a physiological role has been assigned. Another enzyme of interest described in M. mediterranea is a multicopper oxidase encoding a membrane-associated enzyme that shows oxidative activity on a wide range of substrates typical of both laccases and tyrosinases. Finally, an enzyme very specific for l-lysine, which oxidises this amino acid in epsilon position and that has received a new EC number (1.4.3.20), has also been described for M. mediterranea. Overall, the studies carried out on this bacterium illustrate the power of exploring the physiology of selected microorganisms to discover novel enzymes of biotechnological relevance

Caracterización de la marinocina, un compuesto con actividad antimicrobiana sintetizado por "marinomonas mediterranea" : mecanismos regulatorios comunes entre su síntesis y la expresión de actividades polifenol oxidasa / Patricia Lucas Elio ; dirección, Antonio Sánchez Amat , Francisco Solano Muñoz.

Tesis-Universidad de Murcia.Consulte la tesis en: BCA. GENERAL. ARCHIVO UNIVERSITARIO. T.M. 2561

The Antimicrobial Activity of Marinocine, Synthesized by Marinomonas mediterranea, Is Due to Hydrogen Peroxide Generated by Its Lysine Oxidase Activity

Marinocine is a broad-spectrum antibacterial protein synthesized by the melanogenic marine bacterium Marinomonas mediterranea. This work describes the basis for the antibacterial activity of marinocine and the identification of the gene coding for this protein. The antibacterial activity is inhibited under anaerobic conditions and by the presence of catalase under aerobic conditions. Marinocine is active only in culture media containing l-lysine. In the presence of this amino acid, marinocine generates hydrogen peroxide, which causes cell death as confirmed by the increased sensitivity to marinocine of Escherichia coli strains mutated in catalase activity. The gene coding for this novel enzyme was cloned using degenerate PCR with primers designed based on conserved regions in the antimicrobial protein AlpP, synthesized by Pseudoalteromonas tunicata, and some hypothetical proteins. The gene coding for marinocine has been named lodA, standing for lysine oxidase, and it seems to form part of an operon with a second gene, lodB, that codes for a putative dehydrogenase flavoprotein. The identity of marinocine as LodA has been demonstrated by N-terminal sequencing of purified marinocine and generation of lodA mutants that lose their antimicrobial activity. This is the first report on a bacterial lysine oxidase activity and the first time that a gene encoding this activity has been cloned

Distribution in Different Organisms of Amino Acid Oxidases with FAD or a Quinone As Cofactor and Their Role as Antimicrobial Proteins in Marine Bacteria

Amino acid oxidases (AAOs) catalyze the oxidative deamination of amino acids releasing ammonium and hydrogen peroxide. Several kinds of these enzymes have been reported. Depending on the amino acid isomer used as a substrate, it is possible to differentiate between l-amino acid oxidases and d-amino acid oxidases. Both use FAD as cofactor and oxidize the amino acid in the alpha position releasing the corresponding keto acid. Recently, a novel class of AAOs has been described that does not contain FAD as cofactor, but a quinone generated by post-translational modification of residues in the same protein. These proteins are named as LodA-like proteins, after the first member of this group described, LodA, a lysine epsilon oxidase synthesized by the marine bacterium Marinomonas mediterranea. In this review, a phylogenetic analysis of all the enzymes described with AAO activity has been performed. It is shown that it is possible to recognize different groups of these enzymes and those containing the quinone cofactor are clearly differentiated. In marine bacteria, particularly in the genus Pseudoalteromonas, most of the proteins described as antimicrobial because of their capacity to generate hydrogen peroxide belong to the group of LodA-like proteins

A novel type of lysine oxidase: l-lysine-ε-oxidase

The melanogenic marine bacterium M. mediterranea synthesizes marinocine, a protein with antibacterial activity. We cloned the gene coding for this protein and named it lodA [P. Lucas–Elío, P. Hernández, A. Sanchez-Amat, F. Solano, Purification and partial characterization of marinocine, a new broad-spectrum antibacterial protein produced by Marinomonas mediterranea. Biochim. Biophys. Acta 1721 (2005) 193–203; P. Lucas-Elío, D. Gómez, F. Solano, A. Sanchez-Amat, The antimicrobial activity of marinocine, synthesized by M. mediterranea, is due to the hydrogen peroxide generated by its lysine oxidase activity. J. Bacteriol. 188 (2006) 2493–2501]. Now, we show that this protein is a new type of lysine oxidase which catalyzes the oxidative deamination of free l-lysine into 6-semialdehyde 2-aminoadipic acid, ammonia and hydrogen peroxide. This new enzyme is compared to other enzymes related to lysine transformation. Two different groups have been used for comparison. Enzymes in the first group lead to 2-aminoadipic acid as a final product. The second one would be enzymes catalyzing the oxidative deamination of lysine releasing H2O2, namely lysine-α-oxidase (LαO) and lysyl oxidase (Lox). Kinetic properties, substrate specificity and inhibition pattern show clear differences with all above mentioned lysine-related enzymes. Thus, we propose to rename this enzyme lysine-ε-oxidase (lod for the gene) instead of marinocine. Lod shows high stereospecificity for free l-lysine, it is inhibited by substrate analogues, such as cadaverine and 6-aminocaproic acid, and also by β-aminopropionitrile, suggesting the existence of a tyrosine-derived quinone cofactor at its active site. Abbreviations AANaminoacetonitrileβAPNβ-aminopropionitrileLAOl-amino acid oxidaseLαOLysine-α-oxidaseLatLysine-ε-aminotransferaseLodMarinocine (Lysine-ε-oxidase)LoxLysyl oxidaseLTQLysyl-Tyrosyl-QuinoneSDHsaccharopine dehydrogenaseSSAOsemicarbazide sensitive amino oxidaseTDQCtyrosine-derived quinone cofactorsTLCThin layer chromatograph

Characterization Of Recombinant Biosynthetic Precursors Of The Cysteine Tryptophylquinone Cofactors Of L-Lysine-Epsilon-Oxidase And Glycine Oxidase From Marinomonas Mediterranea

Abstract The lysine-ε-oxidase, LodA, and glycine oxidase, GoxA, from Marinomonas mediteranea each possesses a cysteine tryptophylquinone (CTQ) cofactor. This cofactor is derived from posttranslational modifications which are covalent crosslinking of tryptophan and cysteine residues and incorporation of two oxygen atoms into the indole ring of Trp. In this manuscript, it is shown that the recombinant synthesis of LodA and GoxA containing a fully synthesized CTQ cofactor requires coexpression of a partner flavoprotein, LodB for LodA and GoxB for GoxA, which are not interchangeable. An inactive precursor of LodA or GoxA which contained a monohydroxylated Trp residue and no crosslink to the Cys was isolated from the soluble fraction when they were expressed alone. The structure of LodA revealed an Asp residue close to the cofactor which is conserved in quinohemoprotein amine dehydrogenase (QHNDH), containing CTQ, and methylamine dehydrogenase (MADH) containing tryptophan tryptophylquinone (TTQ) as cofactor. To study the role of this residue in the synthesis of the LodA precursor, Asp-512 was mutated to Ala. When the mutant protein was coexpressed with LodB an inactive protein was isolated which was soluble and contained no modifications at all, suggesting a role for this Asp in the initial LodB-independent hydroxylation of Trp. A similar role had been proposed for this conserved Asp residue in MADH. It is noteworthy that the formation of TTQ in MADH from the precursor also requires an accessory enzyme for its biosynthesis but it is a diheme enzyme MauG and not a flavoprotein. The results presented reveal novel mechanisms of post-translational modification involved in the generation of protein-derived cofactors. This article is part of a Special Issue entitled: Cofactor-dependent proteins: evolution, chemical diversity and bio-applications