Publications

• Cloning and characterization of a Nicotiana tabacum methylputrescine oxidase transcript.

  Heim W.G., Sykes K.A., Hildreth S.B., Sun J., Lu R.-H., Jelesko J.G.

  The oxidative deamination of N-methylputrescine is an essential step in both pyridine and tropane alkaloid biosynthesis. Reverse genetic approaches have not resulted in the cloning of a methylputrescine oxidase gene (MPO). However, we have used a homology-based approach to clone a full-length toba ... >> More

  The oxidative deamination of N-methylputrescine is an essential step in both pyridine and tropane alkaloid biosynthesis. Reverse genetic approaches have not resulted in the cloning of a methylputrescine oxidase gene (MPO). However, we have used a homology-based approach to clone a full-length tobacco MPO1 cDNA. The MPO1 gene is part of a small multigene family comprised of approximately six members. MPO1-like transcript levels increased in roots that were either deprived of auxin or treated with methyl jasmonic acid. Similar to other known nicotine biosynthetic genes in domesticated tobacco, MPO1-like mRNA levels were lower in roots with the mutant a and b alleles. The MPO1 protein was expressed in bacteria as a recombinant Thioredoxin-His(6)-MPO1 fusion protein. The recombinant MPO1 protein utilized N-methylputrescine more efficiently than other diamines. Therefore, the kinetic properties of the MPO1 enzyme may play an important role in determining the pyridine alkaloid profiles observed in tobacco roots. << Less

  Phytochemistry 68:454-463(2007) [PubMed] [EuropePMC]

• Molecular cloning of N-methylputrescine oxidase from tobacco.

  Katoh A., Shoji T., Hashimoto T.

  Nicotine biosynthesis in Nicotiana species requires an oxidative deamination of N-methylputrescine, catalyzed by N-methylputrescine oxidase (MPO). In a screen for tobacco genes that were down-regulated in a tobacco mutant with altered regulation of nicotine biosynthesis, we identified two homologo ... >> More

  Nicotine biosynthesis in Nicotiana species requires an oxidative deamination of N-methylputrescine, catalyzed by N-methylputrescine oxidase (MPO). In a screen for tobacco genes that were down-regulated in a tobacco mutant with altered regulation of nicotine biosynthesis, we identified two homologous MPO cDNAs which encode diamine oxidases of a particular subclass. Tobacco MPO genes were expressed specifically in the root, and up-regulated by jasmonate treatment. Recombinant MPO protein expressed in Escherichia coli formed a homodimer and deaminated N-methylputrescine more efficiently than symmetrical diamines. These results indicate that MPO evolved from general diamine oxidases to function effectively in nicotine biosynthesis. << Less

  Plant Cell Physiol. 48:550-554(2007) [PubMed] [EuropePMC]

• Molecular evolution of N-methylputrescine oxidase in tobacco.

  Naconsie M., Kato K., Shoji T., Hashimoto T.

  Biosynthesis of nicotine in tobacco requires N-methylputrescine oxidase (MPO), which belongs to the copper-containing amine oxidase superfamily. Previous studies identified tobacco MPO1 and its close homolog NtDAO1 (formerly called MPO2), of which MPO1 has been shown preferentially to oxidize N-me ... >> More

  Biosynthesis of nicotine in tobacco requires N-methylputrescine oxidase (MPO), which belongs to the copper-containing amine oxidase superfamily. Previous studies identified tobacco MPO1 and its close homolog NtDAO1 (formerly called MPO2), of which MPO1 has been shown preferentially to oxidize N-methylated amines. We show here that NtDAO1, as well as a homologous Arabidopsis diamine oxidase (DAO), accept non-N-methylated amines more efficiently than their corresponding N-methylated amines. MPO1 is coordinately regulated with other nicotine biosynthesis genes with regard to COI1-MYC2-dependent jasmonate induction and its dependence on nicotine-specific ERF transcription factors, whereas NtDAO1 is constitutively expressed at low basal levels in tobacco plants. Both MPO1 and NtDAO1 are targeted to peroxisomes by their C-terminal motifs, and the peroxisomal localization of MPO1 is required for it to function in nicotine biosynthesis in jasmonate-elicited cultured tobacco cells. Restricted occurrence of the MPO subfamily in Nicotiana and Solanum indicates that, during the formation of the Solanaceae, MPO has evolved from a DAO, which functions in polyamine catabolism within peroxisomes, by optimizing substrate preference and gene expression patterns to be suitable for alkaloid formation. << Less

  Plant Cell Physiol. 55:436-444(2014) [PubMed] [EuropePMC]