Masaru Niitsu scite author profile

Loss-of-function mutants of the ACAULIS5 (ACL5) gene in Arabidopsis thaliana have severe defects in stem elongation. ACL5 was previously reported as encoding a spermine synthase. A more recent study, however, showed that the bacterial expressed recombinant ACL5 protein catalyzes the conversion of spermidine to thermospermine, a structural isomer of spermine, rather than to spermine. In the present study, we found that thermospermine was detected in wild-type seedlings but was not detectable in the acl5-1 mutant. We further examined the effect of exogenous application of these isomers on the growth of acl5-1. Daily application of 0.1 mM thermospermine onto the shoot apex partially rescued the dwarf phenotype of acl5-1, while that of spermine had no effects on the morphology of the mutant. The acl5-1 transcript level in acl5-1 seedlings, which is much higher than the ACL5 transcript level in wild-type seedlings, was reduced by exogenous thermospermine. Thus we conclude that thermospermine is indeed produced through the action of ACL5 and required for stem elongation in Arabidopsis.

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Polyamine Oxidase5 Regulates Arabidopsis Growth through Thermospermine Oxidase Activity

Kim

Watanabe

Murayama

et al. 2014

134

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The major plant polyamines (PAs) are the tetraamines spermine (Spm) and thermospermine (T-Spm), the triamine spermidine, and the diamine putrescine. PA homeostasis is governed by the balance between biosynthesis and catabolism; the latter is catalyzed by polyamine oxidase (PAO). Arabidopsis (Arabidopsis thaliana) has five PAO genes, AtPAO1 to AtPAO5, and all encoded proteins have been biochemically characterized. All AtPAO enzymes function in the back-conversion of tetraamine to triamine and/or triamine to diamine, albeit with different PA specificities. Here, we demonstrate that AtPAO5 loss-of-function mutants (pao5) contain 2-fold higher T-Spm levels and exhibit delayed transition from vegetative to reproductive growth compared with that of wild-type plants. Although the wild type and pao5 are indistinguishable at the early seedling stage, externally supplied low-dose T-Spm, but not other PAs, inhibits aerial growth of pao5 mutants in a dose-dependent manner. Introduction of wild-type AtPAO5 into pao5 mutants rescues growth and reduces the T-Spm content, demonstrating that AtPAO5 is a T-Spm oxidase. Recombinant AtPAO5 catalyzes the conversion of T-Spm and Spm to triamine spermidine in vitro. AtPAO5 specificity for T-Spm in planta may be explained by coexpression with T-Spm synthase but not with Spm synthase. The pao5 mutant lacking T-Spm oxidation and the acl5 mutant lacking T-Spm synthesis both exhibit growth defects. This study indicates a crucial role for T-Spm in plant growth and development.Polyamines (PAs) are low-molecular mass aliphatic amines that are present in almost all living organisms. Cellular PA concentrations are governed primarily by the balance between biosynthesis and catabolism. In plants, the major PAs are the diamine putrescine (Put), the triamine spermidine (Spd), and the tetraamines spermine (Spm) and thermospermine (T-Spm; Kusano et al.,

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Constitutively and highly expressed Oryza sativa polyamine oxidases localize in peroxisomes and catalyze polyamine back conversion

et al. 2011

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Polyamine oxidases (PAOs) are FAD-dependent enzymes involved in polyamine (PA) catabolism. Recent studies have revealed that plant PAOs are not only active in the terminal catabolism of PAs as demonstrated for maize apoplastic PAO but also in a polyamine back-conversion pathway as shown for most Arabidopsis PAOs. We have characterized Oryza sativa PAOs at molecular and biochemical levels. The rice genome contains 7 PAO isoforms that are termed OsPAO1 to OsPAO7. Of the seven PAOs, OsPAO3, OsPAO4, and OsPAO5 transcripts were most abundant in 2-week-old seedlings and mature plants, while OsPAO1, OsPAO2, OsPAO6, and OsPAO7 were expressed at very low levels with different tissue specificities. The more abundantly expressed PAOs--OsPAO3, OsPAO4, and OsPAO5--were cloned, and their gene products were produced in Escherichia coli. The enzymatic activities of the purified OsPAO3 to OsPAO5 proteins were examined. OsPAO3 favored spermidine (Spd) as substrate followed by thermospermine (T-Spm) and spermine (Spm) and showed a full PA back-conversion activity. OsPAO4 substrate specificity was similar to that of OsPAO5 preferring Spm and T-Spm but not Spd. Those enzymes also converted Spm and T-Spm to Spd, again indicative of PA back-conversion activities. Lastly, we show that OsPAO3, OsPAO4, and OsPAO5 are localized in peroxisomes. Together, these data revealed that constitutively and highly expressed O. sativa PAOs are localized in peroxisomes and catalyze PA back-conversion processes.

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Acrolein toxicity: Comparison with reactive oxygen species

Yoshida¹,

Tomitori²,

Machi³

et al. 2009

Biochemical and Biophysical Research Communications

114

100

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Characterization of five polyamine oxidase isoforms in Arabidopsis thaliana

et al. 2010

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The genome of Arabidopsis thaliana contains five genes (AtPAO1 to AtPAO5) encoding polyamine oxidase (PAO) which is an enzyme responsible for polyamine catabolism. To understand the individual roles of the five AtPAOs, here we characterized their tissue-specific and space-temporal expression. AtPAO1 seems to have a specific function in flower organ. AtPAO2 was expressed in shoot meristem and root tip of seedlings, and to a higher extent in the later growth stage within restricted parts of the organs, such as shoot meristem, leaf petiole and also in anther. The expression of AtPAO3 was constitutive, but highest in flower organ. AtPAO3 promoter activity was detected in cotyledon, distal portion of root, boundary region of mature rosette leaf and in filaments of flower. AtPAO4 was expressed at higher level all over young seedlings including roots, and in the mature stage its expression was ubiquitous with rather lower level in stem. AtPAO5 expression was observed in the whole plant body throughout various growth stages. Its highest expression was in flowers, particularly in sepals, but not in petals. Furthermore, we determined the substrate specificity of AtPAO1 to AtPAO4. None of the AtPAO enzymes recognized putrescine (Put). AtPAO2 and AtPAO3 showed almost similar substrate recognition patterns in which the most preferable substrate is spermidine (Spd) followed by less specificity to other tetraamines tested. AtPAO4 seemed to be spermine (Spm)-specific. More interestingly, AtPAO1 preferred thermospermine (T-Spm) and norspermine (NorSpm) to Spm, but did not recognize Spd. Based on the results, the individual function of AtPAOs is discussed.

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Masaru Niitsu

Thermospermine is Required for Stem Elongation in Arabidopsis thaliana

Polyamine Oxidase5 Regulates Arabidopsis Growth through Thermospermine Oxidase Activity

Constitutively and highly expressed Oryza sativa polyamine oxidases localize in peroxisomes and catalyze polyamine back conversion

Acrolein toxicity: Comparison with reactive oxygen species

Characterization of five polyamine oxidase isoforms in Arabidopsis thaliana

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