Yoshihiko Akakabe scite author profile

Plants receive volatile compounds emitted by neighboring plants that are infested by herbivores, and consequently the receiver plants begin to defend against forthcoming herbivory. However, to date, how plants receive volatiles and, consequently, how they fortify their defenses, is largely unknown. In this study, we found that undamaged tomato plants exposed to volatiles emitted by conspecifics infested with common cutworms (exposed plants) became more defensive against the larvae than those exposed to volatiles from uninfested conspecifics (control plants) in a constant airflow system under laboratory conditions. Comprehensive metabolite analyses showed that only the amount of (Z)-3-hexenylvicianoside (HexVic) was higher in exposed than control plants. This compound negatively affected the performance of common cutworms when added to an artificial diet. The aglycon of HexVic, (Z)-3-hexenol, was obtained from neighboring infested plants via the air. The amount of jasmonates (JAs) was not higher in exposed plants, and HexVic biosynthesis was independent of JA signaling. The use of (Z)-3-hexenol from neighboring damaged conspecifics for HexVic biosynthesis in exposed plants was also observed in an experimental field, indicating that (Z)-3-hexenol intake occurred even under fluctuating environmental conditions. Specific use of airborne (Z)-3-hexenol to form HexVic in undamaged tomato plants reveals a previously unidentified mechanism of plant defense.plant-plant signaling | herbivore-infested plant volatiles | green leaf volatiles | defense induction | glycosylation I n response to herbivory, plants emit specific blends of volatiles (1). When undamaged plants are exposed to volatiles from neighboring herbivore-infested plants, they begin to defend against the impending infestation of herbivores (2, 3). This socalled "plant-plant signaling" has been reported in several plant species (4). For example, a study on the expression profiles of defense-related genes when Arabidopsis was exposed to several volatiles, including green leaf volatiles and a monoterpene, showed that the manner of induction varied with the gene monitored or the volatile used, suggesting that the plant responses were specific to the individual volatile compound (5). Kost and Heil (6) reported that the secretion of extrafloral nectar (an alternative food for carnivores) in undamaged lima bean plants was enhanced by volatiles from infested conspecific plants; this reaction was specific to (Z)-3-hexenyl acetate. Recently, Kikuta et al. (7) showed that wound-induced volatile organic compounds from Chrysanthemum cinerariaefolium induced the biosynthesis of pyrethrins in volatile-exposed neighboring plants. In this plant-plant signaling system, a blend of five compounds at specific concentrations was essential for the pyrethrin biosynthesis in receiver plants.These previous studies on plant-plant signaling raise questions about how different airborne volatiles are received by undamaged neighboring plants. Tamogami et al. (8) reported that airborne (E)...

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Catalytic Properties of Rice α-Oxygenase

Koeduka

Matsui

Akakabe

et al. 2002

Journal of Biological Chemistry

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Long-chain fatty acids can be metabolized to C n؊1 aldehydes by ␣-oxidation in plants. The reaction mechanism of the enzyme has not been elucidated. In this study, a complete nucleotide sequence of fatty acid ␣-oxygenase gene in rice plants (Oryza sativa) was isolated. The deduced amino acid sequence showed some similarity with those of mammalian prostaglandin H synthases (PGHSs). The gene was expressed in Escherichia coli and purified to apparently homogenous state. It showed the highest activity with linoleic acid and predominantly formed 2-hydroperoxide of the fatty acid (C n ), which is then spontaneously decarboxylated to form corresponding C n؊1 aldehyde. With linoleic or linoleic acids as a substrate, rice ␣-oxygenase formed no product having a max at approximately 234 nm, which indicated that the enzyme could not oxygenize the pentadiene system in the substrate. The spectroscopic feature of the purified enzyme in its ferrous state is similar to that of mammalian PGHS, whereas that of dithionite-reduced state showed significant difference. Site-directed mutagenesis revealed that His-158, Tyr-380, and Ser-558 were essential for the ␣-oxygenase activity. These residues are conserved in PGHS and known as a heme ligand, a source of a radical species to initiate oxygenation reaction and a residue involved in substrate binding, respectively. This finding suggested that the initial step of the oxygenation reaction in ␣-oxygenase has a high similarity with that of PGHS. The rice ␣-oxygenase activity was inhibited by imidazole but hardly inhibited by nonsteroidal anti-inflammatory drugs, such as aspirin, ibuprofen, and flurbiprofen, which are known as typical PGHS inhibitors. In addition, peroxidase activity could not be detected with ␣-oxygenase when palmitic acid 2-hydroperoxide was used as a substrate. From these findings, the catalytic resemblance between ␣-oxygenase and PGHS seems to be evident, although there still are differences in their substrate recognitions and peroxidation activities.

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Rice fatty acid -dioxygenase is induced by pathogen attack and heavy metal stress: activation through jasmonate signaling

Koeduka

Matsui

Hasegawa

et al. 2005

Journal of Plant Physiology

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Glycosyltransferase MDR1 assembles a dividing ring for mitochondrial proliferation comprising polyglucan nanofilaments

Yoshida

Kuroiwa

Shimada

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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Mitochondria, which evolved from a free-living bacterial ancestor, contain their own genomes and genetic systems and are produced from preexisting mitochondria by binary division. The mitochondrion-dividing (MD) ring is the main skeletal structure of the mitochondrial division machinery. However, the assembly mechanism and molecular identity of the MD ring are unknown. Multi-omics analysis of isolated mitochondrial division machinery from the unicellular alga revealed an uncharacterized glycosyltransferase, MITOCHONDRION-DIVIDING RING1 (MDR1), which is specifically expressed during mitochondrial division and forms a single ring at the mitochondrial division site. Nanoscale imaging using immunoelectron microscopy and componential analysis demonstrated that MDR1 is involved in MD ring formation and that the MD ring filaments are composed of glycosylated MDR1 and polymeric glucose nanofilaments. Down-regulation of strongly interrupted mitochondrial division and obstructed MD ring assembly. Taken together, our results suggest that MDR1 mediates the synthesis of polyglucan nanofilaments that assemble to form the MD ring. Given that a homolog of MDR1 performs similar functions in chloroplast division, the establishment of MDR1 family proteins appears to have been a singular, crucial event for the emergence of endosymbiotic organelles.

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Linoleic Acid 10-Hydroperoxide as an Intermediate during Formation of 1-Octen-3-ol from Linoleic Acid inLentinus decadetes

Matsui

Sasahara

Akakabe

et al. 2003

Bioscience, Biotechnology, and Biochemistry

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In order to confirm the biosynthetic pathway to 1-octen-3-ol from linoleic acid, a crude enzyme solution was prepared from the edible mushroom, Lentinus decadetes. When the reaction was performed in the presence of glutathione peroxidase, which can reduce organic hydroperoxide to the corresponding hydroxide, the amount of 1-octen-3-ol formed from linoleic acid was decreased. At the same time, an accumulation of linoleic acid 10-hydroxide could be detected. The 10-hydroperoxide therefore seems to be an intermediate on the biosynthetic pathway.

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Enantioselective α-hydroperoxylation of long-chain fatty acids with crude enzyme of marine green alga Ulva pertusa

Akakabe

Matsui

Kajiwara

1999

Tetrahedron Letters

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Hydroperoxy-arachidonic acid mediated n-hexanal and (Z)-3- and (E)-2-nonenal formation in Laminaria angustata

et al. 2003

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Volatile Organic Compounds with Characteristic Odor in Bamboo Vinegar

Akakabe

Tamura

Iwamoto

et al. 2006

Bioscience, Biotechnology, and Biochemistry

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Bamboo vinegar solutions had pHs of 2.5 to 2.8, and the amounts of organic constituents were estimated to be 2.3 to 4.6% (w/w). Volatile organic compounds (28 components) were detected by GC-MS, and among of these, 11 compounds were common to three samples of bamboo vinegar. Perhaps acetic acid, 3-methyl-1,2-cyclohexadione, guaiacol, p-cresol, and syringol contributed to the characteristic odors (sour, smoky, and medicinal note) in bamboo vinegar.

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