Munenori Suzuki scite author profile

Triterpenoid saponins are a diverse group of specialized (secondary) metabolites with many biological properties. The model legume Medicago truncatula has an interesting profile of triterpenoid saponins from which sapogenins are differentiated into hemolytic and non-hemolytic types according to the position of their functional groups and hemolytic properties. Gene co-expression analysis confirmed the presence of candidate P450s whose gene expression correlated highly with that of β-amyrin synthase (bAS). Among these, we identified CYP716A12 and CYP93E2 as key enzymes in hemolytic and non-hemolytic sapogenin biosynthetic pathways. The other candidate P450s showed no β-amyrin oxidation activity. However, among the remaining candidate P450s, CYP72A61v2 expression highly correlated with that of CYP93E2, and CYP72A68v2 expression highly correlated with that of CYP716A12. These correlation values were higher than occurred with bAS expression. We generated yeast strains expressing bAS, CPR, CYP93E2 and CYP72A61v2, and bAS, CPR, CYP716A12 and CYP72A68v2. These transgenic yeast strains produced soyasapogenol B and gypsogenic acid, respectively. We were therefore able to identify two CYP72A subfamily enzymes: CYP72A61v2, which modifies 24-OH-β-amyrin, and CYP72A68v2, which modifies oleanolic acid. Additionally, P450s that seemed not to work together in planta were combinatorially expressed in transgenic yeast. The yeast strains (expressing bAS, CPR, CYP72A63 and CYP93E2 or CYP716A12) produced rare triterpenoids that do not occur in M. truncatula. These results show the potential for combinatorial synthesis of diverse triterpenoid structures and enable identification of the enzymes involved in their biosynthesis.

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Development of Capsicum EST–SSR markers for species identification and in silico mapping onto the tomato genome sequence

Shirasawa

Ishii

Kim

et al. 2012

Mol Breeding

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Capsicum spp. are widely cultivated for use as vegetables and spices. The Kihara Institute for Biological Research, Yokohama City University, Japan, has stocks of approximately 800 lines of Capsicum spp. collected from various regions of Central and South America, the regions of origin for Capsicum spp. In this study, 5,751 primer pairs for simple sequence repeat markers, based on 118,060 publicly available sequences of expressed sequence tags of Capsicum annuum, were designed and subjected to a similarity search against the genomic sequence of tomato, a model Solanaceae species. Nucleotide sequences spanning 2,245 C. annuum markers were successfully mapped onto the tomato genome, and 96 of these, which spanned the entire tomato genome, were selected for further analysis. In genotyping analysis, 60 out of the 77 markers that produced specific DNA amplicons showed polymorphism among the Capsicum lines examined. On the basis of the resulting data, the 192 tested lines were grouped into five main clusters. The additional sequencing analysis of the plastid genes, matK and rbcL, divided the resources into three groups. As a result, 19 marker loci exhibited genotypes specific to species and cluster, suggesting that the DNA markers are useful for species identification. Information on the DNA markers will contribute to Capsicum genetics, genomics, and breeding.Electronic supplementary materialThe online version of this article (doi:10.1007/s11032-012-9774-z) contains supplementary material, which is available to authorized users.

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Comparative functional analysis of CYP71AV1 natural variants reveals an important residue for the successive oxidation of amorpha‐4,11‐diene

et al. 2012

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a b s t r a c tArtemisinin is an antimalarial sesquiterpenoid isolated from the aerial parts of the plant Artemisia annua. CYP71AV1, a cytochrome P450 monooxygenase was identified in the artemisinin biosynthetic pathway. CYP71AV1 catalyzes three successive oxidation steps at the C12 position of amorpha-4,11-diene to produce artemisinic acid. In this study, we isolated putative CYP71AV1 orthologs in different species of Artemisia. Comparative functional analysis of CYP71AV1 and its putative orthologs, together with homology modeling, enabled us to identify an amino acid residue (Ser479) critical for the second oxidation reaction catalyzed by CYP71AV1. Our results clearly show that a comparative study of natural variants is useful to investigate the structure-function relationships of CYP71AV1.

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Functional Analysis of Amorpha-4,11-Diene Synthase (ADS) Homologs from Non-Artemisinin-ProducingArtemisiaSpecies: The Discovery of Novel Koidzumiol and (+)-α-Bisabolol Synthases

et al. 2016

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The production of artemisinin, the most effective antimalarial compound, is limited to Artemisia annua. Enzymes involved in artemisinin biosynthesis include amorpha-4,11-diene synthase (ADS), amorpha-4,11-diene 12-monooxygenase (CYP71AV1) and artemisinic aldehyde Δ(11)13 reductase (DBR2). Although artemisinin and its specific intermediates are not detected in other Artemisia species, we reported previously that CYP71AV1 and DBR2 homologs were expressed in some non-artemisinin-producing Artemisia plants. These homologous enzymes showed similar functions to their counterparts in A. annua and can convert fed intermediates into the following products along the artemisinin biosynthesis in planta These findings suggested a partial artemisinin-producing ability in those species. In this study, we examined genes highly homologous to ADS, the first committed gene in the pathway, in 13 Artemisia species. We detected ADS homologs in A. absinthium, A. kurramensis and A. maritima. We analyzed the enzymatic functions of all of the ADS homologs after obtaining their cDNA. We found that the ADS homolog from A. absinthium exhibited novel activity in the cyclization of farnesyl pyrophosphate (FPP) to koidzumiol, a rare natural sesquiterpenoid. Those from A. kurramensis and A. maritima showed similar, but novel, activities in the cyclization of FPP to (+)-α-bisabolol. The unique functions of the novel sesquiterpene synthases highly homologous to ADS found in this study could provide insight into the molecular basis of the exceptional artemisinin-producing ability in A. annua.

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Identification and characterization of (+)-α-bisabolol and 7-epi-silphiperfol-5-ene synthases from Artemisia abrotanum

et al. 2019

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Functional analysis of orthologous artemisinic aldehyde Δ11(13)-reductase reveals potential artemisinin-producing activity in non-artemisinin-producing <i>Artemisia absinthium</i>

Muangphrom

Suzuki

Seki

et al. 2014

Plant Biotechnology

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Artemisinin is the most effective antimalarial compound isolated from Artemisia annua. Artemisinic aldehyde Δ11(13)-reductase (DBR2) catalyzes the reduction of artemisinic aldehyde into dihydroartemisinic aldehyde, switching the pathway towards artemisinin production. Although other Artemisia species cannot produce artemisinin, we found a putative DBR2 ortholog expressed in A. absinthium (abDBR2). We examined the catalytic activity of abDBR2 in vitro and found that it shows comparable activity to that of DBR2 based on the reduction of artemisinic aldehyde into dihydroartemisinic aldehyde. Furthermore, we found that dihydroartemisinic aldehyde was detected in the extract of A. absinthium leaves fed with artemisinic aldehyde, suggesting the presence of active abDBR2 in planta. Our results indicate that A. absinthium may be a potential host for the production of artemisinin through metabolic engineering.

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Enzyme modification using mutation site prediction method for enhancing the regioselectivity of substrate reaction sites

Ikebe

Suzuki²,

Komori³

et al. 2021

Sci Rep

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Enzymes with low regioselectivity of substrate reaction sites may produce multiple products from a single substrate. When a target product is produced industrially using these enzymes, the production of non-target products (byproducts) causes adverse effects such as increased processing costs for purification and the amount of raw material. Thus it is required the development of modified enzymes to reduce the amount of byproducts’ production. In this paper, we report a method called mutation site prediction for enhancing the regioselectivity of substrate reaction sites (MSPER). MSPER takes conformational data for docking poses of an enzyme and a substrate as input and automatically generates a ranked list of mutation sites to destabilize docking poses for byproducts while maintaining those for target products in silico. We applied MSPER to the enzyme cytochrome P450 CYP102A1 (BM3) and the two substrates to enhance the regioselectivity for four target products with different reaction sites. The 13 of the total 14 top-ranked mutation sites predicted by MSPER for the four target products succeeded in selectively enhancing the regioselectivity up to 6.4-fold. The results indicate that MSPER can distinguish differences of substrate structures and the reaction sites, and can accurately predict mutation sites to enhance regioselectivity without selection by directed evolution screening.

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Dihydrocoronatine, Promising Candidate for a Chemical Probe to Study Coronatine-, Jasmonoid- and Octadecanoid-binding Protein

Suzuki

Hasegawa

Kodama

et al. 2004

Bioscience, Biotechnology, and Biochemistry

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Coronatine (1), its synthetic analogs (6-13) and jasmonic acid induced various volatiles in rice leaves. In the range of 0.01-0.1 mM, dihydrocoronatine (7) exhibited 4-687 times higher activity for linalool emission than that of 1. The radioactive derivative of 7, [4,5-3H]-7, was employed to identify the putative coronatine-binding protein in rice leaves. 7 would be a promising candidate for a chemical probe to study cornatine-binding protein related to the jasmonoid and octadecanoid signaling pathway in higher plants. A detailed study of coronatine-binding protein in rice leaves and cell culture with [4,5-3H]-7 is now in progress.

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Munenori Suzuki

Combinatorial Biosynthesis of Legume Natural and Rare Triterpenoids in Engineered Yeast

Development of Capsicum EST–SSR markers for species identification and in silico mapping onto the tomato genome sequence

Comparative functional analysis of CYP71AV1 natural variants reveals an important residue for the successive oxidation of amorpha‐4,11‐diene

Functional Analysis of Amorpha-4,11-Diene Synthase (ADS) Homologs from Non-Artemisinin-ProducingArtemisiaSpecies: The Discovery of Novel Koidzumiol and (+)-α-Bisabolol Synthases

Identification and characterization of (+)-α-bisabolol and 7-epi-silphiperfol-5-ene synthases from Artemisia abrotanum

Functional analysis of orthologous artemisinic aldehyde Δ11(13)-reductase reveals potential artemisinin-producing activity in non-artemisinin-producing <i>Artemisia absinthium</i>

Enzyme modification using mutation site prediction method for enhancing the regioselectivity of substrate reaction sites

Dihydrocoronatine, Promising Candidate for a Chemical Probe to Study Coronatine-, Jasmonoid- and Octadecanoid-binding Protein

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Munenori Suzuki

Combinatorial Biosynthesis of Legume Natural and Rare Triterpenoids in Engineered Yeast

Development of Capsicum EST–SSR markers for species identification and in silico mapping onto the tomato genome sequence

Comparative functional analysis of CYP71AV1 natural variants reveals an important residue for the successive oxidation of amorpha‐4,11‐diene

Functional Analysis of Amorpha-4,11-Diene Synthase (ADS) Homologs from Non-Artemisinin-ProducingArtemisiaSpecies: The Discovery of Novel Koidzumiol and (+)-α-Bisabolol Synthases

Identification and characterization of (+)-α-bisabolol and 7-epi-silphiperfol-5-ene synthases from Artemisia abrotanum

Functional analysis of orthologous artemisinic aldehyde &#916;11(13)-reductase reveals potential artemisinin-producing activity in non-artemisinin-producing <i>Artemisia absinthium</i>

Enzyme modification using mutation site prediction method for enhancing the regioselectivity of substrate reaction sites

Dihydrocoronatine, Promising Candidate for a Chemical Probe to Study Coronatine-, Jasmonoid- and Octadecanoid-binding Protein

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Product

Resources

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Functional analysis of orthologous artemisinic aldehyde Δ11(13)-reductase reveals potential artemisinin-producing activity in non-artemisinin-producing <i>Artemisia absinthium</i>