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(+)-carvone + NADH + H+
(1R,4S)-isodihydrocarvone + NAD+
Substrates: -
Products: plus about 20% of (1S,4S)-dihydrocarvone
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2-cyclohexen-1-one + NADH + H+
cyclohexanone + NAD+
Substrates: -
Products: -
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2E-nonenal + NADH + H+
nonanal + NAD+
Substrates: about 12% of the activity with artemisinic aldehyde
Products: -
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3beta-hydroxycostunolide + NADPH + H+
3beta-hydroxy-dihydroparthenolide + NADP+
Substrates: -
Products: -
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artemisinic aldehyde + NADH + H+
(11R)-dihydroartemisinic aldehyde + NAD+
Substrates: -
Products: -
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artemisinic aldehyde + NADPH + H+
(11R)-dihydroartemisinic aldehyde + NADP+
artemisinic aldehyde + NADPH + H+
dihydroartemisinic aldehyde + NADP+
Substrates: -
Products: -
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costunolide + NADPH + H+
dihydrocostunolide + NADP+
Substrates: -
Products: -
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parthenolide + NADPH + H+
dihydroparthenolide + NADP+
Substrates: good substrate
Products: -
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additional information
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artemisinic aldehyde + NADPH + H+
(11R)-dihydroartemisinic aldehyde + NADP+
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Substrates: -
Products: -
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artemisinic aldehyde + NADPH + H+
(11R)-dihydroartemisinic aldehyde + NADP+
Substrates: -
Products: -
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artemisinic aldehyde + NADPH + H+
(11R)-dihydroartemisinic aldehyde + NADP+
Substrates: double bond reductase 2 (DBR2) reduces the DELTA11(13) double bond of artemisinic aldehyde
Products: -
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additional information
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Substrates: no substrate: arteannuin B, artemisinic acid, artemisinic alcohol, artemisitene, coniferyl aldehyde, (2E)-nonenal, alpha-pinene, (+)-pulegone, and sabinone
Products: -
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additional information
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Substrates: no substrate: arteannuin B, artemisinic acid, artemisinic alcohol, artemisitene, coniferyl aldehyde, (2E)-nonenal, alpha-pinene, (+)-pulegone, and sabinone
Products: -
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additional information
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Substrates: GC-MS analysis of dihydroartemisinic acid synthesized in different plant varieties, overview
Products: -
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additional information
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Substrates: LC-MS/MS analysis of dihydroartemisinic acid synthesized in plants
Products: -
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additional information
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Substrates: the conversion of dihydroartemisinic acid to artemisinin is a non-enzymatic photochemical oxidation process
Products: -
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additional information
heterologous expression of Artemisia annua amorphadiene synthase and CYP71AV1, the cytochrome P450 responsible for oxidation of amorphadiene, in tobacco lead to the accumulation of amorphadiene and artemisinic alcohol, but not artemisinic acid, in leaf. Additional expression of artemisinic aldehyde DELTA11(13) double-bond reductase with or without aldehyde dehydrogenase 1 leads to the additional accumulation dihydroartemisinic alcohol
additional information
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heterologous expression of Artemisia annua amorphadiene synthase and CYP71AV1, the cytochrome P450 responsible for oxidation of amorphadiene, in tobacco lead to the accumulation of amorphadiene and artemisinic alcohol, but not artemisinic acid, in leaf. Additional expression of artemisinic aldehyde DELTA11(13) double-bond reductase with or without aldehyde dehydrogenase 1 leads to the additional accumulation dihydroartemisinic alcohol
additional information
branch pathway blocking in Artemisia annua is a useful method for obtaining high yield artemisinin. In anti-squalene synthase (SQS) transgenic plants, the transcription levels of beta-caryophyllene synthase (CPS), beta-farnesene synthase (BFS), germacrene A synthase (GAS), amorpha-4,11-diene synthase (ADS), amorphadiene 12-hydroxylase (CYP71AV1) and aldehyde dehydrogenase 1 (ALDH1) all increase. Contents of artemisinin and dihydroartemisinic acid are enhanced by 71% and 223%, respectively, while beta-farnesene is raised to 123% compared to control. The mRNA level of artemisinic aldehyde DELTA11(13) reductase (DBR2) does negligibly change in almost all transgenic plants, overview
additional information
the yield of artemisinin from Artemisia annua is relatively low when cultivated under Indian climatic conditions. Artemisinin biosynthesized at clinically meaningful levels in Nicotiana tabacum by engineering two metabolic pathways targeted to three different cellular compartments (chloroplast, nucleus, and mitochondria). The doubly transgenic lines show a 3fold enhancement of isopentenyl diphosphate, and targeting AACPR, DBR2, and CYP71AV1 to chloroplasts results in higher expression and an efficient photooxidation of dihydroartemisinic acid to artemisinin. Partially purified extracts from the leaves of transgenic Nicotiana tabacum plants inhibit in vitro growth progression of Plasmodium falciparum-infected red blood cells, parasitemia is observed in mice fed with pure artemisinin as well as those fed with the wild-type plant extract, Plasmodium berghei murine malaria model. Artemisinin biosynthesis by sequential metabolic engineering of chloroplast and nuclear genomes, overview
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expression levels of farnesyl diphosphate synthase (FPS), cytochrome P450-dependent hydroxylase CYP71AV1, and double bond reductase 2 (DBR2) are increased significantly in plants overexpressing Artemisia annua allene oxide cyclase, AaAOC. The product of AOC is jasmonate, that induces the expression of FPS, CYP71AV1, and DBR2
methyljasmonate does not induce significant changes in the expression of DBR2
the enzyme DBR2 is induced by 0.12 mmol/l of cadmium. Appropriate doses of cadmium can increase the concentrations of artemisinic metabolites at a certain time point by upregulating the relative expression levels of key enzyme genes involved in artemisinin biosynthesis, overview
three jasmonate-responsive transcription factors, ethylene response factor 1, ethylene response factor 2, and octadecanoidresponsive AP2/ERF, all transcriptionally activate the expression of artemisinin biosynthetic genes, such as amorpha-4,11-diene synthase (ADS), CYP71AV1, DBR2, and aldehyde dehydrogenase 1 (ALDH1). Cold stress indirectly activates the DBR2 expression by increasing the amount of jasmonate through upregulation of jasmonate biosynthetic genes (LOX1, LOX2, allene oxide cyclase [AOC], and jasmonate resistant 1 [JAR1]). Levels of artemisinin and related secondary metabolites, such as dihydroartemisinic acid, artemisinin B, and artemisinic acid, are increased in Artemisia annua under cold stress
treatment for 30 min and 4 h with miconazole induces about four- und fivefold upregulation of the DBR2 gene, respectively
YABBY5 significantly increases the activity of the promoter of the enzyme
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Zeng, Q.; Zeng, L.; Lu, W.; Feng, L.; Yang, R.; Qiu, F.
Enhanced artemisinin production from engineered yeast precursors upon biotransformation
Biocatal. Biotransform.
30
190-202
2012
Artemisia annua
-
brenda
Zhang, Y.; Teoh, K.H.; Reed, D.W.; Maes, L.; Goossens, A.; Olson, D.J.; Ross, A.R.; Covello, P.S.
The molecular cloning of artemisinic aldehyde DELTA11(13) reductase and its role in glandular trichome-dependent biosynthesis of artemisinin in Artemisia annua
J. Biol. Chem.
283
21501-21508
2008
Artemisia annua (C5H429), Artemisia annua
brenda
Caretto, S.; Quarta, A.; Durante, M.; Nisi, R.; De Paolis, A.; Blando, F.; Mita, G.
Methyl jasmonate and miconazole differently affect arteminisin production and gene expression in Artemisia annua suspension cultures
Plant Biol.
13
51-58
2011
Artemisia annua (C5H429)
brenda
Zhang, Y.; Nowak, G.; Reed, D.W.; Covello, P.S.
The production of artemisinin precursors in tobacco
Plant Biotechnol. J.
9
445-454
2011
Artemisia annua (C5H429), Artemisia annua
brenda
Bertea, C.; Freije, J.; Van Der Woude, H.; Verstappen, F.; Perk, L.; Marquez, V.; De Kraker, J.; Posthumus, M.; Jansen, B.; De Groot, A.; Franssen, M.; Bouwmeester, H.
Identification of intermediates and enzymes involved in the early steps of artemisinin biosynthesis in Artemisia annua
Planta Med.
71
40-47
2005
Artemisia annua
brenda
Yuan, Y.; Liu, W.; Zhang, Q.; Xiang, L.; Liu, X.; Chen, M.; Lin, Z.; Wang, Q.; Liao, Z.
Overexpression of artemisinic aldehyde DELTA11(13) reductase gene - enhanced artemisinin and its relative metabolite biosynthesis in transgenic Artemisia annua L
Biotechnol. Appl. Biochem.
62
17-23
2015
Artemisia annua (C5H429)
brenda
Liu, W.; Wang, H.; Chen, Y.; Zhu, S.; Chen, M.; Lan, X.; Chen, G.; Liao, Z.
Cold stress improves the production of artemisinin depending on the increase in endogenous jasmonate
Biotechnol. Appl. Biochem.
64
305-314
2016
Artemisia annua (C5H429)
brenda
Zhou, L.; Yang, G.; Sun, H.; Tang, J.; Yang, J.; Wang, Y.; Garran, T.A.; Guo, L.
Effects of different doses of cadmium on secondary metabolites and gene expression in Artemisia annua L
Front. Med.
11
137-146
2017
Artemisia annua (C5H429)
brenda
Malhotra, K.; Subramaniyan, M.; Rawat, K.; Kalamuddin, M.; Qureshi, M.I.; Malhotra, P.; Mohmmed, A.; Cornish, K.; Daniell, H.; Kumar, S.
Compartmentalized metabolic engineering for artemisinin biosynthesis and effective malaria treatment by oral delivery of plant cells
Mol. Plant
9
1464-1477
2016
Artemisia annua (C5H429)
brenda
Lv, Z.; Zhang, F.; Pan, Q.; Fu, X.; Jiang, W.; Shen, Q.; Yan, T.; Shi, P.; Lu, X.; Sun, X.; Tang, K.
Branch pathway blocking in Artemisia annua is a useful method for obtaining high yield artemisinin
Plant Cell Physiol.
57
588-602
2016
Artemisia annua (C5H429)
brenda
Yang, K.; Monfared, S.R.; Monafared, R.S.; Wang, H.; Lundgren, A.; Brodelius, P.E.
The activity of the artemisinic aldehyde ?11(13) reductase promoter is important for artemisinin yield in different chemotypes of Artemisia annua L.
Plant Mol. Biol.
88
325-340
2015
Artemisia annua (C5H429)
brenda
Lu, X.; Zhang, F.; Shen, Q.; Jiang, W.; Pan, Q.; Lv, Z.; Yan, T.; Fu, X.; Wang, Y.; Qian, H.; Tang, K.
Overexpression of allene oxide cyclase improves the biosynthesis of artemisinin in Artemisia annua L.
PLoS ONE
9
e91741
2014
Artemisia annua (C5H429)
brenda
Kayani, S.I.; Shen, Q.; Ma, Y.; Fu, X.; Xie, L.; Zhong, Y.; Tiantian, C.; Pan, Q.; Li, L.; Rahman, S.U.; Sun, X.; Tang, K.
The YABBY family transcription factor AaYABBY5 directly targets cytochrome P450 monooxygenase (CYP71AV1) and double-bond reductase 2 (DBR2) involved in artemisinin biosynthesis in Artemisia annua
Front. Plant Sci.
10
1084
2019
Artemisia annua
brenda
Beyraghdar Kashkooli, A.; van der Krol, A.; Rabe, P.; Dickschat, J.; Bouwmeester, H.
Substrate promiscuity of enzymes from the sesquiterpene biosynthetic pathways from Artemisia annua and Tanacetum parthenium allows for novel combinatorial sesquiterpene production
Metab. Eng.
54
12-23
2019
Artemisia annua (C5H429)
brenda