Metabolic, Genomic, and Biochemical Analyses of Glandular Trichomes from the Wild Tomato Species<i>Lycopersicon hirsutum</i>Identify a Key Enzyme in the Biosynthesis of Methylketones

Fridman, Eyal; Wang, Jihong; Iijima, Yoko; Froehlich, John E.; Gang, David R.; Ohlrogge, John B.; Pichersky, Eran

doi:10.1105/tpc.104.029736

Cited by 181 publications

(174 citation statements)

References 61 publications

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“…Recently, the first methylketone synthase was isolated from tomato, which catalyzes the hydrolysis and subsequent decarboxylation of C 12 , C 14 and C 16 b-ketoacyl ACPs to give C 11 , C 13 and C 15 methylketones, respectively (Fridman et al, 2005). In contrast, in fungi, methylketones are derived from b-oxidative degradation of fatty acids through b-ketoacyl CoA intermediates (Schwab and Schreier, 2002).…”

Section: Fatty Acid-derived and Other Lipophylic Flavor Compoundsmentioning

confidence: 99%

“…Moreover, as these tissues contain many of the enzymes and significantly express many of the genes involved in the production of such metabolites, the isolation of secretory cells has greatly contributed to characterization of many of the enzymes and genes involved in the formation of many plant natural products in peppermint, sweet and lemon basil, as well as tomato and other crops (Fridman et al, 2005;Gang et al, 2002;Iijima et al, 2004a,b;McConkey et al, 2000). The following sections describe the biosynthesis of plant-derived flavor molecules grouped by their biogenetic origin.…”

Section: Biosynthetic Pathwaysmentioning

confidence: 99%

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Biosynthesis of plant‐derived flavor compounds

Schwab¹,

Davidovich‐Rikanati²,

Lewinsohn³

2008

The Plant Journal

910

704

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SummaryPlants have the capacity to synthesize, accumulate and emit volatiles that may act as aroma and flavor molecules due to interactions with human receptors. These low-molecular-weight substances derived from the fatty acid, amino acid and carbohydrate pools constitute a heterogenous group of molecules with saturated and unsaturated, straight-chain, branched-chain and cyclic structures bearing various functional groups (e.g. alcohols, aldehydes, ketones, esters and ethers) and also nitrogen and sulfur. They are commercially important for the food, pharmaceutical, agricultural and chemical industries as flavorants, drugs, pesticides and industrial feedstocks. Due to the low abundance of the volatiles in their plant sources, many of the natural products had been replaced by their synthetic analogues by the end of the last century. However, the foreseeable shortage of the crude oil that is the source for many of the artifical flavors and fragrances has prompted recent interest in understanding the formation of these compounds and engineering their biosynthesis. Although many of the volatile constituents of flavors and aromas have been identified, many of the enzymes and genes involved in their biosynthesis are still not known. However, modification of flavor by genetic engineering is dependent on the knowledge and availability of genes that encode enzymes of key reactions that influence or divert the biosynthetic pathways of plant-derived volatiles. Major progress has resulted from the use of molecular and biochemical techniques, and a large number of genes encoding enzymes of volatile biosynthesis have recently been reported.

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Section: Fatty Acid-derived and Other Lipophylic Flavor Compoundsmentioning

confidence: 99%

Section: Biosynthetic Pathwaysmentioning

confidence: 99%

Biosynthesis of plant‐derived flavor compounds

Schwab¹,

Davidovich‐Rikanati²,

Lewinsohn³

2008

The Plant Journal

910

704

View full text Add to dashboard Cite

show abstract

“…Analysis of a type VI-specific EST database from wild tomato, which is a methylketone-producing line, followed by gene expression comparison with a trichome EST database from wild tomato (accession no. LA1777), which does not produce methylketones, identified the gene Solanum habrochaites methylketone synthase1 (ShMKS1) as correlated with methylketone production (Fridman et al, 2005). Additional genetic and genomic analyses identified a second gene, designated ShMKS2, whose expression was also positively associated with methylketone production (BenIsrael et al, 2009).…”

mentioning

confidence: 99%

“…Methylketones accumulate in large amounts in type VI trichomes, specifically in the apical gland cells, with concentrations of up to 8 mg/g fresh leaf weight (FLW) observed (Fridman et al, 2005). Analysis of a type VI-specific EST database from wild tomato, which is a methylketone-producing line, followed by gene expression comparison with a trichome EST database from wild tomato (accession no.…”

mentioning

confidence: 99%

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Heterologous Expression of Methylketone Synthase1 and Methylketone Synthase2 Leads to Production of Methylketones and Myristic Acid in Transgenic Plants

Geng

Pichersky

2014

Plant Physiology

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Some plants produce methylketones as potent defense compounds against various insects. Wild tomato (Solanum habrochaites), a relative of the cultivated tomato (Solanum lycopersicum), synthesizes large amounts of 2-methylketones in its glandular trichomes, but cultivated tomato trichomes contain little or no methylketones. Two enzymes, Solanum habrochaites methylketone synthase1 (ShMKS1) and ShMKS2, are required to convert b-ketoacyl acyl-carrier protein intermediates of the fatty acid biosynthetic pathway to methylketones. ShMKS2 is a thioesterase that hydrolyzes b-ketoacyl acyl-carrier protein, and ShMKS1 is a decarboxylase that converts the resulting 3-ketoacids to 2-methylketones. We introduced ShMKS2 by itself or together with ShMKS1 to Arabidopsis (Arabidopsis thaliana), tobacco (Nicotiana tabacum), and cultivated tomato under the control of the 35S, Rubisco small subunit, and tomato trichome-specific promoters. Young tobacco and Arabidopsis plants expressing both genes under the control of 35S and Rubisco small subunit promoters produced methylketones in their leaves but had serious growth defects. As plants matured, they ceased to produce methylketones. Tobacco plants but not Arabidopsis or tomato plants expressing only ShMKS2 under the 35S promoter also synthesized methylketones, but at a lower rate. Transgenic cultivated tomato plants expressing ShMKS1 and ShMKS2 under trichome-specific promoters had slightly elevated levels of methylketone. Trace amounts of myristic acid were also detected in transgenic plants constitutively expressing ShMKS2 with or without ShMKS1. These results suggest that increases in methylketone production in plants will require the targeting of the pathway to self-contained structures in the plant and may also require increasing the flux of fatty acid biosynthesis.

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