Tomato root specialized metabolites evolved through gene duplication and regulatory divergence within a biosynthetic gene cluster

Kerwin, Rachel E.; Hart, Jaynee E.; Fiesel, Paul D.; Lou, Yann-Ru; Fan, Pengxiang; Jones, A. Daniel; Last, Robert L.

doi:10.1126/sciadv.adn3991

Cited by 6 publications

References 127 publications

(219 reference statements)

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Sticky business: the intricacies of acylsugar biosynthesis in the Solanaceae

Vendemiatti,

Nowack,

Peres

et al. 2024

Phytochem Rev

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Plants display tremendous chemical diversity. Like all organisms, they possess a core set of metabolites for growth and development. However, plants are notorious for their specialized chemical repertoire. Biologically active specialized metabolites enable plants to interact with their environment and provide humans with diverse medicines. Specialized metabolites are derived from core metabolites, often using enzymes that evolved from core pathways in a lineage-specific manner. Biochemical understanding of plant specialized metabolic pathways provides insight into the evolutionary origins of chemical diversity and tools for engineering the production of biologically active metabolites. Acylsugars are a class of specialized metabolites occurring widely in the Solanaceae and other plant families where they contribute to fitness. Although assembled from simple core metabolic precursors, sugars and acyl chains, tremendous acylsugar structural diversity is observed across the Solanaceae family. Enzymes that catalyze the esterification of acyl chains to sugar cores have been well characterized from phylogenetically diverse species, and their biochemical diversity contributes to acylsugar structural variation. The upstream metabolic pathways that provide the acyl chain precursors also contribute to acylsugar structural variation. Yet, biochemical and genetic understanding of these upstream biosynthetic pathways is less well known. Here, we focus on recent advances in acyl chain biosynthesis and elongation pathways, the subcellular distribution of acylsugar biosynthesis, and how biochemical innovations in acylsugar biosynthesis contribute to structural diversity specifically focusing on Solanaceae-type acylsugars.

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Sticky business: the intricacies of acylsugar biosynthesis in the Solanaceae

Vendemiatti,

Nowack,

Peres

et al. 2024

Phytochem Rev

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Decoding resilience: ecology, regulation, and evolution of biosynthetic gene clusters

Cawood,

Ton

2024

Trends in Plant Science

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Trading acyls and swapping sugars: metabolic innovations in Solanum trichomes

Fiesel,

Kerwin,

Jones

et al. 2024

Plant Physiology

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Solanaceae (nightshade family) species synthesize a remarkable array of clade- and tissue-specific specialized metabolites. Protective acylsugars, one such class of structurally diverse metabolites, are produced by ACYLSUGAR ACYLTRANSFERASE (ASAT) enzymes from sugars and acyl-coenzyme A esters. Published research has revealed trichome acylsugars composed of glucose and sucrose cores in species across the family. In addition, acylsugars have been analyzed across a small fraction of the >1200 species in the phenotypically megadiverse Solanum genus, with a handful containing inositol and glycosylated inositol cores. The current study sampled several dozen species across subclades of Solanum to get a more detailed view of acylsugar chemodiversity. In depth characterization of acylsugars from the Clade II species brinjal eggplant (Solanum melongena) led to the identification of eight unusual structures with inositol or inositol glycoside cores and hydroxyacyl chains. Liquid chromatography-mass spectrometry analysis of 31 additional species in the Solanum genus revealed striking acylsugar diversity, with some traits restricted to specific clades and species. Acylinositols and inositol-based acyldisaccharides were detected throughout much of the genus. In contrast, acylglucoses and acylsucroses were more restricted in distribution. Analysis of tissue-specific transcriptomes and interspecific acylsugar acetylation differences led to the identification of the brinjal eggplant ASAT 3-LIKE 1 (SmASAT3-L1; SMEL4.1_12g015780) enzyme. This enzyme is distinct from previously characterized acylsugar acetyltransferases, which are in the ASAT4 clade, and appears to be a functionally divergent ASAT3. This study provides a foundation for investigating the evolution and function of diverse Solanum acylsugar structures and harnessing this diversity in breeding and synthetic biology.

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Tomato root specialized metabolites evolved through gene duplication and regulatory divergence within a biosynthetic gene cluster

Cited by 6 publications

References 127 publications

Sticky business: the intricacies of acylsugar biosynthesis in the Solanaceae

Sticky business: the intricacies of acylsugar biosynthesis in the Solanaceae

Decoding resilience: ecology, regulation, and evolution of biosynthetic gene clusters

Trading acyls and swapping sugars: metabolic innovations in Solanum trichomes

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