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1. Coordinated regulation of the entry and exit steps of aromatic amino acid biosynthesis supports the dual lignin pathway in grasses

   https://doi.org/10.1038/s41467-023-42587-7  

   El-Azaz, Jorge; Moore, Bethany; Takeda-Kimura, Yuri; Yokoyama, Ryo; Wijesingha Ahchige, Micha; Chen, Xuan; Schneider, Matthew; Maeda, Hiroshi A. (November 2023, Nature Communications)

   Abstract Vascular plants direct large amounts of carbon to produce the aromatic amino acid phenylalanine to support the production of lignin and other phenylpropanoids. Uniquely, grasses, which include many major crops, can synthesize lignin and phenylpropanoids from both phenylalanine and tyrosine. However, how grasses regulate aromatic amino acid biosynthesis to feed this dual lignin pathway is unknown. Here we show, by stable-isotope labeling, that grasses produce tyrosine >10-times faster than Arabidopsis without compromising phenylalanine biosynthesis. Detailed in vitro enzyme characterization and combinatorialin plantaexpression uncovered that coordinated expression of specific enzyme isoforms at the entry and exit steps of the aromatic amino acid pathway enables grasses to maintain high production of both tyrosine and phenylalanine, the precursors of the dual lignin pathway. These findings highlight the complex regulation of plant aromatic amino acid biosynthesis and provide novel genetic tools to engineer the interface of primary and specialized metabolism in plants. 

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2. Understanding the chemical language mediating maize immunity and environmental adaptation

   https://doi.org/10.1111/nph.20000  

   Yasmin, Farida; Cowie, Anna E; Zerbe, Philipp (July 2024, New Phytologist)

   Summary Diverse networks of specialized metabolites promote plant fitness by mediating beneficial and antagonistic environmental interactions. In maize (Zea mays), constitutive and dynamically formed cocktails of terpenoids, benzoxazinoids, oxylipins, and phenylpropanoids contribute to plant defense and ecological adaptation. Recent research has highlighted the multifunctional nature of many specialized metabolites, serving not only as elaborate chemical defenses that safeguard against biotic and abiotic stress but also as regulators in adaptive developmental processes and microbiome interactions. Great strides have also been made in identifying the modular pathway networks that drive maize chemical diversity. Translating this knowledge into strategies for enhancing stress resilience traits has the potential to address climate‐driven yield losses in one of the world's major food, feed, and bioenergy crops. 

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3. Exploring Uncharted Territories of Plant Specialized Metabolism in the Postgenomic Era

   https://doi.org/10.1146/annurev-arplant-081519-035634  

   Jacobowitz, Joseph R.; Weng, Jing-Ke (April 2020, Annual Review of Plant Biology)

   For millennia, humans have used plants for food, raw materials, and medicines, but only within the past two centuries have we begun to connect particular plant metabolites with specific properties and utilities. Since the utility of classical molecular genetics beyond model species is limited, the vast specialized metabolic systems present in the Earth's flora remain largely unstudied. With an explosion in genomics resources and a rapidly expanding toolbox over the past decade, exploration of plant specialized metabolism in nonmodel species is becoming more feasible than ever before. We review the state-of-the-art tools that have enabled this rapid progress. We present recent examples of de novo biosynthetic pathway discovery that employ various innovative approaches. We also draw attention to the higher-order organization of plant specialized metabolism at subcellular, cellular, tissue, interorgan, and interspecies levels, which will have important implications for the future design of comprehensive metabolic engineering strategies. 

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4. Redirecting tropane alkaloid metabolism reveals pyrrolidine alkaloid diversity in Atropa belladonna

   https://doi.org/10.1111/nph.18651  

   Parks, Hannah M.; Cinelli, Maris A.; Bedewitz, Matthew A.; Grabar, Josh M.; Hurney, Steven M.; Walker, Kevin D.; Jones, A. Daniel; Barry, Cornelius S. (March 2023, New Phytologist)

   Summary Plant‐specialized metabolism is complex, with frequent examples of highly branched biosynthetic pathways, and shared chemical intermediates. As such, many plant‐specialized metabolic networks are poorly characterized.TheN‐methyl Δ¹‐pyrrolinium cation is a simple pyrrolidine alkaloid and precursor of pharmacologically important tropane alkaloids. Silencing of pyrrolidine ketide synthase (AbPyKS) in the roots ofAtropa belladonna(Deadly Nightshade) reduces tropane alkaloid abundance and causes highN‐methyl Δ¹‐pyrrolinium cation accumulation. The consequences of this metabolic shift on alkaloid metabolism are unknown. In this study, we utilized discovery metabolomics coupled withAbPyKSsilencing to reveal major changes in the root alkaloid metabolome ofA. belladonna.We discovered and annotated almost 40 pyrrolidine alkaloids that increase whenAbPyKSactivity is reduced. Suppression of phenyllactate biosynthesis, combined with metabolic engineeringin planta, and chemical synthesis indicates several of these pyrrolidines share a core structure formed through the nonenzymatic Mannich‐like decarboxylative condensation of theN‐methyl Δ¹‐pyrrolinium cation with 2‐O‐malonylphenyllactate. Decoration of this core scaffold through hydroxylation and glycosylation leads to mono‐ and dipyrrolidine alkaloid diversity.This study reveals the previously unknown complexity of theA. belladonnaroot metabolome and creates a foundation for future investigation into the biosynthesis, function, and potential utility of these novel alkaloids. 

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5. Traditional medicinal use is linked with apparency, not specialized metabolite profiles in the order Caryophyllales

   https://doi.org/10.1002/ajb2.16308  

   Crum, Alex H.; Philander, Lisa; Busta, Lucas; Yang, Ya (April 2024, American Journal of Botany)

   Abstract PremiseBetter understanding of the relationship between plant specialized metabolism and traditional medicine has the potential to aid in bioprospecting and untangling of cross‐cultural use patterns. However, given the limited information available for metabolites in most plant species, understanding medicinal use–metabolite relationships can be difficult. The order Caryophyllales has a unique pattern of lineages of tyrosine‐ or phenylalanine‐dominated specialized metabolism, represented by mutually exclusive anthocyanin and betalain pigments, making Caryophyllales a compelling system to explore the relationship between medicine and metabolites by using pigment as a proxy for dominant metabolism. MethodsWe compiled a list of medicinal species in select tyrosine‐ or phenylalanine‐dominant families of Caryophyllales (Nepenthaceae, Polygonaceae, Simmondsiaceae, Microteaceae, Caryophyllaceae, Amaranthaceae, Limeaceae, Molluginaceae, Portulacaceae, Cactaceae, and Nyctaginaceae) by searching scientific literature until no new uses were recovered. We then tested for phylogenetic clustering of uses using a “hot nodes” approach. To test potential non‐metabolite drivers of medicinal use, like how often humans encounter a species (apparency), we repeated the analysis using only North American species across the entire order and performed phylogenetic generalized least squares regression (PGLS) with occurrence data from the Global Biodiversity Information Facility (GBIF). ResultsWe hypothesized families with tyrosine‐enriched metabolism would show clustering of different types of medicinal use compared to phenylalanine‐enriched metabolism. Instead, wide‐ranging, apparent clades in Polygonaceae and Amaranthaceae are overrepresented across nearly all types of medicinal use. ConclusionsOur results suggest that apparency is a better predictor of medicinal use than metabolism, although metabolism type may still be a contributing factor. 

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