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1. Compartmentalization of specialized metabolites across vegetative and reproductive tissues in two sympatric Psychotria species

   https://doi.org/10.1002/ajb2.16191  

   Schneider, Gerald F.; Carlson, Cole A.; Jos, Elsa M.; Beckman, Noelle G. (July 2023, American Journal of Botany)

   Abstract Premise The specialized metabolites of plants are recognized as key chemical traits in mediating the ecology and evolution of sundry plant–biotic interactions, from pollination to seed predation. Intra‐ and interspecific patterns of specialized metabolite diversity have been studied extensively in leaves, but the diverse biotic interactions that contribute to specialized metabolite diversity encompass all plant organs. Focusing on two species of Psychotria shrubs, we investigated and compared patterns of specialized metabolite diversity in leaves and fruit with respect to each organ's diversity of biotic interactions. Methods To evaluate associations between biotic interaction diversity and specialized metabolite diversity, we combined UPLC‐MS metabolomic analysis of foliar and fruit specialized metabolites with existing surveys of leaf‐ and fruit‐centered biotic interactions. We compared patterns of specialized metabolite richness and variance among vegetative and reproductive tissues, among plants, and between species. Results In our study system, leaves interact with a far larger number of consumer species than do fruit, while fruit‐centric interactions are more ecologically diverse in that they involve antagonistic and mutualistic consumers. This aspect of fruit‐centric interactions was reflected in specialized metabolite richness—leaves contained more than fruit, while each organ contained over 200 organ‐specific specialized metabolites. Within each species, leaf‐ and fruit‐specialized metabolite composition varied independently of one another across individual plants. Contrasts in specialized metabolite composition were stronger between organs than between species. Conclusions As ecologically disparate plant organs with organ‐specific specialized metabolite traits, leaves and fruit can each contribute to the tremendous overall diversity of plant specialized metabolites. 

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2. Subcellular localization of fungal specialized metabolites

   https://doi.org/10.1186/s40694-022-00140-z  

   Skellam, Elizabeth (December 2022, Fungal Biology and Biotechnology)

   Abstract Fungal specialized metabolites play an important role in the environment and have impacted human health and survival significantly. These specialized metabolites are often the end product of a series of sequential and collaborating biosynthetic enzymes that reside within different subcellular compartments. A wide variety of methods have been developed to understand fungal specialized metabolite biosynthesis in terms of the chemical conversions and the biosynthetic enzymes required, however there are far fewer studies elucidating the compartmentalization of the same enzymes. This review illustrates the biosynthesis of specialized metabolites where the localization of all, or some, of the biosynthetic enzymes have been determined and describes the methods used to identify the sub-cellular localization. 

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3. The ease and complexity of identifying and using specialized metabolites for crop engineering

   https://doi.org/10.1042/ETLS20210248  

   Muhich, Anna Jo; Agosto-Ramos, Amanda; Kliebenstein, Daniel J. (March 2022, Emerging Topics in Life Sciences)

   Plants produce a broad variety of specialized metabolites with distinct biological activities and potential applications. Despite this potential, most biosynthetic pathways governing specialized metabolite production remain largely unresolved across the plant kingdom. The rapid advancement of genetics and biochemical tools has enhanced our ability to identify plant specialized metabolic pathways. Further advancements in transgenic technology and synthetic biology approaches have extended this to a desire to design new pathways or move existing pathways into new systems to address long-running difficulties in crop systems. This includes improving abiotic and biotic stress resistance, boosting nutritional content, etc. In this review, we assess the potential and limitations for (1) identifying specialized metabolic pathways in plants with multi-omics tools and (2) using these enzymes in synthetic biology or crop engineering. The goal of these topics is to highlight areas of research that may need further investment to enhance the successful application of synthetic biology for exploiting the myriad of specialized metabolic pathways. 

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4. All type II classic MADS‐box genes in the lycophyte Selaginella moellendorffii are broadly yet discretely expressed in vegetative and reproductive tissues

   https://doi.org/10.1111/ede.12375  

   Ambrose, Barbara A.; Smalls, Tynisha L.; Zumajo‐Cardona, Cecilia (May 2021, Evolution & Development)
5. Engineering insect resistance using plant specialized metabolites

   https://doi.org/10.1016/j.copbio.2021.03.005  

   Zhou, Shaoqun; Jander, Georg (August 2021, Current Opinion in Biotechnology)

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