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17.10.2024 20:00

Key protein for the biosynthesis of defense steroids in solanaceous plants discovered

Angela Overmeyer Presse- und Öffentlichkeitsarbeit
Max-Planck-Institut für chemische Ökologie

    In the journal Science, researchers at the Max Planck Institute for Chemical Ecology present the crucial protein for controlling the biosynthesis of steroidal glycoalkaloids and saponins in plants of the genus Solanum and for the first time demonstrate the ecological role of steroidal saponins in insect defense.

    Researchers at the Max Planck Institute for Chemical Ecology have identified GAME15 as a key protein that regulates the biosynthesis of both steroidal glycoalkaloids and steroidal saponins in plants of the genus Solanum. The new study published in Science shows that the protein is essential for the formation of these natural products from a cholesterol precursor. Black nightshade plants (Solanum nigrum) that were no longer able to produce the protein and thus the steroidal saponins were more susceptible to insects such as leafhoppers and Colorado potato beetles. These results open up new perspectives for the production of high-quality steroidal molecules for medical applications and could support targeted strategies for controlling agricultural pests.

    The biosynthetic pathway of specific steroidal compounds in nightshade plants (such as potatoes, tomatoes and eggplants) starts with cholesterol. Several studies have investigated the enzymes involved in the formation of steroidal glycoalkaloids. Although the genes responsible for producing the scaffolds of steroidal specialized metabolites are known, successfully reconstituting of these compounds in other plants has not yet been achieved. The project group ‘Specialized Steroid Metabolism in Plants’ in the Department of Natural Product Biosynthesis, led by Prashant Sonawane, who is now Assistant Professor at the University of Missouri in the USA, set out to find the missing piece of the puzzle. “With our research project, we particularly wanted to clarify which important component of the biosynthesis pathway has so far remained hidden from research and what role this gene or protein plays in the pathway. We also wanted to find out whether we could reconstitute the biosynthetic pathway after identifying the missing component. An important aspect of our study was also to find out more about the ecological role of steroidal saponins in plants,” says Prashant Sonawane, describing the questions of the study.

    GAME15 - an unknown but crucial player in the biosynthesis of steroidal molecules in Solanum

    The research team used the wild plant Solanum nigrum (black nightshade) for the studies because it produces different steroidal compounds in different tissues, all of which are derived from the same precursor, cholesterol. In the leaves, the most important steroidal metabolite is a saponin called uttroside B, while in the berries the most important compounds are steroidal glycoalkaloids such as α-solasonine, α-solamargine and malonyl-solamargine. The enzymes GAME6, GAME8 and GAME11 are involved in the formation of both types of compounds and are found in both leaves and berries. Confocal microscopy was used to determine where these enzymes are located in the cells. Through biochemical and molecular biological analyses, the researchers identified a gene responsible for a protein called GAME15. Although GAME15 belongs to the family of cellulose synthase-like proteins, it has no function in cellulose production. Instead, it is important for the biosynthesis of steroidal compounds, even though it does not have a catalytic function like other enzymes.

    “Our protein interaction experiments showed that GAME15 interacts with the enzymes GAME6, GAME8 and GAME11. These enzymes are responsible for the first steps in the hydroxylation of cholesterol, leading to the formation of the furostanol-aglycone (16,22,26-trihydroxycholesterol), a key branching point between the synthesis of steroidal saponins and glycoalkaloids. Using Solanum nigrum plants in which the GAME15 gene was knocked out, we were able to show that these plants were no longer able to produce steroidal glycoalkaloids and saponins,' explains first author Marianna Boccia, one of the main findings of the study.

    Steroidal compounds from Solanum have great potential for medical applications

    Steroidal saponins and steroidal glycoalkaloids are groups of compounds with promising medical applications. For example, recent studies show that certain saponins are highly effective in treating liver cancer. Steroidal glycoalkaloids also have anti-cancer properties, as well as antimicrobial and anti-inflammatory activities. "By identifying GAME15, we were able to reconstitute the metabolic pathway for steroidal compounds in heterologous hosts such as Nicotiana benthamiana, up to the scaffold furostanol, a precursor of steroidal saponins, and solasodine, an immediate precursor of steroidal glycoalkaloids," says Prashant Sonawane. Reconstituting medically interesting compounds in plants such as Nicotiana benthamiana is also known as 'pharming', a portmanteau of 'pharmaceutics' and 'farming'. Pharming involves the use of genetically modified plants with an integrated biosynthetic pathway for the production of medical compounds to produce drugs cost-effectively and on a large scale. The results of the study therefore open up possibilities for improved production of important steroid-based compounds.

    First evidence of the ecological role of saponins in the defense against herbivores

    Steroidal glycoalkaloids are already known to be important plant defense substances. They are toxic compounds typical of solanaceous plants and are also found in potatoes, tomatoes and eggplants. However, their toxicity can be significantly reduced in crops by peeling, cooking or frying. In tomatoes, the glycoalkaloids are broken down during ripening, so they are barely detectable in the red fruit. However, the ecological role of steroidal saponins in Solanum nigrum leaves was so far unknown. A key clue came from the greenhouse team, who noticed that GAME15 knockout plants, which are unable to produce saponins, were more susceptible to insect herbivores than wild-type plants. Intrigued by this observation, the researchers carried out ecological experiments in the form of feeding trials with two natural Solanum pests. "In a first experiment, two herbivores, the leafhopper Empoasca decipiens and the Colorado potato beetle Leptinotarsa decemlineata, were given a choice between leaves of wild-type plants (which produce steroidal saponins) and leaves of Game15 knockout plants (which do not produce saponins due to the knockout of the GAME15 gene). After a week, we measured the damage caused by the insects. The results clearly showed that both herbivore species fed almost exclusively on the knockout leaves, showing a preference for them over the wild-type leaves. In a second experiment, we use a "forced-feeding” bioassay, specifically with Colorado potato beetles. In this test, we placed individual beetles with detached leaves from either wild-type or knockout plants. After just six hours, the beetles readily fed on the knockout leaves lacking steroidal saponins, while they largely avoided the wild-type leaves, apparently preferring to starve rather than feed," says Marianna Boccia, describing the first evidence for the role of steroidal saponins in plant defense. One possible explanation for the different groups of compounds in leaves and berries is that these compounds are specialized to protect different plant tissues. Leaves are more likely to be attacked by herbivores, while berries are more susceptible to pathogens.

    “Our discoveries highlight how Solanaceae plants have adapted a cellulose-synthase like protein hijacked from a core metabolism role (such as cellulose biosynthesis) to a structural role, required for the biosynthesis of compounds specialized in the defense of the plants against pathogens. This discovery opens up new opportunities for engineering crops with enhanced resistance to pests and for the production of important steroid-based compounds to fight cancer and other diseases,” says Sarah O'Connor, Director of the Department of Natural Product Biosynthesis and a senior author of the study.


    Wissenschaftliche Ansprechpartner:

    Marianna Boccia, Max Planck Institute for Chemical Ecology, Hans-Knöll-Straße 8, 07745 Jena, Germany, Tel. +49 3641 57-1259, E-Mail mboccia@ice.mpg.de
    Dr. Prashant D. Sonawane, Division of Biochemistry, College of of Agriculture, Food and Natural Resources, University of Missouri, Columbia, MO, USA, Tel. +1 573 882-5300, E-Mail sonawanep@missouri.edu
    Prof. Dr. Sarah E. O’Connor, Max Planck Institute for Chemical Ecology, Hans-Knöll-Straße 8, 07745 Jena, Germany, Tel. +49 3641 57-1200, E-Mail oconnor@ice.mpg.de


    Originalpublikation:

    Boccia, M., Kessler, D., Seibt, W., Grabe, V., Rodríguez López, C. E., Grzech, D., Heinicke, S., O’Connor, S. E., Sonawane, P. D. (2024). A scaffold protein manages the biosynthesis of steroidal defense metabolites in plants, Science, doi:10.1126/science.ado3409
    https://doi.org/10.1126/science.ado3409


    Weitere Informationen:

    https://www.ice.mpg.de/446825/plant-steroidal-metabolism Project Group "Plant steroidal specialized metabolism" in the Department Natural Product Biosynthesis of the Max Planck Institute for Chemical Ecology


    Bilder

    Colorado potato beetle
    Colorado potato beetle
    Danny Kessler
    Max Planck Institute for Chemical Ecology

    Marianna Boccia
    Marianna Boccia
    Anna Schroll
    Max Planck Institute for Chemical Ecology


    Merkmale dieser Pressemitteilung:
    Journalisten, Wissenschaftler
    Biologie, Chemie, Medizin, Umwelt / Ökologie
    überregional
    Forschungsergebnisse, Wissenschaftliche Publikationen
    Englisch


     

    Colorado potato beetle


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    Marianna Boccia


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