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Bibliographic Details
Main Authors: Stefi, Aikaterina, Chalkiadaki, Maria, Bashari, Emily, Mitsigiorgi, Konstantina, Szczeblewski, Paweł, Papageorgiou, Danae, Gkikas, Dimitrios, Vassilacopoulou, Dido, Christodoulakis, Nikolaos S., Halabalaki, Maria
Format: Recurso digital
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Published: Zenodo 2025
Online Access:https://doi.org/10.3390/metabo15090585
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Table of Contents:
  • <p><span>Ecballium elaterium</span> is a widely distributed species and is one of the earliest recorded in traditional medicine. With global temperatures rising, this study aimed to investigate the changes in <span>E. elaterium</span> plantlets subjected to thermal stress. The goal was to understand how thermal stress affects morphology, physiology, and bioactive metabolite production, both for ecological adaptation and potential therapeutic applications. Methods: Seedlings were cultivated under controlled conditions and subjected to either the control temperature (22 °C) or the heat stress temperature (35 °C) for one week. Morphological and anatomical traits were assessed, along with physiological parameters such as chlorophyll content, malondialdehyde (MDA), hydrogen peroxide (H<sub>2</sub>O<sub>2</sub>), L-proline, soluble sugars, and total phenolic content. Methanolic leaf extracts from both groups were analyzed via LC-HRMS/MS and examined <span>in vitro</span> for cytotoxic activity against three human cancer cell lines: MCF-7 (breast), DU-145 (prostate), and SH-SY5Y (neuroblastoma). Results: Heat stress reduced dry mass and stomatal density but increased the diameter of the root transition zone, indicating anatomical adaptation. Leaves exhibited elevated oxidative stress markers and altered metabolite accumulation, while the roots showed a more integrated stress response. LC-HRMS/MS profiling revealed significant shifts in Cucurbitacin composition. Extracts from heat-stressed plants displayed stronger cytotoxicity, particularly toward DU-145 and SH-SY5Y cells, correlating with higher levels of glycosylated Cucurbitacins. Conclusions: <span>E. elaterium</span> demonstrates organ-specific thermotolerance mechanisms, with heat stress enhancing the production of bioactive metabolites. These stress-induced phytochemicals, especially Cucurbitacins, hold promise for future cancer research and therapeutic applications.</p>