The genus echinacea has attracted attention for its diverse medicinal properties, including its ability to enhance immunity, reduce inflammation, and combat microorganisms. Despite its popularity in herbal medicine, the varying concentrations of active compounds among different echinacea species and products create obstacles for achieving uniform quality and reliable efficacy. This study investigates the genetic and molecular mechanisms responsible for producing key bioactive substances such as alkamides, chicoric acid, and complex carbohydrates, which are essential for echinacea’s therapeutic effects. Furthermore, the research explores recent advancements in plant breeding methodologies, including the use of DNA-based selection techniques and cutting-edge genomic tools like CRISPR-Cas9. These innovative approaches seek to develop echinacea varieties with improved tolerance to environmental challenges, heightened disease resistance, and enhanced production of valuable phytochemicals. Additionally, this review addresses the impact of environmental factors, including abiotic stresses like drought and salinity, on gene expression related to secondary metabolite production. These insights are crucial for optimizing both cultivation practices and breeding programs. The conclusions suggest that integrating traditional breeding methods with modern genomic tools holds great promise for improving the consistency and quality of echinacea products, which is essential for their sustained use in global herbal medicine markets.

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