Exploring the Biochemical Profiles of Medicinal Plants Cultivated Under Stressful Environmental Conditions

Abstract

The therapeutic potential of medicinal plants, attributed to diverse bioactive chemicals, is impacted by dynamic metabolic changes under environmental stressors such as salt, drought, and heavy metal exposure. This study aimed to elucidate the biochemical alterations in stressed medicinal plants and their implications for therapeutic qualities. Two groups of plants were compared: one cultivated in optimal conditions, serving as a control, and the other exposed to stressors mimicking real-world scenarios. Biochemical parameters, including total phenolic content, flavonoids, antioxidant activity, and specific secondary metabolites, were assessed using established analytical methods. In a case study involving Aloe vera under elevated soil salinity, a significant decrease in total phenolic content and antioxidant activity was observed. Surprisingly, aloin, an anti-inflammatory bioactive compound, exhibited notable upregulation. Stress-induced biochemical variations in medicinal plants differed significantly from those in ideal conditions, demonstrating adaptive responses, including modulation of secondary metabolite synthesis. While certain stresses led to an overall decrease in secondary metabolites, specific instances showed an overexpression of beneficial chemicals. Exploring drought stress in Lavandula angustifolia (lavender), Vitis vinifera, and Artemisia tridentata, revealed a marked reduction in flavonoids and specific secondary metabolites. The study aimed to establish connections between metabolic alterations and stress-adaptive reactions. The findings contribute to understanding how environmental stress influences the therapeutic efficacy of medicinal plants and shed light on the molecular pathways governing stress-induced changes. In the investigation of heavy metal exposure, Hypericum perforatum, and Coriandrum sativum subjected to cadmium-contaminated soil exhibited an overall decline in secondary metabolites, including reduced hypericin content. Contrarily, hyperforin, linked to antidepressant properties, experienced a significant increase. These results have implications for pharmaceutical applications, sustainable farming practices, and the conservation of medicinal plant biodiversity amidst changing environmental dynamics. The study underscores the intricate relationship between environmental stressors and the biochemical makeup of medicinal plants, emphasizing their resilience and capacity to produce valuable bioactive molecules in challenging conditions. The comparative biochemical analysis of stressed medicinal plants involves assessing various parameters to comprehend how stress influences plant metabolism and bioactive compound production.