Comparative Analyses of Phytochemical Variation Within and Between Congeneric Species of Willow Herb, and : Contribution of Environmental Factors

Overview

Journal Front Plant Sci

Date 2021 Mar 8

PMID 33679815

Citations 15

Authors

Mitra Mohammadi Bazargani

Mohsen Falahati-Anbaran

Jens Rohloff

Affiliations

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Abstract

The plants in the genus are considered to have several important medicinal properties due to their unique chemical composition. Although metabolic profiles of medicinal plants are mainly controlled by genetic factors, their production is also to some degree influenced by environmental factors, thus, variations in the levels of phytochemicals may represent long-term ecological and evolutionary interactions. In order to depict the magnitude of natural variation in level of chemical compounds among conspecific populations of ( = 31) and ( = 16), metabolite profiling of aerial parts of plants was performed with gas chromatography/mass spectrometry analysis. Putative identification and structure annotation revealed the presence of 74 compounds including 46 compounds considered secondary metabolites categorized into flavonoids ( = 8), phenolic acids ( = 26), steroids ( = 3), and terpenes ( = 5) across all populations. Although there was a considerable natural variation among conspecific populations, principal component analysis revealed a clear separation of populations of each species based on the second main principal component which was highly correlated with eight secondary metabolites. The level of secondary metabolites was significantly correlated between species ( = 0.91), suggesting shared metabolic pathways underlying the production of chemical compounds. In addition, redundancy and variance partitioning analyses by including bioclimatic variables and altitude revealed a significant contribution of elevation in explaining the total variation of secondary metabolites in . Two-thirds of all secondary metabolites were significantly correlated with altitude in . The large-scale geographic analyses of populations revealed additionally detected flavonoids and terpenes ( and ) and steroids () for the first time. This study provides significant information on additional chemical compounds found across the distribution range of the two ecologically important species of willow herb and emphasizes the importance of geographic-wide sampling as a valuable strategy to depict intraspecific and interspecific variability in chemical traits.

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