The Intrasectional Chemotaxonomic Placement of Hypericum elegans Stephan ex Willd. Inferred from the Essential‐Oil Chemical Composition

Here we report, for the first time, the results of detailed GC and GC/MS analyses of the essential oil of a rare taxon in Serbia, Hypericum elegans Stephan ex Willd . One hundred and sixty two constituents identified accounted for 98.6% of the oil. The major components of the oil were undecane (31.9%), α‐pinene (16.7%), nonane (6.1%), bicyclogermacrene (5.8%), 2‐methyloctane (3.7%), and germacrene D (3.6%). Non‐terpenoids as chemotaxonomic markers constituted the main fraction of H. elegans oil, whereby n‐alkanes were the most abundant contributors of this fraction. Based on these results and previously published ones, we performed an intrasectional multivariate statistical comparison of corresponding essential‐oil chemical compositions. Principal component analysis (PCA) and agglomerative hierarchical clustering (AHC) of the data on the volatile profiles of section Hypericum taxa revealed that H. elegans either represents an oil chemotype of its own (AHC) or could be considered related to H. perforatum (PCA).     

Chemical composition and antimicrobial activity of volatiles from Degenia velebitica, a European stenoendemic plant of the Brassicaceae family

Free and glucosidic bound leaf volatiles of Degenia velebitica were isolated and fractionated simultaneously into H₂O‐soluble, H₂O‐insoluble, and highly volatile compounds by hydrodistillation–adsorption (HDA) and analyzed by GC/MS. Among the 24 constituents identified, the main compounds obtained by the HDA method were S‐ and/or N‐atom containing compounds, i.e., 6‐(methylsulfanyl)hexanenitrile ( 10 ; 26.78%), dimethyl trisulfide ( 6 ; 26.35%), 3,4,5‐trimethylpyrazole ( 17 ; 13.33%), hex‐5‐enenitrile ( 2 ; 10.11%), dimethyl tetrasulfide ( 8 ; 4.93%), and pent‐4‐enyl isothiocyanate ( 7 ; 4.45%). In addition, O‐glycosidically bound volatiles and free volatiles were isolated by solvent extraction. Sixteen volatile O‐aglycones and twelve free volatile components were identified. The main O‐aglycones were eugenol ( 19 ; 24.15%), 2‐methoxy‐4‐vinylphenol ( 11 ; 11.50%), and benzyl alcohol ( 20 ; 9.49%), and the main free volatiles were (9Z,12Z)‐octa‐9,12‐dienic acid (38.35%), hexadecanoic acid (22.64%), and phytol (5.80%). The H₂O‐soluble volatile fraction obtained by HDA, containing mostly glucosinolate degradation products and 3,4,5‐trimethylpyrazole ( 17 ), was evaluated for antimicrobial activity by determining inhibition zones with the diffusion method as well as minimal inhibitory concentrations (MIC) and minimal microbicidal concentrations (MMC) with the micro‐dilution method. The fraction expressed activity against the tested Gram‐positive and Gram‐negative bacteria as well as against yeast, with MIC values equal to or lower than 16.7 μg/ml.     

Elevated indole-3-acetic acid peroxidase activity is involved in the cadmium-induced hydrogen peroxide production in barley root tip

All of the analyzed heavy metals significantly inhibited root growth, but in addition to Cd exposure an elevated IAA-POD activity was detected under Co, Cu and Hg treatment, while Ni and Pb inhibited its activity. The Cd-induced IAA-POD activity increased from the root apex towards to the mature region of root tips. However similar or even more severe root growth inhibition was observed by exogenously applied IAA, IAA-POD activity was activated only at high IAA concentrations. Elevated Cd-induced H₂O₂ production was detected both in the absence or in the presence of IAA in the reaction mixture, but in the case of IAA as a possible substrate for PODs the production of H₂O₂ increased markedly just in the Cd-treated roots. Exogenously applied H₂O₂ also activated IAA-POD activity. Our results indicated that in the development of Cd toxicity syndrome the production of ROS during IAA degradation by elevated IAA-POD activity plays a crucial role, mainly under severe Cd stress.     

Effect of heavy metals on root growth and peroxidase activity in barley root tip

In the present work, we investigated the alteration of oxidative and peroxidative activities of peroxidases (PODs) along the longitudinal root axis of barley seedlings during heavy metal (HM; e.g., Cd, Cu, Hg, Ni, Pb) treatment. Analysis of the individual root segments revealed that all of the analyzed HMs caused an increase of guaiacol-POD activity, however to a different extent and spatial distribution. Cd-induced ferulic acid POD activity was observed along the whole root tip (RT), while Cu and Hg caused its increase in the meristematic zone and Ni mainly at the end of the differentiation zone of RT. The activation of coniferyl alcohol POD by HMs was detected along the whole RT. HM-induced hydrogen peroxide-generating POD activity was localized mainly to the elongation zone of RT. Elevated chlorogenic acid POD activity was observed in the meristematic zone and at the end of the differentiation zone of RTs. The activation of several PODs is probably associated with enhanced H₂O₂ production and lignification as a defense response of roots to several HM, to prevent their uncontrolled flux. On the other hand, this defense response is accompanied by root growth inhibition, due to the enhanced rigidification of cell wall and accelerated differentiation of RTs.