Original Article |
Corresponding author: Stela Z. Dimitrova ( stela.dimitrova@mu-plovdiv.bg ) © 2022 Yoana P. Georgieva, Petya A. Gardjeva, Mariana N. Katsarova, Petko I. Bozov, Kalina P. Gercheva, Marianna A. Murdjeva, Stela Z. Dimitrova.
This is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Citation:
Georgieva YP, Gardjeva PA, Katsarova MN, Bozov PI, Gercheva KP, Murdjeva MA, Dimitrova SZ (2022) A study of flavonoid composition and antimicrobial activity of Scutellaria altissima L. from different floristic regions of Bulgaria. Folia Medica 64(4): 617-623. https://doi.org/10.3897/folmed.64.e64795
|
Introduction: Scutellaria extracts and its constituents, especially the characteristic flavonoids such as baicalein and its glycoside baicalin, exhibit significant antimicrobial activity.
Aim: To perform a comparative analysis of flavonoid composition and antimicrobial activity of extracts obtained from aerial parts and roots of Scutellaria altissima from the regions of Mezek and Bachkovo, Bulgaria.
Materials and methods: 70% ethanol and aqueous extracts of aerial parts and roots of S. altissima were used. HPLC analysis of S. altissima extracts was performed. Microbiological tests were done on clinical isolates of Streptococcus mitis, Staphylococcus aureus, Escherichia coli, and Candida albicans. Minimal bactericidal and minimal bacteriostatic concentrations of S. altissima extracts were determined by the agar method.
Results: The ethanol extracts contain flavonoids approximately twice as much in comparison with the aqueous extracts. The baicalin content in the aerial parts of S. altissima from the region of Mezek is 5 times higher than that in the roots. S. altissima extracts have effective antimicrobial activity against S. mitis only. The minimal bactericidal concentration of ethanol extracts of S. altissima aerial parts and S. altissima roots is 2000 µg/ml and 8000 µg/ml at 24 hours, respectively. The bactericidal effect of aqueous extracts occurs at 48 hours at minimal bactericidal concentration of S. altissima aerial parts – 2000 µg/ml and of S. altissima roots – 6000 µg/ml.
Conclusions: The finding that extracts of Bulgarian S. altissima possess effective antimicrobial properties against S. mitis suggests that it can be used as a potential source for the development of natural antimicrobial agents to suppress oral pathogens and prevent some oral infections.
baicalin, scutellarin, S. mitis, wogonoside
The plant family Lamiaceae is one of the most used plants in traditional medicine and a subject of phytochemical research. One of the family members is the genus Scutellaria L. which includes about 350 species widespread in East Asia, Europe, and North America. Some species of Scutellaria are documented to have a broad range of medical properties.[
In vitro antibacterial activities of the extracts of S. baicalensis roots have been reported against cariogenic bacterial strains, including Streptococcus mutans, Streptococcus sobrinus, and Streptococcus salivarius.[
In addition, neo-clerodane diterpenoids isolated from several Scutellaria species, distributed in Bulgaria, have also shown substantial antimicrobial effect against Gram-positive bacteria (S. aureus, Bacillus cereus, and Listeria monocytogenes), as well as Gram-negative bacteria (E. coli, Pseudomonas aeruginosa, P. fluorescens, Salmonella abony, and Aeromonas hydrophila).[
S. altissima
is one of the eight species widespread in the Bulgarian flora (Fig.
In our previous study on phenolic composition of S. altissima growing in Bulgaria, we have established for the first time flavonoids similar to those found in S. baicalensis.[
The presence of the biologically active flavonoids baicalin and baicalein in S. altissima, native to Bulgaria, invokes a vested interest in the potential pharmacological benefits of this natural medicine resource.
The aim of this study was to perform a comparative analysis of flavonoids composition in extracts obtained from aerial parts and root of S. altissima from different floristic regions of Bulgaria, as well as the extracts’ antimicrobial activity against S. mitis, S. aureus, E. coli, and C. albicans.
S. altissima was collected during flowering from Bachkovo and Mezek in June 2019. The taxonomic identity of the plant has been confirmed by the Bulgarian botanist prof. Rumen Mladenov. Voucher specimens (No. 062641) were deposited in the Herbarium of the University of Agriculture, Plovdiv, Bulgaria. The collected plant material was separated into roots and aerial parts, and then was dried and powdered. Samples of roots (15 g) and aerial parts (15 g) of each region were extracted with 300 ml 70% ethanol and distilled water for 3 hours using a magnetic stirrer at a temperature of 50°C. After filtration, ethanolic extracts were evaporated at 40°C and all samples were lyophilized. The solutions of lyophilizates were prepared in distilled water in working concentration of 1000 µg/ml, 2000 µg/ml, 3000 µg/ml, 4000 µg/ml, 6000 µg/ml, 8000 µg/ml and 10000 µg/ml.
Baicalin, baicalein, wogonin, wogonoside, scutellarin, and verbascoside were determined by a previously developed and validated HPLC method.[
Microbiological analysis were performed with S. mitis, S. aureus, E. coli, and C. albicans using 3 strains of each, isolated and identified via MALDI TOF mass spectrometer (bioMérieux) from clinical specimens in the Laboratory of Microbiology of St. George University Hospital, Plovdiv, Bulgaria.
The bacterial strains were cultivated in BD Columbia аgar with 5% defibrinated sheep blood plates and for C. albicans in BD CHROMagar Candida. After 24 hours of incubation at 37°C, they were transferred into trypsin broth (0.5 McFarland densities), where after reaching exponential growth they were treated with the corresponding concentrations of the extracts tested. The treated cultures were incubated for 24 and 48 hours at 37°C. Non-treated cultures of the corresponding strains were used in triplicates as controls. Minimal bactericidal concentration (MBCC) and minimal bacteriostatic concentration (MBSC) were determined by microbial number according to colony-forming units – 103, 104, 105 in 5% blood agar or in Chromagar Candida (for C. albicans). MBSC was accepted in microbial count less than 105 (104 or 103) and MBCC was considered if no growth was visible on the culture medium treated with the corresponding concentration of each extract.
Statistical analysis was carried out using IBM SPSS 17.0. When needed statistical comparisons were made using Duncan’s multiple range test. Means were considered significantly different at p<0.05. The results were presented as means ± standard deviation of triplicate experiments.
HPLC analysis was performed on 70% ethanol and aqueous extracts obtained from aerial parts and roots of S. altissima from Bachkovo and Mezek to compare the content of the major flavonoids (scutellarin, baicalin, wogonoside, baicalein, wogonin) and verbascoside.
According to the data presented in Fig.
The results obtained showed that extracts from aerial parts and roots of S. altissima had effective antimicrobial activity against S. mitis, but no bacteriostatic or bactericidal effects were found for S. aureus, E. coli, and C. albicans. The antimicrobial activity of 70% ethanol extracts from roots and aerial parts of S. altissima against S. mitis is presented in Table
Susceptibility of S. mitis to 70% ethanol extracts of S. altissima, 24 hours after treatment
Sample | Microorganism | ||
Streptococcus mitis | |||
Strain 1 | Strain 2 | Strain 3 | |
MBSC/MBCC µg/ml | MBSC/MBCC µg/ml | MBSC/MBCC µg/ml | |
Aerial parts of S. altissima (Bachkovo) | 2000/4000 | 2000/4000 | 2000/4000 |
Aerial parts of S. altissima (Mezek) | 1000/2000 | 1000/2000 | 1000/2000 |
Root of S. altissima (Bachkovo) | 8000/10000 | 8000/10000 | 8000/10000 |
Root of S. altissima (Mezek) | 6000/8000 | 6000/8000 | 6000/8000 |
Susceptibility of S. mitis to aqueous extracts of S. altissima, 48 hours after treatment
Sample | Microorganism | ||
Streptococcus mitis | |||
Strain 1 | Strain 2 | Strain 3 | |
MBSC/MBCC µg/ml | MBSC/MBCC µg/ml | MBSC/MBCC µg/ml | |
Aerial parts of S. altissima (Bachkovo) | 2000/4000 | 2000/4000 | 2000/4000 |
Aerial parts of S. altissima (Mezek) | 1000/2000 | 1000/2000 | 1000/2000 |
Root of S. altissima (Bachkovo) | 6000/8000 | 6000/8000 | 6000/8000 |
Root of S. altissima (Mezek) | 4000/6000 | 4000/6000 | 4000/6000 |
The present study performs a comparative analysis of flavonoids composition and antimicrobial activity of aerial parts and roots of S. altissima obtained from the regions of Mezek and Bachkovo, Bulgaria. The data obtained from HPLC analysis indicated that the content of flavonoid compounds in S. altissima samples vary between geographical regions. Such variation of phytochemical constituents may be due to climatic conditions, e.g. water, intensity of sunlight, temperature conditions. However, the main bioactive flavonoids: baicalin, baicalein, wogonin, wogonoside, and scutellarin, although in different ratios and quantities, were found in all samples from aerial parts and roots of S. altissima from both regions. It is important to note that S. baicalensis radix is registered in the European Pharmacopoeia 8.0 because of the large content of baicalin in comparison with aerial parts.[
It is thought that the antimicrobial properties of S. baicalensis are due to the flavonoids baicalin and its aglycone baicalein. Their antibacterial mechanism of action has been suggested to be related to the inhibition of cell wall synthesis by damaging the peptidoglycan structure.[
Based on our findings, the extracts of S. altissima contain the main bioactive compounds baicalin and baicalein responsible for the therapeutic properties of S. baicalensis, but plant extracts also contain other concomitant substances (e.g.,diterpenes, phenylethanoid glycosides, iridoid glycosides, polysaccharides, and other compounds) which may increase or decrease the effect of the main active compounds. This may be the reason for the stronger antimicrobial activity of substances isolated in pure form, compared to plant extracts and probably the reason why the tested S. altissima extracts were found to be inactive against S. aureus, E. coli, and C. albicans even at the highest concentrations. For instance, Chen et al. have found that sub-inhibitory concentrations of baicalein alone effectively prevent S. aureus biofilm formation and improve antibiotic permeability.[
The flavonoid composition in different plant parts of S. altissima varies as affected by geographical region. The pharmacologically active flavonoids: baicalin, baicalein, wogonoside, wogonin, and scutellarin are contained in all examined plant parts of S. altissima with notably higher baicalin content in the aerial parts of S. altissima from the region of Mezek. The 70% ethanol extracts of S. altissima exhibit a significantly greater antimicrobial effect against S. mitis, while the effect of aqueous extracts occurs after prolonged treatment time. S. mitis is more susceptible to the extracts obtained from the aerial parts than to the extracts obtained from the roots of S. altissima. The effective antimicrobial properties of extracts of Bulgarian S. altissima against S. mitis suggests its potential as a source for the development of natural antimicrobial agents for the suppression of oral pathogens and prevention of some oral infections.
The study was supported by Research Project НО-01/2018, funded by the Medical University of Plovdiv, Bulgaria. We would like to thank Alexandrina Delova for the revision of the English translation.