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RELATIONSHIP BETWEEN BIOCHEMICAL INDICATORS AND PHENOTYPICAL CHARACTERISTICS OF THYME (THYMUS VULGARIS L.)

DOI: https://doi.org/10.29296/25877313-2024-03-04
Issue: 
3
Year: 
2024

E.L. Malankina
Dr.Sc. (Agricul.), Professor, Vegetable Growing Department,
Russian State Agrarian University – Moscow Timiryazev Agricultural Academy (Moscow, Russia)
Е-mail: gandurina@mail.ru
E.N. Tkatchova
Ph.D. (Agricul.), Vegetable Growing Department,
Russian State Agrarian University – Moscow Timiryazev Agricultural Academy (Moscow, Russia)
H.A.H. Al Karavi
Ph.D. (Biol.),
Babylon University / College of Science – Biology Department (Babylon, Iraq)

Introduction. Thyme (Thymus vulgaris L.) is a sought-after medicinal crop, the raw materials of which are included in the Pharmacopoeias of several countries and are widely used in scientific medicine. Due to the presence of strong intraspecific diversity in thyme, it seems interesting to identify phenotypic characteristics that most likely indicate the presence of certain pharmacologically significant compounds. The presence of such information will allow targeted selection both in natural populations and during the hybridization of cultivars and the development of new varieties. The purpose of the work was to identify phenotypic traits indicating a high content of essential oil and thymol in thyme, the amount of phenolic compounds, flavonoids and tannins. Material and methods. Samples and varieties of thyme from different geographical origins were selected as objects. Biometric, anatomical indicators and yield were determined in the flowering phase. The essential oil content was determined by Clevenger hydrodistillation method. Component composition was determined by gas chromatography. The amount of phenolic compounds and tannins according to the Folin-Ciocalteu method in aqueous-alcoholic extract calculated as gallic acid. The determination of flavonoids in the aqueous-alcoholic extract was carried out using the spectrophotometryс method calculated as rutin. Results. As a result of the research, no signs were found indicating a high content of essential oil. Flavonoid content calculated as rutin had a negative correlation (−0.72) with stomatal density. A negative relationship was noted between the intensity of coloring of the pistil and anthers and the content of the total phenolic compounds calculated as gallic acid (0.71 and 0.72, respectively). Large stomata on both the underside and upper side of the leaf may indicate a high tannin content (0.8 and 0.88). All studied components of common thyme belonged to the thymol type, and the content of this component ranged from 37.6 to 80.8%. An increased content of thymol in essential oil is observed such signs as an elongated leaf shape (leaf index R = 0.78), lack of downward curling of the edges of the leaf blade (R = –0.78) and pronounced veins on the underside of the leaf (R = 0.92). Large stomata on the lower epidermis also indicate an increased proportion of thymol in the essential oil (R = 0.78). When analyzing the interdependence between the content of the main components of essential oil, it was noted that there is a close negative correlation between the content of p-cymene and thymol (R = –0.91) and carvacrol (R = –0.88). Conclusion. As a result of the research, phenotypic and anatomical characteristics were identified that make it possible to diagnose promising samples of common thyme, which will help speed up the selection process.
Keywords: 
Common thyme
essential oil
flavonoids
polyphenols
Thymol.
References: 
  1. Mewes S., Krüger H., Pank F. Physiological, morphological, chemical and genomic diversities of different origins of thyme (Thymus vulgaris L.). Genet Resour Crop Evol. 2008; 55: 1303–1311.
  2. Buzuk A., Buzuk G., Leshev S. et al. Variability in essential oil compositions of Thymus pulegioides L. and Thymus serpyl-lum L. growing in the Republic of Belarus. American Journal of Essential Oils and Natural Products. 2017; 5(3): 25–31.
  3. Rustaieea A., Yavari A., Nazerib V. et al. Genetic Diversity and Chemical Polymorphism of Some Thymus Species. Chemistry & Biodiversity. 2013; 10: 1088–1098.
  4. Gosudarstvennaja farmakopeja Rossijskoj Federacii XIV izdanija. Tom IV. Ministerstvo zdravoohranenija Rossijskoj Federacii. URL: https://docs.rucml.ru/feml/pharma/v14/vol4/1287/ (data obrashhenija: 30.03.2023).
  5. Wesołowska A., Jadczak D. Comparison of the Chemical Composition of Essential Oils Isolated from Two Thyme (Thymus vulgaris L.) Cultivars. Not Bot Horti Agrobo. 2019; 47(3): 829–835.
  6. Malankina E.L., Kozlovskaya E.L., Kuzmenko A.N. et al. De-termination of the component composition of essential oil of thyme species by the method of gas chromatograph. Moscow University Chemistry Bulletin. 2019; 74(6): 310–314.
  7. LeBel G., Vaillancourt K., Bercier P. et al. Antibacterial activity against porcine respiratory bacterial pathogens and in vitro biocompatibility of essential oils. Arch Microbiol. 2019; 201: 833–840.
  8. Krause S., Liaob P., Crocollc Chr. et al. The biosynthesis of thymol, carvacrol, and thymohydroquinone in Lamiaceae pro-ceeds via cytochrome P450s and a short-chain dehydro-genase. PNAS. 2021; 118: 52 e2110092118; https://doi.org/ 10.1073/pnas.2110092118.
  9. Malankina E.L., Tkachjova E.N., Al' Karavi H. i dr. Var'irovanie biohimicheskih pokazatelej syr'ja tim'jana polzuchego (Thymus serpyllum L.) v zavisimosti ot sorta. Voprosy biologicheskoj, medicinskoj i farmacevticheskoj himii. 2018; 21(7): 11–15.
  10. Horwath A.B., Grayer R.J., Keith-Lucas D.M. et al. Chemical characterization of wild populations of Thymus from dif-ferent climatic regions in southeast Spain. Biochemical Systematics and Ecology. 2008; 36:117–133.
  11. Patil Sh., R. Ramu, Shivamallu Ch. et al. A systematic review on ethnopharmacology, phytochemistry and pharmacological aspects of Thymus vulgaris L. Heliyon. 2021; 7(5): e07054.
  12. Malankina E.L., Solopov S.G., Romanova N.G. Vzaimosvjaz' mezhdu biohimicheskimi pokazateljami i fenotipicheskimi priznakami chabera sadovogo (Satureja hortensis L.). Voprosy biologicheskoj, medicinskoj i farmacevticheskoj himii. 2023; 26(4): 10–15.
  13. Mewes S., Krüger H., Pank F. Physiological, morphological, chemical and genomic diversities of different origins of thyme (Thymus vulgaris L.). Genet Resour Crop Evol. 2008; 55: 1303–1311.
  14. Lohwasser U., Boerner A., Novak J. Screening der Ga-tersleben Rosmarin-Kollektion. 23. Bernburger Wintersemi-nar Arznei- und Gewuerzpflanzen, 20.02-21.02.2018. Bern-burg. 2018; p. 21–23.
  15. Gosudarstvennaja farmakopeja Rossijskoj Federacii XIV izdanija, tom III. Ministerstvo zdravoohranenija Rossijskoj Federacii. URL: https://docs.rucml.ru/feml/pharma/v14/vol3/151/ (data obrashhenija: 28.09.2023).
  16. Rukovodstvo po metodam kontrolja kachestva i bezopasnosti biologicheski aktivnyh dobavok k pishhe R 4.1.167203/ M., 2004. Metody analiza minornyh biologicheski aktivnyh veshhestv pishhi. Pod red. V.A. Tutel'jana i K.I. Jellera. M.: Dinastija. 2010; 60 s.