Pyrimidine Derivatives As Analogues Of Plant Hormones For Intensification Of Wheat Growth During The Vegetation Period
Keywords:plant growth regulators, pyrimidine derivatives, auxins, wheat (Triticum aestivum L
Wheat is one of the economically important cereals that are widely used in the agricultural sector of many countries. A very important issue is the development of new effective growth regulators to improve the growth and development of this crop in order to increase its productivity. In our investigations the regulating activity of the synthetic low molecular weight heterocyclic compounds, pyrimidine derivatives on growth and development of wheat (Triticum aestivum L.) variety Tyra was studied. It was found that the use of pyrimidine derivatives in a concentration of 10-7M in water solution revealed a positive effect on the growth and development of both shoot and root systems of wheat plants during the vegetation period. Comparative analysis of the growth regulating activity of synthetic compounds showed that the activity of pyrimidine derivatives was differentiated and depended on substituents in their chemical structure. The application of pyrimidine derivatives as new effective regulators of growth and development of wheat (Triticum aestivum L.) variety Tyra was proposed.
Faltermaier А., Waters D., Becker T., Arendt E. and Gastl M. (2014). Common wheat (Triticum aestivum L.) and its use as a brewing cereal – a review. J. Inst. Brew.; 120: 1-15.
Shiferaw B., Smale M., Braun H.J., Duveiller E., Reynolds M., Muricho G. (2013). Crops that feed the world. Past successes and future challenges to the role played by wheat in global food security. Food Sec.; 5(3):291-317.
Rejeb I.B., Pastor V. and Mauch-Mani B. (2014). Plant Responses to Simultaneous Biotic and Abiotic Stress: Molecular Mechanisms. Plants; 3: 458-475.
Dresselhaus, T., and Hückelhoven R. (2018). Biotic and Abiotic Stress Responses in Crop Plants. Agronomy; 8: 267.
Gimenez E., Salinas M. and Manzano-Agugliaro F. (2018). Worldwide Research on Plant Defense against Biotic Stresses as Improvement for Sustainable Agriculture. Sustainability; 10: 391.
Anderson R., Bayer P.E., and Edwards D. (2020). Climate change and the need for agricultural adaptation. Current opinion in plant biology; 56: 197-202.
Fahad S., Bajwa A. A., Nazir U., Anjum S. A., Farooq A., Zohaib A., Sadia S., Nasim W., Adkins S., Saud S., Ihsan M. Z., Alharby H., Wu C., Wang D., & Huang J. (2017). Crop Production under Drought and Heat Stress: Plant Responses and Management Options. Frontiers in plant science; 8: 1147. https://doi.org/10.3389/fpls.2017.01147
Alewu B. and Nosiri C. (2011). Pesticides and Human Health, Pesticides in the Modern World - Effects of Pesticides Exposure, M. Stoytcheva (Ed.), InTechOpen.
Nicolopoulou-Stamati P., Maipas S., Kotampasi C., Stamatis P., Hens L. (2016). Chemical Pesticides and Human Health: The Urgent Need for a New Concept in Agriculture. Front Public Health, 4: Article 148.
Tsygankova V.A., Andrusevich Ya.V., Shtompel O.I., Pilyo S.G., Kornienko A.M., Brovarets V.S. (2018). Acceleration of vegetative growth of wheat (Triticum aestivum L.) using [1,3]oxazolo[5,4-d]pyrimidine and N-sulfonyl substituted 1,3-oxazole. The Pharmaceutical and Chemical Journal; 5(2): 167-175.
Tsygankova V.A., Andrusevich Ya.V, Shtompel O.I, Kopich V.M, Panchyshyn S.Ya, Vydzhak R.M, Brovarets V.S (2019). Application of Pyrazole Derivatives As New Substitutes of Auxin IAA To Regulate Morphometric and Biochemical Parameters of Wheat (Triticum Aestivum L.) Seedlings. Journal of advances in agriculture; 10: 1772-1786. https://doi.org/10.24297/jaa.v10i0.8341
Su Y.H., Liu Y.B. and Zhang X.S. (2011). Auxin–Cytokinin Interaction Regulates Meristem Development. Molecular Plant; 4: 4: 616–625.
Schaller G.E., Bishopp A., and Kieber J.J. (2015). The Yin-Yang of Hormones: Cytokinin and Auxin Interactions in Plant Development. The Plant Cell: 27: 44–63.
Denancé N., Sánchez-Vallet A., Goffner D. and Molina A. (2013). Disease resistance or growth: the role of plant hormones in balancing immune responses and fitness costs. Frontiers in Plant Science; 4 (Article 155): 1–12.
Wania S.H., Kumarb V., Shriramc V., Sah S.K. (2016). Phytohormones and their metabolic engineering for abiotic stress tolerance in crop plants. The crop journal; 4: 162–176.
Rigal A., Ma Q., Rober S. (2014). Unraveling plant hormone signaling through the use of small molecules. Front. Plant Sci.; 5: 1- 20.
Sosnowski J., Malinowska E., Jankowski K., Król J., & Redzik P. (2019). An estimation of the effects of synthetic auxin and cytokinin and the time of their application on some morphological and physiological characteristics of Medicago x varia T. Martyn. Saudi journal of biological sciences; 26(1): 66–73. https://doi.org/10.1016/j.sjbs.2016.12.023
Zhao Yu. (2010). Auxin biosynthesis and its role in plant development. Annu Rev Plant Biol; 61: 49-64.
Enders T.A., Strader L.C. (2015). Auxin activity: Past, present, and future. Am J Bot; 102(2): 180–196.
Mok D.W.S., Mok M.C. (2001). Cytokinin metabolism and action. Annu. Rev. Plant Physiol. Plant Mol Biol; 52: 89-118.
Zwack P.J., Rashotte A.M. (2013). Cytokinin inhibition of leaf senescence. Plant Signaling & Behavior. 8(7): e24737.
Kieber J. J., Schaller G.E. (2018). Cytokinin signaling in plant development. Development; 145 (dev149344): 1–7.
Hönig M., Plíhalová L., Husicková A., Nisler J. and Doležal K. (2018). Role of Cytokinins in Senescence, Antioxidant Defenc, and Photosynthesis. Int. J. Mol. Sci. 19(4045): 1–23.
Kuragano T., Tanaka Y. (2002). Dérivés de la pyrimidine et herbicides les contenant, Patent WO 2002038550 A1.
Minn K., Dietrich H., Dittgen J., Feucht D., Häuser-Hahn I., Rosinger C.H. (2008). Pyrimidine derivatives and their use for controlling undesired plant growth. Patent US 8329717 B2.
Whittingham W.G., Winn C.L., Glithro H., Boussemghoune M.A., Aspinall M.B. (2010). Pyrimidine derivatives and their use as herbicides. WO Patent 2010092339 A1.
Cansev A., Gulen H., Zengin M.K., Ergin S., Cansev M., Kumral N.A. (2016). Use of pyrimidines in stimulation of plant growth and development and enhancement of stress tolerance. Patent US 20160000075.
Kawarada A., Nakayama M., Ota Ya., Takeuchi S. (1973). Use of pyridine derivatives as plant growth regulators and plant growth regulating agents. Patent DE2349745A1.
Mansfield D.J., Rieck H., Greul J., Coqueron P.Y., Desbordes P., Genix P., Grosjean-Cournoyer M.C., Perez J., Villier A. (2010). Pyridine derivatives as fungicidal compounds. Patent US7754741B2.
Tsygankova V., Andrusevich Ya., Shtompel O., Romaniuk O., Yaikova M., Hurenko A., Solomyanny R., Abdurakhmanova E., Klyuchko S., Holovchenko O., Bondarenko O., Brovarets V. (2017). Application of Synthetic Low Molecular Weight Heterocyclic Compounds Derivatives of Pyrimidine, Pyrazole and Oxazole in Agricultural Biotechnology as a New Plant Growth Regulating Substances. Int J Med Biotechnol Genetics; S2: 002: 10-32.
Tsygankova V.A., Andrusevich Ya.V., Shtompel O.I., Kopich V.M., Pilyo S.G., Prokopenko V.M, Kornienko A.M, Brovarets V.S. (2017). Intensification of Vegetative Growth of Cucumber by Derivatives of [1,3]oxazolo[5,4-d]pyrimidine and N-sulfonyl substituted of 1,3-oxazole. Research Journal of Life Sciences, Bioinformatics, Pharmaceutical, and Chemical Sciences (RJLBPCS); 3(4): 107-122.
Tsygankova V.A., Andrusevich Ya.V., Shtompel O.I., Solomyanny R.M., Hurenko A.O., Frasinyuk M.S., Mrug G.P., Shablykin O.V., Pilyo S.G., Kornienko A.M., Brovarets V. (2018). Study of auxin-like and cytokinin-like activity of derivatives of pyrimidine, pyrazole, isoflavones, pyridine, oxazolopyrimidine and oxazole on haricot bean and pumpkin plants. International Journal of ChemTech Researc; 11(10): 174-190.
Tsygankova V., Andrusevich Ya., Shtompel O., Kopich V., Solomyanny R., Bondarenko O., Brovarets V. (2018). Phytohormone-like effect of pyrimidine derivatives on the regulation of vegetative growth of tomato. International Journal of Botany Studies; 3(2): 91–102.
Tsygankova V.A., Andrusevich Ya.V., Shtompel O.I., Shablykin O.V., Hurenko A.O., Solomyanny R.M., Mrug G.P., Frasinyuk M.S., Pilyo S.G., Kornienko A.M., Brovarets V.S. (2018). Auxin-like effect of derivatives of pyrimidine, pyrazole, isoflavones, pyridine, oxazolopyrimidine and oxazole on acceleration of vegetative growth of flax. International Journal of PharmTech Research; 11(3): 274-286.
Tsygankova V.A., Andrusevich Ya.V., Shtompel O.I., Kopich V.M., Solomyanny R.M., Brovarets V.S. (2019). Study of regulating activity of synthetic low molecular weight heterocyclic compounds, derivatives of pyrimidine on growth of tomato (Solanum lycopersicum L.) seedlings. International Journal of ChemTech Research; 12(5):26-38.
Mohilnikova I.V., Tsygankova V.A., Solomyannyi R.M., Brovarets V.S., Bilko N.М., Yemets А.І.. (2020). Screening of growth-stimulating activity of synthetic compounds — pyrimidine derivatives. Dopov. Nac. akad. nauk Ukr.; 10: 62-70. https://doi.org/10.15407/dopovidi2020.10.062
Voytsehovska O.V., Kapustyan A.V., Kosik O.I., Musienko M.M., Olkhovich O.P., Panyuta O.O., Parshikova T.V., Glorious P.S. (2010). Plant Physiology: Praktykum. Lutsk, Teren, 420 p.
Lichtenthaler H. (1987). Chlorophylls and Carotenoids: Pigments of Photosynthetic Biomembranes Methods Enzymol. 148: 331 – 382.
Lichtenthaler H.K., Buschmann C. (2001).Chlorophylls and Carotenoids: Measurement and Characterization by UV-VIS Spectroscopy Current Protocols in Food Analytical Chemistry (CPFA): John Wiley and Sons, New York, F4.3.1-F4.3.8.
Bang H., Zhou X.K., van Epps H.L., Mazumdar M. (2010).Statistical Methods in Molecular Biology. Series: Methods in molecular biology New York: Humana press; 13(620): 636 p.
How to Cite
Copyright (c) 2022 Tsygankova V. A, Voloshchuk I.V, Andrusevich Ya.V., Kopich V. M, Pilyo S. G, Klyuchko S. V, Kachaeva M. V
This work is licensed under a Creative Commons Attribution 4.0 International License.
All articles published in Journal of Advances in Linguistics are licensed under a Creative Commons Attribution 4.0 International License.