Improvement of the technological process of obtaining initial pear plants

The process of obtaining initial pear plants is considered. The technological process includes the selection of plants of a certain variety according to pomological, physiological qualities and productivity; diagnostics for the presence of viruses, phytoplasmas and other harmful organisms by ELISA, PCR and indicators testing; in the absence of healthy plants – release from pathogens by methods of thermotherapy, chemotherapy, in vitro culture, magnetotherapy with re-testing. After preliminary testing in greenhouse conditions, candidate plants for initial plants are obtained, which are then subjected to testing using a set of diagnostic methods. Plants free from the main harmful viruses and phytoplasma are transferred to the category of “initial plants”, and if all the tested plants are infected, they are subjected to recovery. Dry air thermotherapy in combination with grafting of apexes on virus-free rootstocks provides the possibility of obtaining healthy plants during one growing season. For chemotherapy, along with reference drugs (ribavirin), the use of phenolic compounds (salicylic, gallic acids) is promising, which can increase the efficiency of plant recovery from viruses by an average of 28–30%, reduce the cost of the recovery process and improve workplace safety. The use of magnetic pulse processing increases the environmental safety of the technology in the absence of the phytotoxic effect. After diagnosis by a complex of methods in the absence of viruses, pear plants receive the category “initial plant” and are further propagated by budding or grafting.

1. Upadyshev M.T., Kulikov I.M., Petrova A.D., Metlitskaya K.V., Donetskikh V.I. Modern methods of healing fruit and small fruit crops from harmful viruses. Moscow; Saratov, 2019, 168 p. (In Russian).

2. Karpushina M.V., Suprun I.I. Methods and approaches to virus elimination under in vitro and in vivo conditions. Plodovodstvo i vinogradarstvo Yuga Rossii = Fruit Growing and Viticulture of South Russia, 2020, no. 63 (3), pp. 254–269. (In Russian). DOI: 10.30679 / 2219-5335-2020-3-63-254-269.

3. Dadu K.Ya., Chernets A.M., Kalashyan Yu.A., Prodanyuk L.N. Introduction of certificationsystem for fruit planting material in the Republic of Moldova. Sadovodstvo i vinogradarstvo = Horticulture and viticulture, 2018, no. 2, рр. 58–60. (In Russian). DOI: 10.25556/VSTISP.2018.2.12309.

4. Ziza R. Italian certification system. Voluntary genetic and phytosanitary certification of fruit crops. Sadovodstvo i vinogradarstvo = Horticulture and viticulture, 2018, no. 2, рр. 49–53. (In Russian). DOI: 10.25556/VSTISP.2018.2.12307.

5. Hu G., Dong Y., Zhang Z., Fan X., Ren F., Li Z. Efficacy of virus elimination from apple by thermotherapy coupled with in vivo shoot-tip grafting and in vitro meristem culture. Phytopathologische Zeitschrift, 2017, vol. 165, no. 10, pp. 701–706. DOI: 10.1111/jph.12610.

6. Bamatov I.M. Modern methods of plant health improvement. Plodovodstvo i vinogradarstvo Yuga Rossii = Fruit Growing and Viticulture of South Russia, 2018, no. 53 (5), pp. 67–79. (In Russian). DOI: 10.30679/2219-5335-2018-5-53-67-79.

7. Vivek M., Modgil M. Elimination of viruses through thermotherapy and meristem culture in apple cultivar ‘Oregon Spur-II’. Virus Disease, 2018, vol. 29 (1), pp. 75–82. DOI: 10.1007/s13337-018-0437-5.

8. Lizarraga A., Ascasíbar J., Gonzalez M.L. Fast and effective thermotherapy treatment for in vitro virus elimination in apple and pear trees. American Journal of Plant Sciences, 2017, vol. 8 (10), рр. 2474–2482. DOI: 10.4236/ajps.2017.810168.

9. Li X.L., Li M.J., Zhou J., Wei Q.P., Zhang J.K. Anzucht von virusfreien Bäumen durch Wärmebehandlung und Faktoren, die den Erfolg der Virusfreimachung beeinflussen. Erwerbs-Obstbau, 2020, vol. 62, ss. 257–264. DOI: 10.1007/s10341-020-00480-3.

10. Romadanova N., Tolegen A., Koken T., Nurmanov M., Kushnarenko S. Chemotherapy of apple shoots in vitro as method of viruses eradication. International Journal of Biology and Chemistry, 2021, vol. 14 (1), pp. 48–55. DOI: 10.26577/ijbch.2021.v14.i1.04.

11. Karimpour S., Davarynejad G., Aghl M., Safarnejad Reza. In vitro thermotherapy and thermo-chemotherapy approaches to eliminate some viruses in Pyrus communis L. cv. ‘Natanz’. Journal of Agricultural Science and Technology, 2020, vol. 22, pp. 1645–1653.

12. Vysotsky V.A. Improving of micrografting technique for propagation of difficult to root forms of fruit-trees. Plodovodstvo i yagodovodstvo Rassii = Pomiculture and Small Fruits Culture in Russia, 2017, vol. 50, pp. 93–96. (In Russian).

13. Donetskich V.I., Upadyshev M.T., Petrova A.D., Metlitskaya K.V., Selivanov V.G. Application of AMIS‑8 preparatus to combat viruses when preparing planting stock of fruit crops. Tekhnika i oborudovanie dlya sela = Machinery and Equipment for Rural Area, 2017, no. 1 (235). pp. 16–22. (In Russian).