Regulation of Potato Morphogenetic Processes in vitro by Hormonal and Light Actions
الموضوعات :
Kuanysh Syman
1
,
Rauza Turpanova
2
,
Raissa Utegaliyeva
3
,
Nazym Bekenova
4
,
Demeuova Lyazat
5
1 - Institute of Natural Sciences and Geography, Abai Kazakh National pedagogical university, Almaty, Kazakhstan
2 - Department of Biotechnology and Microbiology, Faculty of Natural Sciences, Eurasian National University,
Nur-Sultan, Kazakhstan
3 - Food Biotechnology Department, Faculty of Food Technology, Almaty Technological University, Kazakhstan
4 - Institute of Natural Sciences and Geography, Abai Kazakh National pedagogical university, Almaty, Kazakhstan
5 - Institute of Natural Sciences and Geography, Abai Kazakh National pedagogical university, Almaty, Kazakhstan
تاريخ الإرسال : 10 الثلاثاء , جمادى الثانية, 1444
تاريخ التأكيد : 01 الثلاثاء , شعبان, 1444
تاريخ الإصدار : 16 الجمعة , صفر, 1445
الکلمات المفتاحية:
phytohormones,
rhizogenesis,
Potato,
Light spectrum,
Morphogenesis,
ملخص المقالة :
The research on how phytohormones and light affect the morphogenetic responses of potatoes in culture conditions is presented in this article. Researchers looked at how growth promoters affect the regulation of potato morphogenesis in in vitro cultures of different potato varieties. They also looked at how light quality affects this regulation. Research has been conducted on Kazakh selection potatoes, which are commonly grown in Northern and Central Kazakhstan. In the course of the research, various variants of phytohormones and light quality were used for the growing and developing of micro-gears in vitro. The light quality has a different action on the potatoes' speed of growth. For example, rhizogenesis for the Tamyr variety has increased because of red light use. For the Aksor, Orbitaa, and Nerli varieties the best results were got in case the white light has been used. The concentration of the phytohormones has an influence on the potatoes growing. So, the most effective leafiness of shoots of all considered potato varieties has been gotten by auxin use in the concentration of 0.1 and 0.5 μM.
المصادر:
Beals K.A., 2019. Potatoes, nutrition and health. American Journal of Potato Research. 96(2), 102–110.
Harahagazwe D., Condori B., Barreda C., Bararyenya A., Byarugaba A.A., Kude D.A., Lung’aho C., Martinho C., Mbiri D., Nasona B., 2018. How big is the potato (Solanum tuberosum L.) yield gap in Sub-Saharan Africa and why? A participatory approach. Open Agriculture. 3(1), 180–189.
McGill C.R., Kurilich A.C., Davignon J., 2013. The role of potatoes and potato components in cardiometabolic health: a review. Annals of Medicine. 45(7), 467–473.
Kharumnuid P., Pandey N.K., Devarani L., Chauhan J.K., Singh R., Das B., Marbaniang E.K., 2021. Potato production for nutritional security and doubling farmers’ income. Journal of Pharmacognosy and Phytochemistry. 10(1S), 193–197.
Agarwal S., Fulgoni III V.L., 2021. Intake of potatoes is associated with higher diet quality, and improved nutrient intake and adequacy among US adolescents: NHANES 2001–2018 Analysis. Nutrients. 13(8), 2614.
Agarwal M., Sinha A., Gupta S.K., Mishra D., Mishra R., 2020. Potato crop disease classification using convolutional neural network. Smart Systems and IoT: Innovations in Computing: Proceeding of SSIC 2019. 391–400.
Daurov D., Daurova A., Karimov A., Tolegenova D., Volkov D., Raimbek D., Zhambakin K., Shamekova M., 2020. Determining Effective Methods of Obtaining Virus-Free Potato for Cultivation in Kazakhstan. American Journal of Potato Research. 97 367–375.
Alexandrova A.M., Karpova O.V., Nargilova R.M., Kryldakov R.V., Nizkorodova A.S., Zhigaylov A.V., Yekaterinskaya E.M., Kushnarenko S.V., Akbergenov R.Z., Iskakov B.K., 2018. Distribution of potato (Solanum tuberosum) viruses in Kazakhstan. International Journal of Biology and Chemistry. 11(1), 33–40.
Mahmood-babooi K., Akbari-adergani B., Salehi A., Sadighara P., 2022. Solid-to-Liquid Extraction for Analysis of Polyaromatic Hydrocarbons in Tahdig of Potato by GC/MS: Comparison between Traditional Solvent and Sonication Methodologies. Journal of Chemical Health Risks. 12(3), 349–354.
Torabi Z., MohammadiNafchi A., 2013. The effects of SiO2 nanoparticles on mechanical and physicochemical properties of potato starch films. Journal of Chemical Health Risks. 3(1), 33-42.
Zhambakin K., Zhapar K., 2020. Current status and prospects of plant biotechnology in Kazakhstan. Plant Biotechnology Reports. 14 177–184.
Daurov D., Argynbayeva A., Daurova A., Zhapar K., Sapakhova Z., Zhambakin K., Shamekova M., 2022. Monitoring the Spread of Potato Virus Diseases in Kazakhstan. American Journal of Potato Research. 1–8.
Uskov A.I., Kravchenko D.V., Galushka P.A., Uskova L.B., 2021. New nano-geroprotectors application in seed potato production. Research on Crops. 22(spl), 86–90.
Oves E.V., Zhevora S.V., Gaitova N.A., Boyko N.A., Fenina N.A., Shishkina O.A., 2021. Assessment of potato in vitro morphogenesis. IOP Conference Series: Earth and Environmental Science. 659(1), 012093.
Miku\la A., Tomaszewicz W., Dziurka M., Kaźmierczak A., Grzyb M., Sobczak M., Zdańkowski P., Rybczyński J., 2021. The origin of the Cyathea delgadii Sternb. somatic embryos is determined by the developmental state of donor tissue and mutual balance of selected metabolites. Cells. 10(6), 1388.
Murashige T., Skoog F., 1962. A revised medium for rapid growth and bio assays with tobacco tissue cultures. Physiologia Plantarum. 15(3), 473–497.
Witte C.P., Tiller S.A., Taylor M.A., Davies H.V., 2002. Addition of nickel to Murashige and Skoog medium in plant tissue culture activates urease and may reduce metabolic stress. Plant Cell, Tissue and Organ Culture. 68 103–104.
Al-Taleb M.M., Hassawi D.S., Abu-Romman S.M., 2011. Production of virus free potato plants using meristem culture from cultivars grown under Jordanian environment. American-Eurasian Journal of Agricultural & Environmental Sciences. 11(4), 467–472.
Kolomiets T.M., Malyarovskaya V.I., Samarina L.S., 2016. In vitro Conservation of Campanula sclerophylla Kolak? Endemic Endangered Species of Western Caucasus. Plant Tissue Culture and Biotechnology. 26(2), 143–149.
Belous O.G., Malyarovskaya V.I., Kolomiets T.M., 2012. Effect of spectral composition of light on growth of chryzantemum morifolium in vitro. Nauka i Studia. (10), 30–35.
Sergeeva L.I., Macháčková I., Konstantinova T.N., Golyanovskaya S.A., Eder J., Zaltsman O.O., Hanuš J., Aksenova N.P., 1994. Morphogenesis of potato plants in vitro. II. Endogenous levels, distribution, and metabolism of IAA and cytokinins. Journal of Plant Growth Regulation. 13 147–152.
Singh R.K., Buckseth T., Tiwari J.K., Sharma A.K., Chakrabarti S.K., 2019. Recent advances in production of healthy planting material for disease management in potato. Biotech Today: An International Journal of Biological Sciences. 9(1), 7–15.
Cray J.A., Connor M.C., Stevenson A., Houghton J.D., Rangel D.E., Cooke L.R., Hallsworth J.E., 2016. Biocontrol agents promote growth of potato pathogens, depending on environmental conditions. Microbial Biotechnology. 9(3), 330–354.
Martirosyan Y.T., Dilovarova T.A., Martirosyan V.V., Kreslaversuskii V.D., Kosobryukhov A.A., 2016. Photosynthetic apparatus of potato plants (Solanum tuberosum L.) grown in vitro as influenced by different spectral composition of led radiation. Agric Biol. 51 680–687.
Durnikin D.A., Kolpakov N.A., Guseva K.Y., Matsyura A.V., 2019. In vitro micropropagation and ex vitro rooting of some potato varieties. Ukrainian Journal of Ecology. 9(4), 679–689.
Dhaka M., Nailwal T.K., 2015. High efficiency macropropagation of potato (Solanum tuberosum L.) cv. Kufri Jyoti in Kumaun Hills. Journal of Plant Breeding and Crop Science. 7(7), 203–210.
Burygin G.L., Kargapolova K.Y., Kryuchkova Y.V., Avdeeva E.S., Gogoleva N.E., Ponomaryova T.S., Tkachenko O.V., 2019. Ochrobactrum cytisi IPA7. 2 promotes growth of potato microplants and is resistant to abiotic stress. World Journal of Microbiology and Biotechnology. 35 1–12.