Pollen reaction of mutant tomato forms to abiotic stress factors

Авторы

  • Мilania Makovei Moldova State University, Institute of Genetics, Physiology and Plant Protection, Moldova, Republic of

DOI:

https://doi.org/10.30835/2413-7510.2023.293843

Ключевые слова:

tomato, mutant forms, traits, male gametophyte, resistance, stress factors, high temperature, low temperature, drought

Аннотация

The article presents the results of screening accessions of the mutant tomato gene pool (125 genotypes) based on the response of their pollen to abiotic stress factors (high, low temperatures, drought) in order to study their potential and identify genetic sources/donors of resistance. The studies were carried out in open ground conditions from 2015 to 2017 and in summer greenhouses from 2017 to 2019. High heterogeneity of the genotype-specific response of pollen of mutant forms to various stress factors was shown: with a lethal outcome to all factors (10 genotypes); highly resistant to all stressors (20 genotypes); combining resistance: to high and low temperatures (7 genotypes), to high temperature and drought (9 genotypes), to cold and drought (4 genotypes); resistant only: to high (14 genotypes) or low (17 genotypes) temperatures, drought (6 genotypes). Mutant forms (38 genotypes) with high intrapopulation variability in pollen germination and the ability to form long pollen tubes under various stressors were also identified. It was established that resistance to heat, cold and drought according on traits of the male gametophyte was determined by different genetic systems.

Библиографические ссылки

AtlasBig.com (2018-2020). https://www.atlasbig.com/en-ie/countries-by-tomato-production.

Avdeyev A.Yu. Spontaneous mutations of tomato in size, shape, weight of the fruit and the evolution of the trait. Reports. RAAS. 2014. 1: 16–19. [in Russian]

Chesnokov Yu.V., Kosolapov V.M., Savchenko I.V. Morphological genetic markers in plants. Genetika. 2020; 56(12): 1366–1377. https://doi.org/10.31857/s0016675820120048 [in Russian]

Chetelat, R. T., X. Qin, M. Tan, D. Burkart-Waco, Y. Moritama, X. Huo, T. Wills and R. Pertuze. Introgression lines of Solanum sitiens, a wild nightshade of the Atacama Desert, in the genome of cultivated tomato. The Plant Journal. 2019; 100: 836–850. https://doi.org/10.1111/tpj.14460

Toal, T. W., D. Burkart-Waco, T. Howell, M. Ron, S. et. al. Indel Group in Genomes IGG) Molecular Genetic Markers. 2016. Plant Physiology. 2016; 172: 38–61. https://doi.org/10.1104/pp.16.00354

Qin, X. and Chetelat, R. T. Ornithine decarboxylase genes contribute to S-RNase-independent pollen rejection. Plant Physiology. 2021; 186(1): 452–468. https://doi.org/10.1093/plphys/kiab062.

Bekov R.Kh. Tomatoes. Moscow. 2014. 369 p. ISBN: 978-5-7367-1052-2. [in Russian]

Bocharnikova N.I. Genetic collection of mutant forms of tomato and its use in breeding and genetic studies. Moscow. 2011. 120 p. [in Russian]

Kuzeminskyi A.V. Breeding and genetic studies of mutant forms of tomato. Kharkiv. 2004. 391 p. [in Ukrainian]

Kang M.S. Breeding: Genotype-by-environment interaction. In: R.M. Goodman (ed.). Encyclopedia of Plant and Crop Science. New York: Marcel-Dekker; 2004; 218-221.

Fentic, D.A. Review on Genetics and Breeding of Tomato (Lycopersicon esculentum Mill). Advanced in Crop Sci. and Techology. 2017; 5(5): 306. https://doi.org/10.4172/2329-8863.1000306

Alagna, F., Balestrini, R., Chitarra, W., Marsico, A.D., Nerva, L. Chapet 3 – Getting ready with the priming: innovative weapons against biotic and abiotic crop enemies in a global changing scenario. In: Priming-mediated stress and cross-srtess tolerance in crop plants. Eds. M.A. Hossain, F. Liu, D.J. Burrit, M. Fujita, B. Huang. New York: Academic press. 2020: 35–56. https://doi.org/10.1016/B978-0-12-817892-8.00003-9.

Zhuchenko A.A. Adaptive crop production (ecological and genetic foundations) theory and practice. Moscow: Agrorus. 2009. 2: 647–651. [in Russian]

Udovenko, G.V. Plant resistance to adverse environmental conditions and selection. In: VIR Bulletin. 2011; 86:3–4. [in Russian]

Vavilov N.I. Botanical and geographical bases of breeding (the doctrine of the source material in breeding) In: Theoretical foundations of plant breeding. Leningrad. 1935, 1: 17–74. [in Russian]

Zhuchenko, A. A. Mobilization of genetic resources of flowering plants based on their identification and systematization. Moscow. 2012. 581 p. [in Russian].

Makovey, M.D. The potential of mutant forms of tomato for selection and genetic studies. Chisinau: Print-Caro. 2022. 208 p. [in Moldavian]

Makovey, M.D. Selection of tomato for resistance to abiotic stress factors using gamete technologies. Chisinau: Print-Caro. 2018. 473 p. [in Moldavian]

Рfahler, P.L. Comparative effectiveness of pollen genotype selection in higher plants. Pollen: Biology and Implications for Plant Breeding. N.Y. 1982: 361-366.

Mascarenhas, G.P., Mitcel Altshuler. (1982). The response of pollen to high-temperatures and its potential applications. In: Pollen: Biology and Implications for Plant Breeding. (Ed. Mulcahy D.L., Ottaviano Ercole). New-York. 1982. P. 3-8.

Mulcahy, D.L., Mulcahy, G.B., Popp, R., Fong, et al. Pollen selection for stress tolerance or the advantage of selecting before pollination. In: Sexual reproduction in higher plants. 1988: 43-50.

Ottaviano, Е., Sari-Gorla, М. Gametophytic and sporophytic selection. Plant Breeding Principles and Prospects. Chapman and Hall. 1993; 333–352.

Kravceno, A.N., Lyakh, V.A., Toderash, L.G., et al. Methods of gamete and zygote selection of tomatoes. Kishinev. 1988. 140 p. [in Russian]

Liakh, V.A., Sorika, A.I. Pollen selection as a way to intensify the selection of oilseeds. Scientific and Technical Bulletin of the Institute of Olive Cultures of the National Academy of Sciences of Ukraine. 2014; 20: 72-80. [in Ukrainian]

Singh, A., Chowdhury, R., Das, R. Gametophytic Selection: A simple technique for thermo tolerance genotypes identification in maize. International Journal of Current Microbiology and Applied Sciences. 2017. 6(8): 1649 =–1655. http://dx.doi.org/10.20546/ijcmas.2017.602.198

Pressman, E., Peet, M., Pharr, D. The effect of heat stress on tomato pollen characteristics is associated with changes in carbohydrate concentration in the developing anthers. Ann. Botany. 2002; 90 (5): 631–636.

Reyes, R.D., Simpson, M.G. Preliminary investigation of pollen development of Philydrum lanuginosum. Microsc. Res. and Techn. 2007. Vol. 36. No 4. P. 350- 352.

Batygina, T.B., Kruglova, N.N., Gorbunova, V.Yu. et al. From microspores to varieties. Moscow. Nauka, 2010. 174 p. [in Russian]

Aloni, B., Peet, M., Pharr, M., Karni, L. The effect of high temperature and high atmospheric CO2 on carbohydrate changes in bell pepper (Capsicum annuum) pollen in relation to its germination. Physiologia Plantarum. 2001; 112: 505–512.

Izmailow, R. The effects of soil from polluted sites on reproductive success in Ranunculus repens (Ranunculus). Series Polish Botanical Studies. 2002; 15: 5–10.

Apel, K., Hirt, H. Reactive oxygen species: metabolism, oxidative stress, and signal transduction. Annual Review of Plant Biology. 2004; 55: 373 –399.

Klimenko, O.E., Klimenko, N.I. Effects of artificial acid rain on stone fruit pollen vitality and performance fruiting. Plodovodstvo. 2005; 17(2): 186–191. [in Belorussian]

Suzuki, N., Mittler, R. Reactive oxygen species and temperature stresses: a delicate balance between signaling and destruction. Physiologia Plantarum. 2006; 126: 45–51.

Solntseva, M.P., Glazunova, K.P. Influence of industrial and transport pollution of the environment on the reproduction of seed plants. Journal of General Biology. 2010; 71(2): 163–175.

Dospekhov B.A. Experimental methodology. Moscow: Agropromizdat, 1985. 416 p. [in Russian].

Tomato - UPOV (Solanum lycopersicum L.) V 2012 0007 TG/44/11 Rev. Geneva.

Golubinskiy I.N. Biology of pollen germination. Kyiv. 1974. 368 p. [in Russian]

Miura K. Cold signaling and cold response in plants. International Journal Molecular Science. 2013; 14: 5312–5337. https://doi.org/10.3390/ijms14035312

Zhivetev M.A., Graskova I.A., , Dudareva L.V., Stolbicova A.V., Voinikov V.K. Change of fatty-acid composition in plants during adaptation to hypothermia. JSPB. 2010; 6( 4): 51-65.

Goncharova E. A. A strategy for diagnosing and predicting the resistance of agricultural plants to weather and climate anomalies. J. Agricultural Biology. 2011; 1: 24–31. [in Russian]

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Опубликован

2023-12-27

Выпуск

Раздел

МЕТОДЫ И РЕЗУЛЬТАТЫ СЕЛЕКЦИИ