In vitro screening of the spring wheat F2 hybrids for water deficit resistance

Authors

  • Serhii Pykalo The V. M. Remeslo Myronivka Institute of Wheat National Academy of Agrarian Sciences of Ukraine Tsentralna str., 68, Tsentralne, Myronivka district, Kyiv region, Ukraine, 08853, Ukraine https://orcid.org/0000-0002-3158-3830
  • Oleksandr Demydov The V. M. Remeslo Myronivka Institute of Wheat National Academy of Agrarian Sciences of Ukraine Tsentralna str., 68, Tsentralne, Myronivka district, Kyiv region, Ukraine, 08853, Ukraine https://orcid.org/0000-0002-5715-2908
  • Nataliia Prokopik The V. M. Remeslo Myronivka Institute of Wheat National Academy of Agrarian Sciences of Ukraine Tsentralna str., 68, Tsentralne, Myronivka district, Kyiv region, Ukraine, 08853, Ukraine https://orcid.org/0000-0003-3933-5054
  • Serhii Voloshchuk The V. M. Remeslo Myronivka Institute of Wheat National Academy of Agrarian Sciences of Ukraine Tsentralna str., 68, Tsentralne, Myronivka district, Kyiv region, Ukraine, 08853, Ukraine https://orcid.org/0000-0002-9447-7525
  • Tetiana Yurchenko The V. M. Remeslo Myronivka Institute of Wheat National Academy of Agrarian Sciences of Ukraine Tsentralna str., 68, Tsentralne, Myronivka district, Kyiv region, Ukraine, 08853, Ukraine https://orcid.org/0000-0003-0164-4003
  • Svitlana Khomenko The V. M. Remeslo Myronivka Institute of Wheat National Academy of Agrarian Sciences of Ukraine Tsentralna str., 68, Tsentralne, Myronivka district, Kyiv region, Ukraine, 08853, Ukraine https://orcid.org/0000-0002-6047-7711

DOI:

https://doi.org/10.15587/2519-8025.2018.133030

Keywords:

spring wheat, water deficit, callus culture, mannitol, osmotic stress, resistance

Abstract

In vitro screening of the spring durum and bread wheat F2 hybrids for water deficit resistance by the direct selection using low molecular mannitol as a stressor was conducted. It is shown that with an increase in the concentration of mannitol from 0.2 to 0.8 M in all genotypes there was the inhibition of the growth of the callus culture that indicates the toxic effect of the stress factor. It was established that the concentration of 0.6 M mannitol allows to differentiate spring wheat genotypes for water deficit.

It was found that the F2 hybrid Elehiia myronivska / Krasa Polissia was most resistant to osmotic stress because calli of this genotype under selective conditions are characterized by relatively high morphogenic potential, had the highest survival rate and regenerated plants were obtained only from explants of this hybrid after cultivation on the medium containing mannitol concentration of 0.8 M. The F2 hybrid Zhizel / Lan was most susceptible to osmotic stress because mass necrosis and lack of regenerative ability were observed in its calli, under selective conditions. The genotypic dependence of processes of shoot formation in in vitro culture was observed in the spring wheat forms of studied. The formation of regenerated plants from wheat calli took place through both gemmorizogenesis and somatic embryogenesis.

Plant regenerants were obtained from the induced calli and their rearing, rooting and transfer to in vivo conditions were optimized. Genotypic responses to osmotic stress in the callus culture of spring wheat were manifested by different survival rate and different regenerative ability under the action of a stress factor. The hybrid Elehiia myronivska / Krasa Polissia can be used as a valuable material for further breeding of spring wheat. The in vitro tissue culture can be used as a test system for the screening of wheat genotypes for resistance to osmotic stress. The optimized procedure of vigorous regenerated plants production of spring durum and bread wheat in in vitro callus cultures can be used in cell selection and genetic engineering experiments

Author Biographies

Serhii Pykalo, The V. M. Remeslo Myronivka Institute of Wheat National Academy of Agrarian Sciences of Ukraine Tsentralna str., 68, Tsentralne, Myronivka district, Kyiv region, Ukraine, 08853

PhD, Senior Researcher

Department of Biotechnology, Genetics and Physiology

Oleksandr Demydov, The V. M. Remeslo Myronivka Institute of Wheat National Academy of Agrarian Sciences of Ukraine Tsentralna str., 68, Tsentralne, Myronivka district, Kyiv region, Ukraine, 08853

Doctor of Agricultural Sciences, Corresponding Member of NAAS of Ukraine, Director

Nataliia Prokopik, The V. M. Remeslo Myronivka Institute of Wheat National Academy of Agrarian Sciences of Ukraine Tsentralna str., 68, Tsentralne, Myronivka district, Kyiv region, Ukraine, 08853

Junior Researcher

Department of Biotechnology, Genetics and Physiology

Serhii Voloshchuk, The V. M. Remeslo Myronivka Institute of Wheat National Academy of Agrarian Sciences of Ukraine Tsentralna str., 68, Tsentralne, Myronivka district, Kyiv region, Ukraine, 08853

PhD, Leading Researcher

Department of Biotechnology, Genetics and Physiology

Tetiana Yurchenko, The V. M. Remeslo Myronivka Institute of Wheat National Academy of Agrarian Sciences of Ukraine Tsentralna str., 68, Tsentralne, Myronivka district, Kyiv region, Ukraine, 08853

PhD, Head of DepartmentDepartment of Biotechnology, Genetics and Physiology

Svitlana Khomenko, The V. M. Remeslo Myronivka Institute of Wheat National Academy of Agrarian Sciences of Ukraine Tsentralna str., 68, Tsentralne, Myronivka district, Kyiv region, Ukraine, 08853

PhD, Head of Laboratory

Laboratory of Spring Wheat Breeding

References

  1. Yaremko, Z., Rudiak, O. (2016) Osnovni chynnyky formuvannia koniunktury svitovoho rynku pshenytsi [World wheat market economic situation formation factors]. Naukovyi visnyk Mykolaivskoho natsionalnoho universytetu imeni V. O. Sukhomlynskoho. Seriia: Ekonomichni nauky, 1, 103–109.
  2. Mohammad, F., Ahmad, I. J. A. Z., Khan, N. U., Maqbool, K., Naz, A. Y. S. H. A., Shaheen, S. A. L. M. A., Ali, K. (2011). Comparative study of morphological traits in wheat and triticale. Pakistan Journal of Botany, 43 (1), 165–170.
  3. Krasensky, J., Jonak, C. (2012). Drought, salt, and temperature stress-induced metabolic rearrangements and regulatory networks. Journal of Experimental Botany, 63 (4), 1593–1608. doi: http://doi.org/10.1093/jxb/err460
  4. Bartels, D., Sunkar, R. (2005). Drought and salt tolerance in plants. Critical Reviews in Plant Sciences, 24 (1), 23–58. doi: http://doi.org/10.1080/07352680590910410
  5. Kacem, N. S., Delporte, F., Muhovski, Y., Djekoun, A., Watillon, B. (2017). In vitro screening of durum wheat against water-stress mediated through polyethylene glycol. Journal of Genetic Engineering and Biotechnology, 15 (1), 239–247. doi: http://doi.org/10.1016/j.jgeb.2017.04.004
  6. Morhun, V. V., Dubrovna, O. V., Morhun, B. V. (2016). Suchasni biotekhnolohii otrymannia stiikykh do stresiv roslyn pshenytsi [The modern biotechnologies of producing wheat plants resistant to stresses]. Fiziologiya rasteniy i genetika, 48 (3), 196–214.
  7. Dubrovna, О. V., Chugunkova, T. V., Bavol, А. V., Lialko, І. І.; Morhun, V. V. (Ed.) (2012). Biotekhnologhichni ta cytoghenetychni osnovy stvorennja roslyn, stijkykh do stresiv [Biotechnological and cytogenetic bases for the creation of plants resistant to stresses]. Kyiv: Lohos, 428.
  8. Soliman, H. I. A., Hendawy, M. H. (2013). Selection for drought tolerance genotypes in durum wheat (Triticum durum Desf.) under in vitro conditions. Middle-East Journal of Scientific Research, 14 (1), 69–78.
  9. Dubrovnaya, O. V. (2017). In vitro selection of wheat for resistance to abiotic stress factors [Selektsiya in vitro pshenitsy na ustoychivost' k abioticheskim stressovym faktoram]. Fiziologiya rasteniy i genetika, 49 (4), 279–292.
  10. Lestari, E. G. (2006). In vitro selection and somaclonal variation for biotic and abiotic stress tolerance. Biodiversitas, 7 (3), 297–301. doi: http://doi.org/10.13057/biodiv/d070320
  11. Rai, M. K., Kalia, R. K., Singh, R., Gangola, M. P., Dhawan, A. K. (2011). Developing stress tolerant plants through in vitro selection – an overview of the recent progress. Environmental and Experimental Botany, 71 (1), 89–98. doi: http://doi.org/10.1016/j.envexpbot.2010.10.021
  12. Generozova, I. P., Maevskaya, S. N., Shugaev, A. G. (2009). Ingibirovanie metabolicheskoy aktivnosti mitokhondriy etiolirovannykh prorostkov gorokha, podvergnutykh vodnomu stressu [Inhibition of the metabolic activity of mitochondria of etiolated pea seedlings subjected to water stress]. Fiziologiya rasteniy, 56 (1), 45–52.
  13. Ahmad, A. A. (1999). Response of immature embryos in vitro regeneration of some wheat, Triticum aestivum genotypes under different osmotic stress of mannitol. Assiut Journal of Agricultural Sciences, 30 (3), 25–34.
  14. Al-Kholani, H. A. (2010). Poluchenie stress-tolerantnykh rasteniy kukuruzy metodom kletochnoy selektsii [Obtaining stress-tolerant corn plants by the method of cell selection]. Moscow, 129.
  15. Butt, A., Ahmed, N., Mubin, M., Khaliq, I., Lighfoot, D. A. (2015). Effect of PEG and mannitol induced water stress on regeneration in wheat (Triticum aestivum L.). Pakistan Journal of Agricultural Sciences, 52 (4), 1025–1033.
  16. Dubrovna, O. V., Bavol, A. V., Zinchenko, M. A., Lyalko, I. I., Kruglova, N. М. (2011). Vplyv osmotychnykh rechovyn na kaliusni linii miakoi pshenytsi, stiiki do kulturalnoho filtratu Gaeumannomyces graminis var. tritici [Effect of osmotic substances on the common wheat callus lines resistant to culture filtrate of Gaeumannomyces graminis var. tritici]. Visnyk Ukrainskoho tovarystva henetykiv i selektsioneriv, 9 (1), 10–16.
  17. Murashige, T., Skoog, F. (1962). A revised medium for rapid growth and bio assays with tobacco tissue cultures. Plant Physiology, 15 (3), 473–497. doi: http://doi.org/10.1111/j.1399-3054.1962.tb08052.x
  18. Lakin, G. F. (1990). Biometriya [Biometrics]. Мoscow: Vysshaya shkola, 352.
  19. Delporte, F., Mostadel, O., Jacquemin, J. (2001). Plant regeneration through callus initiation from thin mature embryo fragments of wheat. Plant Cell, Tissue and Organ Culture, 67 (1), 73–80. doi: http://doi.org/10.1007/s11240-004-9221-x
  20. Khlebova, L. P., Nikitina, E. D., Matsyura, A. V., Bychkova, O. V. (2016). Vzaimosvyaz morfogeneticheskikh protsessov v kulture tkani pshenitsy [Relationship of morphogenetic processes in wheat tissue culture]. Biolohichnyi visnyk MDPU imeni Bohdana Khmelnytskoho, 6 (2), 311–320.
  21. Sidor, L. S., Orlov, P. A. (2005). Regeneratsionnyy potentsial razlichnykh vidov pshenitsy, rzhi i yachmenya v kul'ture listovykh eksplantov [Regeneration potential of different types of wheat, rye and barley in culture of leaf explants], Tsitologiya i genetika, 39 (5), 28–34.
  22. Komatsuda, T., Enomoto, S., Nekajima, K. (1989). Genetics of callus proliferation and shoot differentiation in barley. Journal of Heredity, 80 (5), 345–350. doi: http://doi.org/10.1093/oxfordjournals.jhered.a110872
  23. Henry, Y., Marcotte, J., De Buyser, J. (1994). Chromosomal location of genes controlling short-term and long-term somatic embryogenesis in wheat revealed by immature embryo culture of aneuploid lines. Theoretical and Applied Genetics, 89 (2-3), 344–350. doi: http://doi.org/10.1007/bf00225165
  24. Pykalo, S. (2015). Biotekhnologiya polucheniya rasteniy-regenerantov tritikale v kulture razlichnykh tipov eksplantov [Biotechnology of plant regenerant production triticale in culture of various types of explants]. Austrian Journal of Technical and Natural Sciences, 5-6, 34–39.
  25. Kaleikau, E. K., Sears, R. G., Gill, B. S. (1989). Control of tissue culture response in wheat (Triticum aestivum L.). Theoretical and Applied Genetics, 78 (6), 783–787. doi: http://doi.org/10.1007/bf00266658

Downloads

Published

2018-06-06

How to Cite

Pykalo, S., Demydov, O., Prokopik, N., Voloshchuk, S., Yurchenko, T., & Khomenko, S. (2018). In vitro screening of the spring wheat F2 hybrids for water deficit resistance. ScienceRise: Biological Science, (3 (12), 12–18. https://doi.org/10.15587/2519-8025.2018.133030

Issue

No. 3 (12) (2018)

Section

Biological Sciences

License

Copyright (c) 2018 Serhii Pykalo, Oleksandr Demydov, Nataliia Prokopik, Serhii Voloshchuk, Tetiana Yurchenko, Svitlana Khomenko

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

Our journal abides by the Creative Commons CC BY copyright rights and permissions for open access journals.

Authors, who are published in this journal, agree to the following conditions:

1. The authors reserve the right to authorship of the work and pass the first publication right of this work to the journal under the terms of a Creative Commons CC BY, which allows others to freely distribute the published research with the obligatory reference to the authors of the original work and the first publication of the work in this journal.

 2. The authors have the right to conclude separate supplement agreements that relate to non-exclusive work distribution in the form in which it has been published by the journal (for example, to upload the work to the online storage of the journal or publish it as part of a monograph), provided that the reference to the first publication of the work in this journal is included.