Hort. Sci. (Prague), 2021, 48(2):90-97 | DOI: 10.17221/103/2020-HORTSCI

The effects of K+-deficiency on H2O2 dynamics and sucrose in tomatoOriginal Paper

Xiaoming Zhao ORCID...*,1, Ning Zhang2, Xin Liu3, Jing Jiang3
1 College of Life Science and Bioengineering, Shenyang University, Shenyang, P.R. China
2 College of Horticulture, Science and Technology, Hebei Normal University of Science & Technology, Hebei Key Laboratory of Horticultural Germplasm Excavation and Innovative Utilization, Qinhuangdao, Hebei, P.R. China
3 College of Horticulture, Shenyang Agricultural University, Key Laboratory of Protected Horticulture, Ministry of Education, Shenyang, P.R. China

Potassium (K+) deficiency inhibits the transport of photosynthetic products and causes severe crop yield losses. However, the underlying mechanisms are poorly understood. In this study, we used two tomato lines 081018 (K+-deficiency-sensitive) and 081034 (K+-deficiency-tolerant), showing tolerance to K+ deficiency to investigate the relationship between the H2O2 and sucrose in the tomato under K+-deficiency. The H2O2 accumulation was increased by the low K+ condition (0.5 mM) after 8 h in 081018. The enzymes related to the metabolism of H2O2 were decreased, and more malondialdehyde (MDA) was produced. After 24 h, the sucrose content had accumulated significantly in the leaves, however, it was deficient in the roots, and the expression level of the sucrose transporters (SUT1) was inhibited. In 081034, the activity of antioxidant enzymes was increased under K+-deficiency, and then the H2O2 subsequently returned to the control treatment (4 mM) levels and did not produce more MDA. The sucrose content was not significantly different from the control treatment after 24 h. The expression of SUT1 was not suppressed. These results suggested that the H2O2 dynamics played different roles in the two different strains. The transportation of sucrose was suppressed by the H2O2 from the leaf (source) to the root (sink) in 081018, and unrestricted by the advantageous reactive oxygen species dynamics capacity in 081034.

Keywords: low K+ stress; oxidation; antioxidant enzyme activity; sucrose transport; SUT1

Published: June 30, 2021  Show citation

ACS AIP APA ASA Harvard Chicago Chicago Notes IEEE ISO690 MLA NLM Turabian Vancouver
Zhao X, Zhang N, Liu X, Jiang J. The effects of K+-deficiency on H2O2 dynamics and sucrose in tomato. Hort. Sci. (Prague). 2021;48(2):90-97. doi: 10.17221/103/2020-HORTSCI.
Share...
Download citation
  • BibTeX (.bib)
  • Bookends (.ris)
  • EasyBib (.ris)
  • EndNote (.enw)
  • EndNote 8 (.xml)
  • ISI WoS (.isi)
  • Medlars (.medlars)
  • Mendeley (.ris)
  • MODS (.xml)
  • Papers (.ris)
  • RefWorks (.txt)
  • RefManager (.ris)
  • RIS (.ris)
  • MS Word (.xml)
  • Zotero (.ris)
    • Open full article

    References

    1. Apel K., Hirt H. (2004): Reactive oxygen species: metabolism, oxidative stress, and signal transduction. Annual Review of Plant Biology, 55: 373-399. Go to original source... Go to PubMed...
    2. Cakmak I., Hengeler C., Marschner H. (1994a): Partitioning of shoot and root dry matter and carbohydrates in bean plants suffering from phosphorus, potassium and magnesium deficiency. Journal of Experimental Botany, 45: 1245-1250. Go to original source...
    3. Cakmak I., Hengeler C., Marschner H. (1994b): Changes in phloem export of sucrose in leaves in response to phosphorus, potassium and magnesium deficiency in bean plants. Journal of Experimental Botany, 45: 1251-1257. Go to original source...
    4. Chérel I., Lefoulon C., Boeglin M., Sentenac H. (2014): Molecular mechanisms involved in plant adaptation to low K+ availability. Journal of Experimental Botany, 65: 833-848. Go to original source... Go to PubMed...
    5. Couée I., Sulmon C., Gouesbet G., El Amrani (2006): Involvement of soluble sugars in reactive oxygen species balance and responses to oxidative stress in plants. Journal of Experimental Botany, 57: 449-459. Go to original source... Go to PubMed...
    6. Gerardeaux E., Jordan-Meille L., Constantin J., Pellerin S., Dingkuhn M. (2010): Changes in plant morphology and dry matter partitioning caused by potassium deficiency in Gossypium hirsutum (L.). Environmental and Experimental Botany, 67: 451-459. Go to original source...
    7. Hackel A., Schauer N., Carrari F., Fernie A., Grimm B., Kühn C. (2006): Sucrose transporter LeSUT1 and LeSUT2 inhibition affects tomato fruit development in different ways. Plant Journal, 45:180-192. Go to original source... Go to PubMed...
    8. Hafsi C., Debez A., Abdelly C. (2014): Potassium deficiency in plants: effects and signaling cascades. Acta Physiologiae Plantarum, 36: 1055-1070. Go to original source...
    9. Ho C., Tsay Y. (2010): Nitrate, ammonium, and potassium sensing and signaling. Current Opinion in Plant Biology, 13: 604-610. Go to original source... Go to PubMed...
    10. Hu W., Yang J., Meng Y., Wang Y., Chen B., Zhao W., Oosterhuis D., Zhou Z. (2015): Potassium application affects carbohydrate metabolism in the leaf subtending the cotton (Gossypium hirsutum L.) boll and its relationship with boll biomass. Field Crop Research, 179: 120-131. Go to original source...
    11. Huber S. (1984): Biochemical basis for effects of K-deficiency on assimilate export rate and accumulation of soluble sugars in soybean leaves. Plant Physiology, 76: 424-430. Go to original source... Go to PubMed...
    12. Huber S., Israel D. (1982): Biochemical basis for partitioning of photosynthetically fixed carbon between starch and sucrose in soybean (Glycine max Merr.) leaves. Plant Physiology, 69: 691-696. Go to original source... Go to PubMed...
    13. Lemoine R. (2000): Sucrose transporters in plants: update on function and structure. Biochimica et Biophysica Acta -Biomembranes, 1465: 246-262. Go to original source... Go to PubMed...
    14. Moustakas M., Sperdouli I., Kouna T., Antonopoulou C., Therios I. (2011): Exogenous proline induces soluble sugar accumulation and alleviates drought stress effects on photosystem II functioning of Arabidopsis thaliana leaves. Plant Growth Regulation, 65: 315-322. Go to original source...
    15. Neill S., Desikan R., Hancock J. (2002): Hydrogen peroxide signalling. Current Opinion in Plant Biology, 5: 388-395. Go to original source... Go to PubMed...
    16. Osorio S., Ruan Y., Fernie A. (2014): An update on sourceto-sink carbon partitioning in tomato. Frontiers in Plant Science, 5: 516. Go to original source... Go to PubMed...
    17. Patterson B., Macrae E., Ferguson I. (1984): Estimation of hydrogen peroxide in plant extracts using titanium (iv). Analytical Biochemistry, 139: 487-492. Go to original source... Go to PubMed...
    18. Quan L., Zhang B., Shi W., Li H. (2008): Hydrogen peroxide in plants: a versatile molecule of the reactive oxygen species network. Journal of Integrative Plant Biology, 1: 2-18. Go to original source... Go to PubMed...
    19. Schmitt B., Stadler R., Sauer N. (2008): Immunolocalization of solanaceous SUT1 proteins in companion cells and xylem parenchyma: new perspectives for phloem loading and transport. Plant Physiology, 148: 187-199. Go to original source... Go to PubMed...
    20. Suzuki N., Koussevitzky S., Mittler R., Miller G. (2012): ROS and redox signalling in the response of plants to abiotic stress. Plant, Cell & Environment, 35: 259-270. Go to original source... Go to PubMed...
    21. Wang N., Hua H., Eneji A. (2012): Genotypic variations in photosynthetic and physiological adjustment to potassium deficiency in cotton (Gossypium hirsutum). Journal of Photochemistry and Photobiology Biology, 110: 1-8. Go to original source... Go to PubMed...
    22. Wang Y., Wu W. (2010): Plant sensing and signalling in response to K+-deficiency. Molecular Plant, 3: 280-287. Go to original source... Go to PubMed...
    23. Zhao X., Jiang J., Zhang Y. (2011): Different tomato strains growth and development affected by K+-deficiency stress. Jiangsu Agricultural Sciences, 39: 219-223. (in Chinese)
    24. Zhao X., Liu Y., Liu X., Jiang J. (2018): Comparative transcriptome profiling of two tomato genotypes in response to potassium-deficiency stress. International Journal of Molecular Sciences, 19: 2402. Go to original source... Go to PubMed...

    This is an open access article distributed under the terms of the Creative Commons Attribution-NonCommercial 4.0 International (CC BY NC 4.0), which permits non-comercial use, distribution, and reproduction in any medium, provided the original publication is properly cited. No use, distribution or reproduction is permitted which does not comply with these terms.


    Return to the content