Ameloration of salinity stress in tomato by foliar sprays of ascorbic acid and proline

Hossam  S. El-Beltagi; Mohamed  Fathi El-Nady; Ahmed  Mahmoud Ismail; Metwaly Mahfouz  Salem Metwaly

doi:10.51372/bioagro381.2

Authors

Hossam S. El-Beltagi Agricultural Biotechnology Dept., College of Agriculture and Food Sciences, King Faisal University. Al-Ahsa, Saudi Arabia. https://orcid.org/0000-0003-4433-2034
Mohamed Fathi El-Nady Department of Agricultural Botany Dept., Faculty of Agriculture, Kafrelsheikh University. Kafrelsheikh, Egypt. https://orcid.org/0009-0003-6458-2660
Ahmed Mahmoud Ismail Arid Land Agriculture Dept., College of Agriculture and Food Sciences, King Faisal University. Al-Ahsa, Saudi Arabia. Pests and Plant Diseases Unit, College of Agriculture and Food Sciences, King Faisal University, Al-Ahsa 31982, Saudi Arabia https://orcid.org/0000-0001-9679-640X
Metwaly Mahfouz Salem Metwaly Department of Agricultural Botany Dept., Faculty of Agriculture, Kafrelsheikh University. Kafrelsheikh, Egypt. https://orcid.org/0000-0001-5276-4000

DOI:

https://doi.org/10.51372/bioagro381.2

Keywords:

Antioxidant enzymes, chlorophyll, relative water content, vitamin C

Abstract

Globally, salinity stress ranks as one of the most detrimental abiotic stresses constraining agricultural performance. This study evaluated the efficacy of foliar-used ascorbic acid (AsA) and proline (Pro), used separately or concurrently, in mitigating the deleterious effects of saline irrigation (2000 and 4000 mg·L^-1) on the growth and productivity of tomato (cv. Super Strain). Salinity stress significantly reduced plant height, leaf area, dry biomass as well as and yield components. It also led to marked declines in chlorophyll pigments (chl. a, b, and total chl.) and relative water content. In contrast, salinity stress induced increases in endogenous proline and total phenolic contents in leaves. Foliar use of AsA and Pro, whether used independently or in combination, successfully reduced the harmful consequences of salt stress, leading to notable improvements in growth traits, chlorophyll concentration, leaf water status, and fruit yield. Furthermore, treatments enhanced the activities of catalase, peroxidase, and superoxide dismutase and stimulated the endogenous production of proline and phenolic contents. The combined application of AsA and Pro consistently produced the most pronounced improvements across all measured parameters. These findings suggest that the integrated use of AsA and Pro as foliar sprays represents a potential strategy to improve salinity tolerance and sustain tomato productivity under saline conditions.

Downloads

Download data is not yet available.

References

Aebi, H., 1984. Catalase in vitro. Methods in Enzymology 105: 121-126.

Al-Gasadi, K.A., E. Tola, R. Madugundu, A.M. Zeyada, A.A. Alameen et al. 2024. Response of leaf photosynthesis, chlorophyll content and yield of hydroponic tomatoes to different water salinity levels. Plos One 19: 1-20.

Alnusaire, T.S., A.A. Al-Mushhin and M.H. Soliman. 2022. Role of Ascorbic Acid in Alleviating Abiotic Stress in Crop Plants. In antioxidant defense in plants: molecular basis of regulation (pp. 259-283). Singapore: Springer Nature Singapore.

Azmat, M., S.A. Kurd, F. Rahman, I. Ullah, F. Subhan, H. Ullah et al. 2023. Effect of salt stress on the growth and yield of tomato plants cultivated in pots. International Journal of Research Publication and Reviews 4:2892-2899.

Bates, L.S., R.P. Waldren and I.D. Teare. 1973. Rapid determination of free proline for water stress studies. Plant and Soil 39: 205-207.

Bessada, S.M., J.C. Barreira, L. Barros, I.C. Ferreira and M.B.P. Oliveira. 2016. Phenolic profile and antioxidant activity of Coleostephus myconis (L.) Rchb.F.: An under exploited and highly disseminated species. Industrial Crops and Products 89: 45-51.

Chapman, H.D. and R.F. Pratt. 1978. Methods analysis for soil, plant and water, University of California, Division of Agricultural Science 00: 16-38.

Chen, X., H. Han, Y. Cong, X. Li, W. Zhang, J. Cui et al. 2024. Ascorbic acid improves tomato salt tolerance by regulating ion homeostasis and proline synthesis. Plants 13(12): 1-18.‏

Chen, X., Z. Xu, B. Zhao, Y. Yang, J. Mi, Z. Zhao, and J. Liu. 2022. Physiological and Proteomic Analysis Responsive Mechanisms for Salt Stress in Oat. Front. Plant Sci. 13: 1-13.

Chourasia, K.N., M.K. Lal, R.K. Tiwari, D. Dev, H.B. Kardile, V.U. Pati et al. 2021. Salinity Stress in Potato: Understanding Physiological, Biochemical and Molecular Responses. Life 11(6): 1-24.

El Moukhtari, A., C. Cabassa-Hourton, M. Farissi and A. Savouré. 2020. How does proline treatment promote salt stress tolerance during crop plant development?. Frontiers in Plant Science 11: 1-16 ‏.

El-Beltagi, H.S., K.A. El-Naqma, M.I. Al-Daej, M.M. El-Afry, W.F. Shehata. et al. 2024. Effects of zinc nanoparticles and proline on growth, physiological and yield characteristics of pea (Pisum sativum L.) irrigated with diluted seawater. Cogent Food & Agriculture 10: 1-22.

Foyer, C.H. and G. Noctor. 2011. Ascorbate and Glutathione: The Heart of the Redox Hub. Plant Physiol. 155(1): 2-18.

Ghanem, H., S. Ehui, S.W. Omamo and C. Jenane. 2024. Climate Change and Food Security. Climate Change and Sustainable Agro-ecology in Global Drylands 30: 161.

Gharsallah, C., H. Fakhfakh, D. Grubb and F. Gorsane. 2016. Effect of salt stress on ion concentration, proline content, antioxidant enzyme activities and gene expression in tomato cultivars. AoB Plants 8: 1-21.

Giannopolitis, C.N. and S.K. Ries. 1977. Superoxide dismutases: I. Occurrence in higher plants. Plant Physiol. 59(2): 309-314.

Guo, M., X.S. Wang, H.D. Guo, S.Y. Bai, A. Khan, X. Wang and Y. Gao. 2022. Tomato salt tolerance mechanisms and their potential applications for fighting salinity: A review. Frontiers in Plant Science 13: 1-26.

Hossain, M.A., S. Munné-Bosch, D.J. Burritt, P. Diaz-Vivancos, M. Fujita, and A. Lorence. (eds.). 2017. Ascorbic acid in plant growth, development and stress tolerance. Berlin: Springer.

Ishikawa, T., T. Maruta, K. Yoshimura and N. Smirnoff. 2018. Biosynthesis and regulation of ascorbic acid in plants. Antioxidants and Antioxidant Enzymes in Higher Plants 163-179.‏

Kalapos, T. 1994. Leaf water potential, leaf water deficit relationship for ten species of semiarid grassland community. Plant Soil 160(1): 105-112.

Kaur, H. and N. Gupta. 2023. Seed treatment with ascorbic acid and proline improved salt tolerance in tomato (Solanum lycopersicum L. cv. Roma) by enhancing antioxidant enzyme activity. Plant Physiology Reports 28(4): 568-576.

Meena, M., K. Divyanshu, S. Kumar, P. Swapnil, A. Zehra. et al. 2019. Regulation of L-proline biosynthesis, signal transduction, transport, accumulation and its vital role in plants during variable environmental conditions. Heliyon 5(12): 1-20.‏

Mohammadi-Aylar, S., S. Jamaati-e-Somarin and J. Azimi. 2010. Effect of stage of ripening on mechanical damage in tomato fruits. American-Eurasian J. Agric. & Environ. Sci. 9(3): 297-302.

Moran, R. 1982. Formulae for determination of achlorophyllous pigments extracted with N, N-Dimetheylformamide. Plant Physiology 69(6): 1376-1381.

Mundada, P.S., S.V. Jadhav, S.S. Salunkhe, S.T. Gurme, S.D. Umdale et al. 2021. Lant performance and defensive role of proline under environmental stress. plant performance under environmental stress: Hormones, Biostimulants and Sustainable Plant Growth Management 201-223.

Naz, T., M.M. Iqbal, I. Ahmad, M.A. Sohail, S. Iqbal, A. Jamal et al. 2025. Foliar-application of proline mitigates salinity stress in two maize (Zea mays L.) genotypes: A Comparative study of growth, physiology, chlorophyll fluorescence, and ionic composition. Journal of Plant Growth Regulation: 1-18.‏

Polle, A., T. Otter and F. Seifert. 1994. Apoplastic peroxidases and lignification in needles of Norway Spruce Picea abies L. Plant Physiology 106(1): 53-60.

Rahman, A., M.U. Alam, M.S. Hossain, J.A. Mahmud, K. Nahar, M. Fujita, and M. Hasanuzzaman. 2023. Exogenous gallic acid confers salt tolerance in rice seedlings: Modulation of ion homeostasis, osmoregulation, antioxidant defense, and methylglyoxal detoxification systems. Agronomy 13(1): 1-15.

Shafi, A., I. Zahoor and U. Mushtaq. 2019. Proline accumulation and oxidative stress: Diverse roles and mechanism of tolerance and adaptation under salinity stress. Salt Stress, Microbes, and Plant Interactions, Mechanisms and Molecular Approaches 2: 269-300.

Singh, S., P. Singh, R.S. Tomar, R.A. Sharma and S.K. Singh. 2022. Proline: A key player to regulate biotic and abiotic stress in plants. In Towards sustainable natural resources: Monitoring and managing ecosystem biodiversity. Cham: Springer International Publishing 333-346.

Smirnoff, N. 2018. Ascorbic Acid Metabolism and Functions: A Comparison of Plants and Mammals. Free Radic. Biol. Med. 122: 116-129.

Sundararaman, B., S. Jagdev and N. Khatri. 2023. Transformative role of artificial intelligence in advancing sustainable tomato (Solanum lycopersicum) disease management for global food security: A comprehensive review. Sustainability 15(15): 1-23.

Xu, Y. and B. Huang. 2018. Exogenous ascorbic acid mediated abiotic stress tolerance in plants. In Ascorbic acid in plant growth, development and stress tolerance (pp. 233-253). Cham: Springer International Publishing.

Yan, F., J. Zhang, W. Li, Y. Ding, Q. Zhong, X. Xu et al. 2021. Exogenous melatonin alleviates salt stress by improving leaf photosynthesis in rice seedlings. Plant Physiol. Biochem. 163: 367-375.

Ameloration of salinity stress in tomato by foliar sprays of ascorbic acid and proline

Authors

DOI:

Keywords:

Abstract

Downloads

References

Published

How to Cite

Issue

Section