Exogenous Tyrosine Priming Enhances Salt Stress Tolerance in Rice (Oryza sativa L.)

Authors

  • Ravi Pavithra

    Post Graduate and Research Centre in Biotechnology, Arignar Anna College (Arts & Science), Tamil Nadu 635 115, India
  • Sundarasamy Dhanapal

    Post Graduate and Research Centre in Biotechnology, Arignar Anna College (Arts & Science), Tamil Nadu 635 115, India
  • Nagarajan Kiruthiga

    Post Graduate and Research Centre in Biotechnology, Arignar Anna College (Arts & Science), Tamil Nadu 635 115, India
  • Subramani Suganya

    Post Graduate and Research Centre in Biotechnology, Arignar Anna College (Arts & Science), Tamil Nadu 635 115, India
  • Manikandan Mathaiyan

    Post Graduate and Research Centre in Biotechnology, Arignar Anna College (Arts & Science), Tamil Nadu 635 115, India
  • Chinnappan Deepa Joan of Arc

    Post Graduate and Research Centre in Biotechnology, Arignar Anna College (Arts & Science), Tamil Nadu 635 115, India
  • Ravi Dhanalakshmi

    Post Graduate and Research Centre in Biotechnology, Arignar Anna College (Arts & Science), Tamil Nadu 635 115, India
  • Asmath Baig Shabeena Begum

    Post Graduate and Research Centre in Biotechnology, Arignar Anna College (Arts & Science), Tamil Nadu 635 115, India
  • Krishnmoorthy Priya

    Post Graduate and Research Centre in Biotechnology, Arignar Anna College (Arts & Science), Tamil Nadu 635 115, India
  • Raja Manimegala

    Post Graduate and Research Centre in Biotechnology, Arignar Anna College (Arts & Science), Krishnagiri – 635 115, Tamil Nadu, India.
  • Krishnagowdu Saravanan *

    Post Graduate and Research Centre in Biotechnology, Arignar Anna College (Arts & Science), Tamil Nadu 635 115, India

DOI:

https://doi.org/10.55121/nc.v4i2.475

Keywords:

Tyrosine, Salt Stress Tolerance , Oryza Sativa , Photosynthetic Pigments , Antioxidant Defense

Abstract

Salt stress is a key abiotic stressor that contributes to reduced global rice production, particularly in salt-sensitive varieties such as Oryza sativa. This study aimed to assess the possibility of exogenous tyrosine (Tyr) seed priming in mitigating salt stress in rice seedlings (IR64 cultivar). The seeds were subjected to four treatment groups: control (water), 25 mM NaCl (salt stress), 5 mg l⁻¹ tyrosine, and 5 mg l⁻¹ tyrosine + 25 mM NaCl. Key morpho-physiological and biochemical parameters were measured after 14 days. Salt stress significantly inhibited seedling growth, decreased photosynthetic pigments, and elevated malondialdehyde (MDA) levels, indicating oxidative stress. In contrast, tyrosineprimed seedlings under salt stress exhibited notable improvements in seedling length (54.89%), fresh weight (58.88%), and dry weight (50%) relative to salt-stressed plants alone. Photosynthetic pigment levels, particularly total chlorophyll, improved by 55.88%, suggesting preserved chloroplast function. Moreover, tyrosine priming significantly decreased MDA content and increased superoxide dismutase (SOD) activity by 2.03-fold, indicating enhanced antioxidative defense. These findings support the role of tyrosine as a stress-mitigating priming agent, likely due to its function as a precursor for secondary metabolites and its involvement in redox signalling pathways. This study provides novel insights into tyrosine-mediated stress amelioration and suggests its applicability as a sustainable strategy to enhance salt tolerance in rice. Further field-scale studies are warranted to validate these findings under agronomic conditions.

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How to Cite

Pavithra, R., Dhanapal, S., Kiruthiga, N., Suganya, S., Mathaiyan, M., Deepa Joan of Arc, C., Dhanalakshmi, R., Shabeena Begum, A. B., Priya, K., Manimegala, R., & Saravanan, K. (2025). Exogenous Tyrosine Priming Enhances Salt Stress Tolerance in Rice (Oryza sativa L.). New Countryside, 4(2), 45–53. https://doi.org/10.55121/nc.v4i2.475

Issue

Vol. 4 No. 2 (July 2025): In Progress

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Articles

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Copyright (c) 2025 Ravi Pavithra, Sundarasamy Dhanapal, Nagarajan Kiruthiga, Subramani Suganya, Manikandan Mathaiyan, Chinnappan Deepa Joan of Arc, Ravi Dhanalakshmi, Asmath Baig Shabeena Begum, Krishnmoorthy Priya, Raja Manimegala, Krishnagowdu Saravanan

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