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Differences and correlations in physiological and molecular mechanisms of barley germination under drought stress

HE Peng-Xu1,2,YAN Yan1,2,ZHANG Hong1,2,WANG Jun-Cheng1,2,LI Bao-Chun1,3,YANG Ke1,2,SI Er-Jing1,2,MENG Ya-Xiong1,2,MA Xiao-Le1,2,WANG Hua-Jun1,2,YAO Li-Rong1,2,*   

  1. 1 State key laboratory of Aridland Crop Science / The State Key Laboratory of Crop Genetic Improvement and Germplasm Innovation of Gansu Province, Lanzhou730070, Gansu, China; 2 College of Agronomy, Gansu Agricultural University, Lanzhou730070, Gansu, China; 3 College of Life Science and Technology, Gansu Agricultural University, Lanzhou730070, Gansu, China
  • Received:2024-11-12 Revised:2025-06-01 Accepted:2025-06-01 Published:2025-06-19
  • Supported by:
    This study was supported by the East West Science and Technology Cooperation Special Project (25CXNA030),the China Agriculture Research System of MOF and MARA (CARS-05-02A-02), the State Key Laboratory of Aridland Crop Science Open Fund (GSCS-2021-02), the Modern Agricultural Industry Technology System in Gansu Province (Triticeae Crops), the Scientific Research Start-up Funds for Openly-recuited Doctors of Gansu Agricultural University (GAU-KYQD-2022-10), the Industrial Support Project of Colleges and Universities in Gansu Province (2021CYZC-12), the Fuxi Young Talents Fund of Gansu Agricultural University (GAUfx-04Y011, Gaufx-03Y06), and the Gansu Province Longyuan Youth Talent Project (2023).

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Abstract:

Drought is a major abiotic stress affecting the growth and development of barley (Hordeum vulgare L.), with potentially irreversible impacts across all growth stages, including seed germination and flowering. To investigate the germination responses of diverse barley germplasm under drought stress, this study employed a vermiculite-based water control method to evaluate the germination characteristics of 54 barley germplasm accessions. Based on drought tolerance during germination, the accessions were classified into five categories: excellent, good, moderate, poor, and very poor, with the highest proportion (37.04%) falling into the moderate group. Seven accessions with strong drought tolerance during germination, such as E0270389 and ZDM5430, exhibited rapid germination, uniform emergence, and vigorous seedling growth. In contrast, six accessions with poor drought tolerance, including 08J134 and ZY136-21490058, showed low germination rates, asynchronous emergence, and poor seedling uniformity. Six representative accessions (E0270389, ZDM5430, 7DCADA, Z1920057W, FT36, and ZY69-G231M004M) with significantly different drought germination characteristics were further analyzed for physiological and biochemical parameters, as well as DNA damage repair mechanisms during germination under drought conditions. The results revealed that accessions with good drought tolerance had lower expression of HvFPG during mid-germination and lower HvOGG1 expression during early germination compared to drought-sensitive accessions. In addition, these drought-tolerant accessions maintained higher peroxidase (POD) activity during early and middle germination stages, and showed less reduction in superoxide dismutase (SOD) and cysteine protease activities before germination. Soluble sugar content at 6 hours after drought induction did not differ significantly from the control. In contrast, drought-sensitive accessions exhibited significantly reduced POD activity during mid-germination and a marked decrease in soluble sugar content, as observed in FT36. In summary, barley germplasm with good drought tolerance during germination demonstrated enhanced DNA repair capacity, antioxidant activity, and metabolic adaptability under drought stress, leading to faster germination and healthier seedling development.

Key words: barley, drought stress, seed germination, DNA repair capacity, material transformation, antioxidant capacity

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