Abstract

Abiotic stresses like salinity and drought directly affect plant growth and water availability, resulting in lower yield in rice. So, a combination of stress tolerance along with enhanced grain yield is a major focus of rice breeding. It was reported earlier that loss in function of the drought and salt tolerance (DST) gene results in increase in grain production through downregulating Gn1a/OsCKX2 expression. Moreover, dst mutants also showed enhanced drought and salt tolerance in rice by regulating genes involved in ROS homeostasis. In the present study, we proceeded to test these reports by downregulating DST using artificial microRNA technology in the commercial but salt sensitive, high-yielding, BRRIdhan 28 (BR28). This cultivar was transformed with DST_artificial microRNA (DST_amiRNA) driven by the constitutive CaMV35S promoter using tissue culture independent Agrobacterium mediated in planta transformation. DST_amiRNA transgenic plants were confirmed by artificial microRNA specific PCR. Transformed plants at T0 generation showed vigorous growth with significantly longer panicle length and higher primary branching resulting in higher yield, compared to the wild type (WT) BR28. Semi-quantitative RT PCR confirmed the decrease in DST expression in the BR28 transgenic plants compared to WT. T1 transgenic plants also showed improvement in a number of physiological parameters and greater growth compared to WT after 14 days of 120 mM salt (NaCl) stress at seedling stage. Therefore, DST downregulated transgenic plants showed both higher stress tolerance as well as better yields. Furthermore, stable inheritance of the improved phenotype of the DST_amiRNA transgenics will be tested in advanced generations.

Highlights

  • Feeding a growing population that is expected to reach roughly 9 billion by the middle of this century is among the major challenges of our time [1]

  • We proceeded to test these reports by downregulating drought and salt tolerance (DST) using artificial microRNA technology in the commercial but salt sensitive, high-yielding, BRRIdhan 28 (BR28)

  • This cultivar was transformed with DST_artificial microRNA (DST_amiRNA) driven by the constitutive CaMV35S promoter using tissue culture independent Agrobacterium mediated in planta transformation

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Summary

Introduction

Feeding a growing population that is expected to reach roughly 9 billion by the middle of this century is among the major challenges of our time [1]. Many of the plants upon which we depend for food production, like rice, are sensitive to environmental stresses like drought and salinity [3]. Drought is one of the most common environmental factors that limit crop productivity, especially in Asia where at least 23 million hectares of rice (20% of the total world rice area) are drought prone [4]. It affects rice at morphological, physiological and molecular levels and thereby affects its yield [5]. Production of rice is under pressure due to increase in soil salinity stress as more cultivable areas are becoming saline due to added anthropogenic contribution and global warming [6] [7]

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