Exploring phosphorus starvation tolerance in as (Oryza sativa L.) rice: An analysis of stress tolerance attributes and understanding the effect of PSTOL1 gene

IF 1.5 4区农林科学 Q2 AGRONOMY

Plant Breeding Pub Date : 2024-05-09 DOI:10.1111/pbr.13173

Puranjoy Sar, Vilangapurathu S. Aiswarya, Firos T. M. Basha, Rachna Deo, Bibhash Chandra Verma, Debarati Bhaduri, Koushik Chakraborty, Umakanta Ngangkham, Amrita Banerjee, Jitendra Kumar, Nimai Prasad Mandal, Somnath Roy

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Abstract

The limited availability of Phosphorus (P) in the soil poses a significant challenge to of rice productivity in rainfed tropical regions. There has been a constant demand of diverse donors for enhancing tolerance to P‐deficient soils. In this study, we evaluated 181 aus rice accessions of the 3000 Rice Genome Project (3 K‐RGP) for grain yield and six other agronomical traits under control (~20 mg kg−1 available P) and low‐P (8–10 mg kg−1 available P) field trials. The objectives were to assess the level of low‐P tolerance in the aus germplasm and select stable high‐yielding accessions using stress tolerance attributes. We also surveyed the presence of PSTOL1 gene and Pup1 polymorphisms to find the effect of PSTOL1 as well as t Pup1 haplotypes on low‐P tolerance. Principal component analysis (PCA) using five stress tolerance attributes revealed that attributes like mean productivity (MP) and stress tolerance index (STI) are useful for selecting high‐yielding accessions with stable yield under stress and control conditions. Notably, accessions like Kalabokari, Devarasi, ARC 12021, Jasure Aus, ARC 7336 and ARC 12101 had higher level of tolerance than the check varieties Vandana and Sahbhagi Dhan. Majority of aus accessions carried the PSTOL1 gene (73%) and had the tolerant haplotype of Pup1 (65%) like the tolerant checks. Although, at large, the PSTOL1‐positive accessions were more vigorous, and high yielding under low‐P, there were a few PSTOL1‐negative aus accessions showing higher level of tolerance. The findings suggest that non‐PSTOL1 type tolerance exists in aus rice which needs to be substantiated through further studies.

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探索水稻（Oryza sativa L.）的磷饥饿耐受性：分析抗逆属性并了解 PSTOL1 基因的影响

土壤中有限的磷（P）供应对热带雨养地区的水稻生产力构成了巨大挑战。一直以来，人们都需要不同的供体来提高对缺磷土壤的耐受性。在本研究中，我们评估了 3000 水稻基因组计划（3 K-RGP）的 181 个水稻品种在对照（约 20 毫克/千克可用磷）和低磷（8-10 毫克/千克可用磷）田间试验中的谷物产量和其他六个农艺性状。目的是评估 AUS 种质的低 P 耐受水平，并利用抗逆特性筛选出稳定的高产品种。我们还调查了 PSTOL1 基因和 Pup1 的多态性，以发现 PSTOL1 和 t Pup1 单倍型对耐低 P 能力的影响。利用五个抗逆性属性进行的主成分分析（PCA）显示，平均生产力（MP）和抗逆性指数（STI）等属性有助于筛选出在抗逆和对照条件下产量稳定的高产品种。值得注意的是，Kalabokari、Devarasi、ARC 12021、Jasure Aus、ARC 7336 和 ARC 12101 等品种的抗逆性高于对照品种 Vandana 和 Sahbhagi Dhan。与耐受性对照品种一样，大多数 AUS 品种携带 PSTOL1 基因（73%），并具有 Pup1 的耐受性单倍型（65%）。虽然从总体上看，PSTOL1 阳性的品种在低 P 条件下生命力更强、产量更高，但也有少数 PSTOL1 阴性的 aus 品种表现出更高的耐受性。研究结果表明，水稻中存在非 PSTOL1 类型的耐受性，这需要通过进一步研究加以证实。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Plant Breeding 农林科学-农艺学

CiteScore

4.40

自引率

5.00%

发文量

审稿时长

3.0 months

期刊介绍： PLANT BREEDING publishes full-length original manuscripts and review articles on all aspects of plant improvement, breeding methodologies, and genetics to include qualitative and quantitative inheritance and genomics of major crop species. PLANT BREEDING provides readers with cutting-edge information on use of molecular techniques and genomics as they relate to improving gain from selection. Since its subject matter embraces all aspects of crop improvement, its content is sought after by both industry and academia. Fields of interest: Genetics of cultivated plants as well as research in practical plant breeding.