Combined application of biochar and silicon nanoparticles enhance soil and wheat productivity under drought: Insights into physiological and antioxidant defense mechanisms

IF 5.4 Q1 PLANT SCIENCES

Current Plant Biology Pub Date : 2024-12-01 DOI:10.1016/j.cpb.2024.100424

Bilal Zulfiqar , Muhammad Aown Sammar Raza , Muhammad Akhtar , Nan Zhang , Mamoona Hussain , Junaid Ahmad , Mostafa A. Abdel-Maksoud , Hossam Ebaid , Rashid Iqbal , Muhammad Usman Aslam , Mohamed A. El-Tayeb , Shiming Su

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引用次数: 0

Abstract

Agricultural drought periods are enhanced by the change in global climate that threatens food security. One of the main factors affecting soil and wheat productivity worldwide is drought stress. Especially, in semi-arid climates, studies are not found about adding organic amendments may be a viable way to reduce the adverse impacts of drought on crops while enhancing soil qualities and water use efficiency. In this study, we aimed to explore the effects of combined application of biochar (BC = 5 %) and silicon nanoparticles (SiNP = 900 mg/L) on soil and wheat drought resistance. Drought stress was applied at the three most critical growth stages of wheat, tillering (DTS), flowering (DFS), and grain filling (DGFS) stages, then evaluated the soil nutrients and wheat drought physiological resistance under applied treatments (BC, SiNP, BC+SiNP). Results showed that combined treatment of BC and SiNP greatly reduced the adverse effects of drought by enhancing plant height (9.36 %), spike length (25.63 %), number of fertile tillers (29.26 %), grains per spike (10.86 %), thousand-grain weight (18.25 %), and biological yield (16.34 %) with comparison to the control application. Additionally, physiological measures like water use efficiency (20.58 %), stomatal conductance (29.26 %), chlorophyll a (16.25 %), chlorophyll b (18.96 %), transpiration rate (21.65 %), photosynthetic rate (22.94 %), electrolyte leakage (-17.77 %), MDA (29.25 %), hydrogen peroxide (-19.88 %), superoxide dismutase (11.19 %), catalase (9.26 %), peroxidase (18.59 %), nitrogen (14.81 %), phosphorus (13.89 %), and potassium (17.61 %) were also meaningfully improved by treated application. BC and SiNP also significantly amended the organic carbon, nitrogen, and minerals percentage in soil. In conclusion, using the synergistic application of BC and SiNP could be a successful strategy to promote the biological soil properties, plant growth, yield, and quality of wheat crops as compared to all other treatments via dropping the dangerous effects of drought stress.

查看原文本刊更多论文

生物炭和纳米硅的联合应用提高了干旱条件下土壤和小麦的生产力：生理和抗氧化防御机制的见解

威胁粮食安全的全球气候变化加剧了农业干旱期。干旱胁迫是影响全球土壤和小麦产量的主要因素之一。特别是在半干旱气候条件下，没有研究发现添加有机改良剂可能是减少干旱对作物不利影响，同时提高土壤质量和水分利用效率的可行方法。本研究旨在探讨生物炭（BC = 5 %）与纳米硅（SiNP = 900 mg/L）配施对土壤和小麦抗旱性的影响。在分蘖期（DTS）、开花期（DFS）和灌浆期（DGFS）这3个小麦生长关键期施加干旱胁迫，评价不同处理（BC、SiNP、BC+SiNP）对土壤养分和小麦抗旱性的影响。结果表明，与对照相比，BC与SiNP配施可显著提高水稻株高（9.36 %）、穗长（25.63 %）、可育分蘖数（29.26 %）、穗粒数（10.86 %）、千粒重（18.25 %）和生物产量（16.34 %），显著降低干旱对水稻的不利影响。此外,生理指标如水分利用效率(20.58 %),气孔导度(29.26 %),叶绿素a(16.25 %),叶绿素b(18.96 %),蒸腾速率(21.65 %),光合速率(22.94 %)、电解液泄漏(-17.77 %),MDA(29.25 %),过氧化氢(-19.88 %),超氧化物歧化酶(11.19 %),过氧化氢酶(9.26 %),过氧化物酶(18.59 %)、氮(14.81 %),(13.89 %),磷和钾(17.61 %)也有效地提高了处理应用程序。BC和SiNP对土壤有机碳、氮和矿物质含量也有显著的改善作用。综上所述，与所有其他处理相比，通过降低干旱胁迫的危险效应，使用BC和SiNP协同施用可能是一种成功的策略，可以促进土壤生物特性、植物生长、产量和小麦作物品质。

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

Current Plant Biology Agricultural and Biological Sciences-Plant Science

CiteScore

10.90

自引率

1.90%

发文量

审稿时长

50 days

期刊介绍： Current Plant Biology aims to acknowledge and encourage interdisciplinary research in fundamental plant sciences with scope to address crop improvement, biodiversity, nutrition and human health. It publishes review articles, original research papers, method papers and short articles in plant research fields, such as systems biology, cell biology, genetics, epigenetics, mathematical modeling, signal transduction, plant-microbe interactions, synthetic biology, developmental biology, biochemistry, molecular biology, physiology, biotechnologies, bioinformatics and plant genomic resources.