Effect of Water Stress on Weed Germination, Growth Characteristics, and Seed Production: A Global Meta-Analysis

IF 2.1 2区农林科学 Q2 AGRONOMY

Weed Science Pub Date : 2022-10-21 DOI:10.1017/wsc.2022.59

Mandeep Singh, R. Thapa, M. Kukal, S. Irmak, S. Mirsky, A. Jhala

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引用次数: 1

Abstract

Abstract Weeds compete with crops for soil moisture, along with other resources, which can impact the germination, growth, and seed production of weeds; however, this impact has not been systematically recorded and synthesized across diverse studies. To address this knowledge gap, a global meta-analysis was conducted using 1,196 paired observations from 86 published articles assessing the effect of water stress on weed germination, growth characteristics, and seed production. These studies were conducted and published during 1970 through 2020 across four continents (Asia, Australia, Europe, and North America). Imposed water stress was expressed as solution osmotic potential (ψsolution), soil water potential (ψsoil), or soil moisture as percent field capacity. Meta-analysis revealed that water stress inhibits weed germination, growth, and seed production, and the quantitative response intensified with increasing water stress. A ψsolution greater than –0.8 MPa completely inhibits germination of both grass and broadleaf weeds. A ψsolution from –0.09 to –0.32 MPa reduces weed germination by 50% compared with the unstressed condition. Moderate soil water stress, equivalent to 30% to 60% field capacity, inhibits growth characteristics (branches or tillers per plant, leaf area, leaves per plant, plant height, root, and shoot biomass) by 33% and weed seed production by 50%. Severe soil water stress, below 30% field capacity, inhibits weed growth by 51% and seed production by 88%. Although water stress inhibits weed growth, it does not entirely suppress the ability to germinate, grow, and produce seeds, resulting in weed seedbank accumulation. This creates management challenges for producers, because weed seeds can survive in the soil for many years, depending on weed species and environmental conditions. Quantitative information compiled in this meta-analysis can be instrumental to model the weeds' multidimensional responses to water stress and designing integrated weed management strategies for reducing the weed seedbank.

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水分胁迫对杂草萌发、生长特性和种子产量的影响:一项全球荟萃分析

杂草与作物争夺土壤水分和其他资源，影响杂草的萌发、生长和制种;然而，这种影响并没有在不同的研究中得到系统的记录和综合。为了解决这一知识缺口，我们对86篇已发表的文章进行了一项全球荟萃分析，分析了水分胁迫对杂草发芽、生长特性和种子产量的影响。这些研究于1970年至2020年间在四大洲(亚洲、澳大利亚、欧洲和北美)进行并发表。施加的水分胁迫用溶液渗透势(ψsolution)、土壤水势(ψsoil)或土壤水分(田容量百分比)表示。meta分析表明，水分胁迫抑制了杂草的萌发、生长和种子生产，并且随着水分胁迫的增加，定量响应增强。大于-0.8 MPa的ψ溶液完全抑制禾本科和阔叶草的萌发。在-0.09 ~ -0.32 MPa范围内，与无胁迫条件相比，可使杂草萌发率降低50%。中度土壤水分胁迫，相当于田间容量的30%至60%，会使生长特性(每株分枝或分蘖、叶面积、每株叶、株高、根和茎生物量)降低33%，杂草种子产量降低50%。严重的土壤水分胁迫，低于30%的田间容量，抑制了51%的杂草生长和88%的种子产量。虽然水分胁迫抑制了杂草的生长，但它并没有完全抑制杂草的发芽、生长和产生种子的能力，从而导致杂草种子库的积累。这给生产者带来了管理上的挑战，因为杂草种子可以在土壤中存活多年，这取决于杂草的种类和环境条件。本荟萃分析中收集的定量信息有助于建立杂草对水分胁迫的多维响应模型，并设计综合杂草管理策略，以减少杂草种子库。

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来源期刊

Weed Science 农林科学-农艺学

CiteScore

4.60

自引率

12.00%

发文量

审稿时长

12-24 weeks

期刊介绍： Weed Science publishes original research and scholarship in the form of peer-reviewed articles focused on fundamental research directly related to all aspects of weed science in agricultural systems. Topics for Weed Science include: - the biology and ecology of weeds in agricultural, forestry, aquatic, turf, recreational, rights-of-way and other settings, genetics of weeds - herbicide resistance, chemistry, biochemistry, physiology and molecular action of herbicides and plant growth regulators used to manage undesirable vegetation - ecology of cropping and other agricultural systems as they relate to weed management - biological and ecological aspects of weed control tools including biological agents, and herbicide resistant crops - effect of weed management on soil, air and water.