Soil drought duration and severity affect cotton boll biomass by altering recovery times and carbon dynamics of subtending leaf

Zou, Jie; Snider, John L.; Zhu, Honghai; He, Jiaqi; Li, Yuxia; Zhou, Zhiguo; Wang, Youhua; Meng, Yali; Chen, Binglin; Zhao, Wenqing; Wang, Shanshan; Hu, Wei

doi:10.1111/jac.12595

Cited by 5 publications

(2 citation statements)

References 97 publications

(110 reference statements)

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“…Research has established that soil moisture levels of 75 ± 5%, 60 ± 5%, and 45 ± 5% of field capacity indicate wetness, moderate drought, and severe drought, respectively [19]. Based on these findings, our study implemented three conditions: sufficient water supply, limited water supply, and drought stress, by maintaining soil moisture levels at 75 ± 5%, 60 ± 5%, and 45 ± 5% of field capacity.…”

Section: Soil Moisture Control Methodsmentioning

confidence: 82%

Enhanced Post-Drought Compensatory Growth and Water Utilization in Maize via Rhizosphere Soil Nitrification by Heterotrophic Ammonia-Oxidizing Bacteria

Wang,

Tian,

et al. 2023

Water

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Heterotrophic ammonia-oxidizing bacteria (HAOB), crucial for soil nitrification, have unclear benefits for crop water use. This study explored the impact of a novel HAOB strain, S2_8_1, on maize drought resilience via pot culturing. The experiment included various treatments: control with sufficient water (CK), sufficient water + HAOB strain (WI), limited rewatering (DL), sufficient rewatering (DH), sufficient rewatering + HAOB strain (DHI), and limited rewatering + HAOB strain (DLI). The results revealed below-compensatory growth with DL compared to CK. Interestingly, the HAOB strain displayed survival resilience with a 96% increase in its copy numbers in the rhizosphere soils compared to CK during rewatering. The DLI treatment exhibited equal to compensatory growth, showing a remarkable 169% surge in the water use efficiency versus CK. This improvement was attributed to heightened rhizosphere soil nitrification by HAOB, enhancing the cytokinin production in roots and its transference to leaves, leading to a 25% higher leaf cytokinin concentration with DLI compared to CK during rewatering. Additionally, HAOB DHI prompted overcompensatory growth after sufficient rewatering, boosting nitrification and facilitating cytokinin root-to-leaf transport. However, its water use efficiency was 39% lower than DLI. The study highlights HAOB’s importance in optimizing crop water use, particularly in scenarios of limited rewatering in cropland soils.

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Section: Soil Moisture Control Methodsmentioning

confidence: 82%

Enhanced Post-Drought Compensatory Growth and Water Utilization in Maize via Rhizosphere Soil Nitrification by Heterotrophic Ammonia-Oxidizing Bacteria

Wang,

Tian,

et al. 2023

Water

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“…Accumulation of carbohydrates, in photosynthetic and non-photosynthetic organs under drought stress conditions, is a common mechanism of plants to maintain cell turgor and prevent cell dehydration ( Liu et al., 2004 ; Muller et al., 2011 ; Durand et al., 2016 ). Especially in cotton, several studies have noted increases in sucrose under drought stress conditions and they have been credited with alterations in sucrose metabolizing enzymes activities ( Zou et al., 2022b ) or reductions in sucrose translocation ( Lemoine et al., 2013 ). SuSy is most often considered to catalyse the reaction of sucrose decomposition in sink organs ( Winter et al., 1997 ), however, SuSy activity of photosynthetic organs was measured in the synthetic sucrose direction of this study.…”

Section: Discussionmentioning

confidence: 99%

Carbon assimilation and distribution in cotton photosynthetic organs is a limiting factor affecting boll weight formation under drought

Zou

Loka³

et al. 2022

Front. Plant Sci.

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Previous studies have documented cotton boll weight reductions under drought, but the relative importance of the subtending leaf, bracts and capsule wall in driving drought-induced reductions in boll mass has received limited attention. To investigate the role of carbon metabolism in driving organ-specific differences in contribution to boll weight formation, under drought conditions. Controlled experiments were carried out under soil relative water content (SRWC) (75 ± 5)% (well-watered conditions, control), (60 ± 5)% (moderate drought) and (45 ± 5)% (severe drought) in 2018 and 2019 with two cultivars Yuzaomian 9110 and Dexiamian 1. Under severe drought, the decreases of photosynthetic rate (Pn) and carbon isotope composition (δ13C) were observed in the subtending leaf, bract and capsule wall, suggesting that carbon assimilation of three organs was restricted and the limitation was most pronounced in the subtending leaf. Changes in the activities of sucrose phosphate synthase (SPS), sucrose synthase (SuSy), invertases as well as the reduction in expression of sucrose transporter (GhSUT1) led to variabilities in the sucrose content of three organs. Moreover, photosynthate distribution from subtending leaf to seeds plus fibers (the components of boll weight) was significantly restricted and the photosynthetic contribution rate of subtending leaf to boll weight was decreased, while contributions of bracts and capsule wall were increased by drought. This, in conjunction with the observed decreases in boll weight, indicated that the subtending leaf was the most sensitive photosynthetic organ to drought and was a dominant driver of boll weight loss under drought. Therefore, the subtending leaf governs boll weight loss under drought due to limitations in carbon assimilation, perturbations in sucrose metabolism and inhibition of sucrose transport.

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Phosphorus-induced improvement of photosynthate synthesis and transport in the leaf subtending to cotton boll provided sufficient sucrose for fiber thickening during the crucial period and improved fiber bundle strength

Huang,

Wang,

Wang

et al. 2024

Field Crops Research

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Soil drought duration and severity affect cotton boll biomass by altering recovery times and carbon dynamics of subtending leaf

Cited by 5 publications

References 97 publications

Enhanced Post-Drought Compensatory Growth and Water Utilization in Maize via Rhizosphere Soil Nitrification by Heterotrophic Ammonia-Oxidizing Bacteria

Enhanced Post-Drought Compensatory Growth and Water Utilization in Maize via Rhizosphere Soil Nitrification by Heterotrophic Ammonia-Oxidizing Bacteria

Carbon assimilation and distribution in cotton photosynthetic organs is a limiting factor affecting boll weight formation under drought

Phosphorus-induced improvement of photosynthate synthesis and transport in the leaf subtending to cotton boll provided sufficient sucrose for fiber thickening during the crucial period and improved fiber bundle strength

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