Suppression of mercury methylation in soil and methylmercury accumulation in rice by dissolved organic matter derived from sulfur-rich rape straw

Straw amendment significantly enhances mercury (Hg) methylation and subsequent methylmercury (MeHg) bioaccumulation in Hg-contaminated paddy fields by releasing dissolved organic matter (DOM). This study comprehensively investigates the regulatory mechanisms of DOM and its different molecular weight...

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Published in:Environmental pollution (1987) 2024-04, Vol.346, p.123657-123657, Article 123657
Main Authors: Zheng, Zhoujuan, Hu, Jie, He, Tianrong, Liu, Chengbin, Zhou, Xian, Yin, Deliang
Format: Article
Language:English
Subjects:
bioaccumulation factor
Brassica rapa
Dissolved Organic Matter
glutathione
humification
Mercury
Mercury - analysis
Methylation
Methylmercury Compounds
molecular weight
Oryza
paddies
pollution
Rape straw
Rice
Soil
Soil Pollutants - analysis
straw
Sulfates
sulfur
transportation
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creator Zheng, Zhoujuan
Hu, Jie
He, Tianrong
Liu, Chengbin
Zhou, Xian
Yin, Deliang
description Straw amendment significantly enhances mercury (Hg) methylation and subsequent methylmercury (MeHg) bioaccumulation in Hg-contaminated paddy fields by releasing dissolved organic matter (DOM). This study comprehensively investigates the regulatory mechanisms of DOM and its different molecular weights derived from sulfur-rich rape straw (RaDOM) and composted rape straw (CRaDOM) applied in the rice-filling stage on soil MeHg production and subsequent bioaccumulation in rice grains. The results indicated that the amendment of RaDOM and CRaDOM significantly reduced soil MeHg content by 42.40–62.42%. This reduction can be attributed to several factors, including the suppression of Hg-methylating bacteria in soil, the supply of sulfate from RaDOM and CRaDOM, and the increase in the humification, molecular weight, and humic-like fractions of soil DOM. Additionally, adding RaDOM increased the MeHg bioaccumulation factor in roots by 27.55% while inhibiting MeHg transportation by 12.24% and ultimately reducing MeHg content in grains by 21.24% compared to the control group. Similarly, CRaDOM enhanced MeHg accumulation by 25.19%, suppressed MeHg transportation by 39.65%, and reduced MeHg levels in the grains by 27.94%. The assimilation of sulfate derived from RaDOM and CRaDOM into glutathione may be responsible for the increased retention of MeHg in the roots. Over the three days, there was a significant decrease in soil MeHg content as the molecular weight of RaDOM increased; conversely, altering the molecular weight of CRaDOM demonstrated an inverse trend. However, this pattern was not observed after 12 days. Applying sulfur-rich rape DOM can help mitigate MeHg accumulation in paddy fields by regulating the quality of soil DOM, sulfur cycling, and Hg-methylating bacteria. [Display omitted] •Rape straw-derived DOMs elevate soil DOM humification, molecular weight and humic-like fraction.•Sulfur-rich rape straw-derived DOMs elevate glutathione levels in rice root.•Rape straw-derived DOMs reduce Hg-methylating bacteria and MeHg production in soil.•Rape straw-derived DOMs have the potential to reduce MeHg bioaccumulation in rice grains.
doi_str_mv 10.1016/j.envpol.2024.123657
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This study comprehensively investigates the regulatory mechanisms of DOM and its different molecular weights derived from sulfur-rich rape straw (RaDOM) and composted rape straw (CRaDOM) applied in the rice-filling stage on soil MeHg production and subsequent bioaccumulation in rice grains. The results indicated that the amendment of RaDOM and CRaDOM significantly reduced soil MeHg content by 42.40–62.42%. This reduction can be attributed to several factors, including the suppression of Hg-methylating bacteria in soil, the supply of sulfate from RaDOM and CRaDOM, and the increase in the humification, molecular weight, and humic-like fractions of soil DOM. Additionally, adding RaDOM increased the MeHg bioaccumulation factor in roots by 27.55% while inhibiting MeHg transportation by 12.24% and ultimately reducing MeHg content in grains by 21.24% compared to the control group. Similarly, CRaDOM enhanced MeHg accumulation by 25.19%, suppressed MeHg transportation by 39.65%, and reduced MeHg levels in the grains by 27.94%. The assimilation of sulfate derived from RaDOM and CRaDOM into glutathione may be responsible for the increased retention of MeHg in the roots. Over the three days, there was a significant decrease in soil MeHg content as the molecular weight of RaDOM increased; conversely, altering the molecular weight of CRaDOM demonstrated an inverse trend. However, this pattern was not observed after 12 days. Applying sulfur-rich rape DOM can help mitigate MeHg accumulation in paddy fields by regulating the quality of soil DOM, sulfur cycling, and Hg-methylating bacteria. [Display omitted] •Rape straw-derived DOMs elevate soil DOM humification, molecular weight and humic-like fraction.•Sulfur-rich rape straw-derived DOMs elevate glutathione levels in rice root.•Rape straw-derived DOMs reduce Hg-methylating bacteria and MeHg production in soil.•Rape straw-derived DOMs have the potential to reduce MeHg bioaccumulation in rice grains.</description><identifier>ISSN: 0269-7491</identifier><identifier>EISSN: 1873-6424</identifier><identifier>DOI: 10.1016/j.envpol.2024.123657</identifier><identifier>PMID: 38428787</identifier><language>eng</language><publisher>England: Elsevier Ltd</publisher><subject>bioaccumulation factor ; Brassica rapa ; Dissolved Organic Matter ; glutathione ; humification ; Mercury ; Mercury - analysis ; Methylation ; Methylmercury Compounds ; molecular weight ; Oryza ; paddies ; pollution ; Rape straw ; Rice ; Soil ; Soil Pollutants - analysis ; straw ; Sulfates ; sulfur ; transportation</subject><ispartof>Environmental pollution (1987), 2024-04, Vol.346, p.123657-123657, Article 123657</ispartof><rights>2024 Elsevier Ltd</rights><rights>Copyright © 2024 Elsevier Ltd. 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This study comprehensively investigates the regulatory mechanisms of DOM and its different molecular weights derived from sulfur-rich rape straw (RaDOM) and composted rape straw (CRaDOM) applied in the rice-filling stage on soil MeHg production and subsequent bioaccumulation in rice grains. The results indicated that the amendment of RaDOM and CRaDOM significantly reduced soil MeHg content by 42.40–62.42%. This reduction can be attributed to several factors, including the suppression of Hg-methylating bacteria in soil, the supply of sulfate from RaDOM and CRaDOM, and the increase in the humification, molecular weight, and humic-like fractions of soil DOM. Additionally, adding RaDOM increased the MeHg bioaccumulation factor in roots by 27.55% while inhibiting MeHg transportation by 12.24% and ultimately reducing MeHg content in grains by 21.24% compared to the control group. Similarly, CRaDOM enhanced MeHg accumulation by 25.19%, suppressed MeHg transportation by 39.65%, and reduced MeHg levels in the grains by 27.94%. The assimilation of sulfate derived from RaDOM and CRaDOM into glutathione may be responsible for the increased retention of MeHg in the roots. Over the three days, there was a significant decrease in soil MeHg content as the molecular weight of RaDOM increased; conversely, altering the molecular weight of CRaDOM demonstrated an inverse trend. However, this pattern was not observed after 12 days. Applying sulfur-rich rape DOM can help mitigate MeHg accumulation in paddy fields by regulating the quality of soil DOM, sulfur cycling, and Hg-methylating bacteria. [Display omitted] •Rape straw-derived DOMs elevate soil DOM humification, molecular weight and humic-like fraction.•Sulfur-rich rape straw-derived DOMs elevate glutathione levels in rice root.•Rape straw-derived DOMs reduce Hg-methylating bacteria and MeHg production in soil.•Rape straw-derived DOMs have the potential to reduce MeHg bioaccumulation in rice grains.</abstract><cop>England</cop><pub>Elsevier Ltd</pub><pmid>38428787</pmid><doi>10.1016/j.envpol.2024.123657</doi><tpages>1</tpages></addata></record>
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ispartof Environmental pollution (1987), 2024-04, Vol.346, p.123657-123657, Article 123657
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1873-6424
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source ScienceDirect Journals
subjects bioaccumulation factor
Brassica rapa
Dissolved Organic Matter
glutathione
humification
Mercury
Mercury - analysis
Methylation
Methylmercury Compounds
molecular weight
Oryza
paddies
pollution
Rape straw
Rice
Soil
Soil Pollutants - analysis
straw
Sulfates
sulfur
transportation
title Suppression of mercury methylation in soil and methylmercury accumulation in rice by dissolved organic matter derived from sulfur-rich rape straw
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