期刊,土壤圈（英文版） 2024年卷6期_国家学术搜索

期刊信息/Journal information

土壤圈（英文版）

主　　编：周健民

出版周期：双月刊

国际刊号：1002-0160

电子邮箱：eopedos@issas.ac.cn； pedosphere@issas.ac.cn； rmdu@issas.ac.cn eopedo@issas.ac.cn

电　　话：025-86881235、86881359

邮政编码：210008

地　　址：南京市北京东路71号中国科学院南京土壤研究所

土壤圈（英文版）/Journal An International Journal PedosphereCSCDCSTPCD北大核心SCI

查看更多>>《PEDOSPHERE》（土壤圈）是中国出版的土壤学科唯一外文版国际性学术期刊，也是我国土壤学领域唯一的SCI源刊。主要刊登土壤学领域国内外未曾公开发表的具有坚实科学理论和实验基础与创新的最新高水平科研成果，内容包括土壤化学、土壤物理学、土壤生物与生物化学、土壤肥力与植物营养、土壤环境与生态学、土壤微生物学、土壤地理、水土保持、土壤信息与遥感技术、土壤质量与土壤修复等与生物圈、岩石圈、水圈和大气圈密切关联的土壤科学理论、实验技术及应用的学术研究论文、专题综述、研究简报、书评等。旨在及时传播国内外土壤科学最新成果，促进国际学术交流与合作，推动中国和世界土壤科学事业的发展。

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Effects of plasticizer on removal of antibiotics and antibiotic resistance genes from agricultural soils via soil microbial fuel cells

Huixiang WANGXiaoshuai SHENChen ZHANGYi SHAO...

981-992页

查看更多>>摘要：Soil microbial fuel cells(MFCs),a novel ecosystem technology,have recently been intensively studied for antibiotic-polluted soils.However,actual agricultural soils are always contaminated by mixed pollutants,especially plasticizers from extensively used agricultural plastic films.The aim of this study was to investigate the effects of di-2-ethylhexyl phthalate(DEHP),a representative plasticizer in soil,on the removal of sulfadiazine(SDZ),a frequently detected antibiotic in natural environments,and antibiotic resistance genes(ARGs)and microbial community in soil MFCs.Soil MFCs maintained a good antibiotic removal ability even under the influence of residual DEHP and achieved a higher removal performance at higher DEHP concentrations due to enhanced power generation.Specifically,a higher DEHP concentration had a favorable effect on antibiotic removal in soil MFCs,with the SDZ concentration decreased in both the upper and lower layers(from 4.867±0.221 to 0.268±0.021 and 0.293±0.047 mg kg-1,respectively)of polluted soils.Moreover,a high DEHP concentration significantly promoted the abundance of bacteria associated with electricity generation compared with a lower DEHP concentration,resulting in the promotion of extracellular electron transfer and enhancing SDZ degradation.The increased ARG abundance may be caused by the enrichment of ARG potential hosts brought about by high DEHP concentration,likely due to the increased conjugative transfer frequencies of plasmid RP4 by decreasing cell membrane permeability and increasing reactive oxygen species content.The results revealed the ecological risk of residual DEHP in soil that promotes ARG transmission in soil MFCs,although it has the potential to reduce SDZ toxicity through horizontal gene transfer.We also highlight concerns regarding the management of antibiotics and plasticizers in soil.The negative effects of plasticizers on antibiotic removal should be carefully evaluated when using soil MFCs for the in-situ remediation of antibiotic-contaminated soil.

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Biological nitrogen fixation in paddy soils is driven by multiple edaphic factors and available phosphorus is the greatest contributor

Tianlong HUYanhui ZHANGHui WANGHaiyang JIN...

993-1001页

查看更多>>摘要：Biological nitrogen(N)fixation(BNF)is important for sustainable rice cultivation.Various edaphic factors have been individually evaluated for their effects on BNF in paddy soils.However,no single factor could fully explain the different soil outcomes.Paddy BNF is more likely to be simultaneously influenced to various degrees by combinations of several edaphic factors;however,the relative importance of the interaction of multiple edaphic factors on the regulation of BNF in paddy soils is still unclear.Twenty-seven paddy soil samples with different soil properties were collected from the major rice cropping areas in Southwest and Northeast China to determine the edaphic factors affecting paddy BNF amount.Rice was transplanted into pots filled with paddy soils and grown in a 15N2-enriched airtight chamber.Estimation of BNF was based on the measurements of 15N enrichment in the paddy soils and rice plants at the end of a 77-d incubation period.The BNF amounts ranged from 0.66 to 12.3 kg ha-1,with a significant positive relationship with available phosphorus(AP)and significant quadratic relationships with available molybdenum(AMo)and total N(TN).Available P explained 42％of the observed variation in BNF,TN explained 17％,and AMo explained 13％.The specific interaction between soil cation exchange capacity and available soil N(as determined by rice N uptake)accounted for 28％of the variation in BNF.The BNF amount was decreased when AP was＜14 mg kg-1,AMo＜0.09 mg kg-1,or TN was＞3.2 g kg-1.These results provide valuable benchmarks that could be used to guide farmers in managing paddy soils to improve the potential contribution of paddy BNF to soil fertility.

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Silicon reduces cadmium accumulation in Moso bamboo(Phyllostachys edulis)root cell sap by sequestering cadmium in hemicellulose 1

Yuzhen CHANGFan YANGChaofeng YANGYiting ZHENG...

1002-1013页

查看更多>>摘要：Moso bamboo is one of the most important economic bamboo species in China,but cadmium(Cd)pollution has become a potential threat of its sustainable development.Silicon(Si)reduces Cd accumulation in many plant species.However,the exact mechanisms of this effect in Moso bamboo are still poorly understood.Here,we investigated the effect of Si on Cd accumulation in Moso bamboo in terms of Cd concentration in roots,Cd cellular and subcellular distribution,root cell morphology,and gene expression.Seedlings(ten days old)were exposed to different concentrations of Cd(0,1,5,and 50 μmol L-1)in a 0.5 mmol L-1 CaCl2 solution treated with(+Si)and without(-Si)1 mmol L-1 Si(as silicic acid)for two days.The effect of Si on the alleviation of Cd-induced inhibition of root elongation was not obvious,but Si could significantly reduce Cd accumulation in roots at all tested Cd concentrations(1,5,and 50 μmol L-1).Cadmium was localized in all cells of roots,but Si application altered the Cd distribution from all cells to distal side of exodermis cells in roots.Semi-quantitative determination of Cd using energy-dispersive X-rays revealed higher Cd concentrations in exodermis,but lower concentrations in the stele when Si was applied.However,Si increased Cd accumulation in root cell wall,but decreased it in cell sap.Moreover,more than 70％of Cd and Si were found in hemicellulose 1 of the cell wall.These results suggested that Si reduced Cd accumulation by sequestering Cd in hemicellulose 1 in the root cell wall at the subcellular level and retaining most of the Cd in the root exodermis at the cellular level in Moso bamboo under short-term Si application.

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Long-term fallowing produces specific fungal taxa associated with soil carbon storage

Fang LILin CHENYue LIYanlai HAN...

1014-1025页

查看更多>>摘要：Cropland expansion has caused the loss of soil organic carbon(SOC)and the degradation of microbial communities.Fallowing is an important strategy for soil restoration,and fungi are critical in soil fertilization.This study compared the soil properties and fungal assemblage in two adjacent environments(farmland vs.fallowing)using a 30-year field experiment composed of five treatments:fallowing and agricultural management under no fertilization,chemical fertilization,and chemical fertilization plus cow manure or crop straw.The fallowed soil had more diverse fungi and maintained higher SOC than the artificially managed treatments.Importantly,the relative abundance of Chaetomiaceae was positively correlated with all the carbon components(SOC,dissolved organic carbon,and microbial biomass carbon)simultaneously.An RNA-Seq of Trichocladium uniseriatum,the key fungus affiliated with Chaetomiaceae,showed that straw addition significantly upregulated the genes for T.uniseriatum melanogenesis,resulting in recalcitrant necromass formation.A remarkable carbon dioxide(CO2)assimilation capacity of T.uniseriatum was revealed using 13C-labelling assay.Therefore,T.uniseriatum improved SOC storage directly by CO2 fixation and indirectly by melanogenesis.Fertilization of agricultural systems can stimulate the growth of T.uniseriatum.Inoculation of T.uniseriatum promoted crop growth,facilitating carbon absorption from the roots.This study highlights that the valuable microbial species resources preserved in fallowed soils can improve farmland ecosystems.

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Microbial genes for degrading plant-derived carbon are a key factor affecting soil respiration and temperature sensitivity in plateau peatlands

Wei JIANGMingyao XIONGShuzhen ZOUDi KANG...

1026-1037页

查看更多>>摘要：Peatlands on the southwestern plateau of China are important carbon sinks for high-altitude terrestrial ecosystems in Asia.However,the specific microecological mechanism responsible for alterations in carbon processes in this region due to the simultaneous impacts of global warming and drought has not been fully elucidated.Investigating this mechanism will improve our understanding of carbon cycle feedback in peatland ecosystems,as it is affected by changes in hydrology and temperature,especially in vulnerable habitats.This study examined the influence of soil carbon decomposition functional microorganisms on soil respiration and temperature sensitivity(expressed as Q10)in high-elevation peatlands using field investigations,simulated warming experiments,and metagenomic sequencing.We found that hydrothermal conditions had a significant effect on soil respiration,leading to an increase in cumulative soil respiration as soil moisture and temperature increased.Soil moisture affected soil respiration and soil organic carbon mainly through soil microorganisms,with a predominance of carbon-decomposing genes.We found that genes regulating the decomposition of plant-derived carbon such as cellulose and lignin were the critical factor influencing Q10 in peatlands.Genes involved in cellulose and lignin decomposition showed a significant positive correlation with Q10(P＜0.05),while genes involved in hemicellulose decomposition showed a significant negative correlation with Q10(P＜0.05).Specifically,genes such as ACO,xylF,and hpaE,which are involved in lignin decomposition,and glgB,which is responsible for cellulose decomposition,showed significant positive correlations(P＜0.05)with Q10 Conversely,the gene uxaC,involved in the decomposition of hemicellulose,showed a significant negative correlation(P＜0.05)with Q10..Finally,we analyzed the relevant carbon metabolic pathways and found that although they were affected by water,they were not significantly related to Q10.In short,this research highlights the importance of microorganisms with genes for decomposing plant-derived carbon in influencing carbon emissions in plateau peatlands during periods of warming.

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Bacterial community characteristics in epigeic and anecic earthworm vermicompartments within soil-earthworm systems

Zhiming SHIShuyu SHIWenwen LICongying WANG...

1038-1050页

查看更多>>摘要：Earthworms are crucial to soil ecosystems as keystone species.They perform various ecological functions through their associated microbiomes.However,the characteristics of these microbiomes in various vermicompartments(earthworm-associated compartments)within soil-earthworm systems have not been systematically studied.Here,using earthworms of two ecotypes(i.e.,epigeic Eisenia fetida and anecic Metaphire guillelmi)as models,we conducted a full and comprehensive exploration of the bacterial community in several potential distinct compartments,including bulk soil,drilosphere,gut wall,gut content,and casts,through 2D-terraria incubation technology and high-throughput sequencing approaches.Bacterial diversity,community structures in each compartment,differential OTUs in vermicompartments compared with bulk soil,and the co-occurrence relationship of bacteria in bulk soil and gut-compartments(i.e.,gut wall and gut content)were assessed.Results showed that three major vermicompartments,i.e.,drilosphere,gut,and casts,were distinctly different in hosting the bacterial community.The levels of alpha diversity followed the order of drilosphere＞casts＞gut wall ≈ gut content.These patterns of vermicompartments along earthworms did not vary with ecotype,implying that the vermicompartments were the primary factors influencing the bacterial community.Finally,based on the difference in microbiomes in gut-compartments and the state-of-the-art use of the term"gut microbiomes",it is recommended to establish a unified definition of gut microbes that encompasses microbiomes residing in both the gut wall and gut content,which could provide a clear and consistent understanding of gut microbiomes.This work provides a comprehensive overview of earthworm-associated microbiomes,enhancing our understanding of fundamental earthworm ecology and soil biology.

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Arsenic mobilization and nitrous oxide emission modulation by different nitrogen management strategies in a flooded ammonia-enriched paddy soil

Feng WANGJing ZHANGYanqiong ZENGHonghui WANG...

1051-1065页

查看更多>>摘要：Elevated arsenic(As)mobilization and increased nitrous oxide(N2O)emission are two primary environmental concerns existing in flooded paddy soils.In this study,dissolved As(Ⅲ),N isotope-labeled Na15NO3,and/or 14NH4C1 were incorporated into a microcosm incubation to determine the effects of N fertilization regimes on As mobilization and N2O emission in a flooded paddy soil.Because nitrate had a higher redox potential and comprised a higher proportion of N substrate,As(Ⅴ)was preferentially formed due to enhanced nitrate-dependent microbial As(Ⅲ)oxidation.Thus,As availability was correspondingly attenuated due to the improved production of less mobile and toxic As(Ⅴ).After 2-d incubation,more than 90％and 98％of soluble As(Ⅲ)were immobilized in the As+NH4+-N+NO3-N and As+NO3--N treatments,respectively.Following nitrate depletion(after 2 d),microbial As(Ⅴ)and Fe(Ⅲ)reductions were gradually enhanced,which was attributed to stimulation of anaerobic ammonium oxidation(anammox)coupled to Fe(Ⅲ)reduction,known as Feammox,by the abundance of NH4+.By the end of the incubation period(10 d),the As+NO3--N treatment led to higher As immobilization of originally added As(Ⅲ)(ca.61％)than the As+NH4+-N+NO3--N treatment(42％).The As+NH4+-N+NO3--N treatment prominently mitigated N2O emission compared to the As+NO3--N treatment,which was ascribed to anammox,inducing accumulation of byproducts from incomplete denitrification.High-throughput sequencing indicated that the relative abundances of denitrifiers(e.g.,Azoarcus,Ochrobactrum,and Thiobacillus denitrificans)increased in the As+NO3-treatment,whereas quantitative polymerase chain reaction results indicated higher 16S rRNA gene copy numbers for anammox and Feammox(Acidimicrobiaceae bacterium A6)bacteria in the As+NH4++NO3-treatment.Collectively,the experimental results demonstrated that N fertilization can be a feasible As remediation strategy while providing an effective strategy for mitigating N2O emission from paddy soils at the same time.

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Role of nosZ Ⅰ-carrying microorganisms in regulating nitrous oxide reduction during forest conversion:A comparison of plantations and a secondary forest in subtropical soils

Milin DENGGuiping YEHang-Wei HUChao XU...

1066-1075页

查看更多>>摘要：The conversion of natural forests in subtropical regions to plantations or secondary forests has resulted in alterations in soil variables,microbial communities,and microbially mediated processes,including nitrous oxide(N2O)emissions.However,how forest conversion influences soil N2O reduction and the abundance and community structure of N2O-reducing microorganisms remains unclear.Here,we investigated the impact of converting natural forests to a secondary forest and Cunninghamia lanceolata and Pinus massoniana plantations on the abundance and community structure of N2O-reducing microorganisms in both bulk soils and soil aggregates.Compared with the secondary forest,plantations had higher soil pH and available phosphorus and moisture contents,lower soil NH4+content,but similar aggregate sizes.Compared with the secondary forest,the conversion of natural forest to plantations resulted in significantly higher soil N2O reduction rate and increased abundances of nosZ Ⅰ and nosZ Ⅱ genes in bulk soils and soil aggregates.The abundance of nosZ Ⅰ was higher than that of nosZ Ⅱ in all tested soils and had a stronger association with N2O reduction rate,suggesting the greater role of nosZ Ⅰ-carrying microorganisms in N2O consumption.Forest conversion had a greater impact on the community composition of nosZ Ⅰ than nosZ Ⅱ,mainly by increasing the relative abundances of alpha-and beta-Proteobacteria,while decreasing gamma-Proteobacteria.However,nosZ Ⅱ-carrying microorganisms were exclusively dominated by Gemmatimonadetes and less affected by forest conversion.Taken together,our findings significantly contribute to our understanding of the eco-physiological characteristics of N2O-reducing microorganisms and highlight the importance of nosZ Ⅰ-carrying microorganisms in N2O consumption in subtropical forest soils.

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Fe(Ⅱ)oxidation after microbial Fe(Ⅲ)reduction does not cause Cd release

Zhaoyang SUNWenjun ZHANGLei WANGHongwen SUN...

1076-1085页

查看更多>>摘要：Soil flooding and drainage can cause the reduction and oxidation of iron(Fe),as well as the immobilization and mobilization of cadmium(Cd).However,the impact of Fe(Ⅱ)oxidation following microbial Fe(Ⅲ)reduction on Cd mobility remains unclear.In this study,we examined the behavior of Cd during microbial reduction of Fe(Ⅲ)oxides and subsequent chemical re-oxidation of Fe(Ⅱ)using batch reactor systems.The bacterium Shewanella oneidensis MR-1 was incubated with ferrihydrite,lepidocrocite,goethite,or hematite anaerobically and then aerobically in media containing 212 μg L-1 Cd,with or without pH buffering(initial pH=7.0).Compared to the control systems without MR-1,microbial Fe(Ⅲ)reduction significantly promoted the immobilization of dissolved Cd,as well as the conversion of dissolved and adsorbed Cd to strongly bound Cd that could not be extracted by 0.4 mol L-1 HC1.The mechanisms of Cd immobilization were different during the microbial reduction of different Fe(Ⅲ)oxides.The buffering of system pH affected the phase of Fe oxides formed at the reduction and oxidation stages in the systems containing MR-1 and ferrihydrite or lepidocrocite.Nevertheless,in all the systems containing MR-1 and Fe oxides,irrespective of pH buffering,the concentration of dissolved Cd dropped to＜1 μg L-1 after 35 d of anaerobic incubation and remained＜4 μg L-1 after subsequent 72 h of aerobic incubation.This suggests that Fe(Ⅱ)oxidation after microbial Fe(Ⅲ)reduction(generating 0.025-0.22 g L-1 Fe(Ⅱ))does not result in Cd release.

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Increased humic materials explain aggregate-protected carbon and nitrogen accumulation in biochar-amended tropical soils

Emmanuel AMOAKWAHMohammad A.RAHMANKhandakar R.ISLAMKwame A.FRIMPONG...

1086-1099页

查看更多>>摘要：Humic materials make important contributions to soil organic carbon(C)and nitrogen(N)accumulation.However,information on the correlation between humic substances and the accumulation of soil aggregate-protected C and N in response to biochar application under tropical agroecosystems is limited.Therefore,a field trial was conducted to elucidate the effects of biochar on soil aggregate properties and humic materials and how these humic compounds affect aggregate-protected C and N in a humid tropical agroecosystem.The treatments included no-biochar control(CK),15 Mg biochar ha-1(BC-15),30 Mg biochar ha-1(BC-30),and 30 Mg biochar ha-1+phosphate fertilizer(BC-30+P).The treatments BC-30 and BC-30+P significantly increased the contents of humic materials(humic and fulvic acids)as compared to CK.There was a significant increase in the mean-weight diameter of soil aggregates by 3-and 4-fold in BC-30 and BC-30+P,respectively.Similarly,BC-30 and BC-30+P led to significant increases in soil structural coefficient by 3-and 4-fold,respectively,relative to CK.Significant increases in organic C and N accumulation were observed in the macroaggregates of the biochar-amended soils.Inverse relationships between the degree of polymerization and aggregate-protected C and N were observed,implying that low-molecular-weight aliphatic compounds favor organic C and N accumulation with biochar amendments.The important soil property that contributed to organic C and N accumulation in aggregates was fulvic acid content,which could be used as an early and sensitive indicator to notice early changes in aggregate-protected C and N accumulation in soils of the humid tropics.

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