降低水稻籽粒镉砷累积的研究进展

doi:10.19741/j.issn.1673-4831.2021.0244

Abstract

Abstract: Heavy metals pollution in farmland soils induced by mining, waste discharge and sewage irrigation can be concentrated and transported via the food chain, thereby posing great risks to human health. Rice is an important staple food, which however, is readily to uptake and accumulate cadmium (Cd) and arsenic (As) from contaminated soils, rendering it to be a main dietary source of As and Cd of humans. Therefore, exploring strategies to reduce Cd and As content in rice grains has practical importance to ensure food safety and human health. Ways and strategies to reduce Cd and As in rice grains are reviewed, including:(1) Passivate Cd and As by adding biochar, iron salts and fertilizer in paddy soils, decrease their bioavailability and thus the uptake by rice; (2) Eliminate membrane lipid peroxidation stress and promote the formation of non-protein thiol in rice via external application of sulfur (S), fix Cd in vacuoles of rice tissues and reduce its transport to grains, thus reduce Cd accumulation in grains; (3) External application of silicon (Si) to compete with arsenite (As³⁺) for rice uptake of As; (4) Manipulate redox state in rhizosphere by changing water content in rice field, thereby affect the uptake and accumulation of Cd and As in rice. Root oxygen secretion can promote the formation of iron film on rice root surface, facilitate As oxidation into arsenate (As⁵⁺) by changing soil redox state, thereby enhance the adsorption and fixation of As⁵⁺ on root surface to reduce its uptake by rice; (5) Regulate the expression of transporters, i. e., knock out Mn transporter[STBX]OsNRAMP5 or stem/leaf cytoplasmic transporter OsLCT1, silence Si efflux transporter Lsi2, and overexpress OsHMA3n, OsHMA2, and ScAcr3p[STBZ] transporters can reduce Cd and As accumulation in rice grains by promoting root As³⁺ efflux and reducing Cd/As³⁺ translocation to xylem and grain; (6) Screen and cultivate low Cd/As accumulation species. Through the combination of agronomic measures, genetic engineering, and germplasm resource screening, rice species with low Cd/As accumulation and high yield can be selected. Besides, reasonable planning of planting patterns can help to decrease Cd/As uptake and accumulation in rice. The information provide supports for safe production of rice in slight-moderate contaminated soils.

Key words: rice, soil contamination, cadmium, arsenic, manipulate method, transporter, low accumulation species, food safety

CLC Number:

ZHANG Hui-juan, SU Qi-qian, DING Hao-jie, LI Xiao-feng, XU Qi-jing, Rensing Christopher, LIU Xue. Research Progress on Reducing Cadmium and Arsenic Accumulation in Rice Grains[J]. Journal of Ecology and Rural Environment, 2022, 38(7): 827-838.

References

[1] 王玉军,刘存,周东美,等.客观地看待我国耕地土壤环境质量的现状:关于《全国土壤污染状况调查公报》中有关问题的讨论和建议[J].农业环境科学学报,2014,33(8):1465-1473.[WANG Yu-jun,LIU Cun,ZHOU Dong-mei,et al.A Critical View on the Status Quo of the Farmland Soil Environmental Quality in China:Discussion and Suggestion of Relevant Issues on Report on the National General Survey of Soil Contamination[J].Journal of Agro-environment Science,2014,33(8):1465-1473.]
[2] ZHENG R L,CHEN Z,CAI C,et al.Mitigating Heavy Metal Accumulation into Rice (Oryza sativa L.) Using Biochar Amendment:A Field Experiment in Hunan,China[J].Environmental Science and Pollution Research International,2015,22(14):11097-11108.
[3] LI P Z,LIN C Y,CHENG H G,et al.Contamination and Health Risks of Soil Heavy Metals around a Lead/Zinc Smelter in Southwestern China[J].Ecotoxicology and Environmental Safety,2015,113:391-399.
[4] WU Y,YANG J,ZHOU X Y,et al.Risk Assessment of Heavy Metal Contamination in Farmland Soil in Du'an Autonomous County of Guangxi Zhuang Autonomous Region,China[J].Environmental Science,2015,36(8):2964-2971.
[5] ZHAO K L,FU W J,YE Z Q,et al.Contamination and Spatial Variation of Heavy Metals in the Soil-rice System in Nanxun County,Southeastern China[J].International Journal of Environmental Research and Public Health,2015,12(2):1577-1594.
[6] STONE R.Arsenic and Paddy Rice:A Neglected Cancer Risk?[J].Science,2008,321(5886):184-185.
[7] WANG P,CHEN H P,KOPITTKE P M,et al.Cadmium Contamination in Agricultural Soils of China and the Impact on Food Safety[J].Environmental Pollution,2019,249:1038-1048.
[8] YIN D X,WANG X,PENG B,et al.Effect of Biochar and Fe-biochar on Cd and as Mobility and Transfer in Soil-rice System[J].Chemosphere,2017,186:928-937.
[9] FAN Y,ZHU T P,LI M T,et al.Heavy Metal Contamination in Soil and Brown Rice and Human Health Risk Assessment near Three Mining Areas in Central China[J].Journal of Healthcare Engineering,2017,2017:4124302.
[10] ZHUANG P,ZOU B,LI N Y,et al.Heavy Metal Contamination in Soils and Food Crops around Dabaoshan Mine in Guangdong,China:Implication for Human Health[J].Environmental Geochemistry and Health,2009,31(6):707-715.
[11] HENSAWANG S,CHANPIWAT P.Health Impact Assessment of Arsenic and Cadmium Intakevia Rice Consumption in Bangkok,Thailand[J].Environmental Monitoring and Assessment,2017,189(11):599.
[12] ROHMAN A,HELMIYATI S,PENGGALIH M,et al.Rice in Health and Nutrition[J].International Food Research Journal,2014,21(1):13-24.
[13] WATANABE T,SHIMBO S,MOON C S,et al.Cadmium Contents in Rice Samples from Various Areas in the World[J].Science of the Total Environment,1996,184(3):191-196.
[14] ISLAM S,RAHMAN M M,ISLAM M R,et al.Arsenic Accumulation in Rice:Consequences of Rice Genotypes and Management Practices to Reduce Human Health Risk[J].Environment International,2016,96:139-155.
[15] HUANG X F,HU J W,LI C X,et al.Heavy-metal Pollution and Potential Ecological Risk Assessment of Sediments from Baihua Lake,Guizhou,P.R.China[J].International Journal of Environmental Health Research,2009,19(6):405-419.
[16] 谢运河,纪雄辉,黄涓,等.赤泥、石灰对Cd污染稻田改制玉米吸收积累Cd的影响[J].农业环境科学学报,2014,33(11):2104-2110.[XIE Yun-he,JI Xiong-hui,HUANG Juan,et al.Effects of Red-mud and Lime on Cadmium Uptake of Corn in Dryland Converted from Cadmium Polluted Paddy Field[J].Journal of Agro-environment Science,2014,33(11):2104-2110.]
[17] 尹带霞.生物炭对稻田土壤重金属生物有效性的影响与作用机制[D].长沙:湖南师范大学,2016.[YIN Dai-xia.The Affect Mechanism of Biochar on Heavy Metals Bioavailability in Paddy Soil[D].Changsha:Hunan Normal University,2016.]
[18] BIAN R J,DE CHEN,LIU X Y,et al.Biochar Soil Amendment as a Solution to Prevent Cd-tainted Rice from China:Results from a Cross-site Field Experiment[J].Ecological Engineering,2013,58:378-383.
[19] 米雅竹,朱广森,张旭,等.3种水分管理条件下施用木炭和磷酸二铵对水稻Cd、As累积的影响[J].生态与农村环境学报,2020,36(9):1200-1209.[MI Ya-zhu,ZHU Guang-sen,ZHANG Xu,et al.Accumulation of Cd and as in Rice (Oryza sativa) under Different Water Management Coupled with Charcoal and Diammonium Phosphate Amendment[J].Journal of Ecology and Rural Environment,2020,36(9):1200-1209.]
[20] GU J F,ZHOU H,YANG W T,et al.Effects of an Additive (Hydroxyapatite-biochar-zeolite) on the Chemical Speciation of Cd and As in Paddy Soils and Their Accumulation and Translocation in Rice Plants[J].Environmental Science and Pollution Research International,2018,25(9):8608-8619.
[21] 张剑,卢升高.12种钝化剂在镉污染稻田上的应用效果对比[J].浙江农业科学,2020,61(12):2527-2529,2604.[ZHANG Jian,LU Sheng-gao.Comparison of Remediation Effect of Cadmium Contaminated Paddy Fields Using 12 Kinds of Soil Amendments[J].Journal of Zhejiang Agricultural Sciences,2020,61(12):2527-2529,2604.]
[22] MA X M,SHARIFAN H,DOU F G,et al.Simultaneous Reduction of Arsenic (As) and Cadmium (Cd) Accumulation in Rice by Zinc Oxide Nanoparticles[J].Chemical Engineering Journal,2020,384:123802.
[23] 李晓梅,冯廷显,王科举,等.不同施肥措施对重金属污染农田土壤-水稻重金属含量的影响[J].中国农业文摘:农业工程,2019,31(2):49-52.[LI Xiao-mei,FENG Ting-xian,WANG Ke-ju,et al.The Influence of Soil and Rice Heavy Metal Content by Different Fertilization Measures in Heavy Metal Contaminated Farmland[J].Agricultural Science and Engineering in China,2019,31(2):49-52.]
[24] 何其辉,谭长银,曹雪莹,等.肥料对土壤重金属有效态及水稻幼苗重金属积累的影响[J].环境科学研究,2018,31(5):942-951.[HE Qi-hui,TAN Chang-yin,CAO Xue-ying,et al.Effects of Fertilizer on the Availability of Heavy Metals in Soil and Its Accumulation in Rice Seedling[J].Research of Environmental Sciences,2018,31(5):942-951.]
[25] 王丹,李鑫,王代长,等.硫素对水稻根系铁锰胶膜形成及吸收镉的影响[J].环境科学,2015,36(5):1877-1887.[WANG Dan,LI Xin,WANG Dai-chang,et al.Influence of Sulfur on the Formation of Fe-Mn Plaque on Root and Uptake of Cd by Rice (Oryza sativa L.)[J].Environmental Science,2015,36(5):1877-1887.]
[26] MATSUMOTO S,KASUGA J,TAIKI N,et al.Inhibition of Arsenic Accumulation in Japanese Rice by the Application of Iron and Silicate Materials[J].CATENA,2015,135:328-335.
[27] BOGDAN K,SCHENK M K.Arsenic in Rice (Oryza sativa L.) Related to Dynamics of Arsenic and Silicic Acid in Paddy Soils[J].Environmental Science&Technology,2008,42(21):7885-7890.
[28] MA C X,HAO Y,ZHAO J,et al.Graphitic Carbon Nitride (C₃N₄) Reduces Cadmium and Arsenic Phytotoxicity and Accumulation in Rice (Oryza sativa L.)[J].Nanomaterials (Basel,Switzerland),2021,11(4):839.
[29] WILLIAMS P N,VILLADA A,DEACON C,et al.Greatly Enhanced Arsenic Shoot Assimilation in Rice Leads to Elevated Grain Levels Compared to Wheat and Barley[J].Environmental Science&Technology,2007,41(19):6854-6859.
[30] 方至萍,廖敏,张楠,等.施用海泡石对铅、镉在土壤-水稻系统中迁移与再分配的影响[J].环境科学,2017,38(7):3028-3035.[FANG Zhi-ping,LIAO Min,ZHANG Nan,et al.Effect of Sepiolite Application on the Migration and Redistribution of Pb and Cd in Soil Rice System in Soil with Pb and Cd Combined Contamination[J].Environmental Science,2017,38(7):3028-3035.]
[31] 李念,李荣华,冯静,等.粉煤灰改良重金属污染农田的修复效果植物甄别[J].农业工程学报,2015,31(16):213-219.[LI Nian,LI Rong-hua,FENG Jing,et al.Remediation Effects of Heavy Metals Contaminated Farmland Using Fly Ash Based on Bioavailability Test[J].Transactions of the Chinese Society of Agricultural Engineering,2015,31(16):213-219.]
[32] 段然,胡红青,付庆灵,等.生物炭和草酸活化磷矿粉对镉镍复合污染土壤的应用效果[J].环境科学,2017,38(11):4836-4843.[DUAN Ran,HU Hong-qing,FU Qing-ling,et al.Remediation of Cd/Ni Contaminated Soil by Biochar and Oxalic Acid Activated Phosphate Rock[J].Environmental Science,2017,38(11):4836-4843.]
[33] 骆文轩,宋肖琴,陈国安,等.田间施用石灰和有机肥对水稻吸收镉的影响[J].水土保持学报,2020,34(3):232-237.[LUO Wen-xuan,SONG Xiao-qin,CHEN Guo-an,et al.Effects of Applying Lime and Organic Fertilizer on Cadmium Uptake by Rice[J].Journal of Soil and Water Conservation,2020,34(3):232-237.]
[34] 周春海,张振强,黄志红,等.不同钝化剂对酸性土壤中重金属的钝化修复研究进展[J].中国农学通报,2020,36(33):71-79.[ZHOU Chun-hai,ZHANG Zhen-qiang,HUANG Zhi-hong,et al.Passivation and Remediation of Heavy Metals in Acid Soil with Different Passivators:A Research Progress[J].Chinese Agricultural Science Bulletin,2020,36(33):71-79.]
[35] HAO Y,LÜ R T,MA C X,et al.Graphitic Carbon Nitride (g-C₃N₄) Alleviates Cadmium-induced Phytotoxicity to Rice (Oryza sativa L.)[J].Environmental Science and Pollution Research International,2021,28(17):21276-21284.
[36] NATH S,PANDA P,MISHRA S,et al.Arsenic Stress in Rice:Redox Consequences and Regulation by Iron[J].Plant Physiology and Biochemistry,2014,80:203-210.
[37] 林海,潘翰林,贺银海,等.砷污染农田土壤的化学修复技术研究进展[J].环境污染与防治,2020,42(6):780-787.[LIN Hai,PAN Han-lin,HE Yin-hai,et al.Research Advances of Remedying Arsenic-contaminated Farmland Soil by Chemical Techniques[J].Environmental Pollution&Control,2020,42(6):780-787.]
[38] MA J F,YAMAJI N,MITANI N,et al.Transporters of Arsenite in Rice and Their Role in Arsenic Accumulation in Rice Grain[J].Proceedings of the National Academy of Sciences of the United States of America,2008,105(29):9931-9935.
[39] 丁萍,贺玉龙,何欢,等.复合改良剂FZB对砷镉污染土壤的修复效果[J].环境科学,2021,42(2):917-924.[DING Ping,HE Yu-long,HE Huan,et al.Remediation Effect of Compound Modifier FZB on Arsenic and Cadmium Contaminated Soil[J].Environmental Science,2021,42(2):917-924.]
[40] LIU W J,MCGRATH S P,ZHAO F J.Silicon Has Opposite Effects on the Accumulation of Inorganic and Methylated Arsenic Species in Rice[J].Plant and Soil,2014,376(1/2):423-431.
[41] 杨海征.鸡粪堆肥对重金属污染土壤茼蒿品质,土壤Cu、Cd形态和酶活性影响[D].武汉:华中农业大学,2009.[YANG Hai-zheng.Effect of Chicken Manure Compost on the Qulity of Chrysanthemum,Soil Cu,Cd Fractions and Enzymes Activities in Heavy Metal Contaminated Soils[D].Wuhan:Huazhong Agricultural University,2009.]
[42] DUAN G L,SHAO G S,TANG Z,et al.Genotypic and Environmental Variations in Grain Cadmium and Arsenic Concentrations among a Panel of High Yielding Rice Cultivars[J].Rice,2017,10(1):9.
[43] 张亚丽,沈其荣,姜洋.有机肥料对镉污染土壤的改良效应[J].土壤学报,2001,38(2):212-218.[ZHANG Ya-li,SHEN Qi-rong,JIANG Yang.Effects of Organic Manure on the Amelioration of Cd-polluted Soil[J].Acta Pedologica Sinica,2001,38(2):212-218.]
[44] KHAN M I R,NAZIR F,ASGHER M,et al.Selenium and Sulfur Influence Ethylene Formation and Alleviate Cadmium-induced Oxidative Stress by Improving Proline and Glutathione Production in Wheat[J].Journal of Plant Physiology,2015,173:9-18.
[45] MOSTOFA M G,RAHMAN A,ANSARY M M U,et al.Hydrogen Sulfide Modulates Cadmium-induced Physiological and Biochemical Responses to Alleviate Cadmium Toxicity in Rice[J].Scientific Reports,2015,5:14078.
[46] SETH C S,REMANS T,KEUNEN E,et al.Phytoextraction of Toxic Metals:A Central Role for Glutathione[J].Plant,Cell&Environment,2012,35(2):334-346.
[47] 潘智立,李军.硫、硅对水稻体内NPT含量及镉亚细胞分布的影响[J].土壤通报,2016,47(5):1253-1258.[PAN Zhi-li,LI Jun.The Response of Non-protein Thiols and Subcellular Distribution of Cadmium in Rice to the Exogenous Sulfur and Silicon[J].Chinese Journal of Soil Science,2016,47(5):1253-1258.]
[48] 程六龙,黄永春,周桂华,等.叶面喷施S-烯丙基-L-半胱氨酸对晚稻籽粒中铅含量的影响[J].农业环境科学学报,2020,39(10):2134-2142.[CHENG Liu-long,HUANG Yong-chun,ZHOU Gui-hua,et al.Foliar Application of SAC Reduces Lead Concentration in Late Rice Grains by Decreasing the Translocation of Lead from the Roots to the Above-ground Parts[J].Journal of Agro-environment Science,2020,39(10):2134-2142.]
[49] GOLDBERG S.Competitive Adsorption of Arsenate and Arsenite on Oxides and Clay Minerals[J].Soil Science Society of America Journal,2002,66(2):413-421.
[50] YAMAGUCHI N,NAKAMURA T,DONG D,et al.Arsenic Release from Flooded Paddy Soils Is Influenced by Speciation,Eh,pH,and Iron Dissolution[J].Chemosphere,2011,83(7):925-932.
[51] SYU C H,LEE C H,JIANG P Y,et al.Comparison of as Sequestration in Iron Plaque and Uptake by Different Genotypes of Rice Plants Grown in As-contaminated Paddy Soils[J].Plant and Soil,2014,374(1/2):411-422.
[52] LIU W J,ZHU Y G,SMITH F A,et al.Do Iron Plaque and Genotypes Affect Arsenate Uptake and Translocation by Rice Seedlings (Oryza sativa L.) Grown in Solution Culture?[J].Journal of Experimental Botany,2004,55(403):1707-1713.
[53] SYU C H,JIANG P Y,HUANG H H,et al.Arsenic Sequestration in Iron Plaque and Its Effect on as Uptake by Rice Plants Grown in Paddy Soils with High Contents of As,Iron Oxides,and Organic Matter[J].Soil Science and Plant Nutrition,2013,59(3):463-471.
[54] LIU W J,ZHU Y G,SMITH F A.Effects of Iron and Manganese Plaques on Arsenic Uptake by Rice Seedlings (Oryza sativa L.) Grown in Solution Culture Supplied with Arsenate and Arsenite[J].Plant and Soil,2005,277(1/2):127-138.
[55] YAMAGUCHI N,OHKURA T,TAKAHASHI Y,et al.Arsenic Distribution and Speciation near Rice Roots Influenced by Iron Plaques and Redox Conditions of the Soil Matrix[J].Environmental Science&Technology,2014,48(3):1549-1556.
[56] WANG X,PENG B,TAN C Y,et al.Recent Advances in Arsenic Bioavailability,Transport,and Speciation in Rice[J].Environmental Science and Pollution Research International,2015,22(8):5742-5750.
[57] HU P J,HUANG J X,OUYANG Y N,et al.Water Management Affects Arsenic and Cadmium Accumulation in Different Rice Cultivars[J].Environmental Geochemistry and Health,2013,35(6):767-778.
[58] SUN L,XU X X,JIANG Y R,et al.Genetic Diversity,Rather than Cultivar Type,Determines Relative Grain Cd Accumulation in Hybrid Rice[J].Frontiers in Plant Science,2016,7:1407.
[59] 胡培松.土壤有毒重金属镉毒害及镉低积累型水稻筛选与改良[J].中国稻米,2004,10(2):10-12.
[60] XIE L H,TANG S Q,WEI X J,et al.The Cadmium and Lead Content of the Grain Produced by Leading Chinese Rice Cultivars[J].Food Chemistry,2017,217:217-224.
[61] LIU W J,ZHU Y G,HU Y,et al.Arsenic Sequestration in Iron Plaque,Its Accumulation and Speciation in Mature Rice Plants (Oryza sativa L.)[J].Environmental Science&Technology,2006,40(18):5730-5736.
[62] PILLAI T R,YAN W G,AGRAMA H A,et al.Total Grain-arsenic and Arsenic-species Concentrations in Diverse Rice Cultivars under Flooded Conditions[J].Crop Science,2010,50(5):2065-2075.
[63] 殷敬峰,李华兴,卢维盛,等.不同品种水稻糙米对Cd Cu Zn积累特性的研究[J].农业环境科学学报,2010,29(5):844-850.[YIN Jing-feng,LI Hua-xing,LU Wei-sheng,et al.Variations of Cd,Cu,Zn Accumulation among Rice Cultivars[J].Journal of Agro-environment Science,2010,29(5):844-850.]
[64] 蒋彬,张慧萍.水稻精米中铅镉砷含量基因型差异的研究[J].云南师范大学学报(自然科学版),2002,22(3):37-40.[JIANG Bin,ZHANG Hui-ping.Genotypic Differences in Concentrations of Plumbum,Cadmium and Arsenicum in Polished Rice Grains[J].Journal of Yunnan Normal University (Natural Sciences Edition),2002,22(3):37-40.]
[65] 李坤权,刘建国,陆小龙,等.水稻不同品种对镉吸收及分配的差异[J].农业环境科学学报,2003,22(5):529-532.[LI Kun-quan,LIU Jian-guo,LU Xiao-long,et al.Uptake and Distribution of Cadmium in Different Rice Cultivars[J].Journal of Agro-environmental Science,2003,22(5):529-532.]
[66] PINSON S R M,TARPLEY L,YAN W G,et al.Worldwide Genetic Diversity for Mineral Element Concentrations in Rice Grain[J].Crop Science,2015,55(1):294-311.
[67] LEI M,TIE B Q,ZENG M,et al.An Arsenic-contaminated Field Trial to Assess the Uptake and Translocation of Arsenic by Genotypes of Rice[J].Environmental Geochemistry and Health,2013,35(3):379-390.
[68] MARIN A R,MASSCHELEYN P H,PATRICK W H.The Influence of Chemical Form and Concentration of Arsenic on Rice Growth and Tissue Arsenic Concentration[J].Plant and Soil,1992,139(2):175-183.
[69] 涂德辉,李德强,宋诗昀,等.水稻砷耐性差异及砷高耐性材料的筛选[J].应用与环境生物学报,2018,24(5):1065-1072.[TU De-hui,LI De-qiang,SONG Shi-yun,et al.Differences in Arsenic Tolerance and Screening of High Arsenic-tolerant Materials of Rice (Oryza sativa L.)[J].Chinese Journal of Applied and Environmental Biology,2018,24(5):1065-1072.]
[70] CHEN F,DONG J,WANG F,et al.Identification of Barley Genotypes with Low Grain Cd Accumulation and Its Interaction with Four Microelements[J].Chemosphere,2007,67(10):2082-2088.
[71] CHI Y H,LI F B,TAM N FY,et al.Variations in Grain Cadmium and Arsenic Concentrations and Screening for Stable Low-accumulating Rice Cultivars from Multi-environment Trials[J].Science of the Total Environment,2018,643:1314-1324.
[72] 柳赛花,纪雄辉,谢运河,等.基于GGE双标图和BLUP分析筛选镉砷同步低累积水稻品种[J].生态环境学报,2021,30(2):405-411.[LIU Sai-hua,JI Xiong-hui,XIE Yun-he,et al.Screening of Cadmium and Arsenic Synchronous Low-accumulating Rice Cultivars Based on GGE Double Plot and BLUP Analysis[J].Ecology and Environmental Sciences,2021,30(2):405-411.]
[73] 易春丽,刘汇川,李海英,等.镉砷低积累水稻品种筛选[J].湖南农业科学,2020(6):1-4.[YI Chun-li,LIU Hui-chuan,LI Hai-ying,et al.Screening of Rice Varieties with Low Cadmium and Arsenic Accumulation[J].Hunan Agricultural Sciences,2020(6):1-4.]
[74] YANG M,LU K,ZHAO F J,et al.Genome-wide Association Studies Reveal the Genetic Basis of Ionomic Variation in Rice[J].The Plant Cell,2018,30(11):2720-2740.
[75] ZHOU J Q,JIANG Y R,MING X Q,et al.Introgressing the Allelic Variation of a Major Locus in Reducing the Grain Cadmium Accumulation in Indica Rice Hybrids[J].Molecular Breeding,2019,39(6):1-11.
[76] ZHAO F J,WANG P.Arsenic and Cadmium Accumulation in Rice and Mitigation Strategies[J].Plant and Soil,2020,446(1/2):1-21.
[77] ISHIKAWA S,ISHIMARU Y,IGURA M,et al.Ion-beam Irradiation,Gene Identification,and Marker-assisted Breeding in the Development of Low-cadmium Rice[J].Proceedings of the National Academy of Sciences of the United States of America,2012,109(47):19166-19171.
[78] TANG L,MAO B,LI Y,et al.Knockout of OsNRAMP5 Using the CRISPR/Cas9 System Produces Low Cd-accumulating Indica Rice without Compromising Yield[J].Scientific Reports,2017,7:14438.
[79] LIU C L,GAO Z Y,SHANG L G,et al.Natural Variation in the Promoter ofOsHMA3 Contributes to Differential Grain Cadmium Accumulation between Indica and Japonica Rice[J].Journal of Integrative Plant Biology,2020,62(3):314-329.
[80] 冯爱煊,贺红周,李娜,等.基于多目标元素的重金属低累积水稻品种筛选及其吸收转运特征[J].农业资源与环境学报,2020,37(6):988-1000.[FENG Ai-xuan,HE Hong-zhou,LI Na,et al.Screening of Rice Varieties with Low Accumulation of Heavy Metals Based on Multiple Target Elements and Their Absorption and Transport Characteristics in Rice Plants[J].Journal of Agricultural Resources and Environment,2020,37(6):988-1000.]
[81] MA J F,YAMAJI N,MITANI N,et al.An Efflux Transporter of Silicon in Rice[J].Nature,2007,448(7150):209-212.
[82] DENG F L,YAMAJI N,MA J F,et al.Engineering Rice with Lower Grain Arsenic[J].Plant Biotechnology Journal,2018,16(10):1691-1699.
[83] SASAKI A,YAMAJI N,YOKOSHO K,et al.Nramp5 Is a Major Transporter Responsible for Manganese and Cadmium Uptake in Rice[J].The Plant Cell,2012,24(5):2155-2167.
[84] URAGUCHI S,KAMIYA T,SAKAMOTO T,et al.Low-affinity Cation Transporter (OsLCT1) Regulates Cadmium Transport into Rice Grains[J].Proceedings of the National Academy of Sciences of the United States of America,2011,108(52):20959-20964.
[85] CHEN Y,SUN S K,TANG Z,et al.The Nodulin 26-like Intrinsic Membrane Protein OsNIP3[QX (Y12];2 Is Involved in Arsenite Uptake by Lateral Roots in Rice[J].Journal of Experimental Botany,2017,68(11):3007-3016.
[86] DUAN G L,KAMIYA T,ISHIKAWA S,et al.Expressing ScACR3 in Rice Enhanced Arsenite Efflux and Reduced Arsenic Accumulation in Rice Grains[J].Plant&Cell Physiology,2012,53(1):154-163.
[87] HU Y A,CHENG H F,TAO S.The Challenges and Solutions for Cadmium-contaminated Rice in China:A Critical Review[J].Environment International,2016,92/93:515-532.
[88] UENO D,YAMAJI N,KONO I,et al.Gene Limiting Cadmium Accumulation in Rice[J].Proceedings of the National Academy of Sciences of the United States of America,2010,107(38):16500-16505.
[89] TAKAHASHI R,ISHIMARU Y,SHIMO H,et al.The OsHMA2 Transporter Is Involved in Root-to-shoot Translocation of Zn and Cd in Rice[J].Plant,Cell&Environment,2012,35(11):1948-1957.
[90] CAO Y,SUN D,AI H,et al.Knocking out OsPT4 Gene Decreases Arsenate Uptake by Rice Plants and Inorganic Arsenic Accumulation in Rice Grains[J].Environmental Science&Technology,2017,51(21):12131-12138.
[91] YE Y,LI P,XU T Q,et al.OsPT4 Contributes to Arsenate Uptake and Transport in Rice[J].Frontiers in Plant Science,2017,8:2197.
[92] 段桂兰,王利红,陈玉,等.水稻砷污染健康风险与砷代谢机制的研究[J].农业环境科学学报,2007,26(2):430-435.[DUAN Gui-lan,WANG Li-hong,CHEN Yu,et al.Health Risk from Consumption of Rice with Elevated Arsenic and Studies of Arsenic Metabolism in Rice Plants[J].Journal of Agro-environment Science,2007,26(2):430-435.]
[93] CHEN Y S,HUA C Y,CHEN J X,et al.Expressing Arsenite Antiporter PvACR3[QX (Y12];1 in Rice (Oryza sativa L.) Decreases Inorganic Arsenic Content in Rice Grains[J].Environmental Science&Technology,2019,53(17):10062-10069.
[94] CHEN X W,LI H,CHAN W F,et al.Arsenite Transporters Expression in Rice (Oryza sativa L.) Associated with Arbuscular Mycorrhizal Fungi (AMF) Colonization under Different Levels of Arsenite Stress[J].Chemosphere,2012,89(10):1248-1254.
[95] 李威,刘艳,李慧,等.VIP+n技术在轻度酸性镉污染农田的应用[J].安徽农业科学,2019,47(19):99-102.[LI Wei,LIU Yan,LI Hui,et al.Application of VIP+n Technology in Farmland with Mild Acid Cadmium Pollution[J].Journal of Anhui Agricultural Sciences,2019,47(19):99-102.

Research Progress on Reducing Cadmium and Arsenic Accumulation in Rice Grains

RichHTML

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	LIU Chong-wan, ZHU Xiao-hua, XU Zhi-hua, REN Di, MENG Yong, LIU Yi, TANG Jian-qing. Dynamic Non-target Analysis and Occurrence of Herbicides Residues in Rice-crayfish and Rice-crab Co-culture Systems in Jiangsu Province [J]. Journal of Ecology and Rural Environment, 2022, 38(7): 933-943.
[2]	QIU Wei, ZHOU Tong, LI Yuan, SHEN Yi-chen, ZHU Xia, YUN Hao, LUO Yong-ming, XU Ying-ming. Effects of the Modified and Compounded Clay Mineral Conditioners on Cadmium Availability in Soil and Cadmium Content in Brown Rice [J]. Journal of Ecology and Rural Environment, 2022, 38(5): 654-659.
[3]	XIAO Yu, QI Zhen-hong, XU Sheng, YANG Cai-yan, LIU Yu-xiao. Impact of Social Interaction and Information Acquisition Ability on Farmers' Adoption Behavior of Rice-shrimp Co-cultivation Technology [J]. Journal of Ecology and Rural Environment, 2022, 38(3): 308-318.
[4]	BAI Zhong-qiang, FAN Xiao-liang, MENG Fan-yue, ZHAO Yan, SONG Bing, SONG Min. Study on High-efficiency Arsenic Removal Performance and Mechanism of Carbon-supported Ferrihydrite Adsorbent [J]. Journal of Ecology and Rural Environment, 2022, 38(3): 358-366.
[5]	REN Chao, ZHU Li-wen, LI Jing-tian, DU Qian-qian, XIAO Jian-hui, WANG Hao, ZHAO Rui. Study on the Passivation Effect of Different Treatments on Weakly Acidic Cadmium Polluted Soil [J]. Journal of Ecology and Rural Environment, 2022, 38(3): 383-390.
[6]	WANG Chen, WANG Zhen-qi, ZHANG Min, SHEN Gen-xiang, ZHANG Xin-liang, QIAN Xiao-yong, GAO Zong-yuan. Study on the Potential of Rice Straw Dry Anaerobic Fermentation with Biogas and Fertilizer [J]. Journal of Ecology and Rural Environment, 2022, 38(2): 266-272.
[7]	QI Fei, FU Tong-gang, GAO Hui, LIU Jin-tong. Review on Cadmium Pollution from Sewage Irrigation in Farmland Soil. [J]. Journal of Ecology and Rural Environment, 2022, 38(1): 10-20.
[8]	HU Nai-juan, WANG Yu-tao, TAO Bao-rui, ZHU Li-qun. The Influence of Ecological Cognition and External Environment on the Agricultural Input Reduction Behavior of Rice and Crayfish Co-cropping Farmers: Based on the Survey Data of 589 Farmers in Jiangsu Province [J]. Journal of Ecology and Rural Environment, 2021, 37(8): 983-991.
[9]	LI Fu-duo, ZHANG Kang-jie, HAO Ai-bo, YIN Chang-bin. The Incentive Mechanism of Ecological Compensation to the Generation of Green Manure Planting Behavioral Inertia: Estimation Based on Propensity Score Matching [J]. Journal of Ecology and Rural Environment, 2021, 37(7): 894-903.
[10]	YANG Jin-kang, ZHU Li-nan, YANG Qiu-yun, ZHANG Yu-peng, HUA Dang-ling. Effects of Silicon-Calcium-Magnesium Fertilizer and Modified Humic Acid on Soil Cadmium Chemical Fractions and Accumulation in Wheat [J]. Journal of Ecology and Rural Environment, 2021, 37(6): 808-816.
[11]	LI Wen-bo, LIU Shao-jun, YE Xin-xin, GAO Hong-jian, LIU Rong, LI Deng-yun, YAO Guo-liang. Effects of the Integrated Rice-crayfish Farming on Nitrogen Accumulation and Quality of Rice [J]. Journal of Ecology and Rural Environment, 2021, 37(5): 661-667.
[12]	SI Guo-han, PENG Cheng-lin, YUAN Jia-fu, XIA Xian-ge, CHENG Jian-ping, XU Xiang-yu, JIA Ping-an, XIE Yuan-yuan, ZHOU Jian-xiong. Effect of Rice Straw Returning to Field on Ammonia Volatilization in Paddy Fields under the Integrated Rice-crayfish System [J]. Journal of Ecology and Rural Environment, 2021, 37(3): 360-368.
[13]	LI Qun, LONG Tao, ZHOU Yan, FAN Ting-ting, ZUO Fei-ran, WU Yun-jin. The Effect of Soil Samples Preserved with Methanol for VOCs on the Determination of Site Pollution Risk [J]. Journal of Ecology and Rural Environment, 2021, 37(2): 242-248.
[14]	QIN Song-yan, XIA Di, ZHAO Li-xin. Stable Remediation of Arsenic-contaminated Soil by Sludge-based Biochar [J]. Journal of Ecology and Rural Environment, 2021, 37(11): 1481-1486.
[15]	LI Wen-bo, LIU Shao-jun, YE Xin-xin, GAO Hong-jian. Effects of the Co-culture of Rice and Aquatic Animals on Soil Eco-system: A Review [J]. Journal of Ecology and Rural Environment, 2021, 37(10): 1292-1300.