[1]张影,郭桂珍,王斯文,等.水稻耐盐机制及提高水稻耐盐性途径研究进展[J].江苏农业科学,2025,53(18):17-27.
 Zhang Ying,et al.Research progress on salt tolerance mechanism of rice and approaches to enhance rice salt tolerance[J].Jiangsu Agricultural Sciences,2025,53(18):17-27.
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水稻耐盐机制及提高水稻耐盐性途径研究进展()

《江苏农业科学》[ISSN:1002-1302/CN:32-1214/S]

卷:
第53卷
期数:
2025年第18期
页码:
17-27
栏目:
专论与综述
出版日期:
2025-09-20

文章信息/Info

Title:
Research progress on salt tolerance mechanism of rice and approaches to enhance rice salt tolerance
作者:
张影郭桂珍王斯文邱志刚杨春刚
吉林省农业科学院(中国农业科技东北创新中心)水稻研究所,吉林公主岭 136100
Author(s):
Zhang Yinget al
关键词:
水稻盐胁迫生理响应分子机制育种栽培技术
Keywords:
-
分类号:
S511.01
DOI:
-
文献标志码:
A
摘要:
全球盐渍化土壤日益增多,对粮食安全造成威胁,盐胁迫严重制约作物的产量及品质。水稻是世界重要粮食作物之一,因其具有“洗盐、排盐”的效果,对于盐渍化土壤的治理具有独特优势,而深入了解盐胁迫下的耐盐机制对提高水稻的产量与品质有着关键作用。本文概述了盐胁迫对作物生产造成的影响以及水稻对于盐碱地改良的优势性,重点阐述了离子平衡调节、渗透调节、活性氧清除3个生理响应层面、盐胁迫下的激素调节相关基因及耐盐QTL,简述了耐盐性水稻育种的研究进展,总结了水稻耐盐性栽培技术措施,并结合当前耐盐水稻的需求,对未来耐盐性水稻育种及方向进行了探讨与展望,以期为未来耐盐性水稻研究及利用提供方向和参考。
Abstract:
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参考文献/References:

[1]Chele K H,Tinte M M,Piater L A,et al. Soil salinity,a serious environmental issue and plant responses:a metabolomics perspective[J]. Metabolites,2021,11(11):724-724.
[2]王洋,张瑞,刘永昊,等. 水稻对盐胁迫的响应及耐盐机理研究进展[J]. 中国水稻科学,2022,36(2):105-117.
[3]Jha U C,Bohra A,Jha R,et al. Salinity stress response and ‘omics’ approaches for improving salinity stress tolerance in major grain legumes[J]. Plant Cell Reports,2019,38(3):255-277.
[4]Butcher K,Wick A F,DeSutter T,et al. Soil salinity:a threat to global food security[J]. Agronomy Journal,2016,108(6):2189-2200.
[5]Shahid S A,Zaman M,Heng L.Introduction to soil salinity,sodicity and diagnostics techniques[M]//Guideline for salinity assessment,mitigation and adaptation using nuclear and related techniques.Springer Cham,2018:1-42.
[6]魏征,屠乃美,易镇邪. 盐碱地对水稻的胁迫效应及其改良与高效利用的研究进展[J]. 湖南生态科学学报,2019,6(4):45-52.
[7]Hasan M M,Rahman M A,Corpas F J,et al. Salt stress tolerance in rice (Oryza sativa L.):a proteomic overview of recent advances and future prospects[J]. Plant Stress,2024,11:100307.
[8]梁银培,孙健,索艺宁,等. 水稻耐盐性和耐碱性相关性状的QTL定位及环境互作分析[J]. 中国农业科学,2017,50(10):1747-1762.
[9]陈思蓉,李晨,孙炳蕊. 水稻耐盐分子机制研究进展[J]. 广东农业科学,2023,50(12):29-42.
[10]Qin H,Huang R F. The phytohormonal regulation of Na+/K+and reactive oxygen species homeostasis in rice salt response[J]. Molecular Breeding,2020,40(5):47.
[11]李源,蔡勤安,马瑞,等. 植物Na+/H+逆向转运蛋白研究进展[J]. 山东农业科学,2022,54(10):143-152.
[12]Bhatt T,Sharma A,Puri S,et al. Salt tolerance mechanisms and approaches:future scope of halotolerant genes and rice landraces[J]. Rice Science,2020,27(5):368-383.
[13]van Zelm E,Zhang Y X,Testerink C. Salt tolerance mechanisms of plants[J]. Annual Review of Plant Biology,2020,71(1):403-433.
[14]Ali A,Maggio A,Bressan R A,et al. Role and functional differences of HKT1-type transporters in plants under salt stress[J]. International Journal of Molecular Sciences,2019,20(5):1059.
[15]Riedelsberger J,Miller J K,Valdebenito-Maturana B,et al. Plant HKT channels:an updated view on structure,function and gene regulation[J]. International Journal of Molecular Sciences,2021,22(4):1892.
[16]Wang R,Jing W,Xiao L Y,et al. The rice high-affinity potassium transporter1;1 is involved in salt tolerance and regulated by an MYB-type transcription factor[J]. Plant Physiology,2015,168(3):1076-1090.
[17]曲梦宇,许惠滨,陈静,等. 水稻耐盐分子机制与分子改良[J]. 植物遗传资源学报,2022,23(3):644-653.
[18]Horie T,Costa A,Kim T H,et al. Rice OsHKT2;1 transporter mediates large Na+influx component into K+starved roots for growth[J]. The EMBO Journal,2007,26(12):3003-3014.
[19]Yao X,Horie T,Xue S W,et al. Differential sodium and potassium transport selectivities of the rice OsHKT2;1 and OsHKT2;2 transporters in plant cells[J]. Plant Physiology,2010,152(1):341-355.
[20]Liu S P,Zheng L Q,Xue Y H,et al. Overexpression of OsVP1 and OsNHX1 increases tolerance to drought and salinity in rice[J]. Journal of Plant Biology,2010,53(6):444-452.
[21]Chen H L,Xu N,Wu Q,et al. OsMADS27 regulates the root development in a NO-3-dependent manner and modulates the salt tolerance in rice (Oryza sativa L.)[J]. Plant Science,2018,277:20-32.
[22]Zhao C Z,Zhang H,Song C P,et al. Mechanisms of plant responses and adaptation to soil salinity[J]. Innovation,2020,1(1):100017.
[23]Yang Y,Guo Y. Elucidating the molecular mechanisms mediating plant salt-stress responses[J]. New Phytologist,2018,217(2):523-539.
[24]Rajendran K,Tester M,Roy S J. Quantifying the three main components of salinity tolerance in cereals[J]. Plant,Cell and Environment,2009,32(3):237-249.
[25]Sripinyowanich S,Klomsakul P,Boonburapong B,et al. Exogenous ABA induces salt tolerance in indica rice (Oryza sativa L.):the role of OsP5CS1 and OsP5CR gene expression during salt stress[J]. Environmental and Experimental Botany,2013,86:94-105.
[26]Li H W,Zang B S,Deng X W. Overexpression of the trehalose-6-phosphate synthase gene OsTPS1 enhances abiotic stress tolerance in rice[J]. Planta,2011,234(5):1007-1018.
[27]Cao H,Guo S Y,Xu Y Y,et al. Reduced expression of a gene encoding a Golgi localized monosaccharide transporter (OsGMST1) confers hypersensitivity to salt in rice (Oryza sativa)[J]. Journal of Experimental Botany,2011,62(13):4595-4604.
[28]Mathan J,Singh A,Ranjan A. Sucrose transport in response to drought and salt stress involves ABA-mediated induction of OsSWEET13 and OsSWEET15 in rice[J]. Physiologia Plantarum,2021,171(4):620-637.
[29]Hasthanasombut S,Supaibulwatana K,Mii M,et al. Genetic manipulation of Japonica rice using the OsBADH1 gene from Indica rice to improve salinity tolerance[J]. Plant Cell,Tissue & Organ Culture,2011,104(1):79-89.
[30]Tang W,Sun J Q,Liu J,et al. RNAi-directed downregulation of betaine aldehyde dehydrogenase 1 (OsBADH1) results in decreased stress tolerance and increased oxidative markers without affecting glycine betaine biosynthesis in rice (Oryza sativa)[J]. Plant Molecular Biology,2014,86(4-5):443-454.
[31]Duan J L,Cai W M. OsLEA3-2,an abiotic stress induced gene of rice plays a key role in salt and drought tolerance[J]. PLoS One,2012,7(9):e45117.
[32]Hu T Z,Zeng H,He S,et al. Molecular analysis of OsLEA4 and its contributions to improve E.coli viability[J]. Applied Biochemistry and Biotechnology,2012,166(1):222-233.
[33]He S,Tan L L,Hu Z L,et al. Molecular characterization and functional analysis by heterologous expression in E.coli under diverse abiotic stresses for OsLEA5,the atypical hydrophobic LEA protein from Oryza sativa L.[J]. Molecular Genetics & Genomics,2012,287(1):39-54.
[34]Yu J,Lai Y M,Wu X,et al. Overexpression of OsEm1 encoding a group Ⅰ LEA protein confers enhanced drought tolerance in rice[J]. Biochemical and Biophysical Research Communications,2016,478(2):703-709.
[35]Yuan X,Sun H,Tang Z B,et al. A novel little membrane protein confers salt tolerance in rice (Oryza sativa L.)[J]. Plant Molecular Biology Reporter,2016,34:524-532.
[36]Manimaran P,Venkata R S,Moin M,et al. Activation-tagging in indica rice identifies a novel transcription factor subunit,NF-YC13 associated with salt tolerance[J]. Scientific Reports,2017,7(1):9341.
[37]Sun S J,Guo S Q,Yang X,et al. Functional analysis of a novel Cys2/His2-type zinc finger protein involved in salt tolerance in rice[J]. Journal of Experimental Botany,2010,61(10):2807-2818.
[38]Huang J,Sun S J,Xu D Q,et al. A TFIIIA-type zinc finger protein confers multiple abiotic stress tolerances in transgenic rice (Oryza sativa L.)[J]. Plant Molecular Biology,2012,80(3):337-350.
[39]Liu K M,Wang L,Xu Y Y,et al. Overexpression of OsCOIN,a putative cold inducible zinc finger protein,increased tolerance to chilling,salt and drought,and enhanced proline level in rice[J]. Planta,2007,226(4):1007-1016.
[40]Song S Y,Chen Y,Chen J,et al. Physiological mechanisms underlying OsNAC5-dependent tolerance of rice plants to abiotic stress[J]. Planta,2011,234(2):331-345.
[41]Miller G,Suzuki N,Ciftci-Yilmaz S,et al. Reactive oxygen species homeostasis and signalling during drought and salinity stresses[J]. Plant Cell Environment,2010,33(4):453-467.
[42]Gill S S,Tuteja N. Reactive oxygen species and antioxidant machinery in abiotic stress tolerance in crop plants[J]. Plant Physiology and Biochemistry,2010,48(12):909-930.
[43]You J,Chan Z L. ROS regulation during abiotic stress responses in crop plants[J]. Frontiers in Plant Science,2015,6:1092.
[44]Liu C T,Mao B G,Yuan D Y,et al. Salt tolerance in rice:physiological responses and molecular mechanisms[J]. The Crop Journal,2022,10(1):13-25.
[45]Zhang Z G,Zhang Q,Wu J X,et al. Gene knockout study reveals that cytosolic ascorbate peroxidase 2 (OsAPX2) plays a critical role in growth and reproduction in rice under drought,salt and cold stresses[J]. PLoS One,2013,8(2):e57472.
[46]Lu Z Q,Liu D L,Liu S K. Two rice cytosolic ascorbate peroxidases differentially improve salt tolerance in transgenic Arabidopsis[J]. Plant Cell Reports,2007,26(10):1909-1917.
[47]Hong C Y,Hsu Y T,Tsai Y C,et al. Expression of ASCORBATE PEROXIDASE 8 in roots of rice (Oryza sativa L.) seedlings in response to NaCl[J]. Journal of Experimental Botany,2007,58(12):3273-3283.
[48]Chou T S,Chao Y Y,Kao C H. Involvement of hydrogen peroxide in heat shock-and cadmium-induced expression of ascorbate peroxidase and glutathione reductase in leaves of rice seedlings[J]. Journal of Plant Physiology,2012,169(5):478-86.
[49]Sharma R,Priya P,Jain M. Modified expression of an auxin-responsive rice CC-type glutaredoxin gene affects multiple abiotic stress responses[J]. Planta,2013,238(5):871-884.
[50]Wu T M,Lin W R,Kao Y T,et al. Identification and characterization of a novel chloroplast/mitochondria co-localized glutathione reductase 3 involved in salt stress response in rice[J]. Plant Molecular Biology,2013,83(4/5):379-390.
[51]Lima-Melo Y,Carvalho F E L,Martins M O,et al. Mitochondrial GPX1 silencing triggers differential photosynthesis impairment in response to salinity in rice plants[J]. Journal of Integrative Plant Biology,2016,58(8):737-748.
[52]Wu T M,Lin W R,Kao C H,et al. Gene knockout of glutathione reductase 3 results in increased sensitivity to salt stress in rice[J]. Plant Molecular Biology,2015,87(6):555-564.
[53]Dong N Q,Sun Y W,Guo T,et al. UDP-glucosyltransferase regulates grain size and abiotic stress tolerance associated with metabolic flux redirection in rice[J]. Nature Communications,2020,11:2629.
[54]Asano T,Hayashi N,Kobayashi M,et al. A rice calcium-dependent protein kinase OsCPK12 oppositely modulates salt-stress tolerance and blast disease resistance[J]. Plant Journal,2012,69(1):26-36.
[55]Campo S,Baldrich P,Messeguer J,et al. Overexpression of a calcium-dependent protein kinase confers salt and drought tolerance in rice by preventing membrane lipid peroxidation[J]. Plant Physiology,2014,165(2):688-704.
[56]Ouyang S Q,Liu Y F,Liu P,et al. Receptor-like kinase OsSIK1 improves drought and salt stress tolerance in rice (Oryza sativa) plants[J]. Plant Journal,2010,62(2):316-329.
[57]Lakra N,Nutan K K,Das P,et al. A nuclear localized histone-gene binding protein from rice (OsHBP1b) functions in salinity and drought stress tolerance by maintaining chlorophyll content and improving the antioxidant machinery[J]. Journal of Plant Physiology,2015,176:36-46.
[58]Zhang Z Y,Liu H H,Sun C,et al. A C2H2 zinc-finger protein OsZFP213 interacts with OsMAPK3 to enhance salt tolerance in rice[J]. Journal of Plant Physiology,2018,229:100-110.
[59]Xu N,Chu Y L,Chen H L,et al. Rice transcription factor OsMADS25 modulates root growth and confers salinity tolerance via the ABA-mediated regulatory pathway and ROS scavenging[J]. PLoS Genetics,2018,14(10):e1007662.
[60]Yang A,Dai X Y,Zhang W H. A R2R3-type MYB gene,OsMYB2,is involved in salt,cold,and dehydration tolerance in rice[J]. Journal of Experimental Botany,2012,63(7):2541-2556.
[61]Cui L G,Shan J X,Shi M,et al. DCA1 acts as a transcriptional co-activator of DST and contributes to drought and salt tolerance in rice[J]. PLoS Genetics,2015,11(10):e1005617.
[62]Huang X Y,Chao D Y,Gao J P,et al. A previously unknown zinc finger protein,DST,regulates drought and salt tolerance in rice via stomatal aperture control[J]. Genes & Development,2009,23(15):1805-1817.
[63]Li C R,Liang D D,Li J,et al. Unravelling mitochondrial retrograde regulation in the abiotic stress induction of rice ALTERNATIVE OXIDASE 1 genes[J]. Plant,Cell and Environment,2013,36(4):775-788.
[64]Guan Q J,Liao X,He M L,et al. Tolerance analysis of chloroplast OsCu/Zn-SOD overexpressing rice under NaCl and NaHCO3 stress[J]. PLoS One,2017,12(10):e0186052.
[65]Danquah A,Zelicourt A,Colcombet J,et al. The role of ABA and MAPK signaling pathways in plant abiotic stress responses[J]. Biotechnology Advances,2014,32(1):40-52.
[66]Huang Y,Guo Y M,Liu Y Y,et al. 9-cis-epoxycarotenoid dioxygenase 3 regulates plant growth and enhances multi-abiotic stress tolerance in rice[J]. Frontiers in Plant Science,2018,9:162.
[67]Huang Y,Jiao Y,Xie N K,et al. OsNCED5,a 9-cis-epoxycarotenoid dioxygenase gene,regulates salt and water stress tolerance and leaf senescence in rice[J]. Plant Science,2019,287:110188.
[68]Zheng C K,Zhou J J,Zhang F,et al. OsABAR1,a novel GRAM domain containing protein,confers drought and salt tolerance via an ABA-dependent pathway in rice[J]. Plant Physiology and Biochemistry,2020,152:138-146.
[69]Ge Y W,Chen G M,Cheng X R,et al. The superior allele LEA12OR in wild rice enhances salt tolerance and yield.[J]. Plant Biotechnology Journal,2024,22(11):2971-2984.
[70]Luo C K,Guo C M,Wang W J,et al. Overexpression of a new stress-repressive gene OsDSR2 encoding a protein with a DUF966 domain increases salt and simulated drought stress sensitivities and reduces ABA sensitivity in rice[J]. Plant Cell Reports,2014,33(2):323-336.
[71]Singh A,Jha S K,Bagri J,et al. ABA inducible rice protein phosphatase 2C confers ABA insensitivity and abiotic stress tolerance in Arabidopsis[J]. PLoS One,2015,10(4):e0125168.
[72]Zhou J H,Li Z Y,Xiao G Q,et al. CYP71D8L is a key regulator involved in growth and stress responses by mediating gibberellin homeostasis in rice[J]. Journal of Experimental Botany,2020,71(3):1160-1170.
[73]Shan C,Mei Z L,Duan J L,et al. OsGA2ox5,a gibberellin metabolism enzyme,is involved in plant growth,the root gravity response and salt stress[J]. PLoS One,2014,9(1):e87110.
[74]Mo W P,Tang W J,Du Y X,et al. Phytochrome-Interacting Factor-Like14 and Slender Rice1 interaction controls seedling growth under salt stress[J]. Plant Physiology,2020,184(1):506-517.
[75]Yang C,Ma B,He S J,et al. MAOHUZI6/ETHYLENE INSENSITIVE3-LIKE1 and ETHYLENE INSENSITIVE3-LIKE2 regulate ethylene response of roots and coleoptiles and negatively affect salt tolerance in rice[J]. Plant Physiology,2015,169(1):148-165.
[76]Tao J J,Chen H W,Ma B,et al. The role of ethylene in plants under salinity stress[J]. Frontiers in Plant Science,2015,6:1059.
[77]Zhuang J,Jiang H H,Wang F,et al. A rice OsAP23,functioning as an AP2/ERF transcription factor,reduces salt tolerance in transgenic Arabidopsis[J]. Plant Molecular Biology Reporter,2013,31(6):1336-1345.
[78]Liu D F,Chen X J,Liu J Q,et al. The rice ERF transcription factor OsERF922 negatively regulates resistance to Magnaporthe oryzae and salt tolerance[J]. Journal of Experimental Botany,2012,63(10):3899-3911.
[79]Jisha V,Dampanaboina L,Vadassery J,et al. Overexpression of an AP2/ERF type transcription factor OsEREBP1 confers biotic and abiotic stress tolerance in rice[J]. PLoS One,2015,10(6):e0127831.
[80]Sah S K,Reddy K R,Li J X. Abscisic acid and abiotic stress tolerance in crop plants[J]. Front Plant Science,2016,7:571.
[81]Chen K,Li G J,Bressan R A,et al. Abscisic acid dynamics,signaling,and functions in plants[J]. Journal of Integrative Plant Biology,2020,62(1):25-54.
[82]Jia W S,Wang Y Q,Zhang S Q,et al. Salt-stress induced ABA accumulation is more sensitively triggered in roots than in shoots[J]. Journal of Experimental Botany,2002,53(378):2201-2206.
[83]汤日圣,童红玉,唐现洪,等. 脱落酸提高水稻秧苗耐盐性的效果[J]. 江苏农业学报,2012,28(4):910-911.
[84]Hubbard K E,Nishimura N,Hitomi K,et al. Early abscisic acid signal transduction mechanisms:newly discovered components and newly emerging questions[J]. Genes & Development,2010,24(16):1695-1708.
[85]Belda-Palazón B,Adamo M,Valerio C,et al. A dual function of SnRK2 kinases in the regulation of SnRK1 and plant growth[J]. Nature Plants,2020,6(11):1345-1353.
[86]Cai S G,Chen G,Wang Y Y,et al. Evolutionary conservation of ABA signaling for stomatal closure[J]. Plant Physiology,2017,174(2):732-747.
[87]Kim H,Hwang H,Hong J W,et al. A rice orthologue of the ABA receptor,OsPYL/RCAR5,is a positive regulator of the ABA signal transduction pathway in seed germination and early seedling growth[J]. Journal of Experimental Botany,2012,63(2):1013-1024.
[88]Kim H,Lee K,Hwang H,et al. Overexpression of PYL5 in rice enhances drought tolerance,inhibits growth,and modulates gene expression[J]. Journal of Experimental Botany,2014,65(2):453-464.
[89]Fahad S,Hussain S,Matloob A,et al. Phytohormones and plant responses to salinity stress:a review[J]. Plant Growth Regulation,2015,75(2):391-404.
[90]Divi U K,Rahman T,Krishna P. Brassinosteroid-mediated stress tolerance in Arabidopsis shows interactions with abscisic acid,ethylene and salicylic acid pathways[J]. BMC Plant Biology,2010,10:151.
[91]Yang D L,Yang Y N,He Z H. Role of plant hormones and their interplay in rice immunity[J]. Molecular Plant,2013,6(3):675-685.
[92]Takeuchi K,Gyohda A,Tominaga M,et al. RSOsPR10 expression in response to environmental stresses is regulated antagonistically by jasmonate/ethylene and salicylic acid signaling pathways in rice roots[J]. Plant and Cell Physiology,2011,52(9):1686-1696.
[93]Zou X,Liu L,Hu Z B,et al. Salt-induced inhibition of rice seminal root growth is mediated by ethylene-jasmonate interaction[J]. Journal of Experimental Botany,2021,72(15):5656-5672.
[94]Chen T X,Shabala S,Niu Y N,et al. Molecular mechanisms of salinity tolerance in rice[J]. The Crop Journal,2021,9(3):506-520.
[95]Singh R K,Kota S,Flowers T J.Salt tolerance in rice:seedling and reproductive stage QTL mapping come of age[J]. Theoretical and Applied Genetics,2021,134(11):3495-3533.
[96]Lin H X,Zhu M Z,Yano M,et al. QTLs for Na+and K+uptake of the shoots and roots controlling rice salt tolerance[J]. TAG.Theoretical and Applied Genetics,2004,108(2):253-260.
[97]Javed M A,Huyop F Z,Wagiran A,et al. Identification of QTLs for morph-physiological traits related to salinity tolerance at seedling stage in indica rice[J]. Procedia Environmental Sciences,2011,8:389-395.
[98]马梦影,白玉,巩文靓,等. 利用DH系定位水稻苗期耐盐碱QTLs[J]. 东北农业科学,2022,47(2):34-37,123.
[99]程怡冰,黄倩,韩冰,等. 利用东乡普通野生稻染色体片段置换系定位水稻苗期耐盐性QTL[J]. 植物遗传资源学报,2024,25(8):1245-1253.
[100]Wang Z F,Cheng J P,Chen Z W,et al. Identification of QTLs with main,epistatic and QTL×environment interaction effects for salt tolerance in rice seedlings under different salinity conditions[J]. Theoretical and Applied Genetics,2012,125(4):807-815.
[101]马国辉,郑殿峰,母德伟,等. 耐盐碱水稻研究进展与展望[J]. 杂交水稻,2024,39(1):1-10.
[102]Vinod K K,Krishnan S G,Babu N N,et al. Improving salt tolerance in rice:looking beyond the conventional[M]. New York:Springer Science & Business Media,2013:219-260.
[103]Das P,Nutan K K,Singla-Pareek S L,et al. Understanding salinity responses and adopting ‘omics-based’ approaches to generate salinity tolerant cultivars of rice[J]. Frontiers in Plant Science,2015,6:712.
[104]井文,章文华. 水稻耐盐基因定位与克隆及品种耐盐性分子标记辅助选择改良研究进展[J]. 中国水稻科学,2017,31(2):111-123.
[105]Bimpong I K,Manneh B,Sock M,et al. Improving salt tolerance of lowland rice cultivar ‘Rassi’ through marker-aided backcross breeding in West Africa[J]. Plant Science,2016,242:288-299.
[106]Singh A K,Gopalakrishnan S,Singh V P,et al. Marker assisted selection:a paradigm shift in Basmati breeding[J]. Indian Journal of Genetics and Plant Breeding,2011,71(2):120-128.
[107]Singh R,Singh Y,Xalaxo S,et al. From QTL to variety-harnessing the benefits of QTLs for drought,flood and salt tolerance in mega rice varieties of India through a multi-institutional network[J]. Plant Science,2016,242:278-287.
[108]Linh L H,Linh T H,Xuan T D,et al. Molecular breeding to improve salt tolerance of rice (Oryza sativa L.) in the Red River Delta of Vietnam[J]. International Journal of Plant Genomics,2012,2012:949038.
[109]王彩芬,刘冬成,马晓玲,等. 水稻耐盐基因SKC1特异性CAPS标记的开发与验证[J]. 分子植物育种,2015,13(11):2437-2440.
[110]李瑶,程灿,周继华,等. 水稻耐盐性基因SKC1的KASP标记的开发与利用[J]. 分子植物育种,2024,22(9):2923-2929.
[111]Farhat S,Jain N,Singh N,et al. CRISPR-Cas 9 directed genome engineering for enhancing salt stress tolerance in rice[J]. Seminars in Cell and Developmental Biology,2019,96:91-99.
[112]Ganie S A,Wani S H,Henry R,et al. Improving rice salt tolerance by precision breeding in a new era[J]. Current Opinion in Plant Biology,2021,60:101996.
[113]Ly L K,Ho T M,Bui T P,et al. CRISPR/Cas9 targeted mutations of OsDSG1 gene enhanced salt tolerance in rice[J]. Functional and Integrative Genomics,2024,24(2):70.
[114]Huang S C,Xin S C,Xie G Q,et al. Mutagenesis reveals that the rice OsMPT3 gene is an important osmotic regulatory factor[J]. The Crop Journal,2020,8(3):465-479.
[115]Alam M S,Kong J R,Tao R F,et al. CRISPR/Cas9 mediated knockout of the OsbHLH024 transcription factor Improves salt stress resistance in rice (Oryza sativa L.)[J]. Plants,2022,11(9):1184-1184.
[116]Nan N,Wang J,Shi Y J,et al. Rice plastidial NAD-dependent malate dehydrogenase 1 negatively regulates salt stress response by reducing the vitamin B6 content[J]. Plant Biotechnology Journal,2020,18(1):172-184.
[117]Jiang M,Liu Y H,Li R Q,et al. An inositol 1,3,4,5,6-pentakisphosphate 2-kinase 1 mutant with a 33-nt deletion showed enhanced tolerance to salt and drought stress in rice[J]. Plants,2020,10(1):23.
[118]Wang J,Qin H,Zhou S R,et al. The ubiquitin-binding protein OsDSK2a mediates seedling growth and salt responses by regulating gibberellin metabolism in rice[J]. Plant Cell,2020,32(2):414-428.
[119]莫天宇,徐善斌,邹德堂,等. 利用CRISPR/Cas9技术敲除OsEIL1和OsEIL2基因改良水稻耐盐性[J]. 华北农学报,2021,36(1):71-80.
[120]宋虎彪,李新永,张鹏里,等. 滨海盐碱地水稻栽培关键技术的探索与总结[J]. 中国稻米,2005,11(2):29-30.
[121]任永泉,孙久红. 滨海盐碱地水稻高产栽培关键技术[J]. 北方水稻,2010,40(1):38-40.
[122]侯立刚,齐春艳,马巍,等. 苏打盐碱地水稻“一抢三替”栽培技术研究[J]. 北方水稻,2016,46(4):9-13.
[123]高海东. 陕北地区盐碱地土地开发工程实践研究[J]. 中国资源综合利用,2019,37(3):86-89.
[124]Cheng Y W,Kong X W,Wang N,et al. Thymol confers tolerance to salt stress by activating anti-oxidative defense and modulating Na+homeostasis in rice root[J]. Ecotoxicology and Environmental Safety,2020,188:109894.
[125]张晓伟,周新翔,陈浩,等. 麝香草酚调控盐土中水稻耐盐作用研究[J]. 安徽农业科学,2024,52(15):55-58.
[126]毛庆莲,王胜. 国内盐碱地治理趋势探究浅析[J]. 湖北农业科学,2020,59(增刊1):302-306.
[127]孟庆英,杨晓贺,姚亮亮,等. 秸秆与微生物菌肥配施对盐碱稻田土壤团聚体及真菌群落多样性的影响[J]. 黑龙江农业科学,2022(8):25-30.
[128]曹力毅. 微生物肥料对盐碱地水稻生长及其土壤环境的影响[D]. 银川:宁夏大学,2019.
[129]何钟响,李尝君,刘尚儒,等. 不同土壤改良剂对耐盐水稻的增产效果[J]. 湖南农业科学,2021,(10):36-39.
[130]朱芸,傅庆林,郭彬,等. 腐殖酸和脱硫石膏对滨海盐土及水稻产量的影响[J]. 浙江农业科学,2022,63(6):1139-1143.
[131]罗春峰,张晓蓉,巩宗强,等. 活化铁尾砂与镁改性生物炭配施对水稻幼苗生长及盐碱土性质的影响[J]. 农业环境科学学报,2024,43(1):68-78.
[132]徐君言,马宁,裘高扬,等. 沸石与腐殖酸对滨海盐土水稻产量及土壤性质的影响[J]. 浙江农业科学,2022,63(6):1165-1168,1173.

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备注/Memo

备注/Memo:
收稿日期:2025-07-01
基金项目:国家重点研发计划子课题(编号:2024YFD1201003-1);吉林省重点研发项目(编号:20230202010NC)。
作者简介:张影(1997—),女,吉林长春人,硕士,研究实习员,主要从事水稻耐盐碱育种研究。E-mail:yz970820@163.com。
通信作者:杨春刚,硕士,研究员,主要从事水稻耐盐碱育种、种质资源挖掘研究。E-mail:yangchungang2011@163.com。
更新日期/Last Update: 2025-09-20