doi:10.16178/j.issn.0528-9017.20220104

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References 66

[1]	PARK D S, SAYLER R J, HONG Y G, et al. A method for inoculation and evaluation of rice sheath blight disease[J]. Plant Disease, 2008, 92(1):25-29.
[2]	ALMASIA N I, BAZZINI A A, HOPP H E, et al. Overexpression of snakin-1 gene enhances resistance to Rhizoctonia solani and Erwinia carotovora in transgenic potato plants[J]. Molecular Plant Pathology, 2008, 9(3):329-338.
[3]	PARMETER J R, WHITNEY H S. Taxonomy and nomenclature of the imperfect state[M]// Rhizoctonia solani, Biology and Pathology. Berkeley: University of California Press, 1970:7-19.
[4]	KUNINAGA S, GODOY-LUTZ G, YOKOSAWA R, et al. rDNA-ITS nucleotide sequences analysis of Thanatephoruscucumeris AG-1 associated with web blight on common beans in Central America and Caribbean[J]. Annuals of the Phytopathological Society of Japan, 2002, 68(2):187.
[5]	SNEH B, BURPEE L, OGOSHI A. Identification of Rhizoctonia species[M]. New York: APS press, 1991.
[6]	OGOSHI A. Ecology and pathogenicity of anastomosis and intraspecific groups of Rhizoctonia solani Kuhn[J]. Annual Review of Phytopathology, 1987, 25:125-143.
[7]	AKHTAR J, JHA V K, KUMAR A, et al. Occurrence of banded leaf and sheath blight of maize in harkhand with reference to diversity in Rhizoctonia solani[J]. Asian Journal of Agricultural Science, 2009, 1(2):32-35.
[8]	杨迎青, 杨媚, 兰波, 等. 水稻纹枯病菌致病机理的研究进展[J]. 中国农学通报, 2014, 30(28):245-250.
[9]	KING B C, WAXMAN K D, NENNI N V, et al. Arsenal of plant cell wall degrading enzymes reflects host preference among plant pathogenic fungi[J]. Biotechnology for Biofuels, 2011, 4:4.
[10]	陈夕军, 徐艳, 童蕴慧, 等. 水稻纹枯病菌毒素致病机理研究[J]. 植物病理学报, 2009, 39(4):439-443.
[11]	GHOSH S, KANWAR P, JHA G. Alterations in rice chloroplast integrity,photosynthesis and metabolome associated with pathogenesis of Rhizoctonia solani[J]. Scientific Reports, 2017, 7:41610.
[12]	XIA Y, FEI B H, HE J Y, et al. Transcriptome analysis reveals the host selection fitness mechanisms of the Rhizoctonia solani AG1IA pathogen[J]. Scientific Reports, 2017, 7:10120.
[13]	CHEN L, AI P, ZHANG J F, et al. RSIADB,a collective resource for genome and transcriptome analyses in Rhizoctonia solani AG1 IA[J]. Database:the Journal of Biological Databases and Curation, 2016, 2016:baw031.
[14]	陈斌. 福建水稻种质资源纹枯病抗性及转基因水稻广谱抗病性的鉴定[D]. 福州: 福建农林大学, 2010.
[15]	彭绍裘. 水稻纹枯病及其防治[M]. 上海: 上海科学技术出版社, 1986:164.
[16]	左示敏, 陈天晓, 邹杰, 等. 水稻不同类群品种间的纹枯病抗性评价和抗病新种质筛选[J]. 植物病理学报, 2014, 44(6):658-670.
[17]	ZENG Y X, SHI J S, JI Z J, et al. Genotype by environment interaction:the greatest obstacle in precise determination of rice sheath blight resistance in the field[J]. Plant Disease, 2017, 101(10):1795-1801.
[18]	王玲, 黄雯雯, 刘连盟, 等. 对中国南方部分籼型杂交水稻纹枯病抗性的评价[J]. 作物学报, 2011, 37(2):263-270.
[19]	宋成艳, 王桂玲, 孟庆忠, 等. 寒地水稻纹枯病初步研究[J]. 植物保护, 2002, 28(2):8-11.
[20]	陆岗, 梁耀懋, 黎坤爱, 等. 深水稻种质资源耐淹性及抗稻纹枯病特性研究[J]. 西南农业学报, 2004, 17(6):701-704.
[21]	PRASAD B, EIZENGA G C. Rice sheath blight disease resistance identified in Oryza spp. accessions[J]. Plant Disease, 2008, 92(11):1503-1509.
[22]	SRINIVASACHARY, WILLOCQUET L, SAVARY S. Resistance to rice sheath blight (Rhizoctonia solani Kühn) [(teleomorph: Thanatephorus cucumeris (A.B. Frank) Donk.] disease: current status and perspectives[J]. Euphytica, 2011, 178(1):1-22.
[23]	PERSAUD R, SARAVANAKUMAR D. Identification of resistant cultivars for sheath blight and use of ammi models to understand genotype and environment interactions[J]. Plant Disease, 2019, 103(9).
[24]	LI Z K, PINSON S R M, MARCHETTI M A, et al. Characterization of quantitative trait loci (QTLs) in cultivated rice contributing to field resistance to sheath blight (Rhizoctonia solani)[J]. Theoretical and Applied Genetics, 1995, 91(2):382-388.
[25]	ZENG Y X, JI Z J, MA L Y, et al. Advances in mapping loci conferring resistance to rice sheath blight and mining rhizoctoniasolani resistant resources[J]. Rice Science, 2011, 18(1):56-66.
[26]	FU D, CHEN L, YU G H, et al. QTL mapping of sheath blight resistance in a deep-water rice cultivar[J]. Euphytica, 2011, 180(2):209-218.
[27]	NELSON J C, OARD J H, GROTH D, et al. Sheath-blight resistance QTLs in japonica rice germplasm[J]. Euphytica, 2012, 184(1):23-34.
[28]	EIZENGA G C, PRASAD B, JACKSON A K, et al. Identification of rice sheath blight and blast quantitative trait loci in two different O.sativa/O.nivara advanced backcross populations[J]. Molecular Breeding, 2013, 31(4):889-907.
[29]	LIU G, JIA Y, MCCLUNG A, et al. Confirming QTLs and finding additional loci responsible for resistance to rice sheath blight disease[J]. Plant Disease, 2013, 97(1):113-117.
[30]	ZUO S M, YIN Y J, PAN C H, et al. Fine mapping of qSB-11(LE),the QTL that confers partial resistance to rice sheath blight[J]. Theoretical and Applied Genetics, 2013, 126(5):1257-1272.
[31]	ZUO S M, ZHU Y J, YIN Y J, et al. Comparison and confirmation of quantitative trait loci conferring partial resistance to rice sheath blight on chromosome 9[J]. Plant Disease, 2014, 98(7):957-964.
[32]	LIU Y, CHEN L, FU D, et al. Dissection of additive,epistatic effect and QTL×environment interaction of quantitative trait loci for sheath blight resistance in rice[J]. Hereditas, 2014, 151(2/3):28-37.
[33]	YADAV S, ANURADHA G, KUMAR R R, et al. Identification of QTLs and possible candidate genes conferring sheath blight resistance in rice (Oryza sativa L.)[J]. Springer Plus, 2015, 4:175.
[34]	WEN Z H, ZENG Y X, JI Z J, et al. Mapping quantitative trait loci for sheath blight disease resistance in Yangdao 4 rice[J]. Genetics and Molecular Research, 2015, 14(1):1636-1649.
[35]	GOAD D M, JIA Y L, GIBBONS A, et al. Identification of novel QTL conferring sheath blight resistance in two weedy rice mapping populations[J]. Rice (New York,NY), 2020, 13(1):21.
[36]	JIA L M, YAN W G, ZHU C S, et al. Allelic analysis of sheath blight resistance with association mapping in rice[J]. PLoS One, 2012, 7(3):e32703.
[37]	孙晓棠, 卢冬冬, 欧阳林娟, 等. 水稻纹枯病抗性关联分析及抗性等位变异发掘[J]. 作物学报, 2014, 40(5):779-787.
[38]	LAVALE S A, PRASHANTHI S K, FATHY K. Mapping association of molecular markers and sheath blight (Rhizoctonia solani) disease resistance and identification of novel resistance sources and loci in rice[J]. Euphytica, 2018, 214(4):1-11.
[39]	CHEN Z X, FENG Z M, KANG H X, et al. Identification of new resistance loci against sheath blight disease in rice through genome-wide association study[J]. Rice Science, 2019, 26(1):21-31.
[40]	WANG A J, SHU X Y, JING X, et al. Identification of rice (Oryza sativa L.) genes involved in sheath blight resistance via a genome-wide association study[J]. Plant Biotechnology Journal, 2021, 19(8):1553-1566.
[41]	LIN W, ANURATHA C S, DATTA K, et al. Genetic engineering of rice for resistance to sheath blight[J]. Bio/Technology, 1995, 13(7):686-691.
[42]	BAISAKH N, DATTA K, OLIVA N, et al. Rapid development of homozygous transgenic rice using anther culture harboring rice chitinase gene for enhanced sheath blight resistance[J]. Plant Biotechnology, 2001, 18(2):101-108.
[43]	DATTA K, TU J M, OLIVA N, et al. Enhanced resistance to sheath blight by constitutive expression of infection-related rice chitinase in transgenic elite indica rice cultivars[J]. Plant Science, 2001, 160(3):405-414.
[44]	CHEZEM W R, MEMON A, LI F S, et al. SG2-type R2R3-MYB transcription factor MYB15 controls defense-induced lignification and basal immunity in Arabidopsis[J]. The Plant Cell, 2017, 29(8):1907-1926.
[45]	LI N, LIN B, WANG H, et al. Natural variation in ZmFBL41 confers banded leaf and sheath blight resistance in maize[J]. Nature Genetics, 2019, 51(10):1540-1548.
[46]	陈夕军, 张红, 徐敬友, 等. 水稻纹枯病菌胞壁降解酶的产生及致病作用[J]. 江苏农业学报, 2006, 22(1):24-28.
[47]	WANG R, LU L X, PAN X B, et al. Functional analysis of OsPGIP₁ in rice sheath blight resistance[J]. Plant Molecular Biology, 2015, 87(1/2):181-191.
[48]	CHEN X J, CHEN Y, ZHANG L N, et al. Overexpression of OsPGIP₁ enhances rice resistance to sheath blight[J]. Plant Disease, 2016, 100(2):388-395.
[49]	CHEN X J, CHEN Y W, ZHANG L N, et al. Amino acid substitutions in a polygalacturonase inhibiting protein (OsPGIP₂) increases sheath blight resistance in rice[J]. Rice (New York,NY), 2019, 12(1):56.
[50]	GAO Y, ZHANG C, HAN X, et al. Inhibition of OsSWEET11 function in mesophyll cells improves resistance of rice to sheath blight disease[J]. Molecular Plant Pathology, 2018, 19(9):2149-2161.
[51]	XUE X, CAO Z X, ZHANG X T, et al. Overexpression of OsOSM1 enhances resistance to rice sheath blight[J]. Plant Disease, 2016, 100(8):1634-1642.
[52]	MOLLA K A, KARMAKAR S, MOLLA J, et al. Understanding sheath blight resistance in rice:the road behind and the road ahead[J]. Plant Biotechnology Journal, 2020, 18(4):895-915.
[53]	KARMAKAR S, MOLLA K A, CHANDA P K, et al. Green tissue-specific co-expression of chitinase and oxalate oxidase 4 genes in rice for enhanced resistance against sheath blight[J]. Planta, 2016, 243(1):115-130.
[54]	CAO W L, ZHANG H M, ZHOU Y, et al. Suppressing chlorophyll degradation by silencing OsNYC₃ improves rice resistance to Rhizoctonia solani,the causal agent of sheath blight[J]. Plant Biotechnology Journal, 2022, 20(2):335-349.
[55]	TSUDA K, SATO M, STODDARD T, et al. Network properties of robust immunity in plants[J]. PLoS Genetics, 2009, 5(12):e1000772.
[56]	PANDEY S P, SOMSSICH I E. The role of WRKY transcription factors in plant immunity[J]. Plant Physiology, 2009, 150(4):1648-1655.
[57]	WANG H H, MENG J, PENG X X, et al. Rice WRKY4 acts as a transcriptional activator mediating defense responses toward Rhizoctonia solani,the causing agent of rice sheath blight[J]. Plant Molecular Biology, 2015, 89(1/2):157-171.
[58]	PENG X X, HU Y J, TANG X K, et al. Constitutive expression of rice WRKY30 gene increases the endogenous jasmonic acid accumulation,PR gene expression and resistance to fungal pathogens in rice[J]. Planta, 2012, 236(5):1485-1498.
[59]	PENG X X, WANG H H, JANG J C, et al. OsWRKY80-OsWRKY4 module as a positive regulatory circuit in rice resistance against Rhizoctonia solani[J]. Rice (New York,NY), 2016, 9(1):63.
[60]	JOHN LILLY J, SUBRAMANIAN B. Gene network mediated by WRKY 13 to regulate resistance against sheath infecting fungi in rice (Oryza sativa L.)[J]. Plant Science, 2019, 280:269-282.
[61]	HELLIWELL E E, WANG Q, YANG Y N. Transgenic rice with inducible ethylene production exhibits broad-spectrum disease resistance to the fungal pathogens Magnaportheoryzae and Rhizoctoniasolani[J]. Plant Biotechnology Journal, 2013, 11(1):33-42.
[62]	LI N, KONG L G, ZHOU W H, et al. Overexpression of Os2H16 enhances resistance to phytopathogens and tolerance to drought stress in rice[J]. Plant Cell,Tissue and Organ Culture (PCTOC), 2013, 115(3):429-441.
[63]	LI N, WEI S T, CHEN J, et al. OsASR2 regulates the expression of a defence-related gene,Os2H16,by targeting the GT-1 Cis-element[J]. Plant Biotechnology Journal, 2018, 16(3):771-783.
[64]	ZHU Q L, ZENG D C, YU S Z, et al. From golden rice to aSTARice:bioengineering astaxanthin biosynthesis in rice endosperm[J]. Molecular Plant, 2018, 11(12):1440-1448.
[65]	LIU X X, LIU H L, ZHANG Y Y, et al. Fine-tuning flowering time via genome editing of upstream open reading frames of heading date 2 in rice[J]. Rice (New York,NY), 2021, 14(1):59.
[66]	SINGH P, MAZUMDAR P, HARIKRISHNA J A, et al. Sheath blight of rice:a review and identification of priorities for future research[J]. Planta, 2019, 250(5):1387-1407.

染色体	QTL	标记区间或最近的标记	定位群体	LOD	变异解释率	参考文献
1	qshb1.1	RM151-RM12253	BPT-5204×ARC10531	10.70	10.99	[33]
1	qShB1-2	—	BHA×DGWG	5.71	6.00	[35]
2	qSBR2-2	RM110-osr14	HH1B×RSB03	5.20	5.30	[26]
2	qsbr_2.1	RM8254-RM8252	MCR10277×Cocodrie	29.70	8.00	[27]
2	qsbr_2.2	RM3857-RM5404	MCR10277×Cocodrie	37.80	10.00	[27]
2	qSB2.1	RM279-RM71	Lemont×Jasmine 85	3.70	6.80	[29]
2	qSB2.2	RM221-RM112	Lemont×Jasmine 85	3.60	6.50	[29]
2	qShB4	—	BHA×DGWG	3.71	3.82	[35]
4	qDR-4	RM1155-RM5757	HH1B×RSB02	2.71	—	[32]
6	qShB6-mc	RM3183-RM541	wild1×O.sativa^Bengal	3.30	5.80	[28]
6	qShB6(wild1)	RM3431-RM3183	wild1×O.sativa^Bengal	7.80	13.30	[28]
6	qShB6(wild 2)	RM253-RM3431	wild2×O.sativa^Bengal	21.20	32.00	[28]
7	qSB7	RM5711-RM2	Lemont×Jasmine 85	4.00	7.10	[29]
7	qshb7.1	RM81-RM6152	BPT-5204×ARC10531	8.80	10.52	[33]
7	qshb7.2	RM10-RM21693	BPT-5204×ARC10531	6.70	9.72	[33]
7	qSBL7	D760-RM248	Yangdao4×Lemont	3.12	4.82	[34]
8	qshb8.1	RM21792-RM310	BPT-5204×ARC10531	4.20	21.76	[33]
9	qSBR9	RM23869-RM3769	HH1B×RSB03	5.00	11.90	[26]
9	qsbr_9.1	RM24708-RM3823	MCR10277×Cocodrie	53.30	15.00	[27]
9	qSB9	RM215-RM245	Lemont×Jasmine 85	5.40	8.55	[29]
9	qSB9^TQ	CY-85 and Y86	Teqing×Lemont	—	—	[31]
11	qSB-11^LE	Z22-27C-Z23-33C	Teqing×Lemont	—	—	[30]
12	qsbr_12.1	RM3747-RM27608	MCR10277×Cocodrie	49.10	14.00	[27]
12	qSBD12-2	RM1246-D1252	Yangdao4×Lemont	3.74	11.95	[34]

染色体	QTL	标记区间或最近的标记	定位群体	LOD	变异解释率	参考文献
1	qshb1.1	RM151-RM12253	BPT-5204×ARC10531	10.70	10.99	[33]
1	qShB1-2	—	BHA×DGWG	5.71	6.00	[35]
2	qSBR2-2	RM110-osr14	HH1B×RSB03	5.20	5.30	[26]
2	qsbr_2.1	RM8254-RM8252	MCR10277×Cocodrie	29.70	8.00	[27]
2	qsbr_2.2	RM3857-RM5404	MCR10277×Cocodrie	37.80	10.00	[27]
2	qSB2.1	RM279-RM71	Lemont×Jasmine 85	3.70	6.80	[29]
2	qSB2.2	RM221-RM112	Lemont×Jasmine 85	3.60	6.50	[29]
2	qShB4	—	BHA×DGWG	3.71	3.82	[35]
4	qDR-4	RM1155-RM5757	HH1B×RSB02	2.71	—	[32]
6	qShB6-mc	RM3183-RM541	wild1×O.sativa^Bengal	3.30	5.80	[28]
6	qShB6(wild1)	RM3431-RM3183	wild1×O.sativa^Bengal	7.80	13.30	[28]
6	qShB6(wild 2)	RM253-RM3431	wild2×O.sativa^Bengal	21.20	32.00	[28]
7	qSB7	RM5711-RM2	Lemont×Jasmine 85	4.00	7.10	[29]
7	qshb7.1	RM81-RM6152	BPT-5204×ARC10531	8.80	10.52	[33]
7	qshb7.2	RM10-RM21693	BPT-5204×ARC10531	6.70	9.72	[33]
7	qSBL7	D760-RM248	Yangdao4×Lemont	3.12	4.82	[34]
8	qshb8.1	RM21792-RM310	BPT-5204×ARC10531	4.20	21.76	[33]
9	qSBR9	RM23869-RM3769	HH1B×RSB03	5.00	11.90	[26]
9	qsbr_9.1	RM24708-RM3823	MCR10277×Cocodrie	53.30	15.00	[27]
9	qSB9	RM215-RM245	Lemont×Jasmine 85	5.40	8.55	[29]
9	qSB9^TQ	CY-85 and Y86	Teqing×Lemont	—	—	[31]
11	qSB-11^LE	Z22-27C-Z23-33C	Teqing×Lemont	—	—	[30]
12	qsbr_12.1	RM3747-RM27608	MCR10277×Cocodrie	49.10	14.00	[27]
12	qSBD12-2	RM1246-D1252	Yangdao4×Lemont	3.74	11.95	[34]

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