[1]Chen J,Clinton M,Qi G,Wang DW,Liu FQ,Fu ZQ. Reprogramming and remodeling: transcriptional and epigenetic regulation of salicylic acid-mediated plant defense. J Exp Bot,2020, 71:5256–5268.
[2]Zhang YX,Xu SH,Ding PT,Wang DM,Cheng YT,He J,Gao MH,Xu F,Li Y,Zhu ZH,Li X,Zhang YL.Control of salicylic acid synthesis and systemic acquired resistance by two members of a plant-specific family of transcription factors. Proc Natl Acad Sci USA,2010, 107:18220–18225.
[3]Wang L,Tsuda K,Truman W,Sato M,Nguyen le V,Katagiri F,Glazebrook J. CBP60g and SARD1 play partially redundant critical roles in salicylic acid signaling. Plant J,2011, 67:1029–1041.
[4]Gao QM,Venugopal S,Navarre D,Kachroo A. Low oleic acid-derived repression of jasmonic acid-inducible defense responses requires the WRKY50 and WRKY51 proteins. Plant Physiol,2011, 155:464–476.
[5]van Verk MC,Bol JF,Linthorst HJ. WRKY transcription factors involved in activation of SA biosynthesis genes. BMC Plant Biol,2011, 11:89–100.
[6]van Verk MC,Bol JF,Linthorst HJ. A tripartite amplification loop involving the transcription factor WRKY75, salicylic acid, and reactive oxygen species accelerates leaf senescence. Plant Cell,2017, 29:2854–2870.
[7]Zhang SH,Li C,Wang R,Chen YX,Shu S,Huang RH,Zhang DW,Li J,Xiao S,Yao N,Yang CW. The Arabidopsismitochondrial rrotease FtSH4 is involved in leaf senescence via regulation of WRKY-dependent salicylic acid accumulation and signaling. Plant Physiol,2017, 173:2294–2307.
[8]Jiang J J,Ma S H,Ye N H,Jiang M,Cao J S,Zhang J H. WRKY transcription factors in plant responses to stresses. J Integr Plant Biol,2017, 59:86–101.
[9]Yamasaki K, Kigawa T, Inoue M, Tateno M, Yamasaki T, Yabuki T, Aoki M, Seki E, Matsuda T, Tomo Y, Hayami N, Terada T, Shirouzu M, Tanaka A, Seki M, Shinozaki K, Yokoyama S. Solution structure of an ArabidopsisWRKY DNA binding domain. Plant Cell, 2005, 17: 86–101.
[10]Rushton P J, Somssich I E, Ringler P, Shen Q J. WRKY transcription factors. Trends Plant Sci, 2010, 15: 247–258.
[11]Xie W Y, Ke Y G, Cao J B, Wang S P, Yuan M. Knock out of transcription factor WRKY53thickens sclerenchyma cell walls, confers bacterial blight resistance. Plant Physiol, 2021, 187: 1746–1761.
[12]Li C, He X, Luo X Y, Xu L, Liu L L, Min L, Jin L, Zhu L F, Zhang X L. Cotton WRKY1 mediates the plant defense-to-development transition during infection of cotton by Verticillium dahliaeby activating JASMONATEZIM-DOMAIN1expression. Plant Physiol, 2014, 166: 2179–2194.
[13]Yang S,Cai WW, Shen L, Cao JS,Liu CL,Hu J,Guan DY,He SL. A CaCDPK29-CaWRKY27b module promotes CaWRKY40-mediated thermotolerance and immunity to Ralstonia solanacearumin pepper. New Phytol,2022, 233:1843–1863.
[14]徐爱武.近十年我国棉花生产量与消费量分析及建议.棉花科学,2022,44(4):61–64.
Xu A W. Analysis and suggestion of cotton production and consumption in China in recent ten years. Cotton Sci, 2022, 44(4): 61–64 (in Chinese with English abstract).
[15]Yang X Y, Zhang X L, Yuan D J, Jin F Y, Zhang Y C, Xu J. Transcript profiling reveals complex auxin signalling pathway and transcription regulation involved in dedifferentiation and redifferentiation during somatic embryogenesis in cotton. BMC Plant Biol, 2012, 12: 110–128.
[16]GaoW,LongL,ZhuLF,XuL,GaoWH,SunLQ,LiuLL,ZhangXL. Proteomic and virus-induced gene silencing (VIGS) analyses reveal that gossypol, brassinosteroids, and jasmonic acid contribute to the resistance of cotton to Verticillium dahliae. Mol Cell Proteomics, 2013,12: 3690–3703.
[17]Xu L, Zhu L F, Tu L L, Gao X P, Long L, Sun L Q, Gao W, Zhang X L. Differential gene expression in cotton defence response to Verticillium dahliaeby SSH. J Phytopathol, 2011, 159: 606–615.
[18]Xu F, Yang L, Zhang J, Guo X P, Zhang X L, Li G Q. Prevalence of the defoliating pathotype of Verticillium dahliaeon cotton in central China and virulence on selected cotton cultivars. J Phytopath,2012, 160: 369–376.
[19]Tan JF,Tu LL,Deng FL,Hu HY,Nie YC,Zhang XL. A genetic and metabolic analysis revealed that cotton fiber cell development was retarded by flavonoid naringenin. Plant Physiol,2013, 162:86–95.
[20]HuQ,ZhuLF,ZhangXL,GuanQQ,XiaoSH,MinL,ZhangXL. GhCPK33 negatively regulates defense against Verticillium dahliaeby phosphorylating GhOPR3. Plant Physiol, 2018, 178:876–889.
[21]Xiao SH,Ming YQ,Hu Q,Ye ZX,Si H,Liu SM,Zhang XJ,Wang WR,Yu Y,Kong J,Klosterman SJ,Lindsey K,Zhang XL,Aierxi A,Zhu LF. GhWRKY41 forms a positive feedback regulation loop and increases cotton defence response against Verticillium dahliaeby regulating phenylpropanoid metabolism. Plant Biotechnol J,2023, 21:961–978.
[22]Li Y, Zhou Y J, Dai P H, Ren Y P, Wang Q. Liu X D. Cotton bsr-k1modulates lignin deposition participating in plant resistance against Verticillium dahliaeand fusarium oxysporum. Plant Growth Regul, 2021, 95: 283–292.
[23]ChenF, HuY,VannozziA,WuKC,CaiHY,QinY,MullisA,LinZG, ZhangLS.The WRKY transcription factor family in model plants and crops. Critical Rev Plant Sci, 2017, 36: 311–335.
[24]Anderssen S, Naômé A, Jadot C, Brans A, Tocquin P, Rigali S. AURTHO: Autoregulation of transcription factors as facilitator of cis-acting element discovery. Biochim Biophys Acta Gene Regul Mech, 2022, 1865:194847.
[25]Ng DW,Abeysinghe JK,Kamali M. Regulating the Regulators: The control of transcription factors in plant defense signaling. Int JMol Sci,2018,19: 3737–3755.
[26]Wang H L, Cheng X, Yin D M, Chen D L, Luo C, Liu H, Huang C L. Advances in the research on plant WRKY transcription factors responsive to external stresses. Curr Issues Mol Biol, 2023, 45: 2861–2880.
[27]Bakshi M,Oelmüller R. WRKY transcription factors: jack of many trades in plants. Plant Signal Behav,2014, 9:e27700.
[28]Long L X, Gu L J, Wang S J, Cai H Y, Wu J H, Wang J M, Yang M S. Progress in the understanding of WRKY transcription factors in woody plants. Int J Biol Macromol, 2023, 242: 124379.
[29]Liu DL,Leib K,Zhao PY,Kogel KH,Langen G. Phylogenetic analysis of barley WRKY proteins and characterization of HvWRKY1 and -2 as repressors of the pathogen-inducible gene HvGER4c. Mol Genet Genomics,2014, 289:1331–1345.
[30]Lippok B,Birkenbihl RP,Rivory G,Brümmer J,Schmelzer E,Logemann E,Somssich IE. Expression of AtWRKY33encoding a pathogen- or PAMP-responsive WRKY transcription factor is regulated by a composite DNA motif containing W box elements. Mol Plant Microbe Interact,2007, 20:420–429.
[31]Huang SX,Gao YF,Liu JK,Peng XL,Niu XG,Fei ZJ,Cao SQ,Liu YS. Genome-wide analysis of WRKY transcription factors in Solanum lycopersicum. Mol Genet Genomics,2012, 287:495–513.
[32]Deng B,Wang WJ,Ruan CQ,Deng LL,Yao SX,Zeng KF. Involvement of CsWRKY70 in salicylic acid-induced citrus fruit resistance against Penicillium digitatum. Hortic Res,2020, 7:157–169.
[33]Zhou R,Dong YH,Liu X,Feng S,Wang CX,Ma XM,Liu JN,Liang Q,Bao Y,Xu SY,Lang XY,Gai SS,Yang KQ,Fang HC. JrWRKY21 interacts with JrPTI5L to activate the expression of JrPR5Lfor resistance to Colletotrichum gloeosporioidesin walnut. Plant J,2022, 111:1152–1166.
[34]Wang WJ,Li T,Chen Q,Yao SX,Zeng KF. Transcriptional regulatory mechanism of a variant transcription factor CsWRKY23 in citrus fruit resistance to Penicillium digitatum. Food Chem,2023, 413:135573.
[35]Zhang SL,Dong LJ,Zhang X,Fu XH,Zhao L,Wu LZ,Wang XF,Liu JF. The transcription factor GhWRKY70from Gossypiumhirsutumenhances resistance to verticillium wilt via the jasmonic acid pathway.BMC Plant Biol,2023, 23:141–156.
[36]Wang YQ,Cui X,Yang B,Xu ST,Wei XY,Zhao PY,Niu FF,Sun MT,Wang C,Cheng H,Jiang YQ. WRKY55 transcription factor positively regulates leaf senescence and the defense response by modulating the transcription of genes implicated in the biosynthesis of reactive oxygen species and salicylic acid in Arabidopsis.Development,2020, 147: 189647.
[37]Ulker B,Shahid M M,Somssich IE. The WRKY70 transcription factor of Arabidopsisinfluences both the plant senescence and defense signaling pathways. Planta,2007, 226:125–137.
[38]Rekhter D, Lüdke D,Ding Y,Feussner K,Zienkiewicz K,Lipka V,Wiermer M,Zhang Y,Feussner I. Isochorismate-derived biosynthesis of the plant stress hormone salicylic acid. Science,2019, 365:498–502.
[39]Li Z,Liu HM,Ding ZH,Yan JP,Yu HY,Pan RH,Hu J,Guan YJ,Hua J. Low temperature enhances plant immunity via salicylic acid pathway genes that are repressed by ethylene. Plant Physiol,2020, 182:626–639.
[40]LiaoRJ,WeiXC,ZhaoYY,XieZQ,NathU.K,YangSJ,SuHN,WangZY,LiL,TianBM,WeiF,YuanYX, ZhangXW. Bra-miR167a targets ARF8and negatively regulates Arabidopsis thalianaimmunity against plasmodiophora brassicae.Int J Mol Sci, 2023, 24: 11850–11866.
[41]YangJ,WangYF,LiuL,LiuLN,WangCM,WangCM,LiCY.Effects of exogenous salicylic acid and pH on pathogenicity of biotrophy-associated secreted protein 1 (BAS1)-overexpressing strain, Magnaporthe oryzae. Environ Sci Pollut Res Int, 2019, 26:13725–13737.
[42]ElsharkawyMM,OmaraRI,MostafaYS,AlamriSA,HashemM,AlrummanSA,AhmadAA. Mechanism of wheat leaf rust control using chitosan nanoparticles and salicylic acid.J Fungi, 2022, 8: 304–321.
[43]Guo P R, Li Z H, Huang P X, Li B S, Fang S, Chu J F, Guo H W. “A tripartite amplification loop involving the transcription factor WRKY75, salicylic acid, and reactive oxygen species accelerates leaf senescence”. Plant Cell, 2017, 29: 2854–2870.
