|
|
|
| Gene Cloning and Expression Pattern Analysis of Transcription Factor Flo8 in Setosphaeria turcica |
|
|
|
|
Abstract Flo8 is a key transcription factor at the downstream of cAMP signal pathway and plays an important role in fungal development. In this experiment, in order to clarify the function of transcription factor Flo8 and cAMP singal pathway in regulating the pathogenicity of Setosphaeria turcica, the genes encoding transcription factor Flo8 was cloned and the expression pattern of the gene was analyzed during the development of infective structures and the early stage of infecting the host. The homologous search was carried out in the database of S. turcica using the Candida albicans Flo8 amino acid sequence as a probe. The gene encoding the transcription factor Flo8 was identified by PCR. The structural characteristics of the gene and protein were analyzed through GSDS, ProtParam, SOMPA and SMART software, respectively. Subcellular localization of protein was analyzed by WoLF PSORT online software. Quantitative real-time PCR (qRT-PCR) was used to analyze the gene expression patterns. The results showed that there was a protein sequence containing the conserved domain of LisH which belonged to the typical FLO8 protein, and its coding gene was named StFlo8. The total length of the gene was 2 384 bp, and that of the cDNA was 2 037 bp, this gene contained 6 introns and 7 exons, encoding 678 amino acids. The results of expression pattern analysis showed that, compared with the mycelial period, the expression level of StFlo8 was significantly decreased in the conidia and germ tube period, and was significantly higher in appressorium and invade mycelial period, reaching more than 4 times of that in the mycelia. During the interaction of S. turcica with the susceptible host, the expression of StFlo8 was down-up-down regulated, and reached the highest level at 18 h after inoculation, which was as about twice as that of the beginning of inoculation. The results indicated that StFlo8 was involved in the regulation of appressorium development and infected mycelial formation. The results provide a theoretical basis for the further study of the function of StFlo8 gene and the infection mechanism of S. turcica.
|
|
Received: 14 March 2017
Published: 30 October 2017
|
|
|
|
| [1]曹芳.转录因子CaFlo8在白念珠菌形态发生和毒性表现中的功能作用[D]. 博士学位论文, 中国科学院(上海生命科学研究院), 导师: 陈江野, 2005, pp.8-16. (Cao F. 2005. Functional study of a transcription factor CaFlo8 in morphogenesis and virulence of Candida albicans[D]. Thesis for PhD.University of Chinese Academy of Sciences(Shanghai Institutes for Biological Sciences), Supervisor: Chen JY, pp.8-16.)[2]郭安源, 朱其慧, 陈新, 等.GSDS: 基因结构显示系统[J].遗传, 2002, 29(8):1023-1026[3]贾慧, 孟庆江, 李志勇, 等.玉米大斑病菌黑色素合成酶基因的全基因组定位及表达模式分析[J].中国农业科学, 2015, 48(14):2767-2776[4]李文静a, 沈韻, 刘锦燕, 等.转录因子Flo8 G723R、T751D突变增强白念珠菌毒力[J].检验医学, 2016, 0(11):987-992[5]李文静b, 刘锦燕, 史册, 等.白念珠菌FLO8基因高表达菌株构建及鉴定[J].诊断学理论与实践, 2016, 0(01):9-14[6]李文静c, 刘明, 刘锦燕, 等.白念珠菌FLO8基因突变株构建及鉴定[J]. 中国真菌学杂志, 2016, (01):1-7.[J].中国真菌学杂志, 2016, 0(01):1-7[7]申珅, 王晶晶, 佟亚萌, 等.玉米大斑病菌腺苷酸环化酶基因的克隆与功能分析[J].中国农业科学, 2013, 46(5):881-888[8]宋文静, 董金皋.玉米大斑病菌孢子萌发和附着胞形成的影响因素研究[J].植物病理学报, 2008, 38(5):536-539[9]孙淑琴, 温雷蕾, 董金皋.玉米大斑病菌的生理小种及交配型测定[J].玉米科学, 2005, 13(4):112-113[10]Berman J, Sudbery PE.Candida albicans: a molecular revolutionbuilt on lessons from budding yeast[J].Nat Rev Genet, 2002, 3(12):918-930[11]Cao F, Lane S, Raniga PP, et al.The Flo8 transcription factoris essential for hyphal development and virulence in Candida albicans[J].Mol Biol Cell, 2006, 17(1):295-307[12]Conner J and Liu Z. .LEUNIG, a putative transcriptional corepressor that regulates AGAMOUS expression during flower development[J].Proc. Natl. Acad. Sci., USA, 2000, 97(23):12902-12907[13]Hao ZM, Tong YM, Han Y, et al.Molecular characterization of StpkaC2 and expression patterns of both PKA-c isoforms during the invasive growth of Setosphaeria turcica[J].Tropical Plant Pathology, 2002, 40(4):244-250[14]Huang G.Regulation of phenotypic transitions in the fungal patho-gen Candida albicans[J].Virulence, 2012, 3(3):251-261[15]Kim HY, Lee SB, Kang HS, et al.Two distinct domains of Flo8 activator mediates its role in transcriptional activation and the physi-cal interaction with Mss11[J].Biochem Biophys Res Commun, 2014, 449(2):202-207[16]Kim MH., Cooper D. R., Oleksy A., et al..The structure of the N-terminal domain of the product of the lissencephaly gene Lis1 and its functional implications[J].Structure, 2004, 12(6):987-998[17]Pan X, Heitman J. .Protein kinase A operates a molecular switch that governs yeast pseudohyphal differentiation[J].Mol. Cell. Biol, 2002, 22(12):3981-3993[18]Pan XW, Heitman J.Cyclic AMP-Dependent Protein Kinase Regulates Pseudohyphal Differentiation in Saccharomyces cerevisiae[J].Molecular & Cellular Biology, 1999, 19(7):4874-4887[19]Sarikaya B O, Bayram O, Valerius O, et al.LaeA control of velvet family regulatory proteins for light dependentdevelopment and fungal cell-type specificity[J].PLoS Genet., 2010, 6(12):e1001226-e1001226[20]Su C, Li Y, Lu Y, et al.Mss11,a transcriptional activator,is required for hyphal development in Candida albicans[J].Eukaryot Cell, 2009, 8(11):1780-1791[21]Wang Q, Zhao W, Hao J, et al.mRNA level of PKA-c gene in Setosphaeria turcica with different nutrition sources under metalion or osmotic stress[J].Frontiers of Agriculture in China, 2011, 5(3):361-365[22]Whiteway M, Oberholzer U.Candida morphogenesis and host-pathogen interactions[J].Curr Opin Microbiol, 2004, 7(4):350-357 |
|
|
|
