1 State Key Laboratory of Crop Improvement and Regulation in North China, Baoding 071001, China; 2 College of Life Sciences/Key Laboratory of Hebei Province for Plant Physiology and Molecular Pathology, Hebei Agricultural University, Baoding 071001, China; 3 College of Plant Protection, Hebei Agricultural University, Baoding 071001, China
Abstract:Protein kinase A (PKA) is the core element of cAMP signal transduction pathway in eukaryotie, which regulates the growth and development of filamentous fungus through phosphorylation of a variety of active proteins. In order to clarify the possible interaction protein of PKA in Setosphaeria turcica, and further analyze the molecular mechanism of its acts, in this study, the complete coding region of StPKA-C1/2 was amplified from the total complementary DNA of S. turcica to construct the expression vector pGST-StPKA-C1/2, which was introduced into Eschaeria coli. The fusion protein GST-StPKA-C1/C2 was induced in E. coli by isopropyl β-D-thiogalactopyranoside and then purfied by affinity chromatography. The GST pull-down strategy was used to screen the interacting proteins of StPKA-C1/2. The interacting proteins were detected by liquid chromatography-tandem mass spectrometry (LC-MS/MS). The results showed that 69 StPKA-C1 interacting proteins and 70 StPKA-C2 interacting proteins were identified. The functional annotations of proteins included catalytically active protein, enzyme regulating active protein, transport electron carrier protein, molecular chaperone protein, structural molecular protein, metabolic enzyme, etc. Venn analysis found that StPKA-C1 shared 52 interacting proteins with StPKA-C2, with only 17 proteins interacting with StPKA-C1, and only 18 proteins interacting with StPKA-C2. The target protein SETTUDRAFT_ 168881, as a member of the elongation factor G (EFG) family, may regulate hyphal growth. The target protein SETTUDRAF_37808 belonged to the Fimbrin protein family of microfilament-binding proteins and may be involved in the regulation of the actin cytoskeleton, oxidative stress response, and morphogenesis. It was suggested that StPKA-C1/2 might play important biological functions by interacting with these target proteins.The above results preliminarily clarified the potential interaction protein of StPKA-C1/2. This study provides a theoretical basis for further analyzing the molecular mechanism of PKA.
[1] 郝志敏. 2008. 玉米大斑病菌G蛋白和磷脂酶C基因的克隆与功能分析[D]. 博士学位论文, 河北农业大学, 导师:董金皋, pp. 1-7. (Hao Z M.2008. Cloning and functional analysis of genes encoding heterotrimeric G protein and phospholipase C in Setosphaeria turcica[D]. Thesis for Ph.D,. Hebei Agricultural University, Supervisor: Dong J G, pp. 1-7) [2] 黄倩, 管国波, 黄广华, 等. 2019. 白念珠菌Ras/cAMP/PKA途径研究进展[J]. 菌物研究, 17(04): 192-198. (Huang Q, Guan G P, Huang G H, et al.2019. Research advances in the Ras/cAMP/PKA pathway of Candida albicans[J]. Journal of Fungal Research, 17 (04): 192-198.). [3] 张梦娟. 2019. 蛋白激酶A核心催化亚基FpCpk1对假禾谷镰孢菌生长和致病性的影响[D]. 硕士学位论文, 河南农业大学, 导师: 丁胜利, pp. 7-77. (Zhang M J.2019. 2015. Effects of protein kinase A core catalytic subnit FpCpk1 on growth and pathogenicity of Fusarium pseudograminearum[D]. Thesis for M.S., Henan Agricultural University, Supervisor: Ding S L, pp. 7-77.) [4] 赵杰, 王兵, 骆梅, 等. 2012. GST-pull down技术筛选毛白杨天冬氨酸蛋白酶PtoAED3互作蛋白[J]. 北京林业大学学报, 43(05): 64-74. (Zhao J, Wang B, Luo M, et al.2012. Identification of asptic acid protease PtoAED3-interacting proteins through GST pull-down assays in Populus tometosa[J]. Journal of Beijing Forestry University, 43(05): 64-74.) [5] 张永慧. 2017. 禾谷镰刀菌中cAMP-PKA下游基因FgSFL1的鉴定及功能分析[D]. 硕士学位论文, 西北农林科技大学, 导师: 王晨芳, pp. 33-35. (Zhang Y H.2017. cAMP-PKA downstream gene fgsfl1 identification and functional analysis in Fusarium graminearum[D]. Thesis for M.S., Northwest University of A&F Science and Technology, Supervisor: Wang C F, pp. 33-35.) [6] Burghard B, Liebmann M, Braun A, et al.2004. The cyclic AMP-dependent protein kinase a network regulates development and virulence in Aspergillus fumigatus[J]. Infection and Immunity, 72(9): 5193-5203. [7] Bockmühl D P, Ernst J F.2001. A potential phosphorylation site for an A-type kinase in the efg1 regulator protein contributes to hyphal morphogenesis of Candida albicans[J]. Genetics, 157(4): 1523-1530. [8] Cao F, Lane S, Raniga P P.2006. The Flo8 transcription factor is essential for hyphal development and virulence in Candida albicans[J]. Molecular Biology of the Cell, 17(1): 295-307. [9] Fuller K K, Richie D L, Feng X, et al.2011. Divergent protein kinase A isoforms co-ordinately regulate conidial germination, carbohydrate metabolism and virulence in Aspergillus fumigatus[J]. Molecular Microbiology, 79(4): 1045-1062. [10] Hu S, Zhou X, Gu X, et al.2014. The cAMP-PKA pathway regulates growth, sexual and asexual differentiation, and pathogenesis in Fusarium graminearum[J]. Molecular Plant-Microbe Interactions, 27(6): 557. [11] Huang G, Wang H, Song C, et al.2006. Bistable expression of wor1, a master regulator of white-opaque switching in Candida albicans[J]. Proceedings of the National Academy of Sciences of the USA, 103(34): 12813-12818. [12] Kronstad J W.1997. Virulence and cAMP in smuts, blasts and blights[J]. Trends in Plant Science, 2(5): 193-199. [13] Klimpel A, Gronover C S, Williamson B, et al.2002. The adenylate cyclase (BAC) in Botrytis cinerea is required for full pathogenicity[J]. Molecular Plant Pathology. 3(6):439-450. [14] Lee N, D'Souza C A, Kronstad J W, et al.2003. Of smuts, blasts, mildews, and blights: cAMP signaling in phytopathogenic fungi[J]. Annual Review of Phytopathology, 41(1): 399-427. [15] Lengeler K B, Davidson R C, Souza C, et al.2000. Signal transduction cascades regulating fungal development and virulence[J]. Microbiology and Molecular Biology Reviews, 64(4): 746-785. [16] Mcdonough K A, Rodriguez A.2012. The myriad roles of cyclic AMP in microbial pathogens: From signal to sword[J]. Nature Reviews Microbiology, 10(1): 27-38. [17] Montminy M.1997. Transcriptional regulation by cyclic AMP[J]. Annual Review of Biochemiistry, 66(1): 807-822. [18] Poonguzhali S, Shen Q, Fan Y, et al.2017. Cpk2, a catalytic subunit of cyclic cAMP-PKA, regulates growth and pathogenesis in rice blast[J]. Frontiers in Microbiology, 12(8): 2289-2306. [19] Ptacek J, Devgan G, Michaud G, et al.2005. Global analysis of protein phosphorylation in yeast[J]. Nature, 438(7068): 679-684. [20] Pan X, Heitman J.1999. Cyclic AMP-dependent protein kinase regulates pseudohyphal differentiation in Saccharomyces cerevisiae[J]. Molecular and Cellular Biology, 19(7): 4874-4887. [21] Selvaraj P, Fai T H, Ramanujam R, et al.2017. Subcellular compartmentation, interdependency and dynamics of the cyclic AMP-dependent PKA subunits during pathogenic differentiation in Rice Blast[J]. Molecular Microbiology, 105(3): 484-504. [22] Schaerer C, Riezman H.2000. Saccharomyces cerevisiae Arc35p works through two genetically separable calmodulin functions to regulate the actin and tubulin cytoskeletons[J]. Journal of Cell Science, 113(3):521-532. [23] Taylor S S, Buechler J A, Yonemoto W, et al.2014. cAMP-dependent protein kinase: Framework for a diverse family of regulatory enzymes[J]. Annual Review of Biochemistry, 59(1): 971-1005. [24] Zhang B, Yu Q, Wang Y, et al.2016. The Candida albicans fimbrin Sac6 regulates oxidative stress response (OSR) and morphogenesis at the transcriptional level[J]. Biochimica et Biophysica Acta, 1863(9): 2255-2266. [25] Zhang Z, Smith M M, Mymryk J S, et al.2001. Interaction of the e1a oncoprotein with Yak1p, a novel regulator of Yeast pseudohyphal differentiation, and related mammalian kinases[J]. Molecular Biology of the Cell, 12(3):699-710.