透過您的圖書館登入
IP:3.145.2.87
  • 學位論文

黑腐病菌 pmeA 基因之轉錄調控

Transcriptional regulation of pmeA gene in Xanthomonas campestris pv. campestris

指導教授 : 蕭懿民
若您是本文的作者,可授權文章由華藝線上圖書館中協助推廣。

摘要


革蘭氏陰性植物病原菌 Xanthomonas campestris pv. campestris (Xcc),主要感染十字花科植物造成黑腐病 (black rot),導致農業上的重大損失。本菌尚能分泌大量胞外多醣以及多種胞外酵素,如蛋白酶、纖維酶、聚甘露糖酶和果膠酶等,為本菌重要的致病因子。這些胞外產物的產生,由訊號擴散因子 (diffusible signal factor, DSF),進行細胞與細胞間訊息的傳遞調控。DSF 的合成需要 RpfF (putative enoyl-CoA hydratase),而訊號的感應與傳遞則是由 RpfC 及 RpfG 組成之双成員 (two component system) 負責。最近研究也指出多元轉錄因子 Clp (cAMP receptor protein-like protein) 蛋白,對於 DSF 調控毒力因子產生是必要的。 本研究主要探討 Xcc 果膠酶中之果膠甲基酯酶 (pectin methyl esterase, PME) 基因 pmeA。首先構築 pmeA 突變株 YL17 及其互補株 YL17(pRKpmeA),並與不同 Xcc 菌株比較胞外 PME 活性。結果顯示 AU56E (clp 基因缺損突變株)、RM17F (rpfF 基因缺損突變株) 及 YL17 之 PME 活性輕微下降,而 YL17(pRKpmeA) 可回復 YL17 產生 PME 之能力。由此推測 Clp 及 RpfF 均參與 PME 的表現,而 pmeA 主導 Xcc 之次要 PME。在致病性測試上,YL17 病癥出現的速度與 Xc17 相比只具輕微差異,推測 PmeA 在 Xcc 致病性方面可能扮演次要的角色。其次,利用 5’-RACE (rapid amplication of cDNA ends) 技術來訂定 pmeA 之轉錄起始點。結果得知,pmeA 之轉錄起始點為核苷酸“G”,位於起始密碼上游 54 nt 處。最後,將不同長度的 pmeA 上游片段,個別選殖於 pFY13-9 (為 promoter-probing vector) 中 lacZ 之上游,獲得之 PpmeA-lacZ transcriptional fusion constructs 再經電孔法分別送入 Xc17、AU56E 與 RM17F。啟動子活性分析指出 pmeA 之轉錄起始點上游 -359 至 +46 的區域,為 pmeA 完全表現所必需。轉錄融合分析也顯示 pmeA 啟動子活性,不論在 clp 突變株或是 rpfF 突變株,其活性均比野生株低,因此推測 Clp 與 RpfF 正調控 pmeA 之轉錄。另外,pmeA 基因之轉錄也受到代謝抑制 (catabolite repression) 作用、高滲透度 (osmolarity)、限氧 (oxygen limitation) 及缺氮 (nitrogen starvation) 所影響。

並列摘要


Abstract Xanthomonas campestris pv. campestris (Xcc) is a Gram-negative plant-pathogenic bacterium that causes black rot in crucifers, resulting in tremendous losses in agriculture. This organism is capable of producing large amounts of exopolysaccharides and secreting several extracellular enzymes (such as protease, endoglucanase, mannanase, and pectinase), which have been considered to be important virulence determinants. The production of these extracellular products is coordinated by a cell-cell communication mechanism through diffusible signal factor (DSF), which is dependent on RpfF, a putative enoyl-CoA hydratase, for synthesis and the RpfC/RpfG two component system for perception and signal transduction. A recent study also indicated that global transcription factor cAMP receptor protein-like protein (Clp) is essential for DSF regulation of virulence factor production. The aim of this study was to characterize the pmeA gene encoding one of the pectinases, pectin methyl esterase (PME), in Xcc. First, the pmeA mutant YL17 and its complementary strain YL17(pRKpmeA) were constructed and the extracellular PME activity was compared with different Xcc strains. The result showed that the PME activity of AU56E (clp mutant), RM17F (rpfF mutant), and YL17 were slightly reduced, whereas the activity was restored in YL17(pRKpmeA). It was suggested that Clp and RpfF are involved in PME expression and pmeA gene might code for a secondary PME in Xcc. In pathogenicity test, the rate of symptoms development in YL17 was slightly slower than Xc17. These findings deduced that PmeA of Xcc plays a minor role in pathogenesis. Second, nucleotide G at 54 nt upstream of the pmeA start codon was mapped as the pmeA transcriptional initiation site by using the 5’-RACE (rapid amplication of cDNA ends) technique. Third, seven PpmeA-lacZ transcriptional fusion constructs were generated by cloning PCR fragments into the broad-host-range-promoter-probing vector pFY13-9, which uses lacZ as the reporter. The resultant PpmeA-lacZ transcriptional fusion constructs were introduced into Xc17, AU56E and RM17F by electroporation, respectively. Reporter assay indicated that the -359/+46 region contains the complete promoter and is capable of maximal-level expression. Transcriptional fusion analysis also revealed that the promoter activity of pmeA was reduced in either AU56E or RM17F, suggested that Clp and RpfF positively regulate transcription of the pmeA gene. In addition, the pmeA expression was affected by catabolite repression, osmolarity, oxygen limitation, and nitrogen starvation.

參考文獻


Barber, C. E., Tang, J. L., Feng, J. X., Pan, M. Q., Wilson, T. J., Slater, H., Dow, J. M., Williams, P. & Daniels, M. J. (1997). A novel regulatory system required for pathogenicity of Xanthomonas campestris is mediated by a small diffusible signal molecule. Mol Microbiol 24, 555-566.
Becker, A., Katzen, F., Puhler, A. & Ielpi, L. (1998). Xanthan gum biosynthesis and application: a biochemical/genetic perspective. Appl Microbiol Biotechnol 50, 145-152.
Birnboim, H. C. & Doly, J. (1979). A rapid alkaline extraction procedure for screening recombinant plasmid DNA. Nucleic Acids Res 7, 1513-1523.
Blin, N. & Stafford, D. W. (1976). A general method for isolation of high molecular weight DNA from eukaryotes. Nucleic Acids Res 3, 2303-2308.
Chan, J. W. & Goodwin, P. H. (1999). The molecular genetics of virulence of Xanthomonas campestris. Biotechnol Adv 17, 489-508.

延伸閱讀