Wu Dandan, Yuan Yihui, Liu Pengming, Wu Yan, Gao Meiying
Key Laboratory of Agricultural and Environmental Microbiology, Wuhan Institute of Virology, Chinese Academy of Sciences, Wuhan, People's Republic of China.
Key Laboratory of Agricultural and Environmental Microbiology, Wuhan Institute of Virology, Chinese Academy of Sciences, Wuhan, People's Republic of China.
J Proteomics. 2014 Apr 14;101:192-204. doi: 10.1016/j.jprot.2014.02.016. Epub 2014 Feb 22.
Bacillus thuringiensis (Bt) has been widely used for 50years as a biopesticide for controlling insect pests. However, bacteriophage infection can cause failures in 50%-80% of the batches during Bt fermentation, resulting in severe losses. In the present work, the physiological and biochemical impacts of Bt strain CS33 have been studied during bacteriophage infection. This study adopted a gel-based proteomics approach to probe the sequential changed proteins in phage-infected Bt cells. To phage, it depressed the host energy metabolism by suppressing the respiration chain, the TCA cycle, and the utilization of PHB on one hand; on the other hand, it hijacked the host translational machine for its own macromolecular synthesis. To host, superinfection exclusion might be triggered by the changes of S-layer protein and flagella related proteins, which were located on the cell surface and might play as the candidates for the phage recognition. More importantly, the growth rate, cell mass, and ICPs yield were significantly decreased. The low yield of ICPs was mainly due to the suppressed utilization of PHB granules. Further functional study on these altered proteins may lead to a better understanding of the pathogenic mechanisms and the identification of new targets for phage control.
B. thuringiensis (Bt) has been widely used for 50years as a safe biopesticide for controlling agricultural and sanitary insect pests. However, bacteriophage infection can cause severe losses during B. thuringiensis fermentation. The processes and consequences of interactions between bacteriophage and Bt were still poorly understood, and the molecular mechanisms involved were more unknown. This study adopted a gel-based proteomics approach to probe the physiological and biochemical impacts of Bt strain CS33 after phage-infection. The interactions between phage BtCS33 and its host Bt strain CS33 occurred mainly on four aspects. First, phage synthesized its nucleic acids through metabolic regulation by increasing the amount of NDK. Second, it is reasonable to infer that a phage resistance or superinfection exclusion was triggered by several increased or decreased proteins (SLP, FliD, FlaB), which were located on the cell surface and might play as candidates for the phage recognition. Third, combining the decreased flavoproteins (SdhA and EtfB) and the down regulated Fe-S cluster biosynthesis pathway together, it can be suggested that the respiration chain was weakened after phage infection. Additionally, three key enzymes (AcnB, FumC and AdhA) involved in the TCA cycle were all decreased, indicating the TCA cycle was seriously inhibited after infection. Fourth, the growth rate, cell mass and ICPs yield of the host were significantly decreased. To the best of our knowledge, this work represents the first systematic study on the interactions of an insecticidal bacterium with its phage, and has contributed novel information to understand the molecular events in the important biological pesticide producer, B. thuringiensis, in response to phage challenge.
苏云金芽孢杆菌(Bt)作为一种生物杀虫剂用于控制害虫已有50年历史。然而,噬菌体感染会导致Bt发酵过程中50%-80%的批次失败,造成严重损失。在本研究中,对噬菌体感染期间Bt菌株CS33的生理生化影响进行了研究。本研究采用基于凝胶的蛋白质组学方法来探究噬菌体感染的Bt细胞中蛋白质的序列变化。对于噬菌体而言,一方面它通过抑制呼吸链、三羧酸循环(TCA循环)和聚-β-羟基丁酸(PHB)的利用来抑制宿主能量代谢;另一方面,它劫持宿主的翻译机器用于自身大分子合成。对于宿主而言,表面层蛋白和鞭毛相关蛋白的变化可能触发了超感染排斥,这些蛋白位于细胞表面,可能是噬菌体识别的候选者。更重要的是,生长速率、细胞量和晶体蛋白(ICPs)产量显著降低。ICPs产量低主要是由于PHB颗粒的利用受到抑制。对这些变化蛋白的进一步功能研究可能有助于更好地理解致病机制并确定噬菌体控制的新靶点。
苏云金芽孢杆菌(Bt)作为一种安全的生物杀虫剂用于控制农业和卫生害虫已有50年历史。然而,噬菌体感染会在Bt发酵过程中造成严重损失。噬菌体与Bt之间相互作用的过程和后果仍知之甚少,涉及的分子机制更是未知。本研究采用基于凝胶的蛋白质组学方法来探究噬菌体感染后Bt菌株CS33的生理生化影响。噬菌体BtCS33与其宿主Bt菌株CS33之间的相互作用主要发生在四个方面。首先,噬菌体通过增加核苷二磷酸激酶(NDK)的量进行代谢调控来合成其核酸。其次,可以合理推断,一些位于细胞表面且可能作为噬菌体识别候选者的蛋白质(表面层蛋白、菌毛蛋白D、鞭毛蛋白B)的增加或减少触发了噬菌体抗性或超感染排斥。第三,结合黄素蛋白(琥珀酸脱氢酶A和电子传递黄素蛋白β亚基)的减少以及铁硫簇生物合成途径的下调,可以表明噬菌体感染后呼吸链减弱。此外,参与TCA循环的三种关键酶(顺乌头酸酶B、延胡索酸酶C和乙醇脱氢酶A)均减少,表明感染后TCA循环受到严重抑制。第四,宿主菌株的生长速率、细胞量和ICPs产量显著降低。据我们所知,这项工作代表了对杀虫细菌与其噬菌体相互作用的首次系统研究,并为理解重要生物杀虫剂生产者苏云金芽孢杆菌应对噬菌体挑战时的分子事件提供了新信息。
