Ana Katrina Y Tiu, Grace C Conroy, Cedric E Bobst, Christine L Hagan
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Our results indicate that a hydrophobic, membrane-like environment is required for CdiA to fold, and the proteolysis occurs through an asparagine cyclization mechanism. Our <i>in vitro</i> assay thus provides a starting point for analyzing the conformational state of the CdiA protein when it is inserted into a target cell's OM and engaged in transporting the toxin across that membrane.</p><p><strong>Importance: </strong>It is challenging to develop new antibiotics capable of killing Gram-negative bacteria because their outer membranes are impermeable to many small molecules. Some Gram-negative bacteria, however, deliver much larger protein toxins through the outer membranes of competing bacteria in their environments using contact-dependent inhibition (CDI) systems. How these toxins traverse the outer membranes of their targets is not well understood. We have therefore developed a method to study the toxin delivery process in a highly simplified system using a fragment of a CDI protein. Our results indicate that the CDI protein assembles into a structure in the target membrane that catalyzes the release of the toxin. 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引用次数: 0
摘要
接触依赖性抑制(CDI)是革兰氏阴性细菌的一种细菌间竞争机制。含有 CDI 系统的细菌会在细胞表面产生一种大型丝状蛋白质 CdiA。CdiA 含有一个 C 端毒素结构域,可穿过邻近细菌的外膜(OM)进行运输。一旦进入目标细菌体内,毒素就会通过蛋白水解机制从 CdiA 蛋白中释放出来,但这种机制目前还没有很好的表征。我们开发了一种体外检测方法来监测这一毒素释放过程,并确定了在自催化机制中起关键作用的几个保守氨基酸。我们的研究结果表明,CdiA 的折叠需要一个疏水的膜样环境,而蛋白水解是通过天冬酰胺环化机制进行的。因此,我们的体外试验为分析 CdiA 蛋白插入靶细胞 OM 并参与毒素跨膜运输时的构象状态提供了一个起点:开发能够杀死革兰氏阴性细菌的新抗生素具有挑战性,因为这些细菌的外膜对许多小分子具有不透性。然而,一些革兰氏阴性细菌会利用接触依赖性抑制(CDI)系统,通过其环境中竞争细菌的外膜释放大得多的蛋白质毒素。人们对这些毒素如何穿过目标细菌的外膜还不甚了解。因此,我们开发了一种方法,利用 CDI 蛋白的一个片段,在一个高度简化的系统中研究毒素的传递过程。我们的研究结果表明,CDI 蛋白在靶膜上组装成一个结构,催化毒素的释放。这种 CDI 蛋白片段有助于进一步研究毒素的递送机制。
Autoproteolytic mechanism of CdiA toxin release reconstituted in vitro.
Contact-dependent inhibition (CDI) is a mechanism of interbacterial competition in Gram-negative bacteria. Bacteria that contain CDI systems produce a large, filamentous protein, CdiA, on their cell surfaces. CdiA contains a C-terminal toxin domain that is transported across the outer membranes (OMs) of neighboring bacteria. Once inside a target bacterium, the toxin is released from the CdiA protein via a proteolytic mechanism that has not been well characterized. We have developed an in vitro assay to monitor this toxin release process and have identified several conserved amino acids that play critical roles in the autocatalytic mechanism. Our results indicate that a hydrophobic, membrane-like environment is required for CdiA to fold, and the proteolysis occurs through an asparagine cyclization mechanism. Our in vitro assay thus provides a starting point for analyzing the conformational state of the CdiA protein when it is inserted into a target cell's OM and engaged in transporting the toxin across that membrane.
Importance: It is challenging to develop new antibiotics capable of killing Gram-negative bacteria because their outer membranes are impermeable to many small molecules. Some Gram-negative bacteria, however, deliver much larger protein toxins through the outer membranes of competing bacteria in their environments using contact-dependent inhibition (CDI) systems. How these toxins traverse the outer membranes of their targets is not well understood. We have therefore developed a method to study the toxin delivery process in a highly simplified system using a fragment of a CDI protein. Our results indicate that the CDI protein assembles into a structure in the target membrane that catalyzes the release of the toxin. This CDI protein fragment enables further studies of the toxin delivery mechanism.
期刊介绍:
The Journal of Bacteriology (JB) publishes research articles that probe fundamental processes in bacteria, archaea and their viruses, and the molecular mechanisms by which they interact with each other and with their hosts and their environments.