控制 Halomonas titanicae KHS3 中 Wsp 类传导途径的化学感受器与嘌呤衍生物结合并做出反应。

Fernando E Ramos Ricciuti, Anabel Soldano, M Karina Herrera Seitz, Ana F Gasperotti, Alexandra Boyko, Kirsten Jung, Marco Bellinzoni, María-Natalia Lisa, Claudia A Studdert
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引用次数: 0

摘要

海洋细菌 Halomonas titanicae KHS3 的化学感应途径 HtChe2 控制着一种二聚氰胺环化酶的活性。该通路的持续激活会导致菌落形态改变,并增强形成生物膜的能力。这些特征与假单胞菌的 Wsp 通路行为相似。在这项工作中,我们研究了 Htc10 的特异性,它是 HtChe2 基因簇中唯一编码的化学感受器。我们发现嘌呤衍生物鸟嘌呤和次黄嘌呤是重组产生的 Htc10 配体结合结构域的配体,其解离常数在微摩尔范围内。Htc10的传感器结构域采用双Cache折叠,配体结合在膜远端口袋中。通过所占鸟嘌呤结合口袋的高分辨率结构,确定了参与配体识别的残基。这些残基通过定点突变和等温滴定量热分析得到了验证。此外,在缺乏原生 Wsp 化学感受器的假单胞菌突变体中异源表达 Htc10 能促进生物膜的形成,Htc10 特异性配体进一步增强了这种表型。据我们所知,这是首次描述一种化学感受器的结合特异性,这种化学感受器可控制相关二聚氰胺环化酶的活性,为动态研究这类感觉复合体的信号行为开辟了道路。
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The chemoreceptor controlling the Wsp-like transduction pathway in Halomonas titanicae KHS3 binds and responds to purine derivatives.

The chemosensory pathway HtChe2 from the marine bacterium Halomonas titanicae KHS3 controls the activity of a diguanylate cyclase. Constitutive activation of this pathway results in colony morphology alterations and an increased ability to form biofilm. Such characteristics resemble the behavior of the Wsp pathway of Pseudomonas. In this work, we investigate the specificity of Htc10, the only chemoreceptor coded within the HtChe2 gene cluster. The purine derivatives guanine and hypoxanthine were identified as ligands of the recombinantly produced Htc10 ligand-binding domain, with dissociation constants in the micromolar range, and its structure was solved by X-ray protein crystallography. The sensor domain of Htc10 adopts a double Cache folding, with ligands bound to the membrane-distal pocket. A high-resolution structure of the occupied guanine-binding pocket allowed the identification of residues involved in ligand recognition. Such residues were validated by site-directed mutagenesis and isothermal titration calorimetry analyses of the protein variants. Moreover, heterologous expression of Htc10 in a Pseudomonas putida mutant lacking the native Wsp chemoreceptor promoted biofilm formation, a phenotype that was further enhanced by Htc10-specific ligands. To our knowledge, this is the first description of binding specificity of a chemoreceptor that controls the activity of an associated diguanylate cyclase, opening the way for dynamic studies of the signaling behavior of this kind of sensory complex.

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