Synthesis and biochemical characterization of naphthoquinone derivatives targeting bacterial histidine kinases

IF 2.1 4区医学 Q3 BIOTECHNOLOGY & APPLIED MICROBIOLOGY Journal of Antibiotics Pub Date : 2024-06-25 DOI:10.1038/s41429-024-00726-2

Teruhiko Ishikawa, Yoko Eguchi, Masayuki Igarashi, Toshihide Okajima, Kohei Mita, Yuri Yamasaki, Kaho Sumikura, Taisei Okumura, Yuna Tabuchi, Chigusa Hayashi, Martina Pasqua, Marco Coluccia, Gianni Prosseda, Bianca Colonna, Chie Kohayakawa, Akiyoshi Tani, Jun-ichi Haruta, Ryutaro Utsumi

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Abstract

Waldiomycin is an inhibitor of histidine kinases (HKs). Although most HK inhibitors target the ATP-binding region, waldiomycin binds to the intracellular dimerization domain (DHp domain) with its naphthoquinone moiety presumed to interact with the conserved H-box region. To further develop inhibitors targeting the H-box, various 2-aminonaphthoquinones with cyclic, aliphatic, or aromatic amino groups and naphtho [2,3-d] isoxazole-4,9-diones were synthesized. These compounds were tested for their inhibitory activity (IC50) against WalK, an essential HK for Bacillus subtilis growth, and their minimum inhibitory concentrations (MIC) against B. subtilis. As a result, 11 novel HK inhibitors were obtained as naphthoquinone derivatives (IC50: 12.6–305 µM, MIC: 0.5–128 µg ml−1). The effect of representative compounds on the expression of WalK/WalR regulated genes in B. subtilis was investigated. Four naphthoquinone derivatives induced the expression of iseA (formerly yoeB), whose expression is negatively regulated by the WalK/WalR system. This suggests that these compounds inhibit WalK in B. subtilis cells, resulting in antibacterial activity. Affinity selection/mass spectrometry analysis was performed to identify whether these naphthoquinone derivatives interact with WalK in a manner similar to waldiomycin. Three compounds were found to competitively inhibit the binding of waldiomycin to WalK, suggesting that they bind to the H-box region conserved in HKs and inhibit HK activity.

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以细菌组氨酸激酶为靶标的萘醌衍生物的合成和生化特性。

华地霉素是组氨酸激酶（HKs）的抑制剂。虽然大多数 HK 抑制剂都以 ATP 结合区为靶点，但华帝霉素与细胞内二聚化结构域（DHp 结构域）结合，其萘醌分子推测与保守的 H-box 区相互作用。为了进一步开发针对 H-box 的抑制剂，合成了各种带有环状、脂肪族或芳香族氨基的 2-氨基萘醌和萘并 [2,3-d] 异恶唑-4,9-二酮。测试了这些化合物对枯草芽孢杆菌生长所必需的 HK WalK 的抑制活性（IC50）及其对枯草芽孢杆菌的最低抑制浓度（MIC）。结果获得了 11 种新型 HK 抑制剂，它们都是萘醌衍生物（IC50：12.6-305 µM，MIC：0.5-128 µg ml-1）。研究了代表性化合物对枯草杆菌中 WalK/WalR 调控基因表达的影响。四种萘醌衍生物诱导了 iseA（原 yoeB）的表达，而该基因的表达受 WalK/WalR 系统的负调控。这表明这些化合物能抑制枯草杆菌细胞中的 WalK，从而产生抗菌活性。为了确定这些萘醌衍生物是否以类似于华地霉素的方式与 WalK 发生相互作用，我们进行了亲和选择/质谱分析。研究发现，有三种化合物能竞争性地抑制瓦地霉素与 WalK 的结合，这表明它们与 HKs 中保留的 H-box 区域结合并抑制了 HK 的活性。

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来源期刊

Journal of Antibiotics 医学-免疫学

CiteScore

6.60

自引率

3.00%

发文量

审稿时长

1 months

期刊介绍： The Journal of Antibiotics seeks to promote research on antibiotics and related types of biologically active substances and publishes Articles, Review Articles, Brief Communication, Correspondence and other specially commissioned reports. The Journal of Antibiotics accepts papers on biochemical, chemical, microbiological and pharmacological studies. However, studies regarding human therapy do not fall under the journal’s scope. Contributions regarding recently discovered antibiotics and biologically active microbial products are particularly encouraged. Topics of particular interest within the journal''s scope include, but are not limited to, those listed below: Discovery of new antibiotics and related types of biologically active substances Production, isolation, characterization, structural elucidation, chemical synthesis and derivatization, biological activities, mechanisms of action, and structure-activity relationships of antibiotics and related types of biologically active substances Biosynthesis, bioconversion, taxonomy and genetic studies on producing microorganisms, as well as improvement of production of antibiotics and related types of biologically active substances Novel physical, chemical, biochemical, microbiological or pharmacological methods for detection, assay, determination, structural elucidation and evaluation of antibiotics and related types of biologically active substances Newly found properties, mechanisms of action and resistance-development of antibiotics and related types of biologically active substances.