Katie T. Ward, Alexander P. L. Williams, Courtney A. Blair, Ananya M. Chatterjee, Abirami Karthikeyan, Addison S. Roper, Casey N. Kellogg, P. Ryan Steed* and Amanda L. Wolfe*,
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引用次数: 0
摘要
铜绿假单胞菌(Pseudomonas aeruginosa,PA)是一种革兰氏阴性病原体,是引起院内感染的常见原因,尤其是在免疫力低下和囊性纤维化患者中。PA 因其紧密包裹的阴离子脂多糖外膜、外排泵和形成生物膜的能力,对许多目前处方的抗生素具有内在的耐药性。PA 可通过基因突变和水平基因转移获得更多抗药性。PA ATP 合成酶是抗生素开发的一个有吸引力的靶点,因为即使在发酵条件下,它也是细胞存活的必要条件。此前,我们开发了两种先导喹啉化合物,它们能够选择性地抑制 PA ATP 合酶,并可作为抗多药性 PA 的抗菌剂。在此,我们通过合成和评估 18 种喹啉衍生物,对先导化合物进行了结构-活性关系分析。这些化合物在作为新型抗菌剂发挥作用的同时,还让我们深入了解了在保持 PA ATP 合成酶抑制作用的同时促进细胞进入所需的物理性质平衡。
Amine Basicity of Quinoline ATP Synthase Inhibitors Drives Antibacterial Activity against Pseudomonas aeruginosa
Pseudomonas aeruginosa (PA), a Gram-negative pathogen, is a common cause of nosocomial infections, especially in immunocompromised and cystic fibrosis patients. PA is intrinsically resistant to many currently prescribed antibiotics due to its tightly packed, anionic lipopolysaccharide outer membrane, efflux pumps, and ability to form biofilms. PA can acquire additional resistance through mutation and horizontal gene transfer. PA ATP synthase is an attractive target for antibiotic development because it is essential for cell survival even under fermentation conditions. Previously, we developed two lead quinoline compounds that were capable of selectively inhibiting PA ATP synthase and acting as antibacterial agents against multidrug-resistant PA. Herein we conduct a structure–activity relationship analysis of the lead compounds through the synthesis and evaluation of 18 quinoline derivatives. These compounds function as new antibacterial agents while providing insight into the balance of physical properties needed to promote cellular entry while maintaining PA ATP synthase inhibition.
期刊介绍:
ACS Medicinal Chemistry Letters is interested in receiving manuscripts that discuss various aspects of medicinal chemistry. The journal will publish studies that pertain to a broad range of subject matter, including compound design and optimization, biological evaluation, drug delivery, imaging agents, and pharmacology of both small and large bioactive molecules. Specific areas include but are not limited to:
Identification, synthesis, and optimization of lead biologically active molecules and drugs (small molecules and biologics)
Biological characterization of new molecular entities in the context of drug discovery
Computational, cheminformatics, and structural studies for the identification or SAR analysis of bioactive molecules, ligands and their targets, etc.
Novel and improved methodologies, including radiation biochemistry, with broad application to medicinal chemistry
Discovery technologies for biologically active molecules from both synthetic and natural (plant and other) sources
Pharmacokinetic/pharmacodynamic studies that address mechanisms underlying drug disposition and response
Pharmacogenetic and pharmacogenomic studies used to enhance drug design and the translation of medicinal chemistry into the clinic
Mechanistic drug metabolism and regulation of metabolic enzyme gene expression
Chemistry patents relevant to the medicinal chemistry field.
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