控制葡萄球菌病原菌和共生菌微生物组相互作用的次生代谢物。

Pub Date : 2021-01-01 Epub Date: 2021-07-29 DOI:10.1159/000517082
Benjamin O Torres Salazar, Simon Heilbronner, Andreas Peschel, Bernhard Krismer
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引用次数: 11

摘要

各种葡萄球菌定植于温血动物的皮肤和上呼吸道。它们在这些栖息地的恶劣和营养贫乏的条件下成功地与许多其他微生物竞争,使用的机制我们才刚刚开始欣赏。小分子介质,其生物合成需要复杂的酶级联反应,即所谓的次级代谢物,已经成为葡萄球菌微生物组相互作用的关键组成部分。这类介质属于种类繁多的化合物类别,其中一些对未来的药物开发具有吸引力。例如,它们包括细菌素,如硫肽、硫肽和抑制细菌竞争物种的纤维肽;信号分子,如硫代内酯肽,诱导或抑制其他细菌的感觉级联反应;或者像葡萄铁蛋白和葡萄碱这样的金属分子,它们可以清除少量的过渡金属离子。对于一些次生代谢物,如金葡胺,其确切功能仍有待阐明。次生代谢物如何在其他微生物和宿主防御因子的复杂背景下塑造葡萄球菌物种的适应性仍然是未来研究的一个具有挑战性的领域。详细的了解将有助于利用葡萄球菌的次级代谢物从高危患者的鼻腔微生物群中排除致病性金黄色葡萄球菌,并将有助于开发先进的抗感染干预措施。
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Secondary Metabolites Governing Microbiome Interaction of Staphylococcal Pathogens and Commensals.

Various Staphylococcus species colonize skin and upper airways of warm-blooded animals. They compete successfully with many other microorganisms under the hostile and nutrient-poor conditions of these habitats using mechanisms that we are only beginning to appreciate. Small-molecule mediators, whose biosynthesis requires complex enzymatic cascades, so-called secondary metabolites, have emerged as crucial components of staphylococcal microbiome interactions. Such mediators belong to a large variety of compound classes and several of them have attractive properties for future drug development. They include, for instance, bacteriocins such as lanthipeptides, thiopeptides, and fibupeptides that inhibit bacterial competitor species; signaling molecules such as thiolactone peptides that induce or inhibit sensory cascades in other bacteria; or metallophores such as staphyloferrins and staphylopine that scavenge scant transition metal ions. For some secondary metabolites such as the aureusimines, the exact function remains to be elucidated. How secondary metabolites shape the fitness of Staphylococcus species in the complex context of other microbial and host defense factors remains a challenging field of future research. A detailed understanding will help to harness staphylococcal secondary metabolites for excluding the pathogenic species Staphylococcus aureus from the nasal microbiomes of at-risk patients, and it will be instrumental for the development of advanced anti-infective interventions.

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