Chemical and Genetic Triggers of Secondary Metabolite Production

次生代谢产物产生的化学和遗传触发因素

• 批准号: RGPIN-2016-04093
• 负责人: Findlay, Brandon
• 金额: $ 1.82万
• 依托单位: Concordia University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2022
• 资助国家: 加拿大
• 起止时间: 2022-01-01 至 2023-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=748455
• 关键词: Chemical; Genetic; Triggers; Secondary; Metabolite

For over fifty years natural products were the primary source of new drug leads, in many cases moving from isolation to clinic use without modification. Most of these compounds were isolated from bacteria and fungi, the product of a massive industrial effort to isolate cultivable strains from every corner of the globe. This search largely ended two decades ago, due in part to diminishing returns from continual re-isolation of known compounds. The absence of new natural products has hit anticancer and antibiotic research the hardest, as approximately 40% and 80% of small molecule antibiotics and anticancer drugs are natural product based. Recent advances in bioinformatics allow us to identify the genes and proteins involved in natural product biosynthesis, without needing to isolate each compound. These tools reveal that earlier searches for natural products have missed the vast majority of compounds, with even the most productive strains producing only about 20% of their biosynthetic repertoire during normal lab growth. Interestingly, the regulatory elements that control these silent genes appear to be heavily conserved, suggesting that the majority of silent biosynthesis genes rely on a small set of chemical triggers. With bacteria from the related Photorhabdus and Xenorhabdus families as a model, we will use high throughput screening to discover natural products that activate natural product biosynthesis. In concert with genetic studies these activators will provide a handle by which we can probe the regulatory pathways that control secondary metabolism in bacteria. Linking natural product biosynthesis to specific chemical triggers will also make it possible to tie the secondary metabolites bacteria produce to specific environmental stresses, shedding light on how these compounds allow bacteria to adapt to their environment. The chemical triggers will also be a boon to industrial drug discovery efforts, significantly improving the efficiency of natural product screening. At the same time, this approach will activate uncharacterized gene clusters in Photorhabdus and Xenorhabdus species, which will then be identified and characterized. These compounds are likely to have broad applications, as strains from these species are important biocontrol agents in agriculture (through their symbiotic relationship with insecticidal nematodes), as well as an underexplored source of antimicrobial compounds. The metabolites of Photorhabdus luminescens are of particular interest, as this bacteria is thought to be the causative agent behind “Angel's Glow.” Soldiers injured in the Battle of Shiloh during the American Civil War reported that their wounds glowed in the dark, an unsettling effect that nevertheless appeared to prevent infection and aid healing. P. luminescens and its close relatives are the only known terrestrial bacteria to exhibit bioluminescence.

五十多年来，天然产物是新药的主要来源，在许多情况下，从隔离到临床使用，而无需修改。 这些化合物大多数是从细菌和真菌中分离出来的，这是从地球仪的每个角落分离可培养菌株的大规模工业努力的产物。 这项研究在20年前基本结束，部分原因是已知化合物不断重新分离的回报越来越少。 新天然产物的缺乏对抗癌和抗生素研究的打击最大，因为大约40%和80%的小分子抗生素和抗癌药物是基于天然产物的。 生物信息学的最新进展使我们能够识别参与天然产物生物合成的基因和蛋白质，而无需分离每种化合物。 这些工具表明，早期对天然产物的搜索错过了绝大多数化合物，即使是最高产的菌株在正常的实验室生长过程中也只能产生约20%的生物合成谱。 有趣的是，控制这些沉默基因的调控元件似乎是高度保守的，这表明大多数沉默的生物合成基因依赖于一小部分化学触发因子。 我们将以相关发光杆菌属和致病杆菌属的细菌为模型，利用高通量筛选来发现激活天然产物生物合成的天然产物。 与遗传研究相一致，这些激活剂将提供一个手柄，通过它我们可以探测控制细菌次级代谢的调节途径。 将天然产物生物合成与特定的化学触发因素联系起来，也将使细菌产生的次级代谢产物与特定的环境压力联系起来，从而揭示这些化合物如何使细菌适应其环境。 化学触发器也将是工业药物发现工作的布恩，显著提高天然产物筛选的效率。 与此同时，这种方法将激活Photorhabdus和Xabrohabdus物种中未表征的基因簇，然后对其进行鉴定和表征。 这些化合物可能具有广泛的应用，因为来自这些物种的菌株是农业中重要的生物防治剂（通过它们与杀虫线虫的共生关系），以及未被探索的抗微生物化合物来源。 发光光杆菌的代谢产物特别令人感兴趣，因为这种细菌被认为是“天使的光芒”背后的病原体。 在美国内战期间的夏伊洛战役中受伤的士兵报告说，他们的伤口在黑暗中会发光，这是一种令人不安的效果，但似乎可以防止感染和帮助愈合。 P. luminescens及其近亲是唯一已知的显示生物发光的陆地细菌。