Ecological and Evolutionary framework for the design of novel bacteriophage therapy products

新型噬菌体治疗产品设计的生态和进化框架

• 批准号: EP/Y029585/1
• 负责人: Cédric Lood
• 金额: $ 25.55万
• 依托单位: University of Oxford
• 依托单位国家: 英国
• 项目类别: Fellowship
• 财政年份: 2023
• 资助国家: 英国
• 起止时间: 2023 至 无数据
• 项目状态: 未结题
• 来源: https://gtr.ukri.org/projects?ref=EP%2FY029585%2F1
• 关键词: Ecological; Evolutionary; framework; design; novel

The healthcare system is increasingly under pressure due to the rise of antimicrobial resistance in bacterial pathogens. Multiple call to arms have resulted in a diversification of strategies to mitigate this issue. Human phage therapy is currently a widely advocated "post-antibiotic" approach in which we use the viruses of bacteria, or phages, to clear bacterial infections. It offers multiple advantages,including i) a high targeting specificity, with phages typically infecting only specific strains within a bacterial species, ii) self-dosing through amplification in situ, and iii) co-evolution of the phages with their host, so that if a bacterial strain becomes resistant to aphage, we can find new phage variants that will be able to infect it.In this proposal, we address two current limitations of phage therapy: the first concerns methods for phage discovery, a task that hasproved challenging in some pathogens. Indeed, isolating virulent phages from the environment to infect specific strains from patients appears at times impossible. We propose here to weaponize the abundant prophages found in bacterial chromosomes using anexperimental evolution approach. The second limitation concerns the combination of phages into cocktails that can be broadly effective to target specific pathogens. For this task, we will implement Biodiversity-Ecosystem functioning strategies to discover design rules for optimized phage combinations. We have chosen to implement our approach on the clinically relevant bacteria: Pseudomonas aeruginosa.This project will be performed in synergy with a lab that has considerable expertise in evolutionary microbiology and ecology, and where I can bring my own expertise of phage microbiology and large-scale omics data analysis. We believe this topic is timely and of high relevance for the EU and beyond as we work to further unleash the potential of phage therapy for human health and limit the cost of antimicrobial resistance in our societies.

由于细菌病原体抗菌素耐药性的上升，医疗保健系统面临着越来越大的压力。多次号召人们采取多种战略来缓解这一问题。人类噬菌体疗法是​​目前广泛提倡的“后抗生素”方法，其中我们使用细菌的病毒或噬菌体来清除细菌感染。它具有多种优势，包括 i) 高靶向特异性，噬菌体通常仅感染细菌物种内的特定菌株，ii) 通过原位扩增进行自我给药，以及 iii) 噬菌体与其宿主的共同进化，因此如果细菌菌株对噬菌体产生抗药性，我们可以找到能够感染它的新噬菌体变体。在这项提案中，我们解决了噬菌体治疗目前的两个局限性：第一个涉及噬菌体方法发现，这项任务在某些病原体中已被证明具有挑战性。事实上，从环境中分离出剧毒噬菌体来感染患者的特定菌株有时似乎是不可能的。我们在这里建议使用实验进化方法将细菌染色体中发现的丰富的噬菌体武器化。第二个限制涉及将噬菌体组合成可广泛有效地针对特定病原体的混合物。对于这项任务，我们将实施生物多样性生态系统功能策略，以发现优化噬菌体组合的设计规则。我们选择在临床相关细菌上实施我们的方法：铜绿假单胞菌。该项目将与在进化微生物学和生态学方面拥有丰富专业知识的实验室协同进行，我可以在其中带来我自己的噬菌体微生物学和大分子专业知识。规模组学数据分析。我们相信这个话题是及时的，并且对欧盟及其他地区具有高度相关性，因为我们正在努力进一步释放噬菌体疗法对人类健康的潜力并限制我们社会中抗菌素耐药性的成本。