{"title":"Abstract PR06: Drugging the human microbiome for combination with tumor immunotherapy","authors":"D. N. Cook, J. Peled, M. Brink, L. Jayaraman","doi":"10.1158/2326-6074.TUMIMM17-PR06","DOIUrl":null,"url":null,"abstract":"The human gut microbiome is a diverse, dynamic, and complex ecosystem that modulates host processes including metabolism, inflammation, and cellular and humoral immune responses. Recent studies have suggested that the microbiome may also influence the development of certain cancers such as colorectal cancer, and equally importantly, tumor response to systemic therapy, especially immunotherapy. Multiple groups are exploring the therapeutic utility of the microbiome to enhance clinical response through the use of defined oral therapeutics comprising living commensal bacteria, which would represent a new therapeutic modality. Exploiting the microbiome for therapeutic benefit is not without its challenges due to the heterogeneity of the gut microbiota across healthy donors and patients. In addition, many aspects of conventional small molecule and biologics drug discovery and development do not apply to this novel class of living drugs. We present an approach that leverages the concept of “reverse translation,” using genomic and immunologic characterization of patient samples from interventional studies to define and better understand the organisms and mechanisms that contribute to response or non-response to immunotherapy. We are investigating the relationship between the composition of the gut microbiome prior to therapy and the antitumor response in patients receiving checkpoint inhibitors (CPI), as well as how CPI treatment modulates the microbiome in both responders and nonresponders. Fecal and blood samples are collected before and during therapy from cancer patients who receive approved CPI; tumor types include renal, bladder, and NSCLC. Whole metagenomic shotgun sequencing of patient microbiomes is used to identify higher order (e.g., order- and family-level) “microbial signatures” that associate with response to CPI treatment. We then utilize proprietary algorithms that enable species- and strain-level resolution of microbial signatures. In addition, global and targeted metabolomics are used to identify functional pathways associated with outcome, and these pathways can be linked to species and strains identified by genomic analysis. Our discovery strategy iterates computational analyses and machine learning approaches with empirical in vitro and ex vivo screening of strains and consortia to inform selection and drive drug design. Data from such a comprehensive approach is invaluable for designing compositions of bacteria that form “functional ecological networks” that can impact response to CPI therapy. Finally, our microbial library of >14,000 isolates from healthy human subjects captures the phylogenetic diversity and functional breadth of the gastrointestinal microbiome, and provides a robust platform to build unique compositions. Such compositions, when tested in syngeneic tumor models in germ-free mice, can provide a preliminary readout of the contributions of members of the consortia and enable candidate identification. We present examples of reverse translation in patients with recurrent Clostridium difficile infection and ulcerative colitis, a form of inflammatory bowel disease, that have led to the translation of three drugs that are currently in clinical trials. This roadmap provides insight into how similar drugs can be discovered and developed in the setting of immunotherapy to augment the efficacy of CPIs by altering the cancer-immune set point. This abstract is also being presented as Poster A06. Citation Format: David N. Cook, Jonathan Peled, Marcel van den Brink, Lata Jayaraman. Drugging the human microbiome for combination with tumor immunotherapy [abstract]. In: Proceedings of the AACR Special Conference on Tumor Immunology and Immunotherapy; 2017 Oct 1-4; Boston, MA. Philadelphia (PA): AACR; Cancer Immunol Res 2018;6(9 Suppl):Abstract nr PR06.","PeriodicalId":309751,"journal":{"name":"Cancer and the Microbiome","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2018-09-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Cancer and the Microbiome","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1158/2326-6074.TUMIMM17-PR06","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
The human gut microbiome is a diverse, dynamic, and complex ecosystem that modulates host processes including metabolism, inflammation, and cellular and humoral immune responses. Recent studies have suggested that the microbiome may also influence the development of certain cancers such as colorectal cancer, and equally importantly, tumor response to systemic therapy, especially immunotherapy. Multiple groups are exploring the therapeutic utility of the microbiome to enhance clinical response through the use of defined oral therapeutics comprising living commensal bacteria, which would represent a new therapeutic modality. Exploiting the microbiome for therapeutic benefit is not without its challenges due to the heterogeneity of the gut microbiota across healthy donors and patients. In addition, many aspects of conventional small molecule and biologics drug discovery and development do not apply to this novel class of living drugs. We present an approach that leverages the concept of “reverse translation,” using genomic and immunologic characterization of patient samples from interventional studies to define and better understand the organisms and mechanisms that contribute to response or non-response to immunotherapy. We are investigating the relationship between the composition of the gut microbiome prior to therapy and the antitumor response in patients receiving checkpoint inhibitors (CPI), as well as how CPI treatment modulates the microbiome in both responders and nonresponders. Fecal and blood samples are collected before and during therapy from cancer patients who receive approved CPI; tumor types include renal, bladder, and NSCLC. Whole metagenomic shotgun sequencing of patient microbiomes is used to identify higher order (e.g., order- and family-level) “microbial signatures” that associate with response to CPI treatment. We then utilize proprietary algorithms that enable species- and strain-level resolution of microbial signatures. In addition, global and targeted metabolomics are used to identify functional pathways associated with outcome, and these pathways can be linked to species and strains identified by genomic analysis. Our discovery strategy iterates computational analyses and machine learning approaches with empirical in vitro and ex vivo screening of strains and consortia to inform selection and drive drug design. Data from such a comprehensive approach is invaluable for designing compositions of bacteria that form “functional ecological networks” that can impact response to CPI therapy. Finally, our microbial library of >14,000 isolates from healthy human subjects captures the phylogenetic diversity and functional breadth of the gastrointestinal microbiome, and provides a robust platform to build unique compositions. Such compositions, when tested in syngeneic tumor models in germ-free mice, can provide a preliminary readout of the contributions of members of the consortia and enable candidate identification. We present examples of reverse translation in patients with recurrent Clostridium difficile infection and ulcerative colitis, a form of inflammatory bowel disease, that have led to the translation of three drugs that are currently in clinical trials. This roadmap provides insight into how similar drugs can be discovered and developed in the setting of immunotherapy to augment the efficacy of CPIs by altering the cancer-immune set point. This abstract is also being presented as Poster A06. Citation Format: David N. Cook, Jonathan Peled, Marcel van den Brink, Lata Jayaraman. Drugging the human microbiome for combination with tumor immunotherapy [abstract]. In: Proceedings of the AACR Special Conference on Tumor Immunology and Immunotherapy; 2017 Oct 1-4; Boston, MA. Philadelphia (PA): AACR; Cancer Immunol Res 2018;6(9 Suppl):Abstract nr PR06.
人类肠道微生物群是一个多样化、动态和复杂的生态系统,它调节宿主的代谢、炎症、细胞和体液免疫反应等过程。最近的研究表明,微生物组也可能影响某些癌症的发展,如结肠直肠癌,同样重要的是,肿瘤对全身治疗,特别是免疫治疗的反应。多个研究小组正在探索微生物组的治疗效用,通过使用含有活共生菌的口服疗法来增强临床反应,这将代表一种新的治疗方式。由于健康供体和患者肠道微生物群的异质性,利用微生物群进行治疗并非没有挑战。此外,传统的小分子和生物制剂药物发现和开发的许多方面并不适用于这类新的活药物。我们提出了一种利用“反向翻译”概念的方法,利用来自介入性研究的患者样本的基因组和免疫学特征来定义和更好地理解导致免疫治疗反应或无反应的生物体和机制。我们正在研究接受检查点抑制剂(CPI)的患者治疗前肠道微生物组组成与抗肿瘤反应之间的关系,以及CPI治疗如何调节应答者和无应答者的微生物组。在接受批准的CPI治疗前和治疗期间收集癌症患者的粪便和血液样本;肿瘤类型包括肾、膀胱和非小细胞肺癌。患者微生物组的全宏基因组散弹枪测序用于识别与CPI治疗反应相关的高阶(例如,阶和家族水平)“微生物特征”。然后,我们利用专有算法,使物种和菌株水平的微生物特征的分辨率。此外,全球和靶向代谢组学用于识别与结果相关的功能途径,这些途径可以与基因组分析确定的物种和菌株相关联。我们的发现策略迭代计算分析和机器学习方法,通过体外和离体筛选菌株和联合体,为选择和驱动药物设计提供信息。来自这种综合方法的数据对于设计形成“功能性生态网络”的细菌成分是无价的,可以影响对CPI治疗的反应。最后,我们从健康人类受试者中分离的超过14,000株微生物文库捕获了胃肠道微生物组的系统发育多样性和功能广度,并提供了一个强大的平台来构建独特的组合物。当在无菌小鼠的同基因肿瘤模型中测试这些组合物时,可以初步读出联盟成员的贡献并进行候选识别。我们介绍了在复发性难辨梭菌感染和溃疡性结肠炎(一种炎症性肠病)患者中进行反向翻译的例子,这导致了目前正在临床试验中的三种药物的翻译。该路线图提供了如何在免疫治疗的背景下发现和开发类似药物的见解,通过改变癌症免疫设定点来增强cpi的疗效。此摘要也以海报A06的形式呈现。引文格式:David N. Cook, Jonathan Peled, Marcel van den Brink, Lata Jayaraman。肿瘤免疫治疗联合用药的人体微生物组研究[摘要]。摘自:AACR肿瘤免疫学和免疫治疗特别会议论文集;2017年10月1-4日;波士顿,MA。费城(PA): AACR;癌症免疫,2018;6(9增刊):摘要nr PR06。