Anaerobic consortia and enzymes for biotransformation of aromatic compounds

用于芳香族化合物生物转化的厌氧菌群和酶

• 批准号: RGPIN-2015-06663
• 负责人: Edwards, Elizabeth
• 金额: $ 2.55万
• 依托单位: University of Toronto
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2016
• 资助国家: 加拿大
• 起止时间: 2016-01-01 至 2017-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=614286
• 关键词: Anaerobic; consortia; enzymes; biotransformation; aromatic

These are very exciting times in fundamental and applied environmental microbiology and biotechnology owing to recent advances in analytical tools and techniques to interrogate complex microbial ecosystems. These tools include quantitative DNA and RNA extraction and amplification tools, affordable large-scale DNA sequencing, and protein and proteomics analyses applicable to environmental samples. These techniques are enabling novel approaches to explore and understand the many ways microbial populations grow and interact in complex “difficult–to-study” ecosystems of global importance, such as microbial communities cycling nutrients in soils, in wastewater treatment systems, and in the human gut. In particular, this research focuses on processes that occur in anaerobic environments that exist in swamps, sediments, the deep subsurface, hot springs, and inside the guts of most creatures. Such anaerobic microbial ecosystems are also key in engineered waste treatment systems like anaerobic digestors and constructed wetlands and in industrial or food fermentation and bioenergy processes. The decomposition of organic matter and the cycling of minerals in anaerobic environments rely on complex microbial communities that have defied traditional reductionist approaches.  The focus of this proposal is on the anaerobic biotransformation of benzene, because of its abundance on the planet. Indeed the benzene ring structure is found in common molecules including lignin, proteins, and plant metabolites, and makes up to 30% of the fossil carbon in crude oil. Benzene is also a valuable industrial chemical and a toxic groundwater contaminant.  In this project, we propose to use sensitive mass spectrometry to finally figure out how enzymes break the benzene ring in the absence of oxygen.  This has been a quest for many years, but the advent of new tools brings us closer to this goal than ever before.   Benzene and related compounds are some of our worst environmental offenders.  The major goal of this work is to unblock major degradation bottlenecks and to develop useful tools and knowledge to improve bioremediation and expand the arsenal of strategies to deal with contaminated sites.

这些都是非常令人兴奋的时代，在基础和应用环境微生物学和生物技术，由于最近的进展，分析工具和技术，以询问复杂的微生物生态系统。这些工具包括定量DNA和RNA提取和扩增工具、负担得起的大规模DNA测序以及适用于环境样本的蛋白质和蛋白质组学分析。这些技术使新方法能够探索和理解微生物种群在具有全球重要性的复杂“难以研究”的生态系统中生长和相互作用的许多方式，例如微生物群落在土壤中循环营养物质，废水处理系统和人类肠道。 特别是，这项研究的重点是在沼泽，沉积物，深层地下，温泉和大多数生物的肠道内存在的厌氧环境中发生的过程。这种厌氧微生物生态系统也是工程废物处理系统的关键，如厌氧发酵罐和人工湿地，以及工业或食品发酵和生物能源过程。厌氧环境中有机物的分解和矿物质的循环依赖于复杂的微生物群落，而这些微生物群落无视传统的还原论方法。 该提案的重点是苯的厌氧生物转化，因为它在地球上丰富。事实上，苯环结构存在于常见的分子中，包括木质素，蛋白质和植物代谢物，并占原油中化石碳的30%。苯也是一种有价值的工业化学品，也是一种有毒的地下水污染物。在这个项目中，我们建议使用灵敏的质谱法来最终弄清楚酶是如何在没有氧气的情况下破坏苯环的。这是多年来的探索，但新工具的出现使我们比以往任何时候都更接近这个目标。 苯和相关化合物是我们最严重的环境罪犯之一。这项工作的主要目标是消除主要的降解瓶颈，开发有用的工具和知识，以改善生物修复，并扩大处理污染场地的战略武器库。