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19-ERACoBioTech SYNBIOGAS: Synthetic landfill microbiomes for enhanced anaerobic digestion to biogas

ReferenceBB/T011076/1
Principal Investigator / Supervisor Professor James McDonald
Co-Investigators /
Co-Supervisors
Professor Peter Golyshin, Professor Davey Jones, Professor Alexander Yakunin
Institution Bangor University
DepartmentSch of Natural Sciences
Funding typeResearch
Value (£) 462,144
StatusCurrent
TypeResearch Grant
Start date 01/01/2020
End date 30/06/2023
Duration42 months

Abstract

The landfill microbiome represents an unexplored repository of biomass-degrading enzyme diversity to enhance existing industrial biomass-conversion processes and identify new hydrolase enzymes of relevance for industrial biotechnology processes. This project aims to utilise a systems biology analysis of biomass-conversion by landfill microbiota, combining novel technological, analytical and computational approaches for microbiome characterisation, in silico discovery and validation of novel enzymes, and process modelling for the design of optimal synthetic biomass-converting microbiomes. Ultimately, the research will generate synthetic landfill microbiomes (SLMs) designed for bioaugmentation of landfill sites and anaerobic digestion plants for enhanced biomass conversion and biogas generation, enabling a progression in TRL in this sector. In addition, we will utilise life cycle assessment and cost benefit analysis approaches to demonstrate the potential industrial benefits of our process model and synthetic microbiome, and will generate a road map for industry adoption of the new technology. The research leverages new approaches to understanding fundamental questions regarding the ecological factors that drive syntrophic interactions between anaerobic biomass-degrading microbiota.

Summary

Lignocellulosic plant biomass is the most abundant waste product generated by society, agriculture and industry. By 2025, global cities will generate approximately 2.2 billion tonnes of solid waste biomass per year, with significant impacts upon health and the economy at both local and global scales. Natural communities of microorganisms (microbiomes) convert waste biomass to methane-rich biogas that can be used as a sustainable and renewable green-energy source to generate electricity, heat and power, and biomethane for injection into the national gas grid and production of transport fuels. Anaerobic digestion (AD) plants and landfill sites are engineered environments where these microbial processes are harnessed for waste decomposition and biogas production. The EU is the largest global producer of biogas from biomass, with over 17,000 AD plants, and consequently, the microbiological conversion of solid waste residues to biogas in AD plants and landfill sites presents an unprecedented opportunity to leverage key enabling technologies for a sustainable bio-based economy for green-energy production. In turn, conversion of waste biomass to biomethane will mitigate the escalating environmental and social impacts of waste residues. However, the metabolic function of microorganisms responsible for anaerobic digestion is poorly understood, and most previous studies have focused on animal gut microorganisms that are typically used to incoluate microorganisms into anaerobic digestion plants as slurry. One of the major bottlenecks to industrial application of microorganisms for biomass-conversion is low substrate specificity, low temperature tolerance, and an inability to perform optimally under reaction conditions. Natural microorganisms found in landfill sites represent an unexplored repository of biomass-degrading enzyme diversity with the potential to enhance existing industrial biomass-conversion processes. Landfill microorganisms are already adapted to engineered environments, mineralise diverse solid waste types, produce methane-rich biogas, and are therefore good candidates for the bioaugmentation of anaerobic digestion processes. The SYNBIOGAS consortium is an academic-industry partnership that will integrate diverse and cutting-edge technological, analytical, engineering and computational approaches for characterisation of the landfill biomass-degrading microbiome. Microbial isolations, DNA sequencing, enzyme characterisation and computational modelling of landfill microbial biomass-conversion processes will inform the design and validation of optimised synthetic landfill microbiomes (SLMs) for enhanced waste biomass-conversion in AD plants and landfill sites, and to develop applications of the SLM that can be readily adopted by industry. Engineering biomass-degrading microbiomes is a new research frontier with many novel applications, including bioaugmentation and optimisation of biomass conversion in AD and landfill systems towards an enhanced bio-based economy for waste management, environmental protection, and sustainable intensification of renewable energy generation.

Impact Summary

The landfill microbiome represents an unexplored repository of biomass-degrading enzyme diversity to enhance existing industrial biomass-conversion processes and identify new hydrolase enzymes of relevance for industrial biotechnology processes (Ransom-Jones et al., 2017). This project will provide the first systems biology analysis of biomass-conversion by landfill microbiota (WP1-3) combining novel technological, analytical and computational approaches for microbiome characterisation (WP1), in silico discovery and validation of novel enzymes (WP2) and process modelling for the design of optimal synthetic biomass-converting microbiomes (WP3). Ultimately, the research in WP's 1-3 will generate synthetic landfill microbiomes (SLMs) designed for bioaugmentation of landfill sites and anaerobic digestion plants for enhanced biomass conversion and biogas generation in WP4, enabling a progression from TRL2 to TRL6 through the project (Figure 2). In WP5, we subsequently utilise life cycle assessment and cost benefit analysis approaches to demonstrate the potential industrial benefits of our process model and synthetic microbiome, and will generate a road map for industry adoption of the new technology. The research leverages new approaches to understanding fundamental questions regarding the ecological factors that drive syntrophic interactions between anaerobic biomass-degrading microbiota. Synthetic biology approaches for the engineering of biomass-degrading microbiomes is a new research frontier with many novel applications, including bioaugmentation and optimisation of biomass conversion in AD systems towards an enhanced bio-based economy for waste management, environmental protection and sustainable intensification of renewable energy generation. Previously, laboratory-based landfill bioreactor experiments undergoing bioaugmentation with natural compost microorganisms demonstrated improved biomass degradation from 65% to 99%, and increased biogas generation (Kinet etal., 2016). The success of bioaugmentation for biomass conversion with relatively undefined microbial populations from natural environments in laboratory reactors is encouraging; however, such approaches have not been extensively validated and demonstrated in relevant industrial environments (i.e. AD plants and landfills), and SLMs have not previously been designed and tested. Consequently, the opportunity to (i) directly manipulate biomass-converting microbiota through characterisation, process modelling and the design of more sophisticated synthetic microbiomes, and (ii), industrial application/validation of SLMs for enhanced biogas generation, in the SYNBIOGAS project is a tantalising challenge, with significant potential to provide a paradigm shift in waste biomass conversion, green-energy production and waste management. The SYNBIOGAS project is directly relevant to the CoBioTech call, and will develop a biotechnological application (synthetic landfill microbial communities for enhanced biomass conversion to biogas) with potential for strong economic and social impacts towards at sustainable bio-based economy. Our integration and development of the approach with industry partners ensures that our research has high potential for commercialisation and industry adoption through achieving high levels of technology readiness (TRL 2-6). Social impacts include sustainable options for waste management, reduce environmental impact of waste biomass, and the development of key enabling technologies for sustainable green-energy generation with key economic benefits. Tangible outputs would include: novel CAZYmes with enhanced catalytic activity and substrate specificity; high resolution datasets on SLM activity; world-leading metabolic process models of anaerobic digestion processes; validated biotechnological applications of SLMs for AD bioaugmentation; life cycle assessment and a stakeholder roadmap for technology implementation.
Committee Not funded via Committee
Research TopicsBioenergy, Industrial Biotechnology, Microbiology, Synthetic Biology, Systems Biology
Research PriorityX – Research Priority information not available
Research Initiative X - not in an Initiative
Funding SchemeX – not Funded via a specific Funding Scheme
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