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Details of Award

NERC Reference : NE/K009044/1

Eco-interactomics: From microbial interactions to the fate of dissolved organic matter in the oceans.

Fellowship Award

Fellow:
Dr J Christie-Oleza, University of Warwick, School of Life Sciences
Science Area:
Earth
Marine
Overall Classification:
Marine
ENRIs:
Biodiversity
Global Change
Natural Resource Management
Science Topics:
Community Ecology
Carbon Capture & Storage
Biogeochemical Cycles
Environmental Microbiology
Proteomics
Abstract:
Greenhouse gas emissions and the growing concentration of carbon dioxide (CO2) in the atmosphere has become more important as evidence increasingly links this to climate change. One of the big questions for science is how plants, algae and other organisms which are able to remove this CO2 from the atmosphere will respond to increasing concentrations and whether they will be able to offset some of this increase. Half of the atmospheric turnover of CO2 comes from land based vegetation and the other half takes place in the oceans. On land uptake of CO2 by plants is balanced by the CO2 released when they die and decompose. In the oceans more CO2 is removed from the air by photosynthesis than is released by decay. This means the oceans can act as carbon stores and one of the main reasons for this is the production of organic matter by the microorganisms in the oceans which subsequently sinks into deeper waters where it can be retained for decades or even centuries. Understanding the marine microbial food web and how this CO2 storage occurs is vitally important as it will allow us to make predictions about how the oceans will react to increasing concentrations of man-made CO2 in the atmosphere and how this could influence climate change. In the oceans, photosynthetic microorganisms, despite their relatively low abundance (under 10% of total organisms) are the main source of food and energy to sustain the whole ecosystem. These organisms release large amounts of organic matter into the water that can then be broken down and used as a food source by other microorganisms present in the water. These degraders will use most of this organic matter, recycling essential elements into new growth. Nevertheless, part of this organic matter will be converted into less degradable compounds that will sink and be retained in the ocean depths. This study will focus on the pathway followed by organic matter through the marine food web, from primary producers to final degraders, until it is converted into these less-degradable compounds, to determine the flow of carbon through the food web and identify who degrades what and in what order. In stable environments, such as oceans, evolution has pushed free-living organisms to lose vital functions in order to use the scarce resources more effectively. This has resulted in a community of organisms dependent on each other. Thus organisms which photosynthesise are dependent on the degrading organisms which feed off the organic compounds they produce and vice versa. This project will look at how this interaction is occurring at the molecular level and will examine how relations within the microbial food web rely on the secretion of natural products. Microorganisms in the ocean secrete an enormous range of compounds in order to modify or exert an influence on their community and environment. The interactions caused by these secreted products can be friendly or hostile. However, the real function and target of the enormous pool of secreted compounds is largely unknown. Understanding the secreted elements will give a greater understanding of the processes and interactions occurring within the marine microbial ecosystem, something which, given its role in driving the marine food web, we still know very little about. Therefore, one of the major objectives of my project is to gain new insights into how primary producers & degraders interact through their secreted products. The study of these secreted products will identify a large array of novel natural products with interest not only for human health (such as antibiotics, probiotics or bactericides) but also for other industrial activities such as fisheries or energy-producing algae plants. This project will provide a much needed understanding of how microbial communities interact in the oceans and how this can influence the retention of atmospheric carbon in the seas and act as a buffer against increasing CO2 in the atmosphere.
Period of Award:
4 Oct 2013 - 3 Oct 2018
Value:
£577,265
Authorised funds only
NERC Reference:
NE/K009044/1
Grant Stage:
Completed
Scheme:
Research Fellowship
Grant Status:
Closed
Programme:
IRF

This fellowship award has a total value of £577,265  

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FDAB - Financial Details (Award breakdown by headings)

DI - Other CostsIndirect - Indirect CostsDA - Estate CostsDI - StaffDA - Other Directly AllocatedDI - T&S
£140,700£143,075£65,211£211,662£6,868£9,751

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