Partitioning of C, N and P between particulate and dissolved phases during growth of phytoplankton at different pH.
Lead Research Organisation:
Swansea University
Department Name: School of the Environment and Society
Abstract
Marine phytoplankton play a central role in the cycling of biologically important elements, such as carbon (C), nitrogen (N) and phosphorous (P) between the atmosphere, ocean and marine sediments. Over short periods (weeks) phytoplankton can proliferate, forming vast blooms of new cells that contribute to the Particulate Organic Matter (POM) in the surface ocean. In so doing, they take up nutrients (N and P) and carbon dioxide (CO2) from seawater. This CO2 is replaced by atmospheric CO2 that dissolves in the surface ocean and restores the long-term ocean-atmosphere balance. During a bloom, some cells are consumed by grazers, supporting marine food webs, while others die or stick together and sink. Material reaching the marine sediment contributes to the 'biological carbon pump' which is capable of burying atmospheric CO2 and other nutrients over geological time scales. However, these are not the only fates for assimilated nutrients. During the growth of phytoplankton, organic molecules are released from the cells to the surrounding seawater. These organics (dissolved organic matter / DOM) are used by bacteria which degrade them, regenerating nutrients and releasing CO2 and other climatically active (or greenhouse) gases to the atmosphere. Consequently, the fate of assimilated nutrients, as either POM or DOM, has important implications for the productivity of marine food webs, for CO2 that may be removed from the atmosphere and for the release of greenhouse gases to the atmosphere from the surface ocean. During blooms, the partitioning of nutrients by phytoplankton between POM and DOM changes substantially although our quantitative understanding of this process is limited. In fact, there are no robust, quantitative data available that describe this partitioning in relation to the health of the phytoplankton cells. Without these data we are unable to develop and refine mathematical models that allow us to investigate the implications for marine ecosystems and for global climate change. This project will address this important shortfall in our understanding. An important factor accompanying the consumption of nutrients during phytoplankton blooms is the increase in seawater pH, from 8.2 to greater than 8.5. Ultimately phytoplankton cease to function if the pH exceeds their tolerance, with implications for species succession during bloom propagation. This aspect is usually ignored in models. We have no quantitative or rigorous data available which describes the combination of nutrient limitation and elevated pH, which is likely to effect nutrient partitioning during the acclimation process, and hence the productivity and biogeochemical impact of the bloom. This project will specifically address the impact of changes in pH upon the growth dynamics of marine phytoplankton. In contrast to periods of elevated seawater pH during blooms, evidence points to an acidification of the oceans (pH falls) during the coming decades as anthropogenic CO2 derived from human activity dissolves in the surface ocean. The impact upon the growth of phytoplankton, nutrient partitioning, and their capacity to acclimate to a relatively acidic environment is completely unknown. The implications for the marine environment and the services that it provides warrants urgent investigation. This project, conducted jointly between Swansea University and Plymouth Marine Laboratory, will see cultures of representative phytoplankton subjected to different conditions (nutrient availability, pH) representing current day and future (acidified oceanic) situations. Data describing changes in growth and activity of the organisms will support the construction and testing of mathematical models. The results will thence be incorporated into ecosystem models that will examine the implications for marine productivity and biogeochemistry of the improved description of phytoplanktonic activity, and of ocean acidification for the UK shelf seas.
Organisations
People |
ORCID iD |
Kevin Flynn (Principal Investigator) |
Publications
Cripps G
(2016)
Ocean Acidification Affects the Phyto-Zoo Plankton Trophic Transfer Efficiency.
in PloS one
Flynn K
(2012)
Changes in pH at the exterior surface of plankton with ocean acidification
in Nature Climate Change
Flynn K
(2017)
What is the limit for photoautotrophic plankton growth rates?
in Journal of Plankton Research
Flynn KJ
(2017)
Minimising losses to predation during microalgae cultivation.
in Journal of applied phycology
Flynn KJ
(2015)
Ocean acidification with (de)eutrophication will alter future phytoplankton growth and succession.
in Proceedings. Biological sciences
Flynn KJ
(2016)
The role of coccolithophore calcification in bioengineering their environment.
in Proceedings. Biological sciences
Kenny P
(2017)
Physiology limits commercially viable photoautotrophic production of microalgal biofuels.
in Journal of applied phycology
Kenny P
(2015)
In silico optimization for production of biomass and biofuel feedstocks from microalgae.
in Journal of applied phycology
Description | Microalgae grown under different conditions of acidity (pH) show different responses to extremes. What this project has shown is that drifting pH to higher levels is more deleterious to these organisms than being held at a constant pH (within certain ranges); such pH increases occur during normal growth of these organisms as they photosynthesis and remove CO2 from the water. In consequence, under the process of ocean acidification (which inputs CO2 into seawater), starting at a lower pH alters the upper end of the pH attained during organism growth, and thus affects species succession. |
Exploitation Route | This information is of use in commercial microalgae production; these systems readily show extreme pH ranges. |
Sectors | Agriculture Food and Drink Environment |
Description | The information has been used to inform research activities both in NE/H01750X/1 and NE/J021008/1; for the latter the results formed a major driver in the grant application. |
First Year Of Impact | 2012 |
Sector | Education |
Description | Carbon Trust Algal Biofuels Challenge |
Amount | £500,000 (GBP) |
Funding ID | ABC 008 |
Organisation | Carbon Trust |
Sector | Charity/Non Profit |
Country | United Kingdom |
Start | 03/2010 |
End | 03/2011 |
Description | Durham University Institute of Advanced Studies |
Amount | € 4,000 (EUR) |
Organisation | Durham University |
Sector | Academic/University |
Country | United Kingdom |
Start | 09/2011 |
End | 12/2011 |
Description | MixITiN H2020 MSCA ITN |
Amount | € 2,860,000 (EUR) |
Funding ID | 766327 |
Organisation | European Union |
Sector | Public |
Country | European Union (EU) |
Start | 09/2017 |
End | 09/2021 |
Title | Model of Algal Production and growth with temperature, nutrients and light + pH |
Description | Variable stoichiometric multi nutrient phytoplankton model with pH (OA) linkage |
Type Of Material | Computer model/algorithm |
Year Produced | 2012 |
Provided To Others? | Yes |
Impact | paper in Nature Climate Change successful subsequent grant application |
Title | Phytoplankton OA |
Description | Plankton-functional type model bidirectionally linked to ocean acidification, so pH rises during net C-fixation and declines otherwise, and with calcification |
Type Of Material | Computer model/algorithm |
Year Produced | 2016 |
Provided To Others? | Yes |
Impact | too early to say beyond the current deployment for papers (Flynn et al. 2016, 2014, 2012) |
Description | The Conversation - Microscopic marine plants bioengineer their environment to enhance their own growth |
Form Of Engagement Activity | A magazine, newsletter or online publication |
Part Of Official Scheme? | No |
Geographic Reach | International |
Primary Audience | Media (as a channel to the public) |
Results and Impact | Article in The Conversation - http://theconversation.com/microscopic-marine-plants-bioengineer-their-environment-to-enhance-their-own-growth-63355 |
Year(s) Of Engagement Activity | 2016 |
URL | http://theconversation.com/microscopic-marine-plants-bioengineer-their-environment-to-enhance-their-... |