PP13C-06:
From Cells to Species – How do Coccolithophore Communities Respond to Climate Change?
Monday, 15 December 2014: 2:55 PM
Samantha Gibbs, University of Southampton, Southampton, United Kingdom, Paul R Bown, University College London, London, United Kingdom and Alex J Poulton, National Oceanography Centre, Southampton, United Kingdom
Abstract:
The geological record contains a rich archive of the exported remains of plankton skeletons that can inform our predictions of their response to current and near-future environmental change. However, these fossilised remains represent integrated populations of millions of individuals recording reproductive success over daily timescales, with each cell responding to its own microenvironment. How then do whole species and communities show ‘response’ to changes in climate occurring on timescales far longer than that of the individual? And what exactly does ‘response’ mean in this context? Here, we utilize remarkably well-preserved assemblages of calcareous nannoplankton in order to interrogate fossil populations uniquely at an individual cellular-level, exploring the link between individuals and the success of the species, thereby tackling these questions from the bottom up. By studying individual fossilized cells we can draw direct comparisons with modern coccolithophore cells and as such we have combined observations from living coccolithophore cultures, naturally occurring populations in the ocean and exquisitely preserved fossil records. The fossils provide us with case studies of community variability alongside environmental change, over both long timescales of greenhouse to icehouse climate states and also more abrupt events such as the Paleogene hyperthermals. Finding these exquisitely preserved fossils is challenging, but there are exceptional situations where preservation bias is greatly reduced and we find complete coccospheres and therefore the intact biomineralised coverings of long-dead cells. These coccospheres preserve invaluable information about the original living cell including its size, levels of particulate organic carbon and inorganic carbon, ontogeny, and growth phase – information that tells us about their reproductive success and their potential role in local biogeochemical cycling. By better understanding these individual cells, we can start to think about the cumulative outcome of seasonal reproductive cycles that results in what we traditionally view as species-level ‘responses’.