Osmotrophy of dissolved organic carbon by coccolithophores in darkness

New Phytol. 2022 Jan;233(2):781-794. doi: 10.1111/nph.17819. Epub 2021 Nov 16.

Abstract

The evolutionary and ecological story of coccolithophores poses questions about their heterotrophy, surviving darkness after the end-Cretaceous asteroid impact as well as survival in the deep ocean twilight zone. Uptake of dissolved organic carbon might be an alternative nutritional strategy for supply of energy and carbon molecules. Using long-term batch culture experiments, we examined coccolithophore growth and maintenance on organic compounds in darkness. Radiolabelled experiments were performed to study the uptake kinetics. Pulse-chase experiments were used to examine the uptake into unassimilated, exchangeable pools vs assimilated, nonexchangeable pools. We found that coccolithophores were able to survive and maintain their metabolism for up to 30 d in darkness, accomplishing about one cell division. The concentration dependence for uptake was similar to the concentration dependence for growth in Cruciplacolithus neohelis, suggesting that it was taking up carbon compounds and immediately incorporating them into biomass. We recorded net incorporation of radioactivity into the particulate inorganic fraction. We conclude that osmotrophy provides nutritional flexibility and supports long-term survival in light intensities well below threshold for photosynthesis. The incorporation of dissolved organic matter into particulate inorganic carbon, raises fundamental questions about the role of the alkalinity pump and the alkalinity balance in the sea.

Keywords: Cruciplacolithus; Pleurochrysis; acetate; dissolved organic carbon (DOC); glycerol; mannitol; osmotrophy; particulate inorganic carbon (PIC).

Publication types

  • Research Support, U.S. Gov't, Non-P.H.S.

MeSH terms

  • Carbon / metabolism
  • Darkness
  • Dissolved Organic Matter*
  • Haptophyta*
  • Photosynthesis

Substances

  • Dissolved Organic Matter
  • Carbon