Diatoms encode two forms of flavodoxin with divergent functions that mitigate the oxidative stress and iron requirements associated with life in contemporary oxygenated iron-poor oceans.

Single-cell analysis of the chloroplast redox response to high light and oxidative stress revealed light-dependent heterogeneity, and was linked to cell fate determination within isogenic diatom populations.

An iron-sensitive gene cluster encodes proteins that co-localize with phytotransferrin endosomes and are involved in key intracellular iron transformation and trafficking processes in a model marine diatom.

The molecular mechanisms of FCPI assembly and selective binding are revealed through comparison of PSI-FCPI structures in two diatom species.

An in silico reconstruction of a chloroplast that existed hundreds of millions of years ago casts new insights in the evolutionary processes, endosymbioses and chimerism events that shape the origin of plastids.

High-throughput systemic approaches on long-term trends identify the environmental factors that cause loss of biodiversity and disrupt ecosystem functions.

The combination of holographic microscopy and deep learning provides a revolutionary tool for plankton ecology that will permit researchers to observe and study the life, feeding habits and reproduction of plankton with unprecedented detail.

Characterization of the molecular mechanisms that enable azelaic acid, a secondary metabolite produced by photosynthetic organisms, to promote or inhibit different bacterial populations.

Dynamic successive blooms of clades of planktonic marine bacteria that can be observed during blooms of marine algae follow discernible patterns, part of which might be explained by substrate-induced forcing.