Abstract
Mitogen-activated protein kinase (MAPK) pathways are central cellular signalling mechanisms in all eukaryotes. They are key regulators of the cell cycle and stress responses, yet evolution of MAPK families took markedly different paths in the animal and plant kingdoms. Instead of the characteristic divergence of MAPK types in animals, in plants an expanded network of ERK-like MAPKs has emerged. To gain insight into the early evolution of the plant MAPK family we identified and analysed MAPKs in 13 representative species across green algae, a large and diverse early-diverging lineage within the plant kingdom. Our results reveal that the plant MAPK gene family emerged from three types of progenitor kinases, which are ubiquitously present in algae, implying their formation in an early ancestor. Low number of MAPKs is characteristic across algae, the few losses or duplications are associated with genome complexity rather than habitat ecology, despite the importance of MAPKs in environmental signalling in flowering plants. ERK-type MAPKs are associated with cell cycle regulation in opisthokont models, yet in plants their stress-signalling function is more prevalent. Unicellular microalgae offer an excellent experimental system to study the cell cycle, and MAPK gene expression profiles show CDKB-like peaks around S/M phase in synchronised Chlamydomonas reinhardtii cultures, suggesting their participation in cell cycle regulation, in line with the notion that the ancestral eukaryotic MAPK was a cell cycle regulator ERK-like kinase. Our work also highlights the scarcity of signalling knowledge in microalgae, in spite of their enormous ecological impact and emerging economic importance.
Highlights
The mitogen-activated protein kinase (MAPK) pathways are pivotal regulatory mechanisms in all eukaryotes[1]
ERK-type Mitogen-activated protein kinase (MAPK) pathways in yeast and animals mainly function in cell cycle regulatory roles and many cancer models are associated with mutations of the ERK pathway, whereas stress signalling is predominantly associated with other pathways, such as p38 and JNK
MAPK pathways are key signal transduction mechanisms in apparently all eukaryotes. Fungi and plants they were identified in protists, such as Dictyostelium discoideum[26] or Naegleria gruberi[5], implying the formation of MAPK signalling in the last eukaryotic common ancestor (LECA)
Summary
The mitogen-activated protein kinase (MAPK) pathways are pivotal regulatory mechanisms in all eukaryotes[1]. ERK-type MAPK pathways in yeast and animals mainly function in cell cycle regulatory roles and many cancer models are associated with mutations of the ERK pathway, whereas stress signalling is predominantly associated with other pathways, such as p38 and JNK. Photosynthetic green microalgae (Chlorophyta) are a large and diverse, early diverging group within the plant kingdom (Viridiplantae), consisting of uni- and multi-cellular species, which are distributed across a wide range of physiological and ecological conditions. At this point the use of algae for biofuels is hindered by high costs of the biomass production Novel approaches such as usage of wastewater instead of fertilisers, and most importantly usage of waste CO2 for supporting algal growth bring the double benefits of decreasing the price of algal biomass and bioremediating waste water and CO2. Physiological knowledge obtained from photosynthetic microalgae has implications for the evolution of these processes in the plant kingdom
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