Summary
Diatoms are a group of highly diverse, globally dominant microalgae which contribute significantly to global carbon fixation and biogeochemical cycling. Understanding how diatoms adapt to changes in their environment is therefore a major research interest. However, whereas the phenotypic outcomes of adaptation have received considerable attention, we understand little about the genomic underpinnings of evolution and adaptation in diatoms. Within DIADAPT, I will investigate the genomic processes that underlie adaptation to climate shifts in diatoms. To this end, I will focus on two evolutionary radiations of non-model diatoms that are characterized by the repeated colonization of different climate zones throughout their evolutionary history, yet that played out in different ecological conditions: the aquatic and terrestrial realm. Comparative analyses of genomes and transcriptomes obtained from taxa that inhabit polar, temperate, or tropical regions will be complemented with experimental evolution. As such, I will investigate the roles of both genome and gene expression evolution in climate-driven adaptation over macro- and microevolutionary timescales, thus capturing different stages of the adaptation process. By implementing DIADAPT within a robust phylogenetic framework and contrasting the two evolutionary radiations, I will (i) formulate general insights into the genomic basis of climate-driven adaptation in diatoms, (ii) reveal the degree of divergence and repeated evolution in adaptive solutions, and (iii) discern if and how adaptation is constrained by evolutionary history, including differences in ecology, population size, and historical patterns of climate zone transitions. Altogether, the integration of macro- and microevolutionary approaches on the scale of genome and gene expression divergence will generate a deep understanding of climate-driven adaptation in a keystone microbial lineage on an unprecedented geographic and taxonomic scale.
Unfold all
/
Fold all
More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/101160805 |
| Start date: | 01-05-2025 |
| End date: | 30-04-2030 |
| Total budget - Public funding: | 1 500 000,00 Euro - 1 500 000,00 Euro |
Cordis data
Original description
Diatoms are a group of highly diverse, globally dominant microalgae which contribute significantly to global carbon fixation and biogeochemical cycling. Understanding how diatoms adapt to changes in their environment is therefore a major research interest. However, whereas the phenotypic outcomes of adaptation have received considerable attention, we understand little about the genomic underpinnings of evolution and adaptation in diatoms. Within DIADAPT, I will investigate the genomic processes that underlie adaptation to climate shifts in diatoms. To this end, I will focus on two evolutionary radiations of non-model diatoms that are characterized by the repeated colonization of different climate zones throughout their evolutionary history, yet that played out in different ecological conditions: the aquatic and terrestrial realm. Comparative analyses of genomes and transcriptomes obtained from taxa that inhabit polar, temperate, or tropical regions will be complemented with experimental evolution. As such, I will investigate the roles of both genome and gene expression evolution in climate-driven adaptation over macro- and microevolutionary timescales, thus capturing different stages of the adaptation process. By implementing DIADAPT within a robust phylogenetic framework and contrasting the two evolutionary radiations, I will (i) formulate general insights into the genomic basis of climate-driven adaptation in diatoms, (ii) reveal the degree of divergence and repeated evolution in adaptive solutions, and (iii) discern if and how adaptation is constrained by evolutionary history, including differences in ecology, population size, and historical patterns of climate zone transitions. Altogether, the integration of macro- and microevolutionary approaches on the scale of genome and gene expression divergence will generate a deep understanding of climate-driven adaptation in a keystone microbial lineage on an unprecedented geographic and taxonomic scale.Status
SIGNEDCall topic
ERC-2024-STGUpdate Date
25-11-2024
Images
No images available.
Geographical location(s)
