SubsidieMeestersMajor transitions made easy? In search of genetic preconditions that help the repeated evolution and loss of fungal multicellularity
This project investigates the genetic mechanisms of convergent evolution in fungi by testing if precursor traits facilitate transitions to multicellularity through experimental and comparative methods.
Projectdetails
Introduction
In this project, we aim to study the genetic mechanisms of convergent evolution by uncovering the mechanistic details of two highly replicated transitions in organismal complexity. Convergent evolution is widespread in nature, even on macroevolutionary timescales.
Background
To explain its pervasiveness, recent studies have proposed the idea of predisposing precursor traits that, if easily co- or exapted for new functions, can increase the likelihood of convergence. However, most of these hypotheses remain untested because of the lack of tractable model systems.
Case Studies
We identified two fungal case studies that offer optimal model systems to mechanistically test the hypothesis that precursor traits increase the likelihood of convergence:
- 8-11 repeated origins of complex multicellularity in mushrooms
-
14 losses of multicellularity in yeast-like fungi
Hypotheses
We hypothesize that both of these occurred by the repeated exaptation of ancient morphogenetic programs and, in the case of yeasts, additionally, by the emergence of mechanisms for bypassing multicellular growth. Our hypotheses imply that both complex multicellular and yeast-like lifestyles are only a few mutations away for any filamentous fungus because precursor traits shorten the mutational path for evolution.
Preliminary Results
Although these are bold hypotheses, we obtained promising preliminary results that support them.
Experimental Plan
We designed an experimental plan involving phylogeny-aware comparative -omics, reverse genetics, and evo-devo, which, when combined with our preliminary results, will provide a robust entry point for testing the role of predisposition in convergent evolution.
Conclusion
Ultimately, this project will allow us to “replay the tape of major fungal transitions” in the laboratory. We expect this project to contribute to uncovering the general principles of convergent evolution and to be one of the first to mechanistically test if certain precursor traits can promote convergence.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 1.997.688 |
| Totale projectbegroting | € 1.997.688 |
Tijdlijn
| Startdatum | 1-7-2023 |
| Einddatum | 30-6-2028 |
| Subsidiejaar | 2023 |
Partners & Locaties
Projectpartners
- HUN-REN SZEGEDI BIOLOGIAI KUTATOKOZPONTpenvoerder
Land(en)
Vergelijkbare projecten binnen European Research Council
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From cell shape to organism shape: the cellular basis for the evolutionary origin of animal morphogenesis
This project investigates the evolution of cellular mechanisms in animal morphogenesis by studying choanoflagellates, aiming to uncover insights into pre-metazoan developmental gene functions.
Search for the missing unicellular relatives of animals
This project aims to explore and characterize novel lineages of unicellular relatives of animals using long-read metabarcoding to enhance understanding of animal origins and multicellularity.
Revealing an active mechanism of horizontal gene transfer in fungi
This project aims to investigate the role of novel transposable elements, called Starships, in facilitating horizontal gene transfer among eukaryotes, potentially reshaping our understanding of evolution.
Evolutionary mechanisms of gene regulation in dynamic environments
This project aims to uncover how gene regulation evolves in dynamic environments by analyzing mutational effects and selective advantages using high-throughput transcriptomic profiling in yeast.
Dissecting the molecular mechanisms of cellular heterogeneity controlling infection-associated development in plant pathogenic fungi
This project aims to uncover the molecular mechanisms of cellular heterogeneity in Magnaporthe oryzae spores to identify virulence factors critical for its infection process.