The life cycles of parasitic worms - from macro-evolutionary patterns to the genetics of adaptation


Many parasites have complex life cycles in which they infect multiple hosts in succession before reproducing. These life cycles are perplexing, because they seem risky. As the number of consecutive hosts in a life cycle increases, so does the risk of not making it to the next host and thus not completing the cycle. Additionally, such parasites must adapt to different host physiologies, immune systems, and often thermal regimes (e.g. when moving from cold- to warm-blooded hosts). What are the offsetting benefits that explain the evolution and persistence of complex life cycles in multiple parasite taxa? And what genetic changes enable such a life style? To address these questions, two complementary kinds of projects are proposed: (i) cross-species comparative analyses and (ii) genomic and transcriptomic comparisons. I
have compiled a comprehensive database of parasitic worm life cycles that includes nearly 1000 species. This database will be used to test hypotheses about life cycle evolution, such as whether complex life cycle parasites grow larger or infect a wider variety of hosts. These analyses will identify key differences between simple- and complex-cycle parasites. Then it will be explored how such differences are manifested in parasite genomes. Existing datasets will be used to look for shared genomic features in independent lineages, like gene family expansions or increases in alternative splicing, that would be indicative of general solutions to the problems posed by complex life cycles.
I also describe transcriptomic experiments assessing when and to what extent parasite stages in different hosts are genetically ‘decoupled’, i.e. whether genetic changes affecting a stage in one host have correlated effects on stages in other hosts. By combining phenotypic, genomic, and transcriptomic approaches, I hope to reveal both why (the costs and benefits) and how (the genetic mechanisms of adaptation) complex life cycles have evolved.

Principal investigators
Benesh, Daniel Dr. (Details) (Molecular Parasitology)

Financer
DFG: Eigene Stelle (Sachbeihilfe)

Duration of project
Start date: 05/2019
End date: 12/2022

Research Areas
Evolution, Anthropology, Life Sciences

Research Areas
Organismische Evolution, Parasitologie

Last updated on 2022-07-09 at 19:08