Medea Selfish Genetic Elements as Tools for Altering Traits of Wild Populations: A Theoretical Analysis

• Main Author: Ward, Catherine Marie
• Format: Others
• Published: 2011
• Online Access: https://thesis.library.caltech.edu/11763/1/CEWard-ThesisDone.pdf; Ward, Catherine Marie (2011) Medea Selfish Genetic Elements as Tools for Altering Traits of Wild Populations: A Theoretical Analysis. Dissertation (Ph.D.), California Institute of Technology. doi:10.7907/T656-ZN91. https://resolver.caltech.edu/CaltechTHESIS:05312011-123357339 <https://resolver.caltech.edu/CaltechTHESIS:05312011-123357339>

Insect-borne diseases kill millions of people annually. One strategy for controlling transmission of insect-borne disease involves replacing the native insect population with transgenic animals unable to transmit disease. Population replacement requires a drive mechanism to ensure the rapid spread of linked transgenes conferring disease refractoriness. Medea selfish genetic elements have the feature that when present in a female, only offspring that inherit the element survive, a behavior that can lead to spread. Here we use modeling to identify conditions under which Medea elements spread. We derive equations describing the allele frequencies required for spread of Medea elements with a fitness cost, and the equilibrium allele frequencies attained. We validate our model against a synthetic Medea element created in Drosophila and find that the model fits the data without parameter fitting. We show that when Medea spreads, it drives the non-Medea genotype out of the population, and we provide estimates of the number of generations required to achieve this goal. We also characterize two contexts in which Medea elements with fitness costs drive the non-Medea allele from the population: an autosomal element in which zygotic rescue is incomplete and an X-linked element in species in which X/Y individuals are male. Finally, we explore costs and benefits associated with the introduction of multiple Medea elements. Our results suggest that Medea elements can drive population replacement under a wide range of conditions, potentially reducing disease burden.