Abstract
Spermatozoa are the most morphologically diverse cell type, leading to the widespread assumption that they evolve rapidly. However, there is no direct evidence that sperm evolve faster than other male traits. Such a test requires comparing male traits that operate in the same selective environment, ideally produced from the same tissue, yet vary in function. Here, we examine rates of phenotypic evolution in sperm morphology using two insect groups where males produce fertile and non-fertile sperm types (Drosophila species from the obscura group and a subset of Lepidoptera species), where these constraints are solved. Moreover, in Drosophila we test the relationship between rates of sperm evolution and the link with the putative selective pressures of fertilization function and postcopulatory sexual selection exerted by female reproductive organs. We find repeated evolutionary patterns across these insect groups—lengths of fertile sperm evolve faster than non-fertile sperm. In Drosophila, fertile sperm length evolved faster than body size, but at the same rate as female reproductive organ length. We also compare rates of evolution of different sperm components, showing that head length evolves faster in fertile sperm while flagellum length evolves faster in non-fertile sperm. Our study provides direct evidence that sperm length evolves more rapidly in fertile sperm, probably because of their functional role in securing male fertility and in response to selection imposed by female reproductive organs.
Highlights
Sperm are the most diverse cell type despite their homologous function across taxa of securing male fertility [1,2]. This diversity suggests sperm evolve rapidly, which is commonly hypothesized to be due to selection for their fertilization function and in response to the postcopulatory processes of sperm competition and selection imposed by the female reproductive tract
Numerous studies demonstrate that sexually selected traits evolve faster than naturally selected ecological and life-history traits (e.g. [6,7,8,9,10]) and phenotypic diversification of sexual traits are exaggerated in species where the strength of sexual selection is stronger (e.g. [11,12,13])
The third study found that sperm midpiece and flagellum length evolved faster in bird lineages where males invested more in testes size, suggesting that postcopulatory sexual selection promotes elevated rates of sperm phenotypic diversification [12]
Summary
Sperm are the most diverse cell type despite their homologous function across taxa of securing male fertility [1,2]. The third study found that sperm midpiece and flagellum length evolved faster in bird lineages where males invested more in testes size (a proxy for sperm competition risk), suggesting that postcopulatory sexual selection promotes elevated rates of sperm phenotypic diversification [12]. As longer sperm are often competitively superior in sperm monomorphic species (e.g. D_melanogaster [28]), we decompose how postcopulatory sexual selection and fertilization may influence evolutionary rates on different sperm components, testing the prediction that flagellum length will exhibit faster evolutionary rates than head length in fertile sperm
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
