Abstract: Emma Hedman
Mentor: Dr. Davis
Recently, Aphids are becoming more and more important as model organisms in developmental biology due to a wide range of polyphenisms, including the so-called reproductive polyphenism. During the summer aphids exist as exclusively female, asexual clonal populations. Female aphids which give rise to more asexual females are known as virginoparae. During the fall, when aphids are exposed to long nights, they will asexually produce a new generation of females known as sexuparae. Sexuparae reproduce asexually, but give rise to females which must reproduce sexually. The details of this process are foggy, and understanding it could be a major step in developmental biology by giving insight into what sorts of molecular responses are responsible for polyphenisms in nature. We do know is that an active signal exists that promotes the production of asexual females, though the nature of the signal is unknown.
One candidate is Juvenile Hormone (JH), as application of JH has been shown to turn sexuparae back into virginoparae. Since previous research continues to show that JH is sufficient to cause the switch from producing sexuals to asexuals, my goal is to prove that it is also necessary. I plan to do this by conducting experiments opposite to the current research, and trying to induce production of sexual offspring in mothers which would typically give rise to asexual offspring by targeting JH production as exclusively as possible. Since JH is suspected of being the asexual signal, it would follow that blocking the production of JH in asexual mothers would make them incapable of continuing the production of asexual offspring in favor of sexuals. We will first try to accomplish this using RNA interference via injections to block the mRNA produced by Juvenile Hormone Acid Methyl Transferase (JHAMT), preventing the production of the protein which is thought to be the rate-determining step in the biosynthesis of JH. I will investigate the expression of JHAMT using quantitative PCR (qPCR) and hope to find which stages of development show most expression of JHAMT. Finally, I might do in situs on brain tissue in the aphids to show explicitly where JHAMT is expressed. By using these three methods, I hope to either credit or discredit JH as a major contributor in the sexual polyphenism. If this research was successful, it would be a major contribution to understanding the underlying role of hormones on phenotypic expression and development.