Aside from few model organisms, little is known about early embryonic development or sex determination in insects, in particular mosquitoes which are major vectors of worldwide disease. The goals of this work were to investigate a mosquito-specific transcription factor and its intronic miRNA cluster and characterize a novel Y chromosome gene in An. stephensi. The aims of these experiments were to expand on the knowledge of genes involved in embryonic development and sex determination with potential application in vector control strategies.

In Ae. aegypti a mosquito-specific bZIP1 transcription factor was demonstrated to be conserved among divergent mosquito species. It was maternally and zygotically-expressed and knock-down of bZIP1 mRNA via siRNA microinjection in the embryo resulted in embryonic death. The expression profile of this gene was determined through the use of RT-PCR and qRT-PCR. Additionally, this gene contains a miRNA cluster that is also relatively conserved amongst members of the Culicidae family suggesting its evolutionary importance. The miRNAs are also maternally and zygotically expressed and are the most abundant embryonic miRNAs as determined by small RNA sequencing and Northern analysis. Promoter activity for bZIP1 was characterized and the promoter was used to direct maternal and zygotic transgene expression in An. stephensi.

Y chromosome genes were successfully identified in An. stephensi from Illumina sequencing data. This work focused on a gene unique to the Y 1 (GUY1). It was shown that GUY1 was male specific and linked to the Y chromosome. RT-PCR and single embryo analysis suggested that GUY1 was expressed during the maternal to zygotic transition and was only expressed in male embryos. It was shown in multiple transient and transgenic assays that the ectopic expression of GUY1 can influence the sex of subjected individuals and skew sex distribution to a male bias.

There is still much to be investigated before a GUY1-based transgenic line can be tested and implemented for use in vector population control. However, the work in this dissertation represents a major step towards novel mosquito control strategies based on the manipulation of Y chromosome genes.