Gametes are the ultimate stem cells with the capacity to produce entire new organisms. We study cellular mechanisms of gamete development using Drosophila as a model system. We are focused on the development of female germline cells, from their early differentiation into oocytes or nurse cells, through the control of oocyte growth during oogenesis. In addition, we study the role of ovarian muscles in the progression of developing egg chambers through the ovary.

Areas of interest:
Germline ring canals and oocyte growth.
Early germline development in animals, including flies, relies on a non-canonical form of mitosis. Daughters of germline stem cells undergo a tightly controlled number of mitotic cell divisions with incomplete cytokinesis so that bridges of cytoplasm remain to connect clusters of sister cells. These residual connections are transformed into stable intercellular junctions called ring canals, which are needed for oocyte growth. In females, this transformation involves recruiting a highly dynamic actin cytoskeleton and many associated actin-binding proteins. Using a variety of genetic and molecular approaches, we have identified many ring canal proteins, and we are actively working toward characterizing their functions. We are also studying the role of ring canals in the polarized transport of maternal mRNAs, proteins and organelles from nurse cells and to the oocyte.
Somatic ring canals.
While ring canals are ubiquitous in germline cells, their presence and function in somatic cells are largely unexplored. In order to understand how these fascinating structures contribute to the biology of non-germline cells, we are characterizing somatic ring canals in epithelial cells of the Drosophila ovary and imaginal discs using cell biology and genetics.
Muscle function.
Recently we discovered a novel muscle type in the Drosophila ovary that contains striated sarcomeres, but only a single nucleus. This indicates the muscles did not form by typical myoblast fusion. Importantly, the presence of one nucleus means we can use powerful genetic clonal analysis to analyze the effects of mutations affecting muscle proteins, including those associated with human musclular dystrophy. In addition, we can study proliferation of these muscles in adults and the pool of progenitor stem cells that supply new muscle cells in adults.