Raw regulates glial population of the eye imaginal disc.

Glia are critical for proper development, support, and function of the nervous system. The Drosophila eye has proven an excellent model for gaining significant insight into the molecular mechanisms regulating glial development and function. Recent studies have demonstrated that Raw is required in glia of the central and peripheral nervous systems; however, the function of Raw in glia of the developing eye has not been explored. These studies demonstrate that raw knockdown results in a reduction in the number of glia in the third instar eye imaginal disc and reduced glial spreading across the field of differentiating photoreceptor neurons. Expression of a raw enhancer trap reveals that raw is expressed in eye disc glia. Exploration of the mechanism by which raw knockdown results in glial reduction reveals that Raw is required for glial proliferation and migration into the eye disc. In addition, Raw negatively regulates Jun N-terminal kinase (JNK) signaling in glia of the developing eye and increased JNK signaling results in a reduction in the number of glia populating the eye disc, similar to that observed upon raw knockdown. Thus, Raw functions as a critical regulator of glial population of the eye imaginal disc by regulating glial proliferation and migration and inhibiting JNK signaling.

Prostaglandins limit nuclear actin to control nucleolar function during oogenesis.

Prostaglandins (PGs), locally acting lipid signals, regulate female reproduction, including oocyte development. However, the cellular mechanisms of PG action remain largely unknown. One cellular target of PG signaling is the nucleolus. Indeed, across organisms, loss of PGs results in misshapen nucleoli, and changes in nucleolar morphology are indicative of altered nucleolar function. A key role of the nucleolus is to transcribe ribosomal RNA (rRNA) to drive ribosomal biogenesis. Here we take advantage of the robust, in vivo system of Drosophila oogenesis to define the roles and downstream mechanisms whereby PGs regulate the nucleolus. We find that the altered nucleolar morphology due to PG loss is not due to reduced rRNA transcription. Instead, loss of PGs results in increased rRNA transcription and overall protein translation. PGs modulate these nucleolar functions by tightly regulating nuclear actin, which is enriched in the nucleolus. Specifically, we find that loss of PGs results in both increased nucleolar actin and changes in its form. Increasing nuclear actin, by either genetic loss of PG signaling or overexpression of nuclear targeted actin (NLS-actin), results in a round nucleolar morphology. Further, loss of PGs, overexpression of NLS-actin or loss of Exportin 6, all manipulations that increase nuclear actin levels, results in increased RNAPI-dependent transcription. Together these data reveal PGs carefully balance the level and forms of nuclear actin to control the level of nucleolar activity required for producing fertilization competent oocytes.

Novel tools for genetic manipulation of follicle stem cells in the Drosophila ovary reveal an integrin-dependent transition from quiescence to proliferation.

In many tissues, the presence of stem cells is inferred by the capacity of the tissue to maintain homeostasis and undergo repair after injury. Isolation of self-renewing cells with the ability to generate the full array of cells within a given tissue strongly supports this idea, but the identification and genetic manipulation of individual stem cells within their niche remain a challenge. Here we present novel methods for marking and genetically altering epithelial follicle stem cells (FSCs) within the Drosophila ovary. Using these new tools, we define a sequential multistep process that comprises transitioning of FSCs from quiescence to proliferation. We further demonstrate that integrins are cell-autonomously required within FSCs to provide directional signals that are necessary at each step of this process. These methods may be used to define precise roles for specific genes in the sequential events that occur during FSC division after a period of quiescence.