Project Summary: The centrosome is a membraneless organelle comprising a pair of centrioles surrounded by pericentriolar material, which nucleates microtubules to direct cellular trafficking and mitosis. Cancer cells frequently possess extra or aberrant centrosomes, which are associated with poor prognosis. Multiple mechanisms for centrosome overexpansion in cancer cells are proposed, including failures in cytokinesis and unregulated centrosome duplication. Centrosome amplification produces erroneous mitotic spindles, which lead to chromosomal segregation defects, contributing to tumorigenesis and cancer progression. Drosophila neural stem cells (NSCs) represent a genetically tractable model to study mechanisms by which centrosomes assure proper mitotic potency. High grade brain cancers frequently exhibit centrosome amplifications, illustrating how the Drosophila NSC model system informs foundational cancer cell biology. NSCs undergo repeated rounds of asymmetric cell division along an invariant apical-basal polarity axis to regenerate a self-renewing stem cell and a daughter cell fated for differentiation. Our lab recently discovered that loss of the RNA-binding protein Orb2 results in centrosome amplification, dysregulation of centrosome asymmetry, and spindle alignment errors in NSCs, but the mechanisms behind these defects remain elusive. Orb2 is a conserved cytoplasmic polyadenylation element binding protein (CPEB) ortholog involved in the translational regulation of mRNAs. I hypothesize that Orb2 represses the translation of specific centrosome and spindle-associated RNAs to control NSC asymmetric cell division. Importantly, my preliminary data show that the basal centrosome is hyperactivated in orb2 null NSCs. To determine the mechanism by which Orb2 influences asymmetric centrosome maturation (Aim1), I will 1) test whether Orb2 represses the translation of the centrosome activation targets aurA, polo, cnb, or wdr62, and 2) determine if Orb2 requires RNA-binding activity to promote NSC centrosome asymmetry. To determine the mechanism by which Orb2 influences spindle alignment and centrosome segregation (Aim2), I will 1) test whether Orb2 represses the translation of spindle stability targets msps, tacc, or eb1; and 2) live image control and orb2 null NSCs to characterize the formation of dysmorphic spindles and supernumerary centrosomes. This proposed study will reveal how centrosome and mitotic asymmetry is guided by translational control of centrosome and spindle proteins, providing insight into how post transcriptional regulation of the centrosome cycle can lead to cancer.