UC Irvine

Metastasis remains the leading cause of cancer mortality but its mitochondrial dysregulation - from its morphology and motility to its metabolic influence - in modulating cancer’s progression is poorly understood. This dissertation describes the development and use of complex microphysiological culture systems to place cancer in its proper environmental context for mitochondrial phenotypic discoveries. FLIM of NADH is used to probe the metabolic differences between invasive and non- or less-invasive cancer cells and elucidate potential invasion-specific therapeutic targets. This dissertation also introduces Mitometer, an algorithm for fast, unbiased, and automated segmentation and tracking of mitochondria in live-cell two-dimensional and three-dimensional time-lapse images. Mitometer finds that mitochondria of triple-negative breast cancer cells are faster, more directional, and more elongated than those in their receptor-positive counterparts. Furthermore, Mitometer shows that mitochondrial motility and morphology in breast cancer, but not in normal breast epithelia, correlate with metabolic activity. Mitometer is then applied to investigate cellular contractility in the influence of mitochondrial phenotype. The goal of this dissertation as a whole is to accentuate the importance of creating new assays and techniques with the impact of context and translatability in mind.