Abstract There is an association between increased lipid accumulation and aggressive breast cancer phenotypes, and therefore poorer clinical outcomes. The mechanism by which dysregulated lipid metabolism may promote metastasis remains incompletely understood. Several potential mechanisms by which the neutral lipid storage organelles, cytoplasmic lipid droplets, may promote metastasis include utilization of fatty acids (FAs) for oxidation, protection against lipotoxcity, and production of lipid signaling mediators. We have previously demonstrated that metastatic MCF10CA1a mammary cancer cells rely on fatty acid oxidation (FAO) compared to non-metastatic MCF10A-ras cells, using etomoxir to inhibit the rate-limiting enzyme of FAO, carnitine palmitoyltransferase 1 (CPT1). Previous literature indicates that there is an increase in various lipid metabolism pathways, including FA uptake, de novo lipogenesis, and FA storage in neutral lipid. We found that there is no significant difference between palmitic acid uptake between the non-metastatic and metastatic cells. In the current study, we show that MCF10CA1a cells have significantly higher levels of carbon incorporation into palmitic and oleic FAs from 13C-acetate (25% and 20% greater), 13C-glucose (21% and 11% greater), and 13C-lactate (29% and 22% greater) respectively, compared to the MCF10A-ras cells, as detected by LC-MS/MS. In order to determine the source of FAs that contributes to the migration-dependent FAO, we assessed MCF10CA1a cell migration following inhibition of lipolysis (adipose triglyceride lipase—ATGL; ATGListatin) alone or in combination with the FAO inhibitor, etomoxir. We determined that inhibition of ATGL, the initial enzyme of triglyceride lipolysis pathway, significantly reduces MCF10CA1a cell migration (20% decrease compared to vehicle). Inhibition of FAO and lipolysis did not induce additional reduction in cell migration. We also showed that MCF10CA1a cells are more dependent on FA metabolism than the non-metastatic MCF10A-ras cells, demonstrated by MCF10CA1a cells having a greater decrease in cell viability compared to the MCF10A-ras cells given each FA metabolism inhibition (p<0.05: 22% greater decrease for FAO inhibition and 16% greater decrease for dual FAO and lipolysis inhibition, p=0.05: 17% greater decrease for FA synthesis inhibition). These data suggest that metastatic MCF10CA1a cells rely on their increased FA metabolism to survive and migrate, and specifically that the catabolism of FAs from triglyceride supports the FAO-driven migration of metastatic cancer cells. Citation Format: Chaylen Andoline, Parik Pawar, Dorothy Teegarden. Differential lipid metabolism in mammary cancer cell progression [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. Philadelphia (PA): AACR; Cancer Res 2021;81(13_Suppl):Abstract nr 2326.