Abstract 522: Macrophage Galectin 3 Protects Against Atherosclerosis By Promoting Repair, Removal And Replacement Of Damaged Lysosomes

Abstract

Understanding the derangements in cellular processes that underlie macrophage dysfunction is critical to the development of future therapeutics. The autophagy-lysosome system in macrophages plays critical role in the degradation and recycling of long-lived/damaged intracellular material. Atherosclerotic plaque macrophages develop an impairment in autophagy and lysosomes which is a contributing factor to plaque progression. Thus, one can surmise that harnessing programs of lysosomal repair and lysosomal biogenesis in macrophages can have atheroprotective effects. A class of important regulators of the autophagy-lysosomal system are cytosolic lectins. When the lysosome membrane becomes damaged, Galectin-3 (Gal3) recognizes the damage and recruits autophagic receptors and delivers the cargo to autophagosomes. Additionally, Gal3 may recruit the ESCRT complex and facilitate the repair and restoration of lysosomes. We hypothesized that Gal3 provides a protective role in atherogenic macrophages, by repairing or removing damaged lysosomes, thus preventing the relevant deleterious signaling pathways such as inflammasome activation and apoptosis. We utilized Gal3-KO macrophages and mice to study the role of Gal3 in atherosclerosis. First, we show that Gal3-KO macrophages are highly sensitive to lysosome membrane damaging agents including atherogenic oxLDL and cholesterol crystals, exhibiting decreased autophagy and protein aggregate clearance compared to the WT controls. Furthermore, the recruitment of lysosome repair mechanisms involving the ESCRT complex are blunted. Such blunting of critical repair mechanisms results in increased macrophage apoptosis and inflammasome/IL-1β activation. These findings are also recapitulated in vivo, where bone marrow transplants of atherogenic LDLR-null mice with Gal3-deficient bone marrow results in increased plaque size and altered plaque composition with significant macrophage accumulation, apoptosis, and necrotic core formation, characteristic features of advanced plaques. Overall, our data demonstrate important roles for Gal3 in macrophage lysosome repair mechanisms which are a critical response against atherosclerosis.