Abstract
Immunometabolic diseases such as obesity, fatty liver, and atherosclerosis arise when lipid-associated macrophages (LAMs) fail to clear excess lipids. Reverse cholesterol transport (RCT), the body's sole macrophage-to-feces lipid-clearance pathway, remains therapeutically inaccessible. By integrating systems modeling with human plaque transcriptomes, we identify LAM subpopulations that drive plaque progression and nominate GIV ( CCDC88A ) as a molecular brake on RCT. Myeloid-specific GIV deletion reduces aortic plaque burden, mobilizes hepatic and adipose lipids, and restores systemic RCT. Mechanistically, GIV traps the efflux transporter ABCA1 in endomembranes and activates Gαi●βγ to suppress cAMP/PKA-CREB signaling, silencing ABCA1 activity. Genetic or pharmacologic disruption of this checkpoint releases ABCA1 to the membrane, reactivating efflux and reprogramming LAMs toward an anti-atherogenic state. In murine and human plaque-in-a-dish models, targeting the GIV●Gαi-cAMP checkpoint restored efflux where statins and β-blockers failed, reducing modeled plaque-progression risk by ∼98%. Findings establish RCT-restoration as a druggable, macrophage-intrinsic therapeutic paradigm for immunometabolic disease. ETOC BLURB: Lipid-associated macrophages drive immunometabolic disease. Katkar et al. show that disabling a GIV-dependent G-protein brake restores cholesterol efflux, reverses plaque lipid accumulation, and establishes reverse cholesterol transport as a druggable therapeutic axis. HIGHLIGHTS: Statins slow but rarely reverse plaque burden, leaving residual risk driven by LAM dysfunctionGIV (CCDC88A) non-canonically modulates Gαi to suppress macrophage cholesterol effluxGIV loss or inhibition restores ABCA1 activity via transcriptional and post-translational controlBlocking the GIV●Gαi checkpoint defats LAMs, regresses plaques, and relieves systemic lipid overloadIdentifies a druggable node that redefines RCT restoration as a therapeutic paradigm in immunometabolic disease.