Selective Targeting of Kinesin on Lipid Droplets in the Liver Reduces Serum Lipids

The liver controls plasma lipids by secreting lipid-rich very low density lipoproteins (VLDL) into blood. Inside hepatocytes in the liver, Lipid Droplets (LDs) are transported to the smooth Endoplasmic Reticulum (sER) by kinesin-1 motors, and then catabolized in the sER to supply lipids for VLDL assembly. LDs are the only cellular organelle bounded by a phospholipid monolayer, and are thus distinct from all other (bilayer-bounded) organelles. It is therefore plausible that a given protein can bind to the LD membrane using mechanisms that are completely different from all other organelles. Indeed, here we find that kinesin-1 uses its tail domain to bind LDs, but alternative mechanisms to bind other organelles. A peptide corresponding to kinesin’s tail domain therefore competes with, and removes kinesin-1 selectively from LDs with minimal effect on other organelles. Delivery of lipids for VLDL assembly is consequently reduced, causing a remarkable reduction of ∼50% of secreted lipids (triglycerides and cholesterol) in cell culture. We further develop Orally fed Egg-liposomes as a method to deliver kinesin tail domain peptide to the liver of Zebrafish. The peptide reverses diet-induced hyperlipidaemia in Zebrafish larvae and brings the larvae back to a normolipidaemic state, thus confirming the effectiveness of our method in a physiologically relevant in-vivo situation. Strikingly, the peptide causes no unwanted accumulation of lipids in the liver, no toxicity and no developmental or behavioural defects in Zebrafish. Using a peptide to displace proteins (e.g. kinesin) selectively from LDs provides a conceptually novel and radically different approach against hyperlipidaemia. This monolayer-versus-bilayer strategy can be potentially extended to target other LD-bound proteins that function as key regulators of Lipid metabolism.