Apolipoprotein A-II regulates HDL stability and affects hepatic lipase association and activity

Jonathan Boucher, Tanya A. Ramsamy, Sylvie Braschi, Daisy Sahoo, Tracey A.M. Neville, and Daniel L. Sparks

University of Ottawa Heart Institute, Ottawa, Ontario K1Y 4W7

Corresponding Author: dsparks{at}ottawaheart.ca

The effects of apolipoprotein (apo)A-II on the structure and stability of HDL has been investigated in reconstituted HDL particles (LpA-I). Purified human apoA-II was incorporated into sonicated, spherical LpA-I particles containing apoA-I, phospholipids (PC) and various amounts of triacylglycerol (TG), diacylglycerol (DG) and/or free cholesterol (FC). While addition of PC to apoA-I reduces the thermodynamic stability of its alpha-helices, PC has the opposite effect on apoA-II and significantly increases its helical stability. Similarly, substitution of apoA-I with various amounts of apoA-II significantly increases the thermodynamic stability of the particle alpha-helical structure. ApoA-II also increases the size and net negative charge of the lipoprotein particles. ApoA-II directly affects apoA-I conformation and increases the immunoreactivity of epitopes in the N- and C-terminus of apoA-I, but decreases the exposure of central domains in the molecule (residues 98-186). ApoA-II appears to increase hepatic lipase (HL) association with HDL and inhibits lipid hydrolysis. ApoA-II mildly inhibited PC hydrolysis in TG-enriched particles, but significantly inhibited DG hydrolysis in DG-rich LpA-I. In addition, apoA-II enhances the ability of reconstituted LpA-I particles to inhibit VLDL-TG hydrolysis by HL. ApoA-II therefore affects both the structure and dynamic behavior of HDL particles and selectively modifies lipid metabolism.

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