Abstract
Humans have two major high density lipoprotein (HDL) sub-fractions, HDL(2) and HDL(3), whereas mice have a monodisperse HDL profile. Epidemiological evidence has suggested that HDL(2) is more atheroprotective; however, currently there is no direct experimental evidence to support this postulate. The amino acid sequence of apoA-I is a primary determinant of HDL subclass formation. The majority of the alpha-helical repeats in human apoA-I are proline-punctuated. A notable exception is the boundary between helices 7 and 8, which is located in the transitional segment between the stable N-terminal domain and the C-terminal hydrophobic domain. In this study we ask whether the substitution of a proline-containing sequence (PCS) separating other helices in human apoA-I for the non-proline-containing sequence (NPCS) between helices 7 and 8 (residues 184-190) influences HDL subclass association. The human apoA-I mutant with PCS2 replacing NPCS preferentially bound to HDL(2). In contrast, the mutant where PCS3 replaced NPCS preferentially associated with HDL(3). Thus, the specific amino acid sequence between helices 7 and 8 influences HDL subclass association. The wild-type and mutant proteins exhibited similar physicochemical properties except that the two mutants displayed greater lipid-associated stability versus wild-type human apoA-I. These results focus new attention on the influence of the boundary between helices 7 and 8 on the properties of apoA-I. The expression of these mutants in mice may result in the preferential generation of HDL(2) or HDL(3) and allow us to examine experimentally the anti-atherogenicity of the HDL subclasses.
Highlights
HDL3 cholesterol has an inverse relationship with the incidence of coronary artery disease [1, 2]
We focused on the potential role of proline residues in this region of human apoA-I on high density lipoprotein (HDL) subclass association
Because we previously showed that apoA-I recombinant protein HDL subclass association in vitro parallels HDL generation in vivo [14], this study is designed to examine the capacity of the sequence between putative helices 7 and 8 of human apoA-I to influence its ability to associate with human HDL subclasses
Summary
In this study we ask whether the substitution of a proline-containing sequence (PCS) separating other helices in human apoA-I for the non-prolinecontaining sequence (NPCS) between helices 7 and 8 (residues 184 –190) influences HDL subclass association. We focused on the potential role of proline residues in this region of human apoA-I on HDL subclass association. This supports the contention that the majority of apoA-I is ␣-helical in structure when lipid-associated This includes the region of the protein where we have focused our attention, residues 184 –190. We hypothesize that it is the segment between putative helices 7 and 8 that contributes to the propensity of the apoprotein to associate with the different HDL subclasses each having a different radius of curvature. We ask whether the nature of the sequence between putative helices 7 and 8 influences the ability of human apoA-I to associate with HDL2 or HDL3
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