A synthetic peptide mimic of plasma apolipoprotein E that binds the LDL receptor.

Human plasma apolipoprotein E (apoE) is a low density lipoprotein (LDL) receptor ligand. It targets cholesterol-rich lipoproteins to LDL receptors on both hepatic and peripheral cells. The region of apoE responsible for its binding to the LDL receptor has been localized to amino acids 140-160. An apoE 141-155 monomeric peptide and a dimeric 141-155 tandem peptide were synthesized and tested for their inhibition of 125I-LDL degradation by human fibroblasts and human monocytic-like cells, THP-1. The monomer had no activity at 250 microM, but the dimer inhibited 125I-LDL degradation by 50% at 5 microM. The inhibition was specific for the LDL receptor because the dimer did not inhibit the degradation of 125I-acetylated LDL by scavenger receptors expressed by phorbol ester-stimulated THP-1 cells. As reported for native apoE, amino acid substitutions of Lys-143----Ala, Leu-144----Pro, and Arg-150----Ala decreased the inhibitory effectiveness of the dimer. Furthermore, a trimer of the 141-155 sequence had a 20-fold greater inhibitory activity than the dimer. Studies with a radioiodinated dimer indicated that some of the inhibitory activity could be a result of the interaction of the dimer with LDL. However, direct binding of the 125I-dimeric peptide to THP-1 cells was observed as well. This binding was time-dependent, linear with increasing cell number, Ca(2+)- but not Mg(2+)-dependent, saturable, inhibited by lipoproteins, and increased by preculture of the cells in lipoprotein-depleted medium. Therefore, a synthetically prepared dimeric repeat of amino acid residues 141-155 of apoE binds the LDL receptor.     

The lipid-associated conformation of the low density lipoprotein receptor binding domain of human apolipoprotein E

Apolipoprotein E (apoE) is a 34-kDa exchangeable apolipoprotein that regulates metabolism of plasma lipoproteins by functioning as a ligand for members of the LDL receptor family. The receptor-binding region localizes to the vicinity of residues 130-150 within its independently folded 22-kDa N-terminal domain. In the absence of lipid, this domain exists as a receptor-inactive, globular four-helix bundle. Receptor recognition properties of this domain are manifest upon lipid association, which is accompanied by a conformational change in the protein. Fluorescence resonance energy transfer has been used to monitor helix repositioning, which accompanies lipid association of the apoE N-terminal domain. Site-directed mutagenesis was used to replace naturally occurring Trp residues with phenylalanine, creating a Trp-null apoE3 N-terminal domain (residues 1-183). Subsequently, tyrosine residues in helix 2, helix 3, or helix 4 were converted to Trp, generating single Trp mutant proteins. The lone cysteine at position 112 was covalently modified with N-iodoacetyl-N'-(5-sulfo-1-naphthyl)ethylenediamine, which serves as an energy acceptor from excited tryptophan residues. Fluorescence resonance energy transfer analysis of apoE N-terminal domain variants in phospholipid disc complexes suggests that the helix bundle opens to adopt a partially extended conformation. A model is presented that depicts a tandem arrangement of the receptor-binding region of the protein in the disc complex, corresponding to its low density lipoprotein receptor-active conformation.     

Semisynthesis and segmental isotope labeling of the apoE3 N-terminal domain using expressed protein ligation

Apolipoprotein E (apoE) is an exchangeable apolipoprotein that functions as a ligand for members of the LDL receptor family, promoting lipoprotein clearance from the circulation. Productive receptor binding requires that apoE adopt an LDL receptor-active conformation through lipid association, and studies have shown that the 22 kDa N-terminal (NT) domain (residues 1–183) of apoE is both necessary and sufficient for receptor interaction. Using intein-mediated expressed protein ligation (EPL), a semisynthetic apoE3 NT has been generated for use in structure-function studies designed to probe the nature of the lipid-associated conformation of the protein. Circular dichroism spectroscopy of EPL-generated apoE3 NT revealed a secondary structure content similar to wild-type apoE3 NT. Likewise, lipid and LDL receptor binding studies revealed that EPL-generated apoE3 NT is functional. Subsequently, EPL was used to construct an apoE3 NT enriched with ¹⁵N solely and specifically in residues 112–183. ¹H-¹⁵N heteronuclear single quantum correlation spectroscopy experiments revealed that the ligation product is correctly folded in solution, adopting a conformation similar to wild-type apoE3-NT. The results indicate that segmental isotope labeling can be used to define the lipid bound conformation of the receptor binding element of apoE as well as molecular details of its interaction with the LDL receptor.     

Modulation of the lipid binding properties of the N-terminal domain of human apolipoprotein E3.

Apolipoprotein E (apoE) plays a critical role in plasma lipid homeostasis through its function as a ligand for the low-density lipoprotein (LDL) receptor family. Receptor recognition is mediated by residues 130-150 in the independently folded, 22-kDa N-terminal (NT) domain. This elongated globular four-helix bundle undergoes a conformational change upon interaction with an appropriate lipid surface. Unlike other apolipoproteins, apoE3 NT failed to fully protect human LDL from aggregation induced by treatment with phospholipase C. Likewise, in dimyristoylglycerophosphocholine (Myr2Gro-PCho) vesicle transformation assays, 100 microg apoE3 NT induced only 15% reduction in vesicle (250 microg) light scattering intensity after 30 min. ApoE3 NT interaction with modified lipoprotein particles or Myr2Gro-PCho vesicles was concentration-dependent whereas the vesicle transformation reaction was unaffected by buffer ionic strength. In studies with the anionic phospholipid dimyristoylglycerophosphoglycerol, apoE3 NT-mediated vesicle transformation rates were enhanced > 10-fold compared with Myr2Gro-PCho and activity decreased with increasing buffer ionic strength. Solution pH had a dramatic effect on the kinetics of apoE3 NT-mediated Myr2Gro-PCho vesicle transformation with increased rates observed as a function of decreasing pH. Fluorescence studies with a single tryptophan containing apoE3 NT mutant (L155W) revealed increased solvent exposure of the protein interior at pH values below 4.0. Similarly, fluorescent dye binding experiments with 8-anilino-1-naphthalene sulfonate revealed increased exposure of apoE3 NT hydrophobic interior as a function of decreasing pH. These studies indicate that apoE3 NT lipid binding activity is modulated by lipid surface properties and protein tertiary structure.     

Lipid-bound structure of an apolipoprotein E-derived peptide

Apolipoprotein (apo) E regulates plasma lipid homeostasis through its ability to interact with the low density lipoprotein (LDL) receptor family. Whereas apoE is not a ligand for receptor binding in buffer alone, interaction with lipid confers receptor recognition properties. To investigate the nature of proposed lipid binding-induced conformational changes in apoE, we employed multidimensional heteronuclear NMR spectroscopy to determine the structure of an LDL receptor-active, 58-residue peptide comprising residues 126-183 of apoE in association with the micelle-forming lipid dodecylphosphocholine (DPC). In the presence of 34 mm DPC the peptide forms a continuous amphipathic helix from Glu131 to Arg178. NMR relaxation studies of DPC-bound apoE-(126-183), in contrast to apoE-(126-183) in the presence of TFE, are consistent with an isotropically tumbling peptide in solution giving a global correlation time of approximately 12.5 ns. These data indicate that the helical peptide is curved and constrained by a lipid micelle consisting of approximately 48 DPC molecules. Although the peptide behaves as if it were tumbling isotropically, spectral density analysis reveals that residues 150-183 have more motional freedom than residues 134-149. These molecular and dynamic features are discussed further to provide insight into the structural basis for the interaction between apoE and the ligand binding repeats of the LDL receptor.     

Human apolipoprotein E7:lysine mutations in the carboxy-terminal domain are directly responsible for preferential binding to very low density lipoproteins

Apolipoprotein E7 (apoE7) (apoE3 E244K/E245K) is a naturally occurring mutant in humans that is associated with increased plasma lipid levels and accelerated atherosclerosis. It is reported to display defective binding to low density lipoprotein (LDL) receptors, high affinity binding for heparin, and like apoE4, preferential association with very low density lipoproteins (VLDL). There are two potential explanations for the preference of apoE7 for VLDL: lysine mutations, which occur in the major lipid-binding region (residues 244-272) of the carboxy-terminal domain of apoE7, could either directly determine the lipoprotein-binding preference or could interact with negatively charged residues in the amino-terminal domain, resulting in a domain interaction similar to that in apoE4 (interaction of Arg-61 with Glu-255), which is responsible for the apoE4 VLDL preference. To distinguish between these possibilities, we determined the binding preferences of recombinant apoE7 and two amino-terminal domain mutants, apoE7 (E49Q/E50Q) and apoE7 (D65N/E66Q), to VLDL-like emulsion particles. ApoE7 and both mutants displayed a higher preference for the emulsion particles than did apoE3, indicating that the carboxy-terminal lysine mutations in apoE7 are directly responsible for its preference for VLDL. Supporting this conclusion, the carboxy-terminal domain 12-kDa fragment of apoE7 (residues 192;-299) displayed a higher preference for VLDL emulsions than did the wild-type fragment. In addition, lipid-free apoE7 had a higher affinity for heparin than did apoE. However, when apoE7 was complexed with dimyristoylphosphatidylcholine or VLDL emulsions, the affinity difference was eliminated. In contrast to previous studies, we found that apoE7 does not bind defectively to the LDL receptor, as determined in both cell culture and solid-phase assays.We conclude that the two additional lysine residues in the carboxy-terminal domain of apoE7 directly alter its lipid- and heparin-binding affinities. These characteristics of apoE7 could contribute to its association with increased plasma lipid levels and atherosclerosis.     

Characterization of the heparin binding sites in human apolipoprotein E

Apolipoprotein (apo) E mediates lipoprotein remnant clearance via interaction with cell-surface heparan sulfate proteoglycans. Both the 22-kDa N-terminal domain and 10-kDa C-terminal domain of apoE contain a heparin binding site; the N-terminal site overlaps with the low density lipoprotein receptor binding region and the C-terminal site is undefined. To understand the molecular details of the apoE-heparin interaction, we defined the microenvironments of all 12 lysine residues in intact apoE3 and examined their relative contributions to heparin binding. Nuclear magnetic resonance measurements showed that, in apoE3-dimyristoyl phosphatidylcholine discs, Lys-143 and -146 in the N-terminal domain and Lys-233 in the C-terminal domain have unusually low pK(a) values, indicating high positive electrostatic potential around these residues. Binding experiments using heparin-Sepharose gel demonstrated that the lipid-free 10-kDa fragment interacted strongly with heparin and a point mutation K233Q largely abolished the binding, indicating that Lys-233 is involved in heparin binding and that an unusually basic lysine microenvironment is critical for the interaction with heparin. With lipidated apoE3, it is confirmed that the Lys-233 site is completely masked and the N-terminal site mediates heparin binding. In addition, mutations of the two heparin binding sites in intact apoE3 demonstrated the dominant role of the N-terminal site in the heparin binding of apoE even in the lipid-free state. These results suggest that apoE interacts predominately with cell-surface heparan sulfate proteoglycans through the N-terminal binding site. However, Lys-233 may be involved in the binding of apoE to certain cell-surface sites, such as the protein core of biglycan.     

Effect of arginine 172 on the binding of apolipoprotein E to the low density lipoprotein receptor

The region of apolipoprotein E (apoE) that interacts directly with the low density lipoprotein (LDL) receptor lies in the vicinity of residues 136-150, where lysine and arginine residues are crucial for full binding activity. However, defective binding of carboxyl-terminal truncations of apoE3 has suggested that residues in the vicinity of 170-183 are also important. To characterize and define the role of this region in LDL receptor binding, we created either mutants of apoE in which this region was deleted or in which arginine residues within this region were sequentially changed to alanine. Deletion of residues 167-185 reduced binding activity (15% of apoE3), and elimination of arginines at positions 167, 172, 178, and 180 revealed that only position 172 affected binding activity (2% of apoE3). Substitution of lysine for Arg(172) reduced binding activity to 6%, indicating a specific requirement for arginine at this position. The higher binding activity of the Delta167-185 mutant relative to the Arg(172) mutant (15% versus 2%) is explained by the fact that arginine residues at positions 189 and 191 are shifted in the deletion mutant into positions equivalent to 170 and 172 in the intact protein. Mutation of these residues and modeling the region around these residues suggested that the influence of Arg(172) on receptor binding activity may be determined by its orientation at a lipid surface. Thus, the association of apoE with phospholipids allows Arg(172) to interact directly with the LDL receptor or with other residues in apoE to promote its receptor-active conformation.     

Anti- and pro-oxidant effects of quercetin in copper-induced low density lipoprotein oxidation. Quercetin as an effective antioxidant against pro-oxidant effects of urate.

We recently reported that, depending on its concentration, urate is either a pro- or an antioxidant in Cu(2+)-induced low-density lipoprotein (LDL) oxidation. We also previously demonstrated an antioxidant synergy between urate and some flavonoids in the Cu(2+)-induced oxidation of diluted serum. As a result, the effect of the flavonoid quercetin on the Cu(2+)-induced oxidation of isolated LDL has been studied either in the presence or absence of urate. We demonstrate that, like urate, quercetin alone, at low concentration, exhibits a pro-oxidant activity. The pro-oxidant behavior depends on the Cu(2+) concentration but it is not observed at high Cu(2+) concentration. When compared with urate, the switch between the pro- and the antioxidant activities occurs at much lower quercetin concentrations. As for urate, the pro-oxidant character of quercetin is related to its ability to reduce Cu(2+) with the formation of semioxidized quercetin and Cu(+) with an expected yield larger than that obtained with urate owing to a more favorable redox potential. It is also shown that the pro-oxidant activity of urate can be inhibited by quercetin. An electron transfer between quercetin and semioxidized urate leading to the repair of urate could account for this observation as suggested by recently published pulse radiolysis data. It is anticipated that the interactions between quercetin-Cu(2+)-LDL and urate, which are tightly controlled by their respective concentration, determine the balance between the pro- and antioxidant behaviors. Moreover, as already observed with other antioxidants, it is demonstrated that quercetin alone behaves as a pro-oxidant towards preoxidized LDL.     

Fluorescence analysis of the lipid binding-induced conformational change of apolipoprotein e4

Apolipoprotein (apo) E is thought to undergo conformational changes in the N-terminal helix bundle domain upon lipid binding, modulating its receptor binding activity. In this study, site-specific fluorescence labeling of the N-terminal (S94) and C-terminal (W264 or S290) helices in apoE4 by pyrene maleimide or acrylodan was employed to probe the conformational organization and lipid binding behavior of the N- and C-terminal domains. Guanidine denaturation experiments monitored by acrylodan fluorescence demonstrated the less organized, more solvent-exposed structure of the C-terminal helices compared to the N-terminal helix bundle. Pyrene excimer fluorescence together with gel filtration chromatography indicated that there are extensive intermolecular helix-helix contacts through the C-terminal helices of apoE4. Comparison of increases in pyrene fluorescence upon binding of pyrene-labeled apoE4 to egg phosphatidylcholine small unilamellar vesicles suggests a two-step lipid-binding process; apoE4 initially binds to a lipid surface through the C-terminal helices followed by the slower conformational reorganization of the N-terminal helix bundle domain. Consistent with this, fluorescence resonance energy transfer measurements from Trp residues to acrylodan attached at position 94 demonstrated that upon binding to the lipid surface, opening of the N-terminal helix bundle occurs at the same rate as the increase in pyrene fluorescence of the N-terminal domain. Such a two-step mechanism of lipid binding of apoE4 is likely to apply to mostly phospholipid-covered lipoproteins such as VLDL. However, monitoring pyrene fluorescence upon binding to HDL(3) suggests that not only apoE-lipid interactions but also protein-protein interactions are important for apoE4 binding to HDL(3).     

Lipid binding-induced conformational change in human apolipoprotein E. Evidence for two lipid-bound states on spherical particles

Apolipoprotein (apo) E contains two structural domains, a 22-kDa (amino acids 1-191) N-terminal domain and a 10-kDa (amino acids 223-299) C-terminal domain. To better understand apoE-lipid interactions on lipoprotein surfaces, we determined the thermodynamic parameters for binding of apoE4 and its 22- and 10-kDa fragments to triolein-egg phosphatidylcholine emulsions using a centrifugation assay and titration calorimetry. In both large (120 nm) and small (35 nm) emulsion particles, the binding affinities decreased in the order 10-kDa fragment approximately 34-kDa intact apoE4 > 22-kDa fragment, whereas the maximal binding capacity of intact apoE4 was much larger than those of the 22- and 10-kDa fragments. These results suggest that at maximal binding, the binding behavior of intact apoE4 is different from that of each fragment and that the N-terminal domain of intact apoE4 does not contact lipid. Isothermal titration calorimetry measurements showed that apoE binding to emulsions was an exothermic process. Binding to large particles is enthalpically driven, and binding to small particles is entropically driven. At a low surface concentration of protein, the binding enthalpy of intact apoE4 (-69 kcal/mol) was approximately equal to the sum of the enthalpies for the 22- and 10-kDa fragments, indicating that both the 22- and 10-kDa fragments interact with lipids. In a saturated condition, however, the binding enthalpy of intact apoE4 (-39 kcal/mol) was less exothermic and rather similar to that of each fragment, supporting the hypothesis that only the C-terminal domain of intact apoE4 binds to lipid. We conclude that the N-terminal four-helix bundle can adopt either open or closed conformations, depending upon the surface concentration of emulsion-bound apoE.     

Structure-guided protein engineering modulates helix bundle exchangeable apolipoprotein properties

Apolipoprotein (apo) E plays a major role in lipid metabolism by mediating cellular uptake of lipoprotein particles through interaction with members of the low density lipoprotein (LDL) receptor family. The primary region of apoE responsible for receptor binding has been limited to a cluster of basic amino acids between residues 134 and 150, located in the fourth helix of the N-terminal domain globular helix bundle structure. To investigate structural and functional requirements of this "receptor binding region" we engineered an apolipoprotein chimera wherein residues 131-151 of human apoE were substituted for residues 146-166 (helix 5) of Manduca sexta apolipophorin III (apoLp-III). Recombinant hybrid apolipoprotein was expressed in Escherichia coli, isolated, and characterized. Hybrid apolipoprotein and apoE3-N-terminal, but not apoLp-III, bound to heparin-Sepharose. Far UV circular dichroism spectroscopy revealed the presence of predominantly alpha-helix secondary structure, and stability studies revealed a urea denaturation midpoint of 1.05 m, similar to wild-type apoLp-III. Hybrid apolipoprotein-induced dimyristoylphosphatidylcholine (DMPC) bilayer vesicle solubilization activity was significantly enhanced compared with either parent protein, consistent with detection of solvent-exposed hydrophobic regions on the protein in fluorescent dye binding experiments. Unlike wild-type apoLp-III.DMPC complexes, disc particles bearing the hybrid apolipoprotein competed with 125ILDL for binding to the LDL receptor on cultured human skin fibroblasts. We conclude that a hybrid apolipoprotein containing a key receptor recognition element of apoE preserves the structural integrity of the parent protein while conferring a new biological activity, illustrating the potential of helix swapping to introduce desirable biological properties into unrelated or engineered apolipoproteins.     

Replacement of helix 1' enhances the lipid binding activity of apoE3 N-terminal domain

The N-terminal domain of human apolipoprotein E (apoE-NT) harbors residues critical for interaction with members of the low-density lipoprotein receptor (LDLR) family. Whereas lipid free apoE-NT adopts a stable four-helix bundle conformation, a lipid binding induced conformational adaptation is required for manifestation of LDLR binding ability. To investigate the structural basis for this conformational change, the short helix connecting helix 1 and 2 in the four-helix bundle was replaced by the sequence NPNG, introducing a beta-turn. Recombinant helix-to-turn (HT) variant apoE3-NT was produced in Escherichia coli, isolated and characterized. Stability studies revealed a denaturation transition midpoint of 1.9 m guanidine hydrochloride for HT apoE3-NT vs. 2.5 M for wild-type apoE3-NT. Wild-type and HT apoE3-NT form dimers in solution via an intermolecular disulfide bond. Native PAGE showed that reconstituted high-density lipoprotein prepared with HT apoE3-NT have a diameter in the range of 9 nm and possess binding activity for the LDLR on cultured human skin fibroblasts. In phospholipid vesicle solubilization assays, HT apoE3-NT was more effective than wild-type apoE3-NT at inducing a time dependent decrease in dimyristoylphosphatidylglycerol vesicle light scattering intensity. In lipoprotein binding assays, HT apoE3-NT protected human low-density lipoprotein from phospholipase C induced aggregation to a greater extent that wild-type apoE3-NT. The results indicate that a mutation at one end of the apoE3-NT four-helix bundle markedly enhances the lipid binding activity of this protein. In the context of lipoprotein associated full-length apoE, increased lipid binding affinity of the N-terminal domain may alter the balance between receptor-active and -inactive conformational states.     

NMR structure and dynamics of a receptor-active apolipoprotein E peptide

Apolipoprotein E (apoE) is important in lipid metabolism due to its interaction with members of the low density lipoprotein (LDL) receptor family. ApoE is able to interact with the LDL receptor only when it is bound to lipid particles. To address structural aspects of this phenomenon, a receptor-active apoE peptide, encompassing the receptor-binding region of the protein, was studied by NMR in the presence of the lipid-mimicking agent trifluoroethanol. In 50% trifluoroethanol, apoE-(126-183) forms a continuous amphipathic alpha-helix over residues Thr(130)-Glu(179). Detailed NMR relaxation analysis indicates a high degree of plasticity for the residues surrounding 149-159. This intrinsic flexibility imposes a curvature to the peptide that may be important in terms of interaction of apoE with various sized lipid particles and the LDL receptor. Residues 165-179 of apoE may act as a molecular switch whereby these residues are unstructured in the absence of lipids and prevent interaction with the LDL receptor. In the presence of lipids, these residues become helical resulting in a receptor-active conformation of the protein. Furthermore, the electrostatic characteristics and geometric features of apoE-(126-183) suggest that apoE binds to the LDL receptor by interacting with more than one of the receptor ligand-binding repeats.     

Apolipoprotein A-I-mimetic peptides with antioxidant actions

To augment antioxidant action of apolipoprotein A-I (Apo A-I)-mimetic peptide, the peptide F3,6,14,18 18A (DWFKAFYDKVAEKFKEAF) was modified by incorporating antioxidant amino acid residues. Introduction of His residue at position 2 or 3 at N-terminal of the peptide remarkably enhanced antioxidant action against Cu2+ oxidation of LDL and the capability of sequestering Cu2+. Likewise, the substitution of Ala for Cys residue at position 12 increased antioxidant action against Cu2+ oxidation of LDL. Additionally, the Cys substitution contributed to enhanced capabilities in the removal of hypochlorous acid (HOCl) and 13-hydroperoxyoctadecadienoic acid. Furthermore, the combined incorporation of His and Cys residues enhanced antioxidant actions in preventing Cu2+ oxidation and reducing HOCl and hydroperoxide levels. Separately, in solubilizing phosphatidylcholine, either peptides with His residue at N-terminal position 2 or 3, or those containing Cys residue at position 11 or 12 were equipotent to peptide F3,6,14,18 18A. Further, the lipid-solubilizing ability of those containing both His and Cys residues was comparable to that of peptide F3,6,14,18 18A. In support of this, a similar structural importance was observed with Trp fluorescence study illustrating the penetration of peptides in phosphatidylcholine liposome. Besides, the modified peptides were also comparable to peptide F3,6,14,18 18A in restoring phosphatidylserine-induced loss of PON1 activity. These results indicate that the insertion of His or Cys residue into peptide F3,6,14,18 18A at appropriate positions could lead to enhanced antioxidant action with no significant change of lipid-solubilizing action.     

A monomeric, biologically active, full-length human apolipoprotein E

Apolipoprotein E (apoE) is an exchangeable apolipoprotein that plays an important role in lipid/lipoprotein metabolism and cardiovascular diseases. Recent evidence indicates that apoE is also critical in several other important biological processes, including Alzheimer's disease, cognitive function, immunoregulation, cell signaling, and infectious diseases. Although the X-ray crystal structure of the apoE N-terminal domain was solved in 1991, the structural study of full-length apoE is hindered by apoE's oligomerization property. Using protein-engineering techniques, we generated a monomeric, biologically active, full-length apoE. Cross-linking experiments indicate that this mutant is nearly 95-100% monomeric even at 20 mg/mL. CD spectroscopy and guanidine hydrochloride denaturation demonstrate that the structure and stability of the monomeric mutant are identical to wild-type apoE. Monomeric and wild-type apoE display similar lipid-binding activities in dimyristoylphosphatidylcholine clearance assays and formation of reconstituted high-density lipoproteins. Furthermore, the monomeric and wild-type apoE proteins display an identical LDL receptor binding activity. Availability of this monomeric, biologically active, full-length apoE allows us to collect high quality NMR data for structural determination. Our initial NMR data of lipid-free apoE demonstrates that the N-terminal domain in the full-length apoE adopts a nearly identical structure as the isolated N-terminal domain, whereas the C-terminal domain appears to become more structured than the isolated C-terminal domain fragment, suggesting a weak domain-domain interaction. This interaction is confirmed by NMR examination of a segmental labeled apoE, in which the N-terminal domain is deuterated and the C-terminal domain is double-labeled. NMR titration experiments further suggest that the hinge region (residues 192-215) that connects apoE's N- and C-terminal domains may play an important role in mediating this domain-domain interaction.     

Molecular basis for the differences in lipid and lipoprotein binding properties of human apolipoproteins E3 and E4

Human apolipoprotein (apo) E4 binds preferentially to very low-density lipoproteins (VLDLs), whereas apoE3 binds preferentially to high-density lipoproteins (HDLs), resulting in different plasma cholesterol levels for the two isoforms. To understand the molecular basis for this effect, we engineered the isolated apoE N-terminal domain (residues 1-191) and C-terminal domain (residues 192-299) together with a series of variants containing deletions in the C-terminal domain and assessed their lipid and lipoprotein binding properties. Both isoforms can bind to a phospholipid (PL)-stabilized triolein emulsion, and residues 261-299 are primarily responsible for this activity. ApoE4 exhibits better lipid binding ability than apoE3 as a consequence of a rearrangement involving the segment spanning residues 261-272 in the C-terminal domain. The strong lipid binding ability of apoE4 coupled with the VLDL particle surface being ～60% PL-covered is the basis for its preference for binding VLDL rather than HDL. ApoE4 binds much more strongly than apoE3 to VLDL but less strongly than apoE3 to HDL(3), consistent with apoE-lipid interactions being relatively unimportant for binding to HDL. The preference of apoE3 for binding to HDL(3) arises because binding is mediated primarily by interaction of the N-terminal helix bundle domain with the resident apolipoproteins that cover ～80% of the HDL(3) particle surface. Thus, the selectivity in the binding of apoE3 and apoE4 to HDL(3) and VLDL is dependent upon two factors: (1) the stronger lipid binding ability of apoE4 relative to that of apoE3 and (2) the differences in the nature of the surfaces of VLDL and HDL(3) particles, with the former being largely covered with PL and the latter with protein.     

Association of apolipoprotein E with the low density lipoprotein receptor: demonstration of its co-operativity on lipid microemulsion particles

When human apolipoprotein E (apoE), which forms a self-associated tetramer in an aqueous solution, bound to the surface of triolein/phosphatidylcholine microemulsion with a particle diameter of 26 nm, it became monomeric on the lipid particle surface without strong evidence for its accumulation on a particular particle that might be expected from its tetramer formation in the aqueous phase. ApoE in the form of the self-associated tetramer did not inhibit binding of human low density lipoprotein (LDL) to its receptor on cultured human skin fibroblast. LDL binding was inhibited only when apoE was bound to the lipid particle surface. The affinity of the apoE-containing lipid particle to the LDL receptor was of the same order as that of LDL on the basis of particle molarity when the surface of the particle was covered with apoE up to 40 to 50% of the saturation level. When the particle was covered more with apoE, the affinity increased by some 20 times. Since the surface of the lipid particle was saturated with 7 apoE molecules, the particle seemed to require to have at least 4 apoE molecules on its surface in order to obtain high binding affinity to LDL receptor.     

Apolipoprotein E receptor binding versus heparan sulfate proteoglycan binding in its regulation of smooth muscle cell migration and proliferation

This study showed that synthetic peptides containing either a single copy or tandem repeat of the receptor binding domain sequence of apolipoprotein (apo) E, or a peptide containing its C-terminal heparin binding domain, apoE-(211-243), were all effective inhibitors of platelet-derived growth factor (PDGF)-stimulated smooth muscle cell proliferation. In contrast, only the peptide containing a tandem repeating unit of the receptor binding domain sequence of apoE, apoE-(141-155)(2), was capable of inhibiting PDGF-directed smooth muscle cell migration. Peptide containing only a single unit of this sequence, apoE-(141-155), or the apoE-(211-243) peptide were ineffective in inhibiting PDGF-directed smooth muscle cell migration. Additional experiments showed that reductively methylated apoE, which is incapable of receptor binding yet retains its heparin binding capability, was equally effective as apoE in inhibiting PDGF-stimulated smooth muscle cell proliferation. However, reductively methylated apoE was unable to inhibit smooth muscle cell migration toward PDGF. Additionally, the receptor binding domain-specific apoE antibody 1D7 also mitigated the anti-migratory properties of apoE on smooth muscle cells. Finally, pretreatment of cells with heparinase failed to abolish apoE inhibition of smooth muscle cell migration. Taken together, these data documented that apoE inhibition of PDGF-stimulated smooth muscle cell proliferation is mediated by its binding to heparan sulfate proteoglycans, while its inhibition of cell migration is mediated through apoE binding to cell surface receptors.     

Apolipoprotein E3-Leiden contains a seven-amino acid insertion that is a tandem repeat of residues 121-127

Apolipoprotein (apo) E3-Leiden is a variant of apoE that is associated with dominant expression of type III hyperlipoproteinemia and that is defective in binding to the low density lipoprotein receptor. Therefore, the structure of apoE3-Leiden was investigated. Upon sodium dodecyl sulfate-polyacrylamide gel electrophoresis apoE3-Leiden and its 22-kDa amino-terminal thrombolytic fragment migrated with a higher than normal apparent molecular weight. The structural abnormality of apoE3-Leiden was determined by sequencing its CNBr-, tryptic-, and Staphylococcus aureus V8 protease-generated peptides. In contrast to normal apoE3, which has a cysteine at residue 112, apoE3-Leiden does not contain any cysteine and has an arginine at position 112 (as does apoE4, which also completely lacks cysteine). The basis for the molecular weight difference was determined to be a seven-amino acid insertion that is a tandem repeat of residues 121-127 of normal apoE3, i.e. Glu-Val-Gln-Ala-Met-Leu-Gly, resulting in apoE3-Leiden having 306 amino acids rather than 299. The negatively charged glutamyl residues within the insertion compensates for the arginine substitution at residue 112; thus apoE3-Leiden focuses in the E3 position. The low density lipoprotein receptor binding activities of both intact apoE3-Leiden and its 22-kDa thrombolytic fragment were determined in an in vitro assay. Although apoE3-Leiden had only about 25% of normal binding activity, its 22-kDa thrombolytic fragment had nearly normal binding, suggesting that the carboxyl-terminal domain of apoE3-Leiden modulates the receptor binding function of its amino-terminal domain.