Sequence-specific 1H NMR resonance assignments and secondary structure of human apolipoprotein C-I in the presence of sodium dodecyl sulfate.

Apolipoprotein (apo) C-I is a 57-residue exchangeable plasma protein distributed mainly in high and very low density lipoprotein. In this report we present the nuclear magnetic resonance spectra of native apoC-I and synthetic apoC-I, containing selected 15N-labelled amino acids, in the presence of sodium dodecyl sulfate. The proton resonances of apoC-I are assigned and the secondary structure is estimated from the difference of measured alpha-proton chemical shifts to random coil values and the observed NOE interactions. According to these data apoC-I forms two helices, Val-4-Lys-30 and Leu-34-Lys-52, linked by an unstructured region Gln-31-Glu-33. The N-terminal segments of each helix, Val-4-Gly-15 and Leu-34-Met-38, appear to be more flexible than the helical core regions Asn-16-Lys-30 and Arg-39-Lys-52.

Inhibition of lipoprotein lipase activity by synthetic peptides of apolipoprotein C-III.

In this study we have examined effects of synthetic polypeptide fragments of apoC-III on the kinetic properties of lipoprotein lipase (LPL) activity. Based on the loss of 79% of LPL-inhibitory activity after CNBr cleavage at the N-terminal portion of apoC-III and a systematic search for synthetic peptides with LPL-inhibitory activity spanning the apoC-III sequence, we concluded that the N-terminal domain is the most important in the modulation of LPL activity. In addition, there are multiple attachment sites in apoC-III for its interaction with LPL and these sites reside in the hydrophilic sequences of apoC-III. Probably for this reason the intact apo-CIII exhibited higher inhibitory potential than its peptide components. Based on the deduced inhibition constants derived for the synthetic apoC-III1-79 we concluded that apoC-III is likely to exhibit a physiological role in regulating LPL activity since the derived dissociation constants for the LPL-apoC-III interaction are within the physiological concentration range of plasma apoC-III. In addition, as the synthetic apoC-III1-79 lacks the carbohydrate moiety, we also concluded that the presence of the oligosaccharide in native apoC-III is not essential for its inhibitory activity on LPL. The fact that the I50 (concentration for inhibition of LPL at 50% activity) decreases for apoC-III-1 when assayed in the presence of apoC-II indicated that the activator actually caused an increased affinity between LPL and apoC-III and demonstrated that apoC-III does not compete for the activator site of apoC-II.

Human plasma apolipoprotein C-II: total solid-phase synthesis and chemical and biological characterization.

The complete amino acid sequence of human plasma apolipoprotein C-II (apoC-II) has been synthesized chemically by the solid-phase method using phenylacetamidomethyl-resin. All amino acids were coupled to the peptide-resin in the presence of 1-hydroxybenzotriazole; tert-butyloxycarbonyl-protected amino acids with the appropriate side-chain-protecting groups that are stable to the reaction conditions used in the solid-phase methodology were used. After cleavage and deprotection, the crude apoC-II was purified by ion-exchange chromatography and then by reverse-phase high-performance liquid chromatography. The purified apolipoprotein was found to elute as a single peak under various chromatographic conditions, and the overall yield of the final purified protein was 20.7%. Synthetic apoC-II was characterized by several complementary analytical techniques including amino acid composition, Edman phenylisothiocyanate degradation, polyacrylamide gel electrophoresis, and high-performance liquid chromatography. The final product was found to be homogeneous and to activate normal human post-heparin lipase to the same extent as native apoC-II. The synthetic protein is also equally immunoreactive as native apoC-II.

Interaction of synthetic peptides of apolipoprotein C-II and lipoprotein lipase at monomolecular lipid films.

The triacylglycerol hydrolyase and phospholipase A1 activities of bovine milk lipoprotein lipase toward long-chain fatty acyl ester substrates were investigated with monomolecular lipid films containing trioleoylglycerol and phosphatidylcholine. In a monolayer of egg phosphatidylcholine containing 3 mol% [14C]trioleoylglycerol, and in the presence of apolipoprotein C-II, a 79 amino acid activator protein for lipoprotein lipase, enzyme activity was maximal at a surface pressure of 21-22 mN X m-1 (37 mumol oleic acid released/h per mg enzyme); enzyme activity was enhanced 9-fold by apolipoprotein C-II. At surface pressures between 22 and 30 mN X m-1, lipoprotein lipase activity decreased over a broad range and was nearly zero at 30 mN X m-1. Apolipoprotein C-II and the synthetic fragments of the activator protein containing residues 56-79, 51-79 and 44-79 were equally effective at 20 mN X m-1 in enhancing lipoprotein lipase catalysis. However, at surface pressures between 25 and 29 mN X m-1, only apolipoprotein C-II and the phospholipid-associating fragment containing residues 44-79 enhanced enzyme catalysis. The effect of apolipoprotein C-II and synthetic peptides on the phospholipase A1 activity of lipoprotein lipase was examined in sphingomyelin:cholesterol (2:1) monolayers containing 5 mol% di[14C]myristoylphosphatidylcholine. At 22 mN X m-1, apolipoprotein C-II and the synthetic fragments containing residues 44-79 or 56-79 enhanced lipoprotein lipase activity (70-80 nmol/h per mg enzyme). In contrast to trioleoylglycerol hydrolysis, the synthetic fragments were not as effective as apolipoprotein C-II enhancing enzyme activity towards di[14C]myristoylphosphatidylcholine at higher surface pressures. We conclude that the minimal amino acid sequence of apolipoprotein C-II required for activation of lipoprotein lipase is dependent both on the lipid substrate and the packing density of the monolayer.

Synthesis of peptide labelled with p-iodophenylalanine which corresponds to the first amphipathic region of apolipoprotein C-I.

The amino terminal fragment (1-15) of apolipoprotein C-1, H-Thr-Pro-Asp-Val-Ser-Ser-Ala-Leu-Asp-Lys-Leu-Lys-Glu-Phe14-Gly was prepared by the solid phase method. However, the phenylalanine residue at position 14 was replaced with p-iodophenylalanine in the chemical synthesis. The preparation of t-butyloxy-carbonyl-p-iodophenylalanine is described. After completion of the synthesis, the product was deprotected and cleaved from the resin with liquid HF. The peptide was purified by gel filtration on Sephadex G-25 and preparative high performance liquid chromatography. The purified material was shown to be homogeneous by amino acid analytical data and by chromatography in three different analytical reversed phase HPLC systems. The peptide was then labelled by the chloroamine-T procedure and good incorporation of 125I was obtained. After purification of the product by gel filtration on Biogel P-2, the labelled pentadecapeptide was tested for ability to bind to Very Low Density Lipoproteins (VLDL) in the following manner: VLDL was isolated from normolipemic serum by ultracentrifugal flotation and 100-microliter samples were incubated with labelled material dissolved in 200 microliter of 0.5 M NaCl, 0.02 M sodium phosphate buffer, pH 7.4 at 37 degrees for 30 min. The VLDL fraction was again isolated by ultracentrifugal flotation and the incorporation of radioactivity into the lipoprotein was measured. Under these conditions, a sample of [3H]-native apolipoprotein C-I was incorporated to an extent of 83% of the total sample, while the [125I]-pentadecapeptide exhibited an incorporation of 8.7%.