No effect of menstrual cycle phase on glucose kinetics and fuel oxidation during moderate-intensity exercise

Resting and exercise fuel metabolism was assessed in three different phases of the menstrual cycle, characterized by different levels of estrogen relative to progesterone: early follicular (EF, low estrogen and progesterone), midfollicular (MF, elevated estrogen, low progesterone), and midluteal (ML, elevated estrogen and progesterone). It was hypothesized that exercise glucose utilization and whole body carbohydrate oxidation would decrease sequentially from the EF to the MF to the ML phase. Normal-weight healthy females, experiencing a regular menstrual cycle, were recruited. Subjects were moderately active but not highly trained. Testing occurred after 3 days of diet control and after an overnight fast (12-13 h). Resting (2 h) and exercise (50% maximal O(2) uptake, 90 min) measurements of whole body substrate oxidation, tracer-determined glucose flux, and substrate and hormone concentrations were made. No significant difference was observed in whole body fuel oxidation during exercise in the three phases (nonprotein respiratory exchange ratio: EF 0.84 +/- 0.01, MF 0.85 +/- 0.01, ML 0.85 +/- 0.01) or in rates of glucose appearance or disappearance. There were, however, significantly higher glucose (P < 0.05) and insulin (P < 0.001) concentrations during the first 45 min of exercise in the ML phase vs. EF and MF phases. In conclusion, whole body substrate oxidation and glucose utilization did not vary significantly across the menstrual cycle in moderately active women, either at rest or during 90 min of moderate-intensity exercise. During the ML phase, however, this similar pattern of substrate utilization was associated with greater glucose and insulin concentrations. Both estrogen and progesterone are elevated during the ML phase of the menstrual cycle, suggesting that one or both of these sex steroids may play a role in this response.     

The influence of the triglyceride content of low density lipoprotein on the interaction of apolipoprotein B-100 with cells

To study the effect of triglyceride content of low density lipoprotein (LDL) on its physicochemical and biological properties, we have depleted the triglyceride by incubation with hepatic lipase (HL-LDL) and raised the triglyceride by incubation of HL-LDL with very low density lipoprotein and lipoprotein-deficient serum. HL-LDL was taken up by human monocyte-derived macrophages and by human skin fibroblasts at an increased rate compared to untreated LDL. Incubation of the various LDL preparations revealed that cellular LDL degradation as well as LDL-mediated cholesterol esterification were inversely related to the triglyceride content of the LDL preparation. Modification of the triglyceride content of LDL also was associated with changes in the free fatty acid content, but the interaction of the LDL with cells was unaffected by the level of this component. The triglyceride content of LDL was found to be reciprocally related to the number of free lysine amino groups of LDL apolipoprotein B (apoB) which could be labeled with trinitrobenzenesulfonic acid. 13C-Nuclear magnetic resonance (NMR) spectra of native LDL and HL-LDL samples containing [13CH3]2 lysine residues formed by reductive methylation (11-13% modification) showed that the arrangement of apoB lysines is perturbed by the exposure to hepatic lipase. The ratio of labeled lysines with pK 8.9 to those with pK 10.5 exposed on the surface of LDL particles was decreased by about 40% by lipase treatment. These effects are apparently due to changes in local apoB conformation because circular dichroism spectra revealed that the average secondary structure of the entire apoB molecule is the same in native LDL and HL-LDL. The triglyceride content of LDL reciprocally affected its binding to a monoclonal antibody which recognizes epitopes around the LDL receptor binding domain of apoB. The above evidence indicates that modulation of the core triglyceride and possibly also surface phospholipid content of LDL can alter the conformation of apoB on the surface of the particle, thereby influencing the interaction with cell surface LDL receptors.     

Major apolipoprotein B-100 mutations in lipoprotein metabolism and atherosclerosis

Apolipoprotein (apo) B-100 is a key protein compound of plasma lipid metabolism. This protein, as a sole component of LDL particles, to a great extent controls the homeostasis of LDL cholesterol in the plasma. Therefore, this protein and its structural variants play an important role in development of hyperlipidemia and atherosclerosis. Intensive research into the structure and biological functions of apoB-100 has led to identification of its complete structure as well as the responsible binding sites. With the development of the methods of molecular biology, some structural variants of the apoB-100 protein that directly affect its binding properties have been described. These are mutations leading to amino acid substitution at positions 3500 (R3500Q and R3500W) and 3531 (R3531C) that have been shown to decrease the binding affinity of apoB-100 in vitro. However, only the former mutations have been unequivocally demonstrated to cause hyperlipidemia in vivo. This minireview is aimed to discuss the impact of apoB-100 and its structural variants on plasma lipid metabolism and development of hyperlipidemia.     

No effect of menstrual cycle phase on glycerol or palmitate kinetics during 90 min of moderate exercise.

The systemic flux of glycerol and palmitate [a representative nonesterified free fatty acid (NEFA)] was assessed in three different phases of the menstrual cycle at rest and during moderate-intensity exercise. It was hypothesized that circulating glycerol and NEFA turnover would be greatest in the midfollicular (MF) phase of the menstrual cycle, when estrogen is elevated but progesterone low, followed by the midluteal phase (ML; high estrogen and progesterone), and lowest in the early follicular (EF) phase of the menstrual cycle (low estrogen and progesterone). Subjects included moderately active, eumenorrheic, healthy women. Testing occurred after 3 days of diet control and after an overnight fast (12-13 h). Resting and exercise (50% maximal oxygen uptake, 90 min) measurements of tracer-determined glycerol and palmitate kinetics were made. There was a significant increase in both glycerol and palmitate turnover from rest to exercise in all phases of the menstrual cycle (P<0.0001). No significant differences, however, were observed between cycle phases in the systemic flux of glycerol or palmitate, at rest or during exercise. Maximal peripheral lipolysis during exercise, as represented by glycerol rate of appearance at 90 min, equaled 8.45+/-0.96, 8.35+/-1.12, and 7.71+/-0.96 micromol.kg-1.min-1 in the EF, MF, and ML phases, respectively. Circulating free fatty acid utilization also peaked at 90 min of exercise, as indicated by the palmitate rate of disappearance (3.31+/-0.35, 3.17+/-0.39, and 3.47+/-0.26 micromol.kg-1.min-1) in the EF, MF, and ML phases, respectively. In conclusion, systemic rates of glycerol and NEFA turnover (as represented by palmitate flux) were not significantly affected by the cyclic fluctuations in estrogen and progesterone that occur throughout the normal menstrual cycle, either at rest or during 90 min of moderate exercise.     

No effect of menstrual cycle phase and oral contraceptive use on endurance performance in rowers

The aim of this study was to examine whether variables commonly used in aerobic exercise testing are influenced by menstrual cycle phases and use of oral contraceptive (OC) in female rowers. Twenty-four eumenorrheic female rowers distinguished on the basis of both menstrual status and athleticism participated in this study and were divided into competitive cyclic athletes (n = 8), recreationally trained cyclic athletes (n = 7), and recreationally trained athletes taking OC pills (ROC; n = 9). Rowers performed 2 incremental tests to voluntary exhaustion on a rowing ergometer during 2 different phases of the menstrual cycle: the follicular phase (FP) and the luteal phase (LP). The study variables were power output (Pa), heart rate (HR), oxygen consumption (VO2), carbon dioxide production (VCO2), minute ventilation (VE), the mean respiratory exchange ratio, and ventilatory equivalents of O2 (VE/VO2)) and CO2 (VE/VCO2), which were measured at maximal and at the aerobic-anaerobic transition intensities. In addition, maximal blood lactate (La) values after the test were obtained. When comparing Pa, &OV0312;o2, HR, and La values, no significant differences (p > 0.05) between FP and LP at maximal load and at threshold intensity were found in all 3 groups of the rowers studied. However, we observed higher values (p < 0.05) for VE/VCO2 at both intensities in LP compared with FP in the ROC group. In conclusion, sport-specific endurance performance was not influenced by the phase of the normal menstrual cycle and the synthetic menstrual cycle of the OC users in the rowers studied. Therefore, normally menstruating female rowers and female rowers taking OC pills should not be concerned about the timing of their menstrual cycle with regard to optimized sport-specific endurance performance.     

A new combined multicompartmental model for apolipoprotein B-100 and triglyceride metabolism in VLDL subfractions

The use of stable isotopes in conjunction with compartmental modeling analysis has greatly facilitated studies of the metabolism of the apolipoprotein B (apoB)-containing lipoproteins in humans. The aim of this study was to develop a multicompartment model that allows us to simultaneously determine the kinetics of apoB and triglyceride (TG) in VLDL(1) and VLDL(2) after a bolus injection of [(2)H(3)]leucine and [(2)H(5)]glycerol and to follow the catabolism and transfer of the lipoprotein particles. Here, we describe the model and present the results of its application in a fasting steady-state situation in 17 subjects with lipid values representative of a Western population. Analysis of the correlations showed that plasma TG was determined by the VLDL(1) and VLDL(2) apoB and TG fractional catabolic rate. Furthermore, the model showed a linear correlation between VLDL(1) TG and apoB production. A novel observation was that VLDL TG entered the circulation within 21 min after its synthesis, whereas VLDL apoB entered the circulation after 33 min. These observations are consistent with a sequential assembly model of VLDL and suggest that the TG is added to a primordial apoB-containing particle in the liver.     

Identification of sequence homology between human plasma apolipoprotein B-100 and apolipoprotein B-48

The structural relationship between apolipoprotein B-100 (apo-B-100) and apolipoprotein B-48 (apo-B-48) has not been elucidated. A peptide fragment (MDB-18) of approximately 6 kDa was isolated from a tryptic digest of apo-B-100. The sequence of the first 22 amino acids of MDB-18 was determined by Edman degradation. A 15-residue peptide corresponding to this sequence was synthesized by the solid-phase method and was utilized to develop a sequence-specific polyclonal antibody. On immunoblot analysis, the antibody recognized both intact apo-B-100 and apo-B-48. In addition, preincubating the antibody with the synthetic peptide abolished the recognition of both apo-B-100 and apo-B-48. These data are interpreted as indicating that there is an amino acid sequence homology between apo-B-100 and apo-B-48. Since the MDB-18 peptide is located in the carboxyl region of the B-100 molecule, we propose apo-B-100 and apo-B-48 share a common carboxyl region sequence.     

Identification of modified tryptophan residues in apolipoprotein B-100 derived from copper ion-oxidized low-density lipoprotein

Oxidative modifications of low-density lipoproteins (LDL) may contribute to the pathogenesis of atherosclerosis. Although the oxidation products of the lipid components of LDL have been studied extensively, less is known about the oxidation products of the apoprotein, apolipoprotein B-100. To identify the specific oxidative modifications, we oxidized LDL in the presence of Cu(2+), treated with DNPH, precipitated and delipidated the protein, digested the protein with trypsin, and analyzed the peptides by high-performance liquid chromatography. We isolated nine peptides that exhibited measurable absorbance at 365 nm, which is characteristic of hydrazones derived from DNPH and is not observed in peptides derived from unoxidized LDL. Unexpectedly, we obtained the same peptides with absorbance at 365 nm in Cu(2+)-oxidized LDL not treated with DNPH. N-terminal sequence analyses and mass spectrometry indicated that the peptides isolated from the Cu(2+)-oxidized LDL all contained kynurenine residues in place of Trp residues found in the native apoprotein. The product profile we observed in Cu(2+)-oxidized LDL was remarkably different from the profiles observed in LDL oxidized by HOCl or myeloperoxidase in vitro, and the preferential oxidation of Trp to kynurenine in Cu(2+)-catalyzed oxidation of LDL contrasts with the products observed following oxidation of LDL with HOCl or myeloperoxidase. Our studies to date support the working hypothesis that the specific products of protein oxidation are sufficiently distinct to be developed as biomarkers of proposed mechanisms of oxidation of LDL and biological molecules in other toxicities and diseases.     

Mapping oxidations of apolipoprotein B-100 in human low-density lipoprotein by liquid chromatography-tandem mass spectrometry

Human low-density lipoprotein (LDL) is a major cholesterol carrier in blood. Elevated concentration of low-density lipoprotein, especially when oxidized, is a risk factor for atherosclerosis and other cardiac inflammatory diseases. Past research has connected free radical initiated oxidations of LDL with the formation of atherosclerotic lesions and plaque in the arterial wall. The role of LDL protein in the associated diseases is still poorly understood, partially due to a lack of structural information. In this study, LDL was oxidized by hydroxyl radical. The oxidized protein was then delipidated and subjected to trypsin digestion. Peptides derived from trypsin digestion were analyzed by liquid chromatography-tandem mass spectrometry (LC-MS/MS). Identification of modified peptide sequences was achieved by a database search against apo B-100 protein sequences using the SEQUEST algorithm. At different hydroxyl radical concentrations, oxidation products of tyrosine, tryptophan, phenylalanine, proline, and lysine were identified. Oxidized amino acid residues are likely located on the exterior of the LDL particle in contact with the aqueous environment or directly bound to the free radical permeable lipid layer. These modifications provided insight for understanding the native conformation of apo B-100 in LDL particles. The presence of some natural variants at the protein level was also confirmed in our study.     

Mutation of lysine residues in apolipoprotein B-100 causes defective lipoprotein[a] formation

Lipoprotein[a] (Lp[a]) is assembled by a two-step process involving an initial lysine-dependent binding between apolipoprotein B-100 (apoB-100) and apolipoprotein[a] (apo[a]) that facilitates the formation of a disulphide bond between apoB-100Cys4,326 and apo[a]Cys4,057. Previous studies of transgenic mice expressing apoB-95 (4,330 amino acids) and apoB-97 (4,397 amino acids) have shown that apoB-100 amino acids 4,330-4,397 are important for the initial binding to apo[a]. Furthermore, a lysine-rich peptide spanning apoB-100 amino acids 4,372-4,392 has recently been shown to bind apo[a] and inhibit Lp[a] assembly in vitro. This suggests that a putative apo[a] binding site exists in the apoB-4,372-4,392 region. The aim of our study was to establish whether the apoB-4,372-4,392 sequence was important for Lp[a] assembly in the context of the full-length apoB-100. Transgenic mice were created that expressed a mutant human apoB-100, apoB-100K4-->S4, in which all four lysine residues in the 4,372-4,392 sequence were mutated to serines. The apoB-100K4-->S4 mutant showed a reduced capacity to form Lp[a] in vitro compared with wild-type human apoB-100. Double transgenic mice expressing both apoB-100K4-->S4 and apo[a] contained significant amounts of free apo[a] in the plasma, indicating a less-efficient assembly of Lp[a] in vivo. Taken together, these results clearly show that the apoB-4,372-4,392 sequence plays a role in Lp[a] assembly.     

The enhanced cellular uptake of very-low-density lipoprotein enriched in apolipoprotein E.

We have recently reported an increased clearance of plasma very-low-density lipoprotein (VLDL) after intravenous injection of apolipoprotein (apo) E in Watanabe heritable hyperlipidemic (WHHL) rabbits. In the present study, we have investigated the cellular uptake of VLDL enriched in apo E (VLDL-E) which had been incubated with purified rabbit apo E. VLDL-E was taken up approx. 2-fold more than VLDL in human skin fibroblast, human monocyte-derived macrophage and Hep G2 cell and its degradation was least in macrophage. To characterize the binding of VLDL-E, we performed a binding assay using hepatic endosome isolated from estradiol-treated rats and we observed both increased EDTA-sensitive and -resistant binding of VLDL-E on endosome. Ligand blotting of hepatic endosome demonstrated two major bands of LDL receptor (130 and 260 kDa protein) and a minor band of LDL receptor-related protein (580 kDa protein) with a ligand of VLDL-E. These results suggested that VLDL-E was endocytosed in liver through a similar pathway among three cell types, and enrichment of apo E in VLDL enhanced the uptake of VLDL not only via an EDTA-sensitive binding site (classical LDL receptor) but also via other binding sites including an EDTA-resistant binding site and an LDL receptor-related protein.     

Degradation of apolipoprotein B-100 in human chylomicrons

The purpose of this study was to investigate the molecular forms of apolipoprotein B (ApoB) in human chylomicrons under well-preserved conditions. To this end, plasma and serum were collected from the same normal subjects after ingestion of a fatty meal. The samples were divided into three or four aliquots before the addition of various preservative mixtures, including antibiotics, antioxidants and proteinase inhibitors. The chylomicrons were isolated immediately, and all steps were carried out at or below 4 degrees C. Changes in the molecular weight of ApoB in chylomicrons were followed by a time study using 3.3% polyacrylamide gel electrophoresis containing SDS. ApoB from chylomicrons analyzed within 5 h of blood collection showed a single band with mobility identical to that of ApoB (ApoB-100) in low-density lipoproteins. When analyzed after 1-2 days, satellite bands smaller than ApoB-100 were observed, and a very faint band with Mr 200,000 appeared, which comigrated with intestinal ApoB (ApoB-48). Upon storage, the molecular weight of ApoB was smaller in chylomicrons subjected to a higher number of reflotations than those in chylomicrons washed less frequently, suggesting that purified chylomicrons degrade faster. A longer storage time at 4 degrees C (i.e., 7 or 14 days) revealed a stepwise degradation of ApoB, yielding Mr 200,000 band as the prominent form. The degradation of ApoB-100 was slower when both proteinase inhibitors, leupeptin and epsilon-amino caproic acid, were employed, and the appearance of Mr 200,000 band was quicker when the chylomicrons were processed at higher temperature (15-25 degrees C) in the absence of a proteinase inhibitor. Immunoblotting shows that the segment removed from ApoB-100 was the carboxyl-terminal portion. These results suggest the possible presence of a proteinase(s), which copurified with chylomicrons, and which converts ApoB-100 from a large to a smaller molecular form. Although the stop codon has been discovered recently in intestinal ApoB mRNA, which explains the mechanism for direct synthesis of ApoB-48, apparently ApoB-100 is also synthesized in the intestine of all eight subjects studied here, and the ApoB-100 degrades to a form which is ApoB-48-like.     

Analysis of modified apolipoprotein B-100 structures formed in oxidized low-density lipoprotein using LC-MS/MS

Oxidatively modified low-density lipoprotein (oxLDL) is one of the major factors involved in the development of atherosclerosis. Because of the insolubility of apolipoprotein B-100 (apoB-100) and the heterogeneous nature of oxidative modification, modified structures of apoB-100 in oxLDL are poorly understood. We applied an on-Membrane sample preparation procedure for LC-MS/MS analysis of apoB-100 proteins in native and modified low-density lipoprotein (LDL) samples to eliminate lipid components in the LDLs followed by collection of tryptic digests of apoB-100. Compared with a commonly used in-gel digestion protocol, the sample preparation procedure using PVDF membrane greatly increased the recovery of tryptic peptides and resulted in improved sequence coverage in the final analysis, which lead to the identification of modified amino acid residues in copper-induced oxLDL. A histidine residue modified by 4-hydroxynonenal, a major lipid peroxidation product, as well as oxidized histidine and tryptophan residues were detected. LC-MS/MS in combination with the on-Membrane sample preparation procedure is a useful method to analyze highly hydrophobic proteins such as apoB-100.     

Effect of alpha-tocopherol on the oxidative modification of apolipoprotein E in human very-low-density lipoprotein

The oxidative modification of apolipoprotein (apo) E and lipid peroxidation in human very-low-density lipoprotein (VLDL) induced by peroxynitrite and cupric ions in vitro were strongly suppressed by enrichment with alpha-tocopherol (alpha-Toc; 170 microM). Alpha-Toc also suppressed the decrease in the heparin-binding activity of apoE in the VLDL oxidation. These results suggest that alpha-Toc protected apoE in VLDL from oxidative stress.     

The physical state of the LDL core influences the conformation of apolipoprotein B-100 on the lipoprotein surface

We assessed the influence of temperature on the secondary structure of apolipoprotein B-100 (apoB) in normal low-density lipoprotein (N-LDL) and triglyceride-rich LDL (T-LDL). Gradual heating from 7 degrees C to the phase-transition temperature of the lipoprotein core ( approximately 28 degrees C and approximately 15 degrees C for N-LDL and T-LDL, respectively) gradually altered the secondary structure of apoB, while further heating from the phase-transition temperature to 45 degrees C had no additional effect. Above the phase-transition temperature of the core, the apoBs of N-LDL and T-LDL had a similar secondary structure. These results indicate that the conformation of apoB on the LDL surface depends strongly on the physical state of the lipoprotein core, and less on the lipid composition of the core per se.     

Effect of apolipoprotein E genotype on apolipoprotein B-100 metabolism in normolipidemic and hyperlipidemic subjects

The effect of apolipoprotein (apo) E genotype on apoB-100 metabolism was examined in three normolipidemic apoE2/E2, five type III hyperlipidemic apoE2/E2, and five hyperlipidemic apoE3/E2 subjects using simultaneous administration of ¹³¹I-VLDL and ¹²⁵I-LDL, and multi-compartmental modeling. Compared with normolipidemic apoE2/E2 subjects, type III hyperlipidemic E2/E2 subjects had increased plasma and VLDL cholesterol, plasma and VLDL triglycerides, and VLDL and intermediate density lipoprotein (IDL) apoB concentrations (P < 0.05). These abnormalities were chiefly a consequence of decreased VLDL and IDL apoB fractional catabolic rate (FCR). Compared with hyperlipidemic E3/E2 subjects, type III hyperlipidemic E2/E2 subjects had increased IDL apoB concentration and decreased conversion of IDL to LDL particles (P < 0.05). In a pooled analysis, VLDL cholesterol was positively associated with VLDL and IDL apoB concentrations and the proportion of VLDL apoB in the slowly turning over VLDL pool, and was negatively associated with VLDL apoB FCR after adjusting for subject group. VLDL triglyceride was positively associated with VLDL apoB concentration and VLDL and IDL apoB production rates after adjusting for subject group. A defective apoE contributes to altered lipoprotein metabolism but is not sufficient to cause overt hyperlipidemia. Additional genetic mutations and environmental factors, including insulin resistance and obesity, may contribute to the development of type III hyperlipidemia.     

Retention of apolipoprotein B and cholesterol by perfused heart during lipolysis of very-low-density lipoprotein

The fate and mechanism of removal of apolipoproteins and lipids of human very-low-density lipoproteins were determined in the perfused rat heart. Approx. 50% of the VLDL triacylglycerol was hydrolyzed during a 2 h perfusion. Phospholipid phosphorus, apolipoproteins C-II, C-III and E were quantitatively recovered in the medium. However, there was a loss of unesterified (17 +/- 6%) and esterified (19 +/- 8%) cholesterol from the perfusion medium. Apolipoprotein B was retained by the heart, as determined by the loss of immunoassayable apolipoprotein B (30 +/- 5%) or the uptake of 125I-labelled apolipoprotein of VLDL (9 +/- 2%) from the perfusion medium. The discrepancy in the two methods for estimating apolipoprotein removal was shown to be due to the modification of apolipoprotein B-containing lipoproteins, which was such that they were no longer precipitated with antibodies to apolipoprotein B. The labelled apolipoprotein B, retained by the heart, could be partially released by perfusion of the heart with buffer containing heparin (14 +/- 2%) or trypsin (50 +/- 2%). Labelled apolipoprotein uptake by the heart was reduced by 90% when lipoprotein lipase was first released by heparin or when VLDL was treated with 1,2-cyclohexanedione to modify arginine residues of apolipoproteins. Very little extensive degradation of the apoprotein to low molecular weight material occurred during the 2 h perfusion, since 95% of the tissue label was precipitated by trichloroacetic acid. It is concluded that there is retention of apolipoprotein B, cholesteryl ester and cholesterol by the perfused heart during catabolism of VLDL. The data are consistent with the concept that the retention of apolipoprotein B requires membrane-bound lipoprotein lipase or an interaction with the cell surfaces that is modified by heparin. The overall process also involves arginine residues of apolipoproteins. At least 50% of the labelled apolipoprotein retained in the tissue is associated with lipoprotein lipase and other cell surface sites, while the remainder may be taken up by the cells.     

Low-density lipoprotein receptor binding determinants switch from apolipoprotein E to apolipoprotein B during conversion of hypertriglyceridemic very-low-density lipoprotein to low-density lipoproteins

Using thrombin and trypsin as probes, we determined: first, that low-density lipoprotein (LDL) receptor binding determinants switch from apolipoprotein (apo) E to apo-B within the very-low-density lipoprotein (VLDL) Sf 20-60 region of the metabolic cascade from VLDL1 (Sf 100-400) of hypertriglyceridemic (HTG) human subjects to LDL. Second, two different conformations of apo-E exist in HTG-VLDL Sf greater than 60, one accessible (greater than or equal to 1 mol/mol of particle) and one inaccessible (1-2 mol/mol) to both thrombin and the LDL receptor; normal VLDL (Sf greater than 60) have only the inaccessible conformation and therefore do not bind to the LDL receptor. Third, thrombin degrades apo-B into large fragments, three of which have electrophoretic mobilities similar to B-48, B-74, and B-26; this, however, has no effect on apo-B-mediated receptor binding. Fibroblast studies showed that thrombin could abolish receptor uptake of HTG-VLDL1 and HTG-VLDL2 (Sf 60-100), had little or no effect on HTG-VLDL3 (Sf 20-60), and no effect on uptake of intermediate-density lipoprotein (IDL) or LDL. Trypsin abolished the binding of HTG-VLDL1 and HTG-VLDL2, reduced that of HTG-VLDL3, but had little to no effect on IDL or LDL binding. Immunochemical techniques revealed that thrombin cleaved some apo-E into the E-22 and E-12 fragments; after trypsin treatment no apo-E was detected in any HTG-lipoprotein. Normal VLDL subclasses contained less apo-E than the corresponding HTG-VLDL subclasses and it was not cleaved by thrombin. Apo-B immunoreactivities of VLDL subclasses were not significantly changed after treatment with thrombin, although thrombin cleaved some of the B-100 of each VLDL subclass, and all apo-B in IDL and LDL, into 4-6 major large fragments. Trypsin converted all of the apo-B of each lipoprotein into smaller fragments (Mr less than 100,000). We conclude that apo-E of the thrombin-accessible conformation mediates uptake of HTG-VLDL1 and HTG-VLDL2 but that apo-B alone is sufficient to mediate receptor binding of IDL and LDL; the switch from apo-E to apo-B as the primary or sufficient binding determinant occurs within the VLDL3 (Sf 20-60) region of the metabolic cascade, where receptor binding first appears in VLDL subclasses from normal subjects.     

Degradation of apolipoprotein B-100 by lysosomal cysteine cathepsins

Although the degradation of cellular or endocytosed proteins comprises the normal function of lysosomal proteinases, these enzymes were also detected extracellularly during diseases such as atherosclerosis. Since lysosomal cysteine cathepsins were demonstrated to transform native LDL particles into a proatherogenic type, the following study was undertaken to characterize the modification of LDL particles and the degradation of apolipoprotein B-100 in more detail. LDL was incubated with cathepsins B, F, K, L, S, and V at pH 5.5 and under physiological conditions (pH 7.4) for 2 h to mimic conditions of limited proteolysis. Gel electrophoretic analysis of the degradation products revealed that cathepsin-mediated proteolysis of apolipoprotein B-100 is a fast process carried out by all enzymes at pH 5.5, and by cathepsin S also at pH 7.4. Electron microscopic analysis showed that cathepsin-mediated degradation of apolipoprotein B-100 rendered LDL particles fusion-competent compared to controls. N-Terminal sequencing of cathepsin cleavage fragments from apolipoprotein B-100 revealed an abundance of enzyme-specific cleavage sites located in almost all structurally and functionally essential regions. Since the cleavage sites superimpose well with results from substrate specificity studies, they might be useful for the development of cathepsin-specific inhibitors and substrates.     

Distribution of lipid-binding regions in human apolipoprotein B-100

The distribution of lipid-binding regions of human apolipoprotein B-100 has been investigated by recombining proteolytic fragments of B-100 with lipids and characterizing the lipid-bound fragments by peptide mapping, amino acid sequencing, and immunoblotting. Fragments of B-100 were generated by digestion of low-density lipoproteins (LDL) in the presence of sodium decyl sulfate with either Staphylococcus aureus V8 protease, pancreatic elastase, or chymotrypsin. Particles with electron microscopic appearance of native lipoproteins formed spontaneously when detergent was removed by dialysis from enzyme digests containing fragments of B-100 and endogenous lipids, or from incubation mixtures of delipidated B-100 fragments mixed with microemulsions of exogenous lipids (cholesteryl oleate and egg phosphatidylcholine). Fractionation of the recombinant particles by isopycnic or density gradient ultracentrifugation yielded complexes similar to native LDL with respect to shape, diameter, electrophoretic mobility, and surface and core compositions. Circular dichroic spectra of these particles showed helicity similar to LDL but a somewhat decreased content of beta-structure. Most of the fragments of B-100 were capable of binding to lipids; 12 were identified by direct sequence analysis and 14 by reaction with antisera against specific sequences within B-100. Our results indicate that lipid-binding regions of B-100 are widely distributed within the protein molecule and that proteolytic fragments derived from B-100 can reassociate in vitro with lipids to form LDL-like particles.