HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Abstract Full Text (PDF) All Versions of this Article: M400306-JLR200v1 46/1/115    most recent Alert me when this article is cited Alert me if a correction is posted Citation Map Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Asatryan, L. Articles by Sevanian, A. Search for Related Content PubMed PubMed Citation Articles by Asatryan, L. Articles by Sevanian, A. Social Bookmarking                      What's this?

Journal of Lipid Research, Vol. 46, 115-122, January 2005
Copyright © 2005 by American Society for Biochemistry and Molecular Biology

LDL phospholipid hydrolysis produces modified electronegative particles with an unfolded apoB-100 protein

Liana Asatryan^1,*, Ryan T. Hamilton^*, J. Mario Isas, Juliana Hwang^*, Rakez Kayed and Alex Sevanian^*

^* Department of Molecular Pharmacology and Toxicology, School of Pharmacy, University of Southern California, Los Angeles, CA 90033
Department of Biochemistry and Molecular Biology, Keck School of Medicine, Zilkha Neurogenetic Institute, and Arnold and Mabel Beckman Macular Research Center, University of Southern California, Los Angeles, CA 90033
Department of Molecular Biology and Biochemistry, University of California, Irvine, CA 92697

Published, JLR Papers in Press, October 16, 2004. DOI 10.1194/jlr.M400306-JLR200

¹ To whom correspondence should be addressed. e-mail: asatryan{at}usc.edu

	ABSTRACT

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Electronegative low density lipoprotein (LDL^–) formation that structurally resembles LDL^– isolated from plasma was evaluated after LDL treatment with snake venom phospholipase A₂ (PLA₂). PLA₂ treatment of LDL increased its electrophoretic mobility in proportion to the amount of LDL^– formed without evidence of lipid peroxidation. These changes dose-dependently correlated with the degree of phospholipid hydrolysis. Strong immunoreactivity of LDL^– subfraction from plasma and PLA₂-treated LDL (PLA₂-LDL) to amyloid oligomer-specific antibody was observed. Higher ß-strand structural content and unfolding proportionate to the loss of -helical structure of apolipoprotein B-100 (apoB-100) of LDL^– isolated from both native and PLA₂-LDLs was demonstrated by circular dichroism (CD) spectropolarimetry. These structural changes resembled the characteristics of some oxidatively modified LDLs and soluble oligomeric aggregates of amyloidogenic proteins. PLA₂-LDL was also more susceptible to nitration by peroxynitrite, likely because of exposure of otherwise inaccessible hydrophilic and hydrophobic domains arising from apoB-100 unfolding. This was also demonstrated for plasma LDL^–. In contrast, PLA₂-LDL was more resistant to copper-mediated oxidation that was reversed upon the addition of small amounts of unsaturated fatty acids.

The observed similarities between PLA₂-LDL^–-derived LDL^– and plasma LDL^– implicate a role for secretory PLA₂ in producing modified LDL^– that is facilitated by unfolding of apoB-100.

Abbreviations: Aß, amyloid ß; apoB-100, apolipoprotein B-100; CD, circular dichroism; LDL^–, electronegative low density lipoprotein; MDA, malondialdehyde; nLDL, normal LDL subfraction devoid of LDL^–; REM, relative electrophoretic mobility; sPLA₂, secretory phospholipase A₂; tLDL, total LDL

Supplementary key words apolipoprotein B-100 • atherogenic low density lipoprotein • lipid peroxidation • oxidation • nitrotyrosine • unsaturated fatty acids • ß-strand structures • protein structure • secretory phospholipase A₂

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Human plasma contains an electronegative LDL subfraction (LDL^–) that possesses atherogenic properties and is associated with increased cardiovascular disease risk (1, 2). Increased levels of LDL^– have been observed in hypercholesterolemic subjects (3), type 2 diabetics (4, 5), uremic subjects (6), after exhaustive physical exercise (7, 8), and during postprandial lipemia (9). LDL^– is associated with small, dense LDLs and is enriched in lipid peroxides (1, 10). Modification of the protein component of LDL^–, apolipoprotein B-100 (apoB-100), with the loss of secondary structure and increased unfolded character, has also been described (11). There are several mechanisms described for LDL^– formation, each yielding a particle resembling circulating LDL^–. Particles similar to LDL^– can be produced in vitro by transition metals or hemoproteins (6, 10), enzymatically by myeloperoxidase (12), lipoxygenase, and lipase (13, 14), and by incubating LDL in the presence of vascular cells (15), particularly under shear stress (16). All of these reactions occur with concomitant lipid peroxidation in LDL particles with levels at times greatly exceeding those found in plasma LDL^–. The requirement for lipid peroxidation for the formation of LDL^– particles remains in question, because various LDL^– particles can contain different amounts of lipid species, notably free fatty acid, oxidized phospholipids, and lysophospholipids, depending on the origin or mechanism of LDL^– formation.

Secretory phospholipase A₂ (sPLA₂) is released into the circulation under inflammatory conditions, where it hydrolyzes lipoprotein phospholipids at the sn-2 position, releasing free unsaturated fatty acids and generating lysophospholipids. Growing evidence suggests that increased sPLA₂ activity may contribute to atherosclerosis (17, 18). Different members of the sPLA₂ family have been found in plasma (17) and extracellularly in the arterial intima and atherosclerotic lesions (19–21); however, direct reactions with plasma or intimal lipoproteins in vivo have been difficult to assess. In vitro hydrolysis of the surface phospholipids on LDL using nonmammalian low molecular weight PLA₂ produces physicochemical changes leading to alterations in particle structure as well as the biological function of LDL (17, 18). Spin resonance spectroscopy studies revealed increased surface free cholesterol and sphingomyelin content accompanied by decreased particle fluidity (22). Hydrolysis of 50% of the phospholipids in LDL leads to the formation of smaller, denser particles with increased ability to bind extracellular matrix proteoglycans (23). A related feature of PLA₂-treated particles involves the conformational alteration of the protein, apoB-100, that imparts a greater tendency to aggregate (24). It has also been shown that reaction of PLA₂ with lipoproteins can occur in the presence of plasma (17) and that storage and minimal LDL oxidation induce the ability of PLA₂ to degrade surface lipids (25).

The aforementioned properties of PLA₂-treated LDL suggest a resemblance to in vivo circulating LDL^–. It was of interest to study whether PLA₂ treatment of LDL may lead to LDL^– formation occurring without evidence of lipid peroxidation.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Materials
Naja naja venom PLA₂ was obtained from Sigma Chemical Co. (St. Louis, MO). Amyloid ß (Aß) was a generous gift from Dr. Ralph Langen (University of Southern California, Los Angeles, CA). Monoclonal nitrotyrosine antibody was purchased from Upstate Cell Signaling Solutions (Lake Placid, NY). An antibody to oligomeric aggregates was produced earlier as described (26). Bovine serum albumin (fatty acid free) and all other reagents were of analytical grade from Sigma.

LDL isolation and treatment with PLA₂
LDL was isolated from expired human plasma obtained from the Blood Bank (University of Southern California Hospital). After ultracentrifugation on a density gradient of sodium bromide (27), LDL (d = 1.019–1.063) was collected, desalted using centrifugal filtering devices with a 30 kDa cutoff (Amicon), and equilibrated in 20 mM Tris-HCl, pH 7.8. Aliquots of LDL were incubated for 1 h at 37°C with different amounts of snake venom PLA₂ in Tris-HCl buffer (pH 7.8) containing 5 mM CaCl₂, in the absence or presence of 0.1% BSA. The enzyme appeared as a single band at 14 kDa on SDS-PAGE stained by Sypro Ruby, and there was no proteolytic activity associated with it (e.g., LDL^–apoB-100 after treatment with PLA₂ was intact; data not shown). In our assays, 1 ng of PLA₂ generated 1.4 µmol of free fatty acids per minute from 1 µg of LDL protein. Appropriate controls were incubated without PLA₂ under identical conditions. Thereafter, reactions were stopped by the addition of 10 mM EDTA (final concentration), and samples were cooled on ice and centrifuged using Amicon filters to remove PLA₂ and salts. Aliquots were taken from reaction mixtures for the measurement of free fatty acid content using a NEFA kit (WAKO). Protein was measured by a modified Lowry method using the Bio-Rad DC assay (Hercules, CA). Lipid peroxides were measured using leukomethylene blue assay with t-BuOOH as a standard (28). Reactive aldehydes were determined spectrophotometrically as thiobarbituric-reactive substances using a modification of a previously described method (6). Malondialdehyde (MDA) was used as a standard.

LDL^– separation, agarose gel electrophoresis, and oxidation of LDL samples
Native LDL, designated as control LDL, and PLA₂-treated samples were separated by HPLC using an anion-exchange column (UNO Q1; Bio-Rad). Normal LDL subfraction devoid of LDL^– (nLDL) and LDL^– fractions were eluted using a NaCl step gradient (from 0.22 to 0.28 M). The procedure for isolating LDL^– was otherwise identical to that described previously (6). Relative electrophoretic mobilities (REMs) of LDL samples were analyzed on agarose gels using the LIPO Gel kit (Beckman, Fullerton, CA). Oxidation of LDL was performed by diluting samples to 0.25 mg/ml and incubation with 10 µM CuSO₄ in PBS at 22°C. Formation of conjugated dienes was monitored continuously at 234 nm as described previously (29). In a series of experiments, samples of control and PLA₂-treated LDLs were incubated for 4 h with 0, 0.04, and 0.2 mM free fatty acid mixtures before subjecting them to oxidation. The free fatty acid mixture consisted of oleic, linoleic, and arachidonic acids at a ratio of 20:40:10. Thereafter, 1% BSA was added to the samples, incubated for 1 h, followed by overnight ultracentrifugation at 85,000 rpm using PBS buffer containing 30% sucrose to separate LDL from BSA.

For nitration, LDL samples at 0.2 mg/ml were incubated with 50 µM peroxynitrite (1 mol peroxynitrite/1 mol LDL^– tyrosine) for 30 min at 37°C. Ten micrograms of protein was dotted on polyvinylidene difluoride membranes and immunoblotted as described below.

Dot blot analysis
Polyvinylidene difluoride membranes with dots of different LDLs were incubated with oligomer-specific (1:10,000) or nitrotyrosine antibody (1:3,000) followed by incubation with appropriate HRP-conjugated secondary antibodies and visualization using the ECL kit (Pierce, Rockford, IL). Oligomer staining blots were blocked in 10% dry milk and TBS containing 0.001% Tween. Blots using secondary antibodies only were also used to assess the specificity of antibody staining. Nitrotyrosine and oligomer-specific blots were quantified by densitometry using Scion software (Scion Corp.).

Circular dichroism
Circular dichroism (CD) analysis of chloride anion-free LDL samples (reconstituted in phosphate buffer, pH 7.4) was performed using 100 µg/ml LDL protein. CD spectra were recorded on a JASCO-810 spectropolarimeter (Japan Spectroscopic Co., Tokyo, Japan) at room temperature using a 0.1 cm quartz cuvette in the region of 190–250 nm. At least 10 spectra for each sample were averaged, and blank measurements were subtracted. Secondary structures were analyzed using CDNN CD spectra deconvolution software.

Statistical analysis
At least three separate experiments were performed for each study, all samples being analyzed in triplicate and standard deviations calculated where appropriate. Significance was determined using Student's t-test and set at P < 0.05.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
LDL treatment with PLA₂ results in LDL^– formation
LDL treatment with snake venom PLA₂ for 1 h resulted in a dose-dependent increase in the net electronegative charge of the LDL particle (Fig. 1A). In the absence of BSA, the REM of particles was increased from 1 in control to 1.1 after incubation with 5 ng/ml PLA₂ and to 1.4 after treatment with 50 ng/ml PLA₂. The presence of 0.1% BSA slightly inhibited the REM increase (e.g., 1.25 versus 1.4 for treatment with 50 ng/ml PLA₂). Notably, PLA₂-treated LDL displayed smearing on agarose gels tailing down to the starting point (Fig. 1A), indicative of a heterogeneous population of particles with different REMs and possible aggregation. Consistent with the REM data, there was a dose-dependent increase in the LDL^– subfraction after incubation with PLA₂ in the presence and absence of 0.1% BSA (Fig. 1B). LDL^– levels increased from 1.41 ± 0.96% in controls to 4.3 ± 0.006% and 13.1 ± 4.3% after exposure to 5 and 50 ng/ml PLA₂, respectively. LDL^– levels were decreased in the presence of 0.1% BSA, being lower by 12% and 40% after treatment with 5 and 50 ng/ml PLA₂, respectively. The PLA₂ inhibitor quinacrine (100 µM) inhibited LDL^– formation by 50% (data not shown), confirming that this LDL^– production was attributable to LDL lipolysis. There was no change in the levels of lipid peroxides measured by leukomethylene blue assay before and after incubation with PLA₂. In all samples, lipid peroxides were below the detection limit. Increases in LDL^– and REM of PLA₂-treated LDL correlated well with the release of free fatty acids (Fig. 1C).

View larger version (24K): [in this window] [in a new window]   Fig. 1. Dose-dependent increase in relative electrophoretic mobility (REM) (A), electronegative low density lipoprotein (LDL–) levels (B), and free fatty acids (C) after treatment of LDL samples with phospholipase A2 (PLA2). LDL preparations at 1 mg/ml were incubated with 5 or 50 ng/ml PLA2 with or without 0.1% BSA for 1 h at 37°C. The specific activity of the PLA2 using LDL as a substrate is described in Materials and Methods. REM of control and PLA2-treated LDL was determined on agarose gels. LDL– was separated on a UNO Q1 column by anion-exchange chromatography, and levels were determined as described in Materials and Methods. Unesterified fatty acids in samples were measured using the NEFA kit. Error bars represent SD of averages of at least 3 individual experiments.

View larger version (21K): [in this window] [in a new window]   Fig. 2. Conformational changes in LDL– from control and PLA2-treated LDL. A: Dot blots of LDL samples were immunostained using oligomer-specific antibody. Control and PLA2-treated LDL samples were dotted on membranes and immunostained as described in Materials and Methods. B and C: CD spectra are shown for control (B) and PLA2-treated (C) LDL and their subfractions. For CD, LDL samples were dialyzed in phosphate buffer, diluted to 0.1 mg/ml, and analyzed by spectropolarimetry. An average of at least 10 CD spectra were taken for each sample, and representative spectra of experiments done in triplicate are shown. Aß, amyloid ß; agLDL, aggregated LDL; nLDL, normal LDL subfraction devoid of LDL–; tLDL, total LDL.

View larger version (26K): [in this window] [in a new window]   Fig. 3. Analysis of CD spectra of native (A) and PLA2-treated (B) LDL. Data from three separate measurements were analyzed using CDNN software. The region of 190–250 nm was taken for analysis of -helical and different ß-strand structures, such as parallel and anti-parallel ß-sheets, ß-turn, and random coil. LDL– subfractions from both native and PLA2-treated LDL displayed significantly lower levels of -helical structure with increases in all ß-sheet structures and random coil. * P < 0.05, * P < 0.005 compared with the tLDL data. Error bars represent SD of averages of at least 3 individual experiments.

View larger version (15K): [in this window] [in a new window]   Fig. 4. Peroxynitrite-induced nitrotyrosine (A) and malondialdehyde (MDA; B) formation in control and PLA2-treated LDL samples. After incubation with 50 µM peroxynitrite (1 mol peroxynitrite/1 mol tyrosine) for 30 min at room temperature, LDL samples were dotted on polyvinylidene difluoride membranes and blotted against nitrotyrosine (NT) antibody. A: Densitometry results of experiments performed at least in triplicate. B: MDA in the same samples was measured using thiobarbituric reactive substances (TBARS) assay. * P < 0.05, ** P < 0.005 compared with tLDL data. Error bars represent SD of averages of at least 3 individual experiments.

View larger version (17K): [in this window] [in a new window]   Fig. 5. Dose-dependent decrease in oxidizability of PLA2-treated LDL (A) and effect of fatty acid enrichment on LDL oxidation kinetics (B). A: Control and PLA2-treated LDL in the presence (dashed lines) and absence (bold lines) of 0.1% BSA was incubated with 10 µM Cu2+, and conjugated dienes were measured at 234 nm. B: In a series of experiments before oxidation, control and PLA2-treated LDL were enriched with free fatty acids at 0 mM (bold thick lines), 0.04 mM (dashed lines), and 0.2 mM (thin lines) as described in Materials and Methods. C: Calculated lag periods of oxidation kinetics after fatty acid enrichment of LDL samples. OD, optical density. Open bars, control LDL; closed bars, PLA2-treated LDL.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Most mechanisms that describe the formation of LDL^– resembling plasma LDL^– involve the oxidative modification of particles (6, 10). However, it has been suggested that plasma LDL^– may arise from a yet undescribed metabolic process acting on LDL (or an LDL precursor) to produce misfolding of apoB-100, which in turn imparts conformational changes to LDL^–-like particles (30). Enzymatic modifications of LDL have been described, including treatment with low molecular weight PLA₂ producing conformational changes in LDL (31). PLA₂-treated LDL has been previously shown by electron microscopy to appear as smaller, denser particles that have a tendency to aggregate (23, 24). Generation of small, dense LDL particles by sPLA₂ (types IIA, III, and X) has also been demonstrated (17, 18, 32). LDL particles modified by PLA₂ as well as by oxidation have greater extracellular matrix retention and can contribute to foam cell formation (18, 32, 33). These properties are also characteristic of plasma LDL^– (10). Consistent with these observations, PLA₂-treated LDL showed an increase in REM proportional to the LDL^– content. The REM and LDL^– content were dose-dependently correlated with the degree of phospholipid hydrolysis (Fig. 1).

LDL^– may be formed by reactions that are independent of lipid peroxidation. This could involve the association of particles with released negatively charged fatty acids after lipolysis. The accumulating negative charge may in turn mask positively charged residues. Benitez et al. (8) showed that the formation of LDL^– arises from free fatty acid association with LDL. However, this may only partially account for the increased electronegativity of lipolyzed LDL. Phospholipid hydrolysis can also produce conformational changes in apoB-100 that would expose different hydrophobic and hydrophilic residues and could account for the increased REM. ApoB-100 appears to undergo conformational changes during LDL lipolysis in the presence of albumin that preferentially binds fatty acids and lysophospholipids released by PLA₂, preventing their association with LDL. However, our findings show that in the presence of 0.1% albumin, PLA₂-treated LDL displayed a decrease in REM that was accompanied by significantly lower amounts of LDL^– formation (Fig. 1). This could simply be accounted for by lesser amounts of fatty acids associating with LDL particles than would occur in the absence of albumin, thus leading to a slightly decreased negative charge. In this case, the contribution of free fatty acids to the net negative charge of particles is not excluded.

The oligomer-specific antibody recognizes soluble oligomeric aggregates of some amyloidogenic proteins regardless of their amino acid sequences, suggesting a common structural feature among them (26). Therefore, the increased reactivity of LDL^– derived from plasma and PLA₂-LDL to this antibody represents a more specific conformational modification of apoB-100 with the formation of oligomeric aggregates that resemble amyloidogenic proteins. Previously, the ability to aggregate has been demonstrated for PLA₂-treated LDL and plasma LDL^– (23, 24, 26). However, this is different from the mechanically induced aggregation of LDL that probably does not induce the formation of the structural feature recognized by oligomer-specific antibody (Fig. 2A). Interestingly, soluble oligomers appear to be the most toxic species of amyloids, thus implicating stronger biological activity to PLA₂-LDL and LDL^– subfractions. Whether the atherogenic properties described for plasma LDL^– (27) and PLA₂-LDL (18, 32, 33) are related to the observed specific structural conformations needs further investigation. Furthermore, conformational modification of lipolyzed LDL resulted in significant conversion of apoB-100 to the ß-sheet conformation (Fig. 2A), as demonstrated by CD (Figs. 2B, C, 3). This appears to be a general characteristic of modified LDLs that have >10% of their particles converted to LDL^– (Table 1). LDLs modified by hemoglobin and by mild oxidation with copper, as well as PLA₂-LDL, showed increased ß-strand content proportional to the extent of apoB-100 unfolding (Table 1). Therefore, disruption of the apoB-100-lipid interaction in LDL by means of either peroxidation or compositional alteration may lead to structural reorganization of the particle. A 50% reduction in phospholipid content of LDL results in a 25% decrease in surface area, producing smaller and denser particles (23). This would produce altered folding of apoB-100 sufficient to accommodate a more compact structure, enabling greater interactions with the lipids remaining on the surface as well as the particle core. This is consistent with the pentapartite computer-generated model for LDL (34) that designates -helices as flexible surface lipid binding domains (allowing for expansion or contraction of particles) and ß-strands that tightly associate with the neutral lipid core as well as amphipathic domains.

LDL treatment with PLA₂ leads to unfolding of apoB-100 and possible exposure of new regions to oxidative or otherwise modifying reactions. One consequence of this could be the exposure of tyrosine residues to an environment more conducive to nitration. A comparable presentation of hydrophobic domains of apoB-100 after its unfolding has been shown by analysis of tryptophan fluorescence lifetimes in LDL^– (11). Comparison of fluorescence lifetimes between nLDL and LDL^– showed that tryptophan residues of LDL^– were buried in more hydrophobic domains. PLA₂-LDL as well as plasma-derived LDL^– demonstrated increased susceptibility to nitration by peroxynitrite (Fig. 4A). Interestingly, an inverse correlation between protein nitration and lipid peroxidation levels was found in LDL after PLA₂ treatment (Fig. 4B). Lipid oxidation has been shown to accompany nitration of LDL by peroxynitrite (35); however, lipolysis of LDL limits the lipid substrate available for peroxidation, slowing the catalysis of lipid oxidation by peroxynitrite. This is in good agreement with the results of copper-mediated LDL oxidation of lipase-hydrolyzed particles (Fig. 5).

LDL^– represents a modified LDL that can be generated by various reactions that in virtually all cases produce particles highly susceptible to lipid peroxidation. This is considered to be a prominent characteristic of atherogenic LDL. For example, LDL treated with lipoprotein lipase and phospholipase is more prone to lipoxygenase-induced oxidation (36). LDL^– isolated from plasma and mixtures enriched with LDL^– also have substantially increased sensitivity to copper- or heme-mediated oxidation (10). The unfolding of apoB-100 also appears to make LDL more susceptible to oxidation (30). However, unlike LDL^– from plasma, treatment with PLA₂ produces LDL that is more resistant to copper-mediated oxidation, as illustrated by the significantly longer oxidation lag period (Fig. 5) and by the formation of less MDA content compared with that of control LDL after treatment with peroxynitrite (Fig. 4B). The LDL^– produced by PLA₂ could be uniquely more oxidation resistant as a result of lower peroxide content and fewer unsaturated fatty acids, two important components of catalytic initiation and the propagation of lipid peroxidation. However, in the absence of albumin, free fatty acids would accumulate within LDL particles, producing micellar structures that are more resistant to copper-mediated oxidation than the monolayer structure of LDL. Indeed, increased oxidative resistance has been shown for LDL enriched with free fatty acids (8, 37, 38). Benitez et al. (8) reported that adding fatty acids in excess of 50 mol/mol LDL protein strongly inhibited oxidation. In our PLA₂-LDL reactions, generation of even lesser amounts of free fatty acids (30 mol/mol LDL using 5 ng/ml PLA₂) already resulted in an increased lag of copper oxidation of LDL (Figs. 1C, 4A). It is plausible that intact oxidizable phospholipids bearing unsaturated fatty acids and arranged in the monolayer configurations found in LDL are required to induce lipid peroxidation. This is consistent with long-established theories for lipid peroxidation in ordered systems (39) and with the remarkable difference in susceptibility to copper-mediated oxidation of liposomes or micelles compared with LDL. Addition of more unsaturated fatty acids to PLA₂-treated LDL in the presence of albumin reversed the oxidative resistance (Fig. 5C). This may be accounted for by substantially more unsaturated fatty acid retention on PLA₂-LDL after LDL separation from albumin (Table 2). PLA₂-LDL possesses greater negative surface charge that is in part explained by apoB-100 conformational changes.

In conclusion, LDL hydrolysis by PLA₂ generates LDL^– particles with structural similarities to circulating LDL^– as well as other modified LDLs containing increased proportions of LDL^–. A potential role for secretory PLA₂ is implicated during the formation of atherogenic LDL particles. Because the resultant modified LDL is less susceptible to oxidation, our findings suggest that initial modification of LDL by sPLA₂ can be protective in terms of oxidative/inflammatory/atherogenic effects. However, when PLA₂-treated LDL particles acquire small amounts of unsaturated fatty acids, are exposed to catalyst such as lipoxygenase (36), or undergo lipid exchange or other interactions with lipoproteins, the particles assume enhanced susceptibility to oxidation as described for LDL^– particles in general.

	ACKNOWLEDGMENTS

 
This study was supported by National Institutes of Health Grant HL-50350 (A.S.).

Manuscript received August 12, 2004 and in revised form September 30, 2004.

	REFERENCES

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

1. Sevanian, A., G. Bittolo-Bon, G. Cazzolato, H. Hodis, J. Hwang, A. Zamburlini, M. Maiorino, and F. Ursini. 1997. LDL^– is a lipid hydroperoxide-enriched circulating lipoprotein. J. Lipid Res. 38: 419–428.[Abstract]

2. Sevanian, A., L. Asatryan, and O. Ziouzenkova. 1999. Low density lipoprotein (LDL) modification: basic concepts and relationship to atherosclerosis. Blood Purif. 17: 66–78.[CrossRef][Medline]

3. Sanchez-Quesada, J. L., C. Otal-Entraigas, M. Franco, O. Jorba, F. Gonzalez-Sastre, F. Blanco-Vaca, and J. Ordonez-Llanos. 1999. Effect of simvastatin treatment on the electronegative low-density lipoprotein present in patients with heterozygous familial hypercholesterolemia. Am. J. Cardiol. 84: 655–659.[CrossRef][Medline]

4. Sanchez-Quesada, J. L., A. Perez, A. Caixas, J. Ordonez-Llanos, G. Carreras, A. Payes, F. Gonzalez-Sastre, and A. de Leiva. 1996. Electronegative low density lipoprotein subform is increased in patients with short-duration IDDM and is closely related to glycaemic control. Diabetologia. 39: 1469–1476.[CrossRef][Medline]

5. Moro, E., C. Zambon, S. Pianetti, G. Cazzolato, M. Pais, and G. Bittolo-Bon. 1998. Electronegative low density lipoprotein subform (LDL^–) is increased in type 2 (non-insulin-dependent) microalbuminuric diabetic patients and is closely associated with LDL susceptibility to oxidation. Acta Diabetol. 35: 161–164.[CrossRef][Medline]

6. Ziouzenkova, O., L. Asatryan, M. Akmal, C. Tetta, M-L. Wratten, J. Heinecke, and A. Sevanian. 1999. Cross-linking between low density lipoprotein apoB and hemoglobin mediates conversion to electronegative LDL^– during the ex-vivo blood circulation. J. Biol. Chem. 274: 18916–18924.[Abstract/Free Full Text]

7. Sanchez-Quesada, J. L., O. Jorba, A. Payes, C. Otal, R. Serra-Grima, F. Gonzalez-Sastre, and J. Ordonez-Llanos. 1998. Ascorbic acid inhibits the increase in low-density lipoprotein (LDL) susceptibility to oxidation and the proportion of electronegative LDL induced by intense aerobic exercise. Coron. Artery Dis. 9: 249–255.[Medline]

8. Benitez, S., J. L. Sanchez-Quesada, L. Lucero, R. Arcelus, V. Ribas, O. Jorba, A. Castellvi, E. Alonso, F. Blanco-Vaca, and J. Ordonez-Llanos. 2002. Changes in low-density lipoprotein electronegativity and oxidizability after aerobic exercise are related to the increase in associated non-esterified fatty acids. Atherosclerosis. 160: 223–232.[CrossRef][Medline]

9. Ursini, F., and A. Sevanian. 2002. Postprandial oxidative stress. Biol. Chem. 383: 599–605.[CrossRef][Medline]

10. Sevanian, A., J. Hwang, H. N. Hodis, G. Cazzolato, P. Avogaro, and G. Bittolo-Bon. 1996. Contribution of an in vivo oxidized LDL to LDL oxidation and its association with dense LDL subpopulations. Arterioscler. Thromb. 16: 784–793.[Abstract/Free Full Text]

11. Parasassi, T., G. Bittolo-Bon, R. Brunelli, G. Cazzolato, E. K. Krasnowska, G. Mei, A. Sevanian, and F. Ursini. 2001. Loss of apoB-100 secondary structure and conformation in hydroperoxide rich, electronegative LDL(–). Free Radic. Biol. Med. 31: 82–89.[CrossRef][Medline]

12. Fabjan, J. S., P. M. Abuja, R. J. Schaur, and A. Sevanian. 2001. Hypochlorite induces the formation of LDL^–, a potentially atherogenic low density lipoprotein subspecies. FEBS Lett. 499: 69–72.[CrossRef][Medline]

13. Kuhn, H., J. Belkner, H. Suzuki, and S. Yamamoto. 1994. Oxidative modification of human lipoproteins by lipoxygenases of different positional specificities. J. Lipid Res. 35: 1749–1759.[Abstract]

14. Pentikainen, M. O., R. Oksjoki, K. Oorni, and P. T. Kovanen. 2002. Lipoprotein lipase in the arterial wall: linking LDL to the arterial extracellular matrix and much more. Arterioscler. Thromb. Vasc. Biol. 22: 211–217.[Abstract/Free Full Text]

15. Hwang, J., J. Wang, P. Morazzoni, H. N. Hodis, and A. Sevanian. 2003. The phytoestrogen equol increases nitric oxide availability by inhibiting superoxide production: an antioxidant mechanism for cell-mediated LDL modification. Free Radic. Biol. Med. 34: 1271–1282.[CrossRef][Medline]

16. Hwang, J., M. H. Ing, A. Salazar, B. Lassegue, K. Griendling, M. Navab, A. Sevanian, and T. K. Hsiai. 2003. Pulsatile versus oscillatory shear stress regulates NADPH oxidase subunit expression: implication for native LDL oxidation. Circ. Res. 93: 1225–1232.[Abstract/Free Full Text]

17. Hurt-Camejo, E., G. Camejo, and P. Sartipy. 2000. Phospholipase A₂ and small, dense low-density lipoprotein. Curr. Opin. Lipidol. 11: 465–471.[CrossRef][Medline]

18. Jaross, W., R. Eckey, and M. Menschikowski. 2002. Biological effects of secretory phospholipase A(2) group IIA on lipoproteins and in atherogenesis. Eur. J. Clin. Invest. 32: 383–393.[CrossRef][Medline]

19. Menschikowski, M., M. Kasper, P. Lattke, A. Schiering, S. Schiefer, H. Stockinger, and W. Jaross. 1995. Secretory group II phospholipase A₂ in human atherosclerotic plaques. Atherosclerosis. 118: 173–181.[CrossRef][Medline]

20. Hurt-Camejo, E., S. Andersen, R. Standal, B. Rosengren, P. Sartipy, E. Stadberg, and B. Johansen. 1997. Localization of nonpancreatic secretory phospholipase A₂ in normal and atherosclerotic arteries. Activity of the isolated enzyme on low-density lipoproteins. Arterioscler. Thromb. Vasc. Biol. 17: 300–309.[Abstract/Free Full Text]

21. Schiering, A., M. Menschikowski, E. Mueller, and W. Jaross. 1999. Analysis of secretory group II phospholipase A₂ expression in human aortic tissue in dependence on the degree of atherosclerosis. Atherosclerosis. 144: 73–78.[CrossRef][Medline]

22. Gorshkova, I. N., M. Menschikowski, and W. Jaross. 1996. Alterations in the physiochemical characteristics of low and high density lipoproteins after lipolysis with phospholipase A₂. A spin-label study. Biochim. Biophys. Acta. 1300: 103–113.[Medline]

23. Sartipy, P., G. Camejo, L. Svensson, and E. Hurt-Camejo. 1999. Phospholipase A(2) modification of low density lipoproteins forms small high density particles with increased affinity for proteoglycans and glycosaminoglycans. J. Biol. Chem. 274: 25913–25920.[Abstract/Free Full Text]

24. Oorni, K., J. K. Hakala, A. Annila, M. Ala-Korpela, and P. T. Kovanen. 1998. Sphingomyelinase induces aggregation and fusion, but phospholipase A₂ only aggregation, of low density lipoprotein (LDL) particles. Two distinct mechanisms leading to increased binding strength of LDL to human aortic proteoglycans. J. Biol. Chem. 273: 29127–29134.[Abstract/Free Full Text]

25. Eckey, R., M. Menschikowski, P. Lattke, and W. Jaross. 1997. Minimal oxidation and storage of low density lipoproteins result in an increased susceptibility to phospholipid hydrolysis by phospholipase A₂. Atherosclerosis. 132: 165–176.[CrossRef][Medline]

26. Kayed, R., E. Head, J. L. Thompson, T. M. McIntire, S. C. Milton, C. W. Cotman, and C. G. Glabe. 2003. Common structure of soluble amyloid oligomers implies common mechanism of pathogenesis. Science. 300: 486–489.[Abstract/Free Full Text]

27. Hodis, H. N., D. M. Kramsch, P. Avogaro, G. Bittolo-Bon, G. Cazzolato, J. Hwang, H. Peterson, and A. Sevanian. 1994. Biochemical and cytotoxic characteristics of an in vivo circulating oxidized low density lipoprotein (LDL^–). J. Lipid Res. 35: 669–677.[Abstract]

28. Auerbach, B. J., J. S. Kiely, and J. A. Cornicelli. 1992. A spectrophotometric microtiter-based assay for the detection of hydroperoxy derivatives of linoleic acid. Anal. Biochem. 201: 375–380.[CrossRef][Medline]

29. Quehenberger, O., G. Jurgens, S. Zadravec, and H. Esterbauer. 1988. Oxidation of human low density lipoprotein initiated by copper (II) chloride. Basic Life Sci. 49: 387–390.[Medline]

30. Ursini, F., K. J. Davies, M. Maiorino, T. Parasassi, and A. Sevanian. 2002. Atherosclerosis: another protein misfolding disease? Trends Mol. Med. 8: 370–374.[CrossRef][Medline]

31. Oorni, K., M. O. Pentikainen, M. Ala-Korpela, and P. T. Kovanen. 2000. Aggregation, fusion, and vesicle formation of modified low density lipoprotein particles: molecular mechanisms and effects on matrix interactions. J. Lipid Res. 41: 1703–1714.[Abstract/Free Full Text]

32. Hanasaki, K., K. Yamada, S. Yamamoto, Y. Ishimoto, A. Saiga, T. Ono, M. Ikeda, M. Notoya, S. Kamitani, and H. Arita. 2002. Potent modification of low density lipoprotein by group X secretory phospholipase A₂ is linked to macrophage foam cell formation. J. Biol. Chem. 277: 29116–29124.[Abstract/Free Full Text]

33. Jessup, W., and L. Kritharides. 2000. Metabolism of oxidized LDL by macrophages. Curr. Opin. Lipidol. 11: 473–481.[CrossRef][Medline]

34. Segrest, J. P., M. K. Jones, V. K. Mishra, G. M. Anantharamaiah, and D. W. Garber. 1994. apoB-100 has a pentapartite structure composed of three amphipathic alpha-helical domains alternating with two amphipathic beta-strand domains. Detection by the computer program LOCATE. Arterioscler. Thromb. 14: 1674–1685.[Abstract/Free Full Text]

35. Rubbo, H., R. Radi, M. Trujillo, R. Telleri, B. Kalyanaraman, S. Barnes, M. Kirk, and B. A. Freeman. 1994. Nitric oxide regulation of superoxide and peroxynitrite-dependent lipid peroxidation. Formation of novel nitrogen-containing oxidized lipid derivatives. J. Biol. Chem. 269: 26066–26075.[Abstract/Free Full Text]

36. Neuzil, J., J. M. Upston, P. K. Witting, K. F. Scott, and R. Stocker. 1998. Secretory phospholipase A₂ and lipoprotein lipase enhance 15-lipoxygenase-induced enzymic and nonenzymic lipid peroxidation in low-density lipoproteins. Biochemistry. 37: 9203–9210.[CrossRef][Medline]

37. Viens, L., A. Athias, G. Lizard, G. Simard, S. Gueldry, S. Braschi, P. Gambert, C. Lallemant, and L. Lagrost. 1996. Effect of lipid transfer activity and lipolysis on low density lipoprotein (LDL) oxidizability: evidence for lipolysis-generated non-esterified fatty acids as inhibitors of LDL oxidation. J. Lipid Res. 37: 2179–2192.[Abstract]

38. Skoglund-Andersson, C., F. Karpe, M. L. Hellenius, J. Regnstrom, A. Hamsten, and P. Tornvall. 2003. In vitro and in vivo lipolysis of plasma triglycerides increases the resistance to oxidative modification of low-density lipoproteins. Eur. J. Clin. Invest. 33: 51–57.[CrossRef][Medline]

39. Prassl, R., B. Schuster, P. Laggner, C. Flamant, F. Nigon, and M. J. Chapman. 1998. Thermal stability of apolipoprotein B100 in low-density lipoprotein is disrupted at early stages of oxidation while neutral lipid core organization is conserved. Biochemistry. 37: 938–944.[CrossRef][Medline]

CiteULike

Complore

Connotea

Del.icio.us

Digg

Reddit

Technorati

This article has been cited by other articles:

				L. Ai, M. Rouhanizadeh, J. C. Wu, W. Takabe, H. Yu, M. Alavi, R. Li, Y. Chu, J. Miller, D. D. Heistad, et al. Shear stress influences spatial variations in vascular Mn-SOD expression: implication for LDL nitration Am J Physiol Cell Physiol, June 1, 2008; 294(6): C1576 - C1585. [Abstract] [Full Text] [PDF]

				J. Lu, W. Jiang, J.-H. Yang, P.-Y. Chang, J. P. Walterscheid, H.-H. Chen, M. Marcelli, D. Tang, Y.-T. Lee, W. S.L. Liao, et al. Electronegative LDL Impairs Vascular Endothelial Cell Integrity in Diabetes by Disrupting Fibroblast Growth Factor 2 (FGF2) Autoregulation Diabetes, January 1, 2008; 57(1): 158 - 166. [Abstract] [Full Text] [PDF]

				M. Sneck, P. T. Kovanen, and K. Oorni Decrease in pH Strongly Enhances Binding of Native, Proteolyzed, Lipolyzed, and Oxidized Low Density Lipoprotein Particles to Human Aortic Proteoglycans J. Biol. Chem., November 11, 2005; 280(45): 37449 - 37454. [Abstract] [Full Text] [PDF]

This Article Abstract Full Text (PDF) All Versions of this Article: M400306-JLR200v1 46/1/115    most recent Alert me when this article is cited Alert me if a correction is posted Citation Map Services Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Asatryan, L. Articles by Sevanian, A. Search for Related Content PubMed PubMed Citation Articles by Asatryan, L. Articles by Sevanian, A. Social Bookmarking                      What's this?