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J Biol Chem, Vol. 274, Issue 29, 20406-20414, July 16, 1999
-(Hexanonyl)lysine in
Protein Exposed to Lipid Hydroperoxide
**,
, and
From the School of Humanities for Environmental
Policy and Technology, Himeji Institute of Technology, Himeji
670-0092, the § Department of Applied Biological Sciences,
Nagoya University, Nagoya 464-8601, and the ¶ Department of
Pathology and 1st Department of Medicine, National Defense
Medical College, Saitama 359-0042, Japan
 |
ABSTRACT |
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 TOP
 ABSTRACT
 INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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The objectives of this study were to estimate the
structure of the lipid hydroperoxide-modified lysine residue and to
prove the presence of the adducts in vivo. The reaction of
lipid hydroperoxide toward the lysine moiety was investigated employing
N-benzoyl-glycyl-L-lysine (Bz-Gly-Lys) as a
model compound of Lys residues in protein and 13-hydroperoxyoctadecadienoic acid (13-HPODE) as a model of the lipid
hydroperoxides. One of the products, compound X, was isolated from the
reaction mixture of 13-HPODE and Bz-Gly-Lys and was then identified as
N-benzoyl-glycyl-N During lipid peroxidation, biomolecules such as proteins or
aminolipids can be covalently modified by lipid decomposition products.
For the case of aliphatic aldehydes (alkanals) such as 1-hexanal or
1-nonanal, the N To estimate the structure after lipid hydroperoxide-derived lysine
modification, the reaction of 13-hydroperoxyoctadecadienoic acid
(13-HPODE)1 with
N-benzoyl-glycyl-L-lysine (Bz-Gly-Lys) was
investigated. In this study, a novel compound,
N-benzoyl-glycyl-N Materials--
The chemicals used were from the following
sources. Bz-Gly-Lys and N-acetyl-glycyl-L-lysine
methyl ester (AGLME) were purchased from Peptide, Inc. Soybean
lipoxygenase, lipid-free BSA (product number A7511, initial
fractionation by cold alcohol precipitation, Preparation of Lipid Hydroperoxides--
13-HPODE was prepared
by the enzymatic reaction of lipoxygenase with linoleic acid (9, 10).
15-Hydroperoxyeicosatetraenoic acid (15-HPETE) was prepared as
described previously (9, 10). Methyl linoleate hydroperoxide (MLOOH)
was prepared by the reaction of soybean lipoxygenase with methyl
linoleate (ML). A 200-mg sample of ML and sodium deoxycholate
(1.62 g) was dissolved in 240 ml of 200 mM borate
buffer (pH 9.0). Lipoxygenase (100 mg, Sigma type I-B) was added to the
solution and reacted for 3 h at room temperature. The formed
peroxide was extracted twice with an equal amount of
chloroform/methanol (1:1). The collected chloroform layer was
evaporated. The obtained peroxide was purified by thin layer
chromatography (TLC) and developed with n-hexane/ether
(6:4). The peroxide was extracted with CHCl3 and then
evaporated. The amount of MLOOH was calculated from the molar
coefficient, Reaction Conditions--
Bz-Gly-Lys (5 mM) and
lipid-free BSA (5 mg/ml) were typically incubated with 13-HPODE,
15-HPETE, or MLOOH (5 mM) at 37 °C in 0.1 M
phosphate buffer (pH 7.4) for 3 days. The lipid hydroperoxide-modified proteins were isolated by ethanol precipitation as already described (9, 10).
Isolation and Structural Determinations of Compound X--
To
obtain 13-HPODE-modified Bz-Gly-Lys, 5 mM Bz-Gly-Lys was
incubated with 5 mM 13-HPODE for 3 days at 37 °C in
phosphate buffer and then freeze-dried. The sample was extracted with
methanol to remove the large amounts of inorganic salts. The extract
was evaporated, dissolved in H2O, and then applied to gel
filtration chromatography (TOYOPEAL HW-40F, 1.5 × 50 cm) with
H2O as an eluent at a flow rate of 0.8 ml/min. The
fractions (5 ml each) were monitored by absorbance at 234 nm and
lipofuscin-like fluorescence (excitation, 350 nm; emission, 420 nm)
using a JASCO Ubest-50 UV-visible spectrophotometer and Hitachi F2000
fluorescence spectrophotometer, respectively. The fluorescent fractions
29-34 were used for further identification because the fluorescence
might be considered as a marker of lipid amine adducts. The fluorescent
fractions were concentrated and then applied to a Sep-Pak cartridge
(Waters) with 0-100% methanol (20% stepwise) elution. The 20%
methanol fraction was used for the isolation of the modified lysine
derivative, because it had the strongest fluorescence. The fraction was
next applied to reversed-phase HPLC (Develosil ODS-HG-5 (8 × 250 mm), Nomura Chemical Co.) and then fractionated using gradient elution
(solvent A, 0.1% acetic acid/CH3CN (7/3); solvent B, 0.1%
acetic acid/CH3CN (1/1)) at a flow rate of 2.0 ml/min. The
gradient program was as follows: 0 min (B 0%), 10 min (B 0%), 50 min
(B 100%), 60 min (B 100%), and 61 min (B 0%). The elution was
monitored by UV absorbance at 234 nm. The peak (retention time 30 min)
was further purified by repeated reversed-phase HPLC. The obtained
compound X weighed 1.3 mg. Spectral data of the isolated compound X are
as follows: 1H NMR (CD3OD) (ppm) 0.80 (t,
J = 6.9Hz, 3H), 1.19 (m, 2H), 1.23 (m, 2H), 1.32 (m,
2H), 1,42 (m, 2H), 1.49 (m, 2H), 1.62 (m, 1H), 1.83 (m, 1H), 2.06 (t,
J = 7.7Hz, 2H), 3.05 (t, J = 6.7Hz, 2H), 3.99 (m, 2H), 4.30 (m, 1H), 7.37 (t, J = 5.1Hz, 2H), 7.45 (t, J = 5.1Hz, 1H),
7.78 (d, J = 7.1Hz, 2H); FAB+-MS
m/z 406 (M+H)+, 428 (M+Na)+.
Synthesis of
N-benzoyl-glycyl-N
N-Benzoyl-glycyl-N Synthesis of
N-acetyl-glycyl-N Amino Acid Analysis--
Samples were hydrolyzed with 6 N HCl in vacuo at 105 °C. The hydrolysates
were dried, dissolved in citrate buffer (pH 2.2), and then applied to
an amino acid analyzer, JLC-500 (JEOL).
Preparation of Antibody against Hexanonyl Keyhole Limpet
Hemocyanin--
The conjugation of hexanoic acid with proteins was
performed as follows. Hexanoic acid (2.3 mg), EDC (4.5 mg), and
sulfo-NHS (5 mg) were dissolved in 400 µl of dimethylformamide, and
the reaction mixture was incubated for 24 h at room temperature.
To the solution, 0.95 ml of KLH or BSA (10 mg in 0.1 M
phosphate buffer (pH 7.4)) was added and further incubated for 4 h
at room temperature. The obtained hexanonyl proteins were dialyzed
against phosphate-buffered saline (PBS) for 3 days at 4 °C. The
hexanonyl KLH was emulsified with an equal volume of complete Freund's
adjuvant to a final concentration of 0.5 mg/ml, and 1 ml of the
solution was then intramuscularly injected into a New Zealand White
rabbit. After 4 weeks, 1 ml of the hexanonyl KLH emulsified with an
equal volume of incomplete adjuvant (0.5 mg/ml) was injected as a
booster every 2 weeks until an adequate antibody generation occurred. Hexanonyl BSA was used for the evaluation of the antibody generation specific to hexanonyl protein.
Preparation of Chemically Modified Proteins--
Conjugates of
acetic acid (C2), propionic acid (C3), butyric acid (C4), valeric acid
(C5), heptanoic acid (C7), octanoic acid (C8), nonanoic acid (C9),
decanoic acid (C10), and undecanoic acid (C11) with BSA were prepared
using EDC and NHS as coupling agents as described previously. Glutaric
acid-BSA was prepared as follows (13). Briefly, lipid-free BSA (4 mg/ml) in PBS was mixed with an equal volume of saturated sodium
acetate. Under ice-cool conditions, glutaric anhydride (3 mM) was added and reacted for 1 h. The modified BSA
was dialyzed against water at 4 °C for 24 h. Azelaic acid-BSA
conjugate was prepared as follows. First, the monomethylazelaic
acid (50 mg), EDC (52.2 mg), and NHS (31.3 mg) in dimethylformamide
(1 ml) were incubated at room temperature for 24 h. Five
milliliters of BSA solution (30 mg/ml in 0.1 M phosphate
buffer (pH 7.4)) was then added to the solution and then incubated at
room temperature for 16 h. The reaction mixture was dialyzed
against PBS at 4 °C for 3 days. Azelaic acid-BSA conjugate was
prepared from obtained monomethylazelaic acid-BSA by saponification.
Alkaine solution (0.25 M NaOH) was added to the
monomethylazelaic acid-BSA and further incubated for 1 h. After
neutralization with HCl, the reaction mixture was dialyzed against PBS
at 4 °C for 24 h. These conjugations were evaluated by the
trinitrobenzenesulfonic acid method (14). The losses (%) of lysine
residue were as follows: C2, 72%; C3, 40%; C4, 17%; C5, 90%; C6
(hexanonyl BSA), 91%; C7, 91%; C8, 89%; C9, 89%; C10, 94%; C11,
90%; glutaric acid-BSA, 38%; azelaic acid-BSA, 62%.
Oxidized lipid-modified proteins were prepared as follows. Lipid
(linoleic acid and arachidonic acid, 5 mM; cardiolipin, 1 mg/ml) was oxidized by 5 mM ascorbic acid and 0.05 mM FeCl3 for 24 h at 37 °C in PBS
containing 20% methanol. To the reaction mixture, lipid-free BSA
(final concentration, 5 mg/ml) was added and further incubated at
37 °C for 3 days. To isolate the modified proteins, an equal amount
of CHCl3:CH3OH (2:1) was added, vigorously mixed, and then centrifuged for 10 min at 4 °C. The lower layer was
discarded, and an equal amount of CHCl3 was added and
mixed. After centrifugation, the lower layer was discarded again. To the residual upper layer, 9 volumes of ice-cool ethanol was added and
kept for 45 min at 4 °C. After centrifugation, the pellet was
dissolved in water with sonication. The protein solution was dialyzed
against water for 2 days at 4 °C. Aldehyde-modified proteins were
prepared as already described (9, 10). The preparation of lipid
hydroperoxide-modified proteins was as follows. The hydroperoxides (13-HPODE or 15-HPETE) were incubated with lipid-free BSA at 37 °C
in 0.1 M phosphate buffer (pH 7.4) for 3 days. Oxidized BSA was prepared by the incubation of lipid free-BSA with hydrogen peroxide/metal ion (9, 10). Modified proteins were dialyzed against PBS
at 4 °C for 2 days. The concentration of all modified proteins was
measured by a BCA assay kit (Pierce).
Modification of LDL--
Human LDL was isolated from healthy
volunteers using density centrifugation (15). The modification of LDL
was performed by copper ion and
2,2'-azobis(2-amidinopropane)dihydrochloride (AAPH) as described
previously (9). The modification by copper ion was performed by
incubation of LDL (0.2 mg/ml) with 50 µM CuSO4 in PBS at 37 °C. AAPH-induced oxidation of LDL was
carried out by incubation of AAPH (0-5 mM) with LDL (0.2 mg/ml) in PBS at 37 °C for 24 h. The reaction was terminated by
the addition of 10 µM butylated hydroxytoluene and 1 mM EDTA. The measurements of lipid peroxidation were
performed by the following two methods. The generation of
thiobarbituric acid reactive substance was measured as described
previously (9, 10). The formation of lipid peroxide was measured by a
Determiner LPO kit (Kyowa medix), a colorimetric method based on the
reaction of lipid peroxides with a methylene blue derivative in the
presence of hemoglobin (16).
LC-MS Measurement--
The sample was applied to a liquid
chromatograph on a Develosil ODS-HG-5 (4.6 × 250 mm), which was
connected with a mass spectrometer (PLATFORM II, VG Biotech). The
separation was performed by a two-pump gradient. The solvent A for
AGLME was 0.1% acetic acid; solvent B for AGLME was CH3CN.
For the Bz-Gly-Lys system, solvent A was 0.1% acetic acid,
CH3CN(7/3), and solvent B was 0.1% acetic acid, CH3CN (3:7). The gradient programs were as follows: AGLME,
0 min, A 100%; 70 min, A 30%; 75 min, A 30%; 80 min, A 100%.
Bz-Gly-Lys, 0 min, A 100%; 30 min, A 0%; 35 min, A 0%; 40 min, A
100%. The electrospray ionization (positive) mode was used for the
detection. For the measurements of the
N Enzyme-linked Immunosorbent Assay (ELISA)--
Indirect
noncompetitive ELISA was performed as already described (9, 10).
Briefly, 50 µl of antigen in PBS was dispensed into a well and kept
at 4 °C overnight. After blocking with Block Ace (Dainihon Seiyaku,
Osaka, Japan), 100 µl of antiserum (1/5000 in PBS containing 0.5%
BSA) was added to the well. The binding of the antibody on the coated
antigen was evaluated as already described (9, 10).
The cross-reactivity of the low molecular weight compound with antibody
was investigated by indirect competitive ELISA (9, 10). As a coating
agent, 50 µl of hexanonyl BSA (0.5 µg/ml) was pipetted onto wells
and kept at 4 °C overnight. At the same time, 50 µl of antiserum
(1/2500 in PBS containing 1% BSA) and 50 µl of sample were mixed in
an Eppendolf tube and reacted at 4 °C overnight. The plate was
washed, and 90 µl of the reacted solution was pipetted onto a well.
The binding of the residual antibody on coated hexanonyl BSA was
estimated as described previously (9, 10).
Reaction between Preincubated 13-HPODE and Lysine
Residue--
The effects of the preincubation of 13-HPODE on the
formation of N Immunohistochemical Analysis--
Tissue sections were prepared
from frozen arteries (8 µm thick). Before immunostaining, frozen
sections were fixed by incubation in ice-cold acetone for 20 min.
Sections were incubated with 10% normal goat serum in PBS (20 min) to
block nonspecific binding before staining and then with primary
antibody (1:350 dilution) for 1 h at room temperature. Sections
were incubated with 5% normal rabbit serum or the anti-HEL antibody
preabsorbed with hexanonyl BSA instead of the primary antibody as
negative controls. Immunostaining was performed with anti-rabbit
antibody peroxidase-label (1:50 dilution, DAKO) with hydrogen peroxide
and 3,3-diaminobenzidine tetrahydrochloride as chromogen. Sections were
counterstained with aqueous hematoxylin.
Isolation of Lipid Hydroperoxide-modified Lysine
Derivative--
To search for the specific hydroperoxide-derived
lysine modification, we used Bz-Gly-Lys as the substrate, and the
isolation of the 13-HPODE-modified lysine derivative was performed. To
remove large amounts of unreacted Bz-Gly-Lys, the reaction mixture was concentrated and then applied to gel filtration chromatography using
TOYOPEAL HW-40 (TOSOH) as a gel. The fractions were monitored by
absorbance at 234 nm and lipofuscin-like fluorescence (Fig. 1A). As a result of the HPLC
analysis of each fraction, fractions 35-40 contained the unreacted
substrate, Bz-Gly-Lys. Fractions 29-34 had a lipofuscin-like
fluorescence, which could be considered as a marker of lipid
decomposition product-modified molecules. Therefore, the fluorescent
fractions were used for further isolation. The mixed fractions 29-34
were applied to a Sep-Pak cartridge with stepwise methanol elutions.
The HPLC profile of the 20% methanol fraction is shown in Fig.
1B. A compound, labeled X, was then isolated by repeated
reversed-phase HPLC.
Identification of N
To further confirm the formation of the
N The Mechanism for Formation of HEL--
HEL was formed by the
reaction of AGLME with 15-HPETE as well as 13-HPODE (Fig.
4, A and B). The
reaction of methyl linoleate hydroperoxide with AGLME could also
generate the HEL derivative (Fig. 4C). The relative ratio of
the formation of HEL from 13-HPODE, 15-HPETE, and MLOOH was
1:0.49:0.47. These results suggested that the adduct should be formed
from not only free fatty acid hydroperoxides but also esterified fatty
acid hydroperoxides, such as cholesteryl ester hydroperoxide and
phosphatidylcholine hydroperoxide.
Hexanal, one of the lipid decomposition products, can react with lysine
and form a Schiff base. However, HEL does not have a Schiff base in its
structure. To deny the participation of 1-hexanal in the amide bond
formation, the formation of N
Furthermore, the catalytic activity of peroxide on the formation of the
amide bond was also investigated. The
N Preparation of Antibody to HEL--
It is difficult to detect HEL
moiety in protein molecules or tissue samples by chemical methods
because HEL is unstable for acid hydrolysis from its amide linkage and
does not have any specific absorbance. Therefore, the preparation of an
antibody specific to HEL was planned. The antibody was prepared by
injection of hexanonyl KLH as an immunogen, and the production of the
antibody, which reacts with hexanonyl BSA, was observed. A detailed
characterization of the obtained antiserum was then performed. At
first, we examined the cross-reactivity of the antibody with amide-type
synthetic adducts
(CH3-(CH2)n-CO-NH-Lys;
n = 0-9) by ELISA. As shown in Fig.
5, hexanonyl (n = 4)
protein has been strongly recognized. Heptanonyl (n = 5) and pentanonyl (n = 3) proteins could be reacted with the antibody to a lesser extent. It is important that propanonyl (n = 1) BSA could not be bound by the antibody,
suggesting that the antibody can be used for the oxidative modification
of
Lipid oxidation leads to the formation of reactive aldehydes such as
1-hexanal, malondialdehyde, and 4-hydroxy-2-nonenal. These reactive
aldehydes can react with biological molecules such as proteins (1, 2).
The cross-reactivity of aldehyde-modified proteins with the anti-HEL
antibody was examined by ELISA. As shown in Fig.
6, aldehyde-modified proteins used were
not recognized by the antibody, whereas hexanonyl BSA was.
To prove that the epitope of the antibody is
N Formation of HEL by Peroxidized The Effect of the Preincubation of 13-HPODE on the Formation of
HEL--
To clarify whether the formation of HEL becomes a marker for
the oxidative damage of protein by lipid hydroperoxide, the effect of
the preincubation of 13-HPODE on the formation of
N The Formation of HEL in Oxidatively Modified LDL--
The
oxidative modification of LDL has been considered as a plausible
inducer of atherosclerosis. We investigated the formation of the HEL
moiety in copper-oxidized LDL using the antibody. During the incubation
of LDL with copper ion (CuSO4), lipid peroxidation proceeded as evaluated by the formation of thiobarbituric acid reactive
substance (Fig. 10A) and
lipid peroxide (Fig. 10B). As shown in Fig. 10C,
antigenic compounds in LDL were increased with increasing incubation
time. Using another initiator, AAPH, similar results were observed
(Figs. 11, A-C).
The Presence of HEL Moiety in Human Atherosclerotic
Lesion--
HEL moiety was formed during the oxidation of LDL (Figs.
10 and 11). To investigate the presence of HEL moiety in
atherosclerotic lesion, immunohistochemical detection was performed. As
shown in Fig. 12A, HEL
positive staining in human atherosclerotic lesion was observed, whereas
the use of a nonspecific antibody (normal rabbit serum) in the
procedure caused the disappearance of the positive staining in the
lesion (Fig. 12B). In addition, no positive staining was
observed with the anti-HEL antibody preabsorbed with hexanonyl BSA
(data not shown). The result suggests that the immunopositive materials
to anti-HEL antibody are present in the human atherosclerotic lesion.
Lipid decomposition products can modify biological materials.
Among the products, the reactivities of malondialdehyde and 4-hydroxy-2-nonenal have been investigated in detail. The chemical structures of modified amino acid residues were identified in vitro (1). The antibodies raised to malondialdehyde or
4-hydroxy-2-nonenal-modified protein were prepared, and the
immunopositive materials were detected in various tissues such as
atherosclerotic plaques (17, 18). These findings suggested that the
modification of lipid decomposition products (advanced lipid
peroxidation end products) occurred in vivo. On the other
hand, considerable amounts of lipid hydroperoxides exist in
vivo (19).
The fluorescence formation from lysine modification by linoleic acid
hydroperoxide was previously observed (20). It has also been reported
that the lipid hydroperoxide can react with protein, followed by the
formation of the lipid-protein covalent adduct (3). However, the
precise structures of the lipid hydroperoxide-lysine adduct are
unknown. We report the identification of a novel adduct, N We also observed the appearance of immunoreactivity against the
anti-HEL antibody during the oxidation of LDL. The uptake of oxidized
LDL by macrophage can be considered as one of the plausible
contributors for foam cell formation, which may initiate atherosclesosis. The presence of HEL moiety in human atherosclerotic lesion was immunohistochemically proven by the anti-HEL antibody. However, the chemical identification of the HEL moiety in
atherosclerotic lesion was not performed. More detailed studies are
needed for the elucidation of the formation of the HEL moieties
in vivo.
Kim et al. (21) prepared antibodies against lipid
hydroperoxide-modified protein and reported the positive staining in
early atherosclerotic lesion, whereas the precise epitopes were not so
clear. Recently, we prepared antibodies to 13-HPODE- or
15-HPETE-modified proteins, which cannot recognize aldehyde-modified
proteins (9, 10). The result assumed that the lipid
hydroperoxide-specific modification can occur. However,
N-benzoyl-glycyl-N In summary, we isolated and identified a novel lipid-Lys adduct,
N
-(hexanonyl)lysine. To
prove the formation of N-(hexanonyl)lysine,
named HEL, in protein exposed to the lipid hydroperoxide, the antibody
to the synthetic hexanonyl protein was prepared and then characterized
in detail. Using the anti-HEL antibody, the presence of HEL in the
lipid hydroperoxide-modified proteins and oxidized LDL was confirmed.
Furthermore, the positive staining by anti-HEL antibody was observed in
human atherosclerotic lesions using an immunohistochemical technique.
The amide-type adduct may be a useful marker for the lipid
hydroperoxide-derived modification of biomolecules.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-amino groups of the lysine
residues in protein can be modified through the formation of a Schiff
base. 
,
-Unsaturated aldehydes (alkenals) such as acrolein or
4-hydroxy-2-nonenal react with lysine, cysteine, and histidine through
a Michael-type addition (1, 2). On the other hand, lipid hydroperoxide
might covalently react with protein without serious decomposition of
its structure (3). Keto fatty acid (4), which is one of the products by lipoxygenase reaction, can also react with protein and amino acids as
previously suggested (5-7). In addition, the pyrrole compounds from
long chain epoxides and lysine were identified (8). However, the
mechanism of lipid hydroperoxide-derived protein modification is not so clear.
-(hexanonyl)lysine
(named HEL), was identified as one of the lipid hydroperoxide-modified
lysine residues. The formation of HEL in lipid hydroperoxide-modified
proteins including oxidatively modified LDL was confirmed using the
specific antibody to the HEL residue. In addition, the HEL moiety was
detected in human atherosclerotic plaques by immunohistochemical
approach. As far as we know, the formation of an amide-type adduct has
not been previously reported. This novel adduct derived from lipid
hydroperoxide may become an initial marker for the oxidative damage of
biological molecules in vivo.
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
97% albumin,
essentially fatty acid free), arachidonic acid, methylglyoxal,
2-hexenal, cardiolipin, and
N-carboxybenzoyl-L-lysine methyl
ester were obtained from Sigma. Linoleic acid, glyoxal, 1-nonanal,
2-nonenal, hexanoic acid, acetic acid, N-hydroxysuccinimide
(NHS), and benzoyl-glycine were purchased from Wako Pure Chemicals
Industries. Methyl linoleate and 1-hexanal were obtained from Nacarai
Tesque, Inc. 1-Ethyl-3-(3-dimethylaminopropyl) carbodiimide (EDC),
N-hydroxysulfosuccinimide (sulfo-NHS), and keyhole limpet
hemocyanin (KLH) were obtained from Pierce. 4-Hydroxy-2-nonenal was
synthesized and provided by Dr. Koji Uchida (Nagoya University). Propionic acid, butyric acid, valeric acid, heptanoic acid, octanoic acid, nonanoic acid, decanoic acid, and undecanoic acid were purchased from GL Science, Inc. Monomethyl azelate was supplied by Larodan Fine
Chemicals. Gluatric anhydride and malonaldehyde bis(dimethylacetal) were purchased from Aldrich.
234 nm=25000 M
1
cm1 using the value of linoleic acid hydroperoxide
(11).
-(hexanonyl)lysine--
For the first
step, benzoyl-glycine (1 eq.) and the
N-(carboxybenzoyl)lysine methyl ester (1 eq.) were
conjugated in dimethylformamide (DMF) with EDC (1.1 eq.) in the
presence of an enhancer, NHS (1.1 eq.), as described previously (12)
with some modifications. After an overnight reaction at room
temperature, the reaction mixture was dissolved with ethyl acetate and
then washed with equal amounts of 1 N HCl, water, 5%
NaHCO3, and then water. The residual ethyl acetate layer
was passed through Na2SO4 for dehydration. The
eluent was concentrated, and the crude
N-benzoyl-glycyl-N-(carboxybenzoyl)lysine methyl ester
was crystallized with water/ethanol at 4 °C for 3 h. The
removal of carboxybenzoyl from the purified peptide was performed using
Pd-C under H2 for 3 h at room temperature in
water/methanol. The obtained N-benzoyl-glycyl-L-lysine
methyl ester was purified by preparative reversed-phase HPLC (Develosil ODS-5 (20 × 250 mm), Nomura Chemical Co.) using 0.1%
trifluoroacetic acid, CH3CN (5/3) as the eluent. Hexanoic
acid and the N-benzoyl-glycyl-L-lysine methyl
ester were conjugated with EDC and NHS as described previously. The
reaction mixture was washed as already described, and the residual
product was purified by reversed-phase HPLC on a Develosil ODS-5
(20 × 250 mm) using 0.1% trifluoroacetic acid, CH3CN
(5/3) as the eluent. The
N-benzoyl-glycyl-N-(hexanonyl)lysine
methyl ester was treated with 0.25 N NaOH at 37 °C for
1 h to remove the methyl ester. The obtained compound was purified
by reversed-phase HPLC on the column using 0.1% trifluoroacetic acid,
CH3CN (5/3) as the eluent. The identification was performed by 1H NMR and mass spectroscopy. The spectral data of the
synthetic N-benzoyl-glycyl-N-(hexanonyl)lysine
are as follows: 1H NMR (CD3OD) (ppm) 0.80 (t,
J = 6.9 Hz, 3H), 1.20 (m, 2H), 1.24 (m, 2H), 1.34 (m,
2H), 1.42 (m, 2H), 1.49 (m, 2H), 1.66 (m, 1H), 1.84 (m, 1H), 2.06 (t,
J = 7.4 Hz, 2H), 3.07 (t, J = 6.9 Hz,
2H), 3.99 (m, 2H), 4.34 (m, 1H), 7.37 (t, J = 7.2 Hz,
2H), 7.45 (t, J = 5.2 Hz, 1H), 7.77 (d,
J = 7.2 Hz, 2H); FAB+-MS
m/z 406 (M + H)+, 428 (M + Na)+.
-(hexanonyl(D-11))lysine
derivative was prepared using D-11-hexanoic acid as follows. Briefly,
benzoyl-glycyl-L-lysine was conjugated with D-11-hexanoic
acid using EDC and NHS as coupling reagents (12). The obtained
benzoyl-glycyl-N-(hexanonyl)lysine was
isolated and purified by reversed-phase HPLC on a Develosil ODS-HG-5
(8 × 250 mm) equilibrated with 0.1% trifluoroacetic acid,
CH3CN (5/3) at a flow rate of 2.0 ml/min. The elution was
estimated by UV absorbance at 234 nm, and identification of the
synthetic deuterified hexanonyl compound was performed by liquid
chromatography-mass spectrometry (LC-MS).
-(hexanonyl)-L-lysine
Methyl Ester--
The
N-acetyl-glycyl-N-(hexanonyl)-L-lysine
methyl ester (N-hexanonyl AGLME) was prepared
by conjugation between AGLME and hexanoic acid using EDC as the
coupling reagent and NHS as the enhancer, as described previously. The
synthetic compound could not be separated with ethyl acetate/water
fractionation because of its high water solubility. Therefore, the
reaction mixture was diluted with 0.1% trifluoroacetic acid and passed
through a Sep-Pak cartridge. The cartridge was washed with 0.1%
trifluoroacetic acid, and the products were then eluted with 0.1%
trifluoroacetic acid, CH3CN (1/1). The eluent was
concentrated and applied to preparative reversed-phase HPLC (Develosil
ODS-5 (20 × 250 mm)) using 0.1% trifluoroacetic acid,
CH3CN (7:3) as the eluent. The elution was monitored by
absorbance at 215 nm. The peak was collected and concentrated. The
obtained
N-acetyl-glycyl-N-(hexanonyl)-L-lysine
methyl ester (N-hexanonyl AGLME) was
identified by 1H NMR and mass spectroscopy (LC-MS). The
spectral data of N-hexanonyl AGLME are as
follows: 1H NMR (CD3OD) (ppm) 0.71 (t,
J = 7.1 Hz, 3H), 1.09 (m, 2H), 1.14 (m, 2H), 1.20 (m,
2H), 1.31 (m, 2H), 1.40 (m, 2H), 1.49 (m, 1H), 1.63 (m, 1H), 1.80 (s,
3H), 1.97 (t, J = 7.7 Hz, 2H), 2.96 (t, J = 6.9 Hz, 2H), 3.51 (s, 3H), 3.68 (m, 2H), 4.22 (m,
1H); LC-MS (ESP+) m/z 358 (M + H)+.
-hexanonyl derivative of Bz-Gly-Lys,
deuterified hexanonyl Bz-Gly-Lys was added to samples at a
concentration of 19 µM before the analysis as an internal standard.
-(hexanonyl)lysine were
investigated as follows: 13-HPODE (50 mM) was incubated in
0.1 M phosphate buffer (pH 7.4) containing 20% methanol at
37 °C. Fifty µl of the incubated solution was withdrawn, and a
10-times diluted sample was reacted with 5 mM substrate
(Bz-Gly-Lys/BSA) in 0.1 M phosphate buffer at 37 °C for
3 days. The reaction mixture of Bz-Gly-Lys and preincubated 13-HPODE
was stored at 
70 °C until LC-MS analysis (see above). The
"preincubated 13-HPODE"-modified BSA was isolated from the reaction
mixture by ice-cool ethanol precipitation and used for ELISA as
described in the previous section. At the same time, an aliquot of the
incubated solution of 13-HPODE was used for the measurement of the loss
of 13-HPODE. Fifty µl of the preincubated solution was reduced with
100 µl of 100 mM NaBH4 in 1 M
NaOH and further incubated for 1 h at room temperature. The
reduction was terminated by the addition of 200 µl of 1N
HCl, and the amount of 13-HODE obtained was measured by reversed-phase
HPLC on a Develosil ODS-HG-5 (4.6 × 250 mm) equilibrated with
0.1% trifluoroacetic acid, methanol (1/3) at a flow rate of 0.8 ml/min. The detection was monitored by the absorbance at 234 nm.
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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Fig. 1.
Separation of lipid-Lys adducts derived from
the reaction of 13-HPODE and Bz-Gly-Lys. A, the
reaction mixture was concentrated and extracted with methanol. The
extract was applied to gel filtration chromatography (HW-40). The
elution was monitored by absorbance at 234 nm and fluorescence
(excitation, 350 nm; emission, 420 nm). Fractions 29-34 were used for
further isolation. B, the concentrated fractions were
further fractionated using Sep-Pak cartridge. An aliquot of the 20%
methanol fraction was applied to reversed-phase HPLC on a Develosil
ODS-HG-5 (4.6 × 250 mm, Nomura Chemical Co.) using a linear
gradient of the two-solvent system at a flow rate of 0.8 ml/min. The
elution was monitored by absorbance at 234 nm. Solvent A (0.01%
trifluoroacetic acid) and solvent B (CH3CN) were used for
the gradient. The gradient employed was as follows: B 0% to B 60% in
60 min, B 60% to B 60% in 5 min, B 60% to B 0% in 10 min.
-(Hexanonyl)lysine
Derivatives--
The molecular weight of X, 405, was confirmed by
FAB-MS. Compound X was hydrolyzed with 6 N HCl at 105 °C
in vacuo and submitted for amino acid analysis.
Interestingly, both Gly and Lys were completely recovered from the acid
hydrolysates of compound X (Gly/Lys = 0.96). This suggested that
the bond between the lipid-derived structure and Bz-Gly-Lys was acid
liable such as an amide bond or a Schiff base. The structure of X was
elucidated using 1H NMR. The proposed structure of X with
the parent molecules is shown in Fig.
2A. To confirm the structure
of compound X, the synthesis of the
N-(hexanonyl)lysine adduct was performed
by carbodiimide conjugation of the lysine derivative with hexanoic
acid. The instrumental analysis of the synthetic
N-benzoyl-glycyl-N-(hexanonyl)lysine
almost agreed with that of isolated compound X. Neither the isolated
compound X nor the synthetic N-hexanonyl
adduct had any fluorescence. The time-dependent changes in
Bz-Gly-Lys during incubation with 13-HPODE were examined. As shown in
Fig. 2B, a loss of Bz-Gly-Lys was observed in a
time-dependent fashion, and the formation of
N-benzoyl-glycyl-N-(hexanonyl)lysine,
compound X, was confirmed. The conversion yield of compound X from the
loss of Bz-Gly-Lys after a 3-day incubation with 13-HPODE was
5.6%.
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Fig. 2.
Proposed structure of the
N -hexanonyl
adduct with the parent molecules (A) and
time-dependent formation of
N-hexanonyl
adduct during incubation of 13-HPODE with Bz-Gly-Lys
(B). A, the proposed structure of a
novel adduct with parent molecules. B, Bz-Gly-Lys (5 mM) was reacted with 13-HPODE (5 mM) in 0.1 M phosphate buffer (pH 7.4) at 37 °C for 3 days. After
incubation, the sample was stored at 70 °C until HPLC analysis.
The amount of adduct was estimated by comparison with the synthetic
compound.
-(hexanonyl)lysine named "HEL" in the
13-HPODE-modified Lys, the AGLME was incubated with 13-HPODE, and the
formation of the HEL derivative was investigated. After a 3-day
incubation, an aliquot of the reaction mixture was applied to LC-MS.
The product, which shows m/z 358 as an (M + H)+ ion, corresponding to
N-hexanonyl AGLME (Mr
357), was eluted at a retention time of 40.79 min, and this completely
agreed with the elution time of the synthetic N-hexanonyl AGLME (Fig.
3). The mass charts of both the product and the synthetic N-hexanonyl AGLME showed
the same fragmentation pattern.
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Fig. 3.
Comparison of HPLC-MS between synthetic
N -hexanonyl AGLME
and 13-HPODE-modified AGLME. The structure of
N-hexanonyl AGLME is shown in the chart
(A). The aliquots of the reaction mixture and synthetic
compound were analyzed by reversed-phase HPLC on a Develosil ODS-HG-5
column as described under "Experimental Procedures"
(B).
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Fig. 4.
Formation of
N -hexanonyl AGLME
by lipid hydroperoxides. An aliquot of the reaction mixture was
applied to HPLC connected with MS (PLATFORM II, VG Biotech.). The
chromatogram was scanned by m/z 358 as the (M + H)+ ion of N-hexanonyl AGLME. The
total current ion is shown in the figure. A,
13-HPODE-modified AGLME. B, 15-HPETE-modified AGLME.
C, MLOOH-modified AGLME.
-hexanonyl AGLME
during incubation of AGLME with aldehyde was examined by LC-MS. HEL was
not formed from the reaction of 1-hexanal with AGLME.
-hexanonyl adduct was not generated by the
reaction of 5 mM AGLME with 5 mM hexanoic acid
(1-hexanal) in the absence or presence of 5 mM
tert-butyl hydroperoxide. This result revealed that the formation of HEL was not derived from the decomposition products, hexanal or hexanoic acid. The existence of other unknown precursors is suggested.
-6 fatty acids but not -3 ones. Similar results were obtained
by indirect competitive ELISA (data not shown). In addition, a
carboxyalkylated protein
(HOOC-(CH2)n-CO-NH-Lys) such as glutaric acid-BSA (n = 3) or azelaic acid-BSA (n = 7)
could not be recognized by the anti-HEL antibody.
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Fig. 5.
Effect of alkyl chain lengths on the
antigenicity of amide-type adduct. The synthetic amide-type
adducts were prepared as described under "Experimental Procedures."
The reactivity was evaluated by indirect noncompetitive ELISA. The
modified proteins (0.1 µg/ml) were coated at 4 °C overnight. The
wells were washed with PBS 0.05% containing Tween 20 and water and
then blocked with Block Ace (Dainihon Seiyaku Co.) for 1 h at
37 °C. The wells were washed again and treated with serum (1/5000 in
PBS containing 0.5% BSA) for 2 h at 37 °C. The binding of the
antibody to the coated samples was evaluated by treatment with
peroxidase-labeled anti-rabbit IgG antibody, followed by the addition
of the substrates for the peroxidase (o-phenylenediamine and
hydrogen peroxide). The color development was terminated by the
addition of 2 N H2SO4 and evaluated
by the absorbance at 492 nm.
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Fig. 6.
Cross-reactivity of aldehyde-modified
proteins with the anti-HEL antibody. The modified proteins were
prepared by incubation of the aldehydes with BSA for 24 h at
37 °C. The reactivity was measured by indirect noncompetitive ELISA
as described in the Fig. 5 legend. As controls, native BSA and
hexanonyl BSA were used at the same time. MDA,
malondialdehyde; HNE, 4-hydroxy-2-nonenal.
-(hexanonyl)lysine (HEL), the
cross-reactivity of the synthetic peptide-containing HEL moiety with
the antibody was investigated by competitive ELISA. Fig.
7 shows that
N-acetyl-glycyl-N-(hexanonyl)lysine
methyl ester and
N-benzoyl-glycyl-N-(hexanonyl)lysine
could be recognized by the antibody. This suggested that the antibody
is specific to the N-(hexanonyl)lysine
moiety.
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Fig. 7.
Cross-reactivity of HEL derivatives with
anti-HEL antibody. The hexanonylated compounds were synthesized as
described under "Experimental Procedures." The immunoreactivity was
evaluated by competitive indirect ELISA using hexanonyl BSA as a
coating agent. HEL(AGLME), hexanonylated AGLME; HEL(BzGK),
hexanonylated N-benzoyl-glycyl-L-lysine; BzGK,
N-benzoyl-glycyl-L-lysine. The results are
expressed as B/Bo, where B is the amount of antibody bound in the
presence and Bo in the absence of the competitor.
-6 Fatty Acids--
As shown in
Fig. 8, the formation of HEL was observed
by incubation of BSA with ascorbate/Fe2+-oxidized linoleic
acid, arachidonic acid, and cardiolipin. The treatments of BSA with
15-HPETE as well as 13-HPODE also generated antigenic compounds. The
result may suggest that the
N-(hexanonyl)lysine, HEL, becomes a marker
for the oxidative modification of lysine by oxidized -6 fatty acids
including phospholipids containing esterified -6 fatty acids. In
addition, oxidized BSA, which was prepared by the oxidation of protein
by hydrogen peroxide/iron, could not generate the antigenic
materials.
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Fig. 8.
Formation of antigenic materials in proteins
modified by lipid peroxidation products. Linoleic acid,
arachidonic acid, and cardiolipin were oxidized by ascorbate/iron, and
the obtained oxidized lipids were then reacted with BSA for 3 days at
37 °C. Oxidized BSA was prepared by the treatment of lipid-free BSA
with H2O2/iron/EDTA as already described (9).
13-HPODE- and 15-HPETE-modified BSAs were made as described (9, 10).
These modified proteins including native BSA were coated at a
concentration of 0.01 mg/ml. After blocking, the antiserum (1/5000) was
added to the wells. The evaluation of binding was performed as
described in the Fig. 5 legend.
-(hexanonyl)lysine was examined by chemical
and immunochemical methods (Scheme I).
The loss of 13-HPODE during preincubation was evaluated (as 13-HODE) by
reduction with NaBH4 followed by HPLC analysis. The
preincubated 13-HPODE was reacted with Bz-Gly-Lys and further incubated
for 3 days at 37 °C. The formation of HEL moiety was evaluated by
LC-MS. During a 3-day preincubation, about 90% of 13-HPODE was
decomposed (Fig. 9A). The
formation of HEL from Bz-Gly-Lys and 13-HPODE was also decreased with
increasing preincubation time (Fig. 9B, squares).
The preincubated 13-HPODE was also mixed with lipid-free BSA, and the
formed HEL moiety in BSA was then estimated by the anti-HEL antibody. A
similar result was observed using BSA as a substrate (Fig.
9B, triangles). The result was in agreement with
the data of the negative reactivity against aldehyde-modified proteins
by the antibody (Fig. 6). These results suggested that the
N-(hexanonyl)lysine was derived from 13-HPODE
itself or its slightly modified compounds but not from considerably
decomposed compounds such as aldehydes.
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Scheme I.
Flow diagram of the preincubation
experiment. The 13-HPODE was prepared from linoleic acid by
lipoxygenase. The obtained 13-HPODE was incubated at neutral pH. An
aliquot of the preincubated solution was used for the estimation of the
residual 13-HPODE. The preincubated solution was divided, one portion
was further incubated with Bz-Gly-Lys, and the other was further
incubated with BSA. The detailed protocol is shown under
"Experimental Procedures," and the result is summarized in Fig.
9.
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Fig. 9.
Effect of preincubation of 13-HPODE on the
formation of HEL moiety. The 13-HPODE was incubated in 0.1 M phosphate-buffered saline (pH 7.4) at 37 °C at various
intervals. An aliquot of the solution was harvested and analyzed.
A, the residual amounts of 13-HPODE were estimated after
conversion to the 13-HODE, followed by HPLC analysis. B,
squares, the preincubated 13-HPODE was incubated with Bz-Gly-Lys
for 3 days at 37 °C, and the formation of
N -hexanonyl compounds was estimated by LC-MS.
B, triangle, the preincubated 13-HPODE was incubated with
BSA for 3 days at 37 °C, and the formation of HEL residues in the
protein was evaluated by ELISA.
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Fig. 10.
Formation of immunoreactive compounds
in copper-oxidized LDL. LDL was oxidized by 50 µM
copper ion at 37 °C at various intervals. The oxidation was
terminated by adding EDTA/butylated hydroxytoluene. Control
means the omission of copper ion. A, the oxidation of LDL
was evaluated by the formation of thiobarbituric acid reactive
substrates (TBARS). The value was expressed as an equivalent
of malondialdehyde (MDA). B, the formation of
lipid hydroperoxide during the oxidation of LDL with copper ions was
evaluated by a Determiner LPO kit (16). The value was expressed as an
equivalent of cumene hydroperoxide. C, the formation of
immunoreactive materials was estimated by ELISA using anti-HEL antibody
as described in the Fig. 5 legend.
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Fig. 11.
Formation of immunoreactive materials in azo
compound-oxidized LDL. LDL was incubated with various
concentration of AAPH at 37 °C for 24 h. The oxidation was
terminated by adding EDTA/butylated hydroxytoluene. A, the
oxidation of LDL was evaluated by the formation of thiobarbituric acid
reactive substrates (TBARS). B, the generation of
lipid hydroperoxide was estimated as described in the Fig. 10 legend.
C, the formation of immunoreactive materials was estimated
by ELISA using anti-HEL antibody.
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Fig. 12.
Immunohistochemical detection of HEL
moieties in human atherosclerotic lesions. Tissue sections (aorta)
were prepared from frozen arteries (8 µm thick). Sections were
incubated with 10% normal goat serum in PBS (20 min) to block
nonspecific binding before staining and then with anti-HEL antibody
(1:350 dilution) (A). Sections were incubated with 5%
normal rabbit serum instead of the primary antibody as negative
controls (B). Immunostaining was performed with anti-rabbit
antibody peroxidase-label (1:50 dilution, DAKO) and with hydrogen
peroxide and 3,3-diaminobenzidine tetrahydrochloride as chromogen.
Sections were counterstained with aqueous hematoxylin.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-(hexanonyl)lysine, which has an amide bond
between the N-amino group and lipid-derived
part, from the reaction mixture of 13-HPODE and Bz-Gly-Lys. As far as
we know, the formation of an amide bond during lipid peroxidation has
not been reported. The chemical approach for the detection of
N-(hexanonyl)lysine, HEL, in a protein is
probably difficult because the HEL moiety can be hydrolyzed with 6 N HCl, which is often used for the detection of modified
amino acid residues. Therefore, to detect HEL immunochemically, we
prepared an antibody against the hexanonyl protein. The antibody
reacted with
N-benzoyl-glycyl-N-(hexanonyl)lysine
(compound X) as well as the
N-(hexanonyl)lysine residue in the protein.
Using the anti-HEL antibody, the formation of
N-(hexanonyl)lysine in both the
13-HPODE-modified protein and 15-HPETE-modified protein was proven
(Fig. 8). This result suggests that the formation of the HEL may be a
good marker for the oxidative modification by oxidized -6 fatty
acids such as linoleic acid or arachidonic acid. The lipid
hydroperoxide can become a precursor of the
N-hexanonyl adduct, whereas it is unknown
whether the reaction of the lipid hydroperoxide and lysine proceeds
directly or indirectly.
-(hexanonyl)-L-lysine
(compound X) and the hexanoyl protein cannot cross-react with the
antibodies raised against the 13-HPODE- or 15-HPETE-modified KLH (data
not shown). This result agreed with the fact of the requirement of the
carboxyl terminus of the lipid moiety in an adduct for the appearance
of the antigenicity (9, 10). On the other hand, the synthetic
carboxyalkylamides (HOOC-(CH2)n-CO-NH-Lys), glutaric acid-BSA and azelaic acid-BSA, were not reacted with the
anti-HEL antibody (Fig. 6). The anti-HEL antibody may become a better
tool for lipid hydroperoxide-derived oxidative modification than the
anti-13-HPODE-KLH and 15-HPETE-KLH antibody because the anti-HEL
antibody recognized the CH3 terminus of the lipid-Lys adduct, which is formed from the reaction of lysine residues and peroxidation products, derived from not only free fatty acids but also
esterified fatty acids (Fig. 4).
-(hexanonyl)lysine, from the reaction
between 13-HPODE and Lys, although the detailed mechanism of formation
of the N-hexanonyl linkage remains unknown.
We also showed the preparation of the antibody to HEL and the formation
of HEL in oxidatively modified LDL using the immunochemical method. The
immunopositive materials were also observed in human atherosclerotic
lesions. The adduct may become a marker for the initial stage of
oxidative damage of biomolecules.
| |
ACKNOWLEDGEMENTS |
|---|
We thank Dr. J. Terao (The University of
Tokushima) for the helpful discussion in preparing the lipid
hydroperoxides and Toshio Niwa (San-ei Toka Co.) for the helpful
suggestion in preparing the synthetic
N-(hexanonyl)lysine derivatives. We are
grateful for the LC-MS measurement of Shigeyuki Kitamura (Nagoya
University). For the LDL preparation, we also thank Masamichi
Kanematsu (Nagoya University).
| |
FOOTNOTES |
|---|
* The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
** To whom correspondence should be addressed. Tel.: 81-792-92-1515; Fax: 81-792-93-5710; E-mail: yojikato@hept.himeji-tech.ac.jp.
| |
ABBREVIATIONS |
|---|
The abbreviations used are:
13-HPODE, 13-hydroperoxyoctadecadienoic acid;
Bz-Gly-Lys, N-benzoyl-glycyl-L-lysine;
AGLME, N-acetyl-glycyl-L-lysine methyl ester;
NHS, N-hydroxysuccinimide;
HEL, N-(hexanonyl)lysine;
LDL, low density
lipoprotein;
sulfo-NHS, N-hydroxysulfosuccinimide;
EDC, 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide;
KLH, keyhole limpet
hemocyanin;
15-HPETE, 15-hydroperoxyeicosatetraenoic acid;
BSA, bovine
serum albumin;
LC-MS, liquid chromatography-mass spectrometry;
PBS, phosphate-buffered saline;
AAPH, 2,2'-azobis(2-amidinopropane)dihydrochloride;
ELISA, enzyme-linked
immunosorbent assay;
13-HODE, 13-hydroxyoctadecadienoic acid;
FAB-MS, fast-atom bombardment MS;
ESP, electrospray ionization;
ML, methyl
linoleate;
MLOOH, ML hydroperoxide;
HPLC, high performance liquid
chromatography.
| |
REFERENCES |
|---|
|
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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