Chemical modification of two tryptophan residues abolishes the catalytic activity of aminoacylase.

1) The reaction of 1 H-diazotetrazole and N-bromosuccinimide with aminoacylase was studied under different conditions. A tenfold molar excess of 1 H-diazotetrazole (2 X 10(-4) M) at pH 5.5 abolishes the catalytic activity of the enzyme while modifying only two tryptophan residues. No other amino acid reacted under these conditions as tested by amino acid analysis. 2) With a 40-fold molar excess of N-bromosuccinimide (8 X 10(-4)M) at pH 5.0, two tryptophan residues of the enzyme were oxidized with complete loss of activity. Under these conditions no significant cleavage of the polypeptide chain was observed. Neither tyrosine nor histidine was modified by this reagent, up to a 100-fold molar excess. 3) Substrates and reversible (N-tosylalanine) and irreversible (TosPheCH2Cl) inhibitors of the enzyme do not protect the two reactive tryptophans against the modification reagents. Under more drastic conditions, lysine, tyrosine and histidine residues are also modified by the reagents.     

Topography of all tyrosine residues in subtilisin DY

The extracellular alkaline proteinase subtilisin DY was nitrated with increasing amounts of tetranitromethane. At 2-fold molar excess of the reagent with respect to the tyrosine residues in the enzyme, when 1.3 residues were modified, a peak of the caseinolytic activity (13% increase) was observed. Evidence is provided that the diminishing of the pK of the phenolic hydroxyl group in Tyr(3NO2)104 causes this phenomenon. The products obtained after nitration of the enzyme with 5-fold and 200-fold molar excess of tetranitromethane were cleaved by trypsin and cyanogen bromide and the peptides obtained were studied by analysis with respect to the tyrosine and 3-nitrotyrosine residues. Their degree of substitution was established. Tyrosine-104 was the first modified residue, then follow the residues with numbers 57, 143, 206, 262 and somewhat later 21, 209, 263, all fully modified by 200-fold molar excess of the reagent. Partial modification was observed at numbers 91, 167, 214, 238 and no modification at numbers 6 and 171. It has been established that the nonmodified residues are buried inside the molecule and the partially modified residues are screened by the side chains of lysine, valine, leucine, and tryptophan as seen on a working video three-dimensional model of subtilisin Carlsberg. The approach for characterization of tyrosyl groups in proteins based on peptide sequencing and HPLC quantitation of the phenylthiohydantoin derivatives of tyrosine and 3-nitrotyrosine was further developed with respect to the quantitation of the HPLC-separated peptides using fragments of the protein studied.     

A method for specific chemical modification of gamma-carboxyglutamic acid residues in proteins

A method for the chemical modification of gamma-carboxyglutamic acid (Gla) residues in proteins is introduced that has the combined advantages of mildness, a high degree of specificity, and the ability to introduce a radiolabel at modification sites for ease in quantitation. Unlike other Gla modification procedures which are performed in the lyophilized state at 110 degrees C, this procedure is carried out in solution at 37 degrees C. The addition of morpholine and formaldehyde to a slightly acidic solution of bovine prothrombin fragment 1 (residues 1-156) results in the conversion of Gla residues to gamma- methyleneglutamic acid (gamma- MGlu ). The extent of modification is controlled by the relative amounts of modification reagents to protein. A 100-fold molar excess of reagents to fragment 1 produced a protein molecule containing two gamma- MGlu residues, while a modification run at 10,000-fold molar excess of reagents to protein yielded fragment 1 containing eight gamma- MGlu residues per molecule. The specificity of this modification is illustrated by the interaction of native and modified protein with antibody populations directed against fragment 1. Native fragment 1, 8 gamma- MGlu fragment 1, and 2 gamma- MGlu fragment 1 show fairly similar behavior toward whole anti-fragment 1 serum. Differential behavior was exhibited by the native and modified proteins toward a subpopulation of antibodies specific to the calcium ion conformation of fragment 1. Unmodified fragment 1 displayed a strong affinity for these antibodies; however, the 2 gamma- MGlu fragment 1 exhibited a moderate affinity and the 8 gamma- MGlu fragment 1 did not bind to these antibodies.(ABSTRACT TRUNCATED AT 250 WORDS)     

Oxidation and nitrosation in the nitrogen monoxide/superoxide system.

Based on the previous report of McCord and co-workers (Crow, J. P., Beckman, J. S., and McCord, J. M. (1995) Biochemistry 34, 3544-3552), the zinc dithiolate active site of alcohol dehydrogenase (ADH) has been studied as a target for cellular oxidants. In the nitrogen monoxide ((*NO)/superoxide (O(2)) system, an equimolar generation of both radicals under peroxynitrite (PN) formation led to rapid inactivation of ADH activity, whereas hydrogen peroxide and ( small middle dot)NO alone reacted too slowly to be of physiological significance. 3-Morpholino sydnonimine inactivated the enzyme with an IC(50) value of 250 nm; the corresponding values for PN, hydrogen peroxide, and (*NO) were 500 nm, 50 microm, and 200 microm. When superoxide was generated at low fluxes by xanthine oxidase, it was quite effective in ADH inactivation (IC(50) (XO) approximately 1 milliunit/ml). All inactivations were accompanied by zinc release and disulfide formation, although no strict correlation was observed. From the two zinc thiolate centers, only the zinc Cys(2)His center released the metal by oxidants. The zinc Cys(4) center was also oxidized, but no second zinc atom could be found with 4-(2-pyridylazo)resorcinol (PAR) as a chelating agent except under denaturing conditions. Surprisingly, the oxidative actions of PN were abolished by a 2-3-fold excess of (*)NO under generation of a nitrosating species, probably dinitrogen trioxide. We conclude that in cellular systems, low fluxes of (*)NO and O(2) generate peroxynitrite at levels effective for zinc thiolate oxidations, facilitated by the nucleophilic nature of the complexed thiolate group. With an excess of (*)NO, the PN actions are blocked, which may explain the antioxidant properties of (*)NO and the mechanism of cellular S-nitrosations.     

Characterization of 4-HNE modified L-FABP reveals alterations in structural and functional dynamics

4-Hydroxynonenal (4-HNE) is a reactive α,β-unsaturated aldehyde produced during oxidative stress and subsequent lipid peroxidation of polyunsaturated fatty acids. The reactivity of 4-HNE towards DNA and nucleophilic amino acids has been well established. In this report, using proteomic approaches, liver fatty acid-binding protein (L-FABP) is identified as a target for modification by 4-HNE. This lipid binding protein mediates the uptake and trafficking of hydrophobic ligands throughout cellular compartments. Ethanol caused a significant decrease in L-FABP protein (P<0.001) and mRNA (P<0.05), as well as increased poly-ubiquitinated L-FABP (P<0.001). Sites of 4-HNE adduction on mouse recombinant L-FABP were mapped using MALDI-TOF/TOF mass spectrometry on apo (Lys57 and Cys69) and holo (Lys6, Lys31, His43, Lys46, Lys57 and Cys69) L-FABP. The impact of 4-HNE adduction was found to occur in a concentration-dependent manner; affinity for the fluorescent ligand, anilinonaphthalene-8-sulfonic acid, was reduced from 0.347 μM to Kd(1)?=?0.395 μM and Kd(2)?=?34.20 μM. Saturation analyses revealed that capacity for ligand is reduced by approximately 50% when adducted by 4-HNE. Thermal stability curves of apo L-FABP was also found to be significantly affected by 4-HNE adduction (ΔTm?=?5.44°C, P<0.01). Computational-based molecular modeling simulations of adducted protein revealed minor conformational changes in global protein structure of apo and holo L-FABP while more apparent differences were observed within the internal binding pocket, revealing reduced area and structural integrity. New solvent accessible portals on the periphery of the protein were observed following 4-HNE modification in both the apo and holo state, suggesting an adaptive response to carbonylation. The results from this study detail the dynamic process associated with L-FABP modification by 4-HNE and provide insight as to how alterations in structural integrity and ligand binding may a contributing factor in the pathogenesis of ALD.     

Carbonylation of adipose proteins in obesity and insulin resistance: identification of adipocyte fatty acid-binding protein as a cellular target of 4-hydroxynonenal

Obesity is a state of mild inflammation correlated with increased oxidative stress. In general, pro-oxidative conditions lead to production of reactive aldehydes such as trans-4-hydroxy-2-nonenal (4-HNE) and trans-4-oxo-2-nonenal implicated in the development of a variety of metabolic diseases. To investigate protein modification by 4-HNE as a consequence of obesity and its potential relationship to the development of insulin resistance, proteomics technologies were utilized to identify aldehyde-modified proteins in adipose tissue. Adipose proteins from lean insulin-sensitive and obese insulin-resistant C57Bl/6J mice were incubated with biotin hydrazide and detected using horseradish peroxidase-conjugated streptavidin. High carbohydrate, high fat feeding of mice resulted in a approximately 2-3-fold increase in total adipose protein carbonylation. Consistent with an increase in oxidative stress in obesity, the abundance of glutathione S-transferase A4 (GSTA4), a key enzyme responsible for metabolizing 4-HNE, was decreased approximately 3-4-fold in adipose tissue of obese mice. To identify specific carbonylated proteins, biotin hydrazide-modified adipose proteins from obese mice were captured using avidin-Sepharose affinity chromatography, proteolytically digested, and subjected to LC-ESI MS/MS. Interestingly enzymes involved in cellular stress response, lipotoxicity, and insulin signaling such as glutathione S-transferase M1, peroxiredoxin 1, glutathione peroxidase 1, eukaryotic elongation factor 1alpha-1 (eEF1alpha1), and filamin A were identified. The adipocyte fatty acid-binding protein, a protein implicated in the regulation of insulin resistance, was found to be carbonylated in vivo with 4-HNE. In vitro modification of adipocyte fatty acid-binding protein with 4-HNE was mapped to Cys-117, occurred equivalently using either the R or S enantiomer of 4-HNE, and reduced the affinity of the protein for fatty acids approximately 10-fold. These results indicate that obesity is accompanied by an increase in the carbonylation of a number of adipose-regulatory proteins that may serve as a mechanistic link between increased oxidative stress and the development of insulin resistance.     

Properties of chemically modified protein S: effect of the conversion of gamma-carboxyglutamic acid to gamma-methyleneglutamic acid on functional properties

Protein S, the protein cofactor for activated protein C in the proteolytic inactivation of factor Va, was chemically modified with a mixture of morpholine and formaldehyde. This treatment resulted in the conversion of the gamma-carboxyglutamic acid (Gla) residues of this vitamin K dependent protein to gamma-methyleneglutamic acid. With a 10,000-fold molar excess of morpholine and formaldehyde over protein S it was found that between 10 and 11 Gla residues could be modified. The degree of modification was proportional to the concentration of the modifying reagents used. The modification of as few as two residues resulted in the 70% loss of activity. Calcium inhibited the modification of several residues. In the presence of 3.2 mM calcium ion, a derivative with 2.5 residues modified was prepared that appeared to have full activity. Modification of protein S resulted in the alteration of a number of its properties. The quenching of intrinsic fluorescence by calcium decreased. The quenching effect of terbium ions was also decreased. However, the modified protein and the native protein were equivalent when protein-dependent terbium fluorescence was measured. When modified, protein S would no longer bind to phospholipid vesicles. Finally, the ability of protein S to self-associate was decreased by modification. These findings suggest that the gamma-carboxyglutamic acid residues of protein S may play several roles in the maintenance of structure.     

alpha-Synuclein protofibrils inhibit 26 S proteasome-mediated protein degradation: understanding the cytotoxicity of protein protofibrils in neurodegenerative disease pathogenesis

The impaired ubiquitin-proteasome activity is believed to be one of the leading factors that contribute to Parkinson disease pathogenesis partially by causing alpha-synuclein aggregation. However, the relationship between alpha-synuclein aggregation and the impaired proteasome activity is yet unclear. In this study, we examined the effects of three soluble alpha-synuclein species (monomer, dimer, and protofibrils) on the degradation activity of the 26 S proteasome by reconstitution of proteasomal degradation using highly purified 26 S proteasomes and model substrates. We found that none of the three soluble alpha-synuclein species impaired the three distinct peptidase activities of the 26 S proteasome when using fluorogenic peptides as substrates. In striking contrast, alpha-synuclein protofibrils, but not monomer and dimer, markedly inhibited the ubiquitin-independent proteasomal degradation of unstructured proteins and ubiquitin-dependent degradation of folded proteins when present at 5-fold molar excess to the 26 S proteasome. Together these results indicate that alpha-synuclein protofibrils have a pronounced inhibitory effect on 26 S proteasome-mediated protein degradation. Because alpha-synuclein is a substrate of the proteasome, impaired proteasomal activity could further cause alpha-synuclein accumulation/aggregation, thus creating a vicious cycle and leading to Parkinson disease pathogenesis. Furthermore we found that alpha-synuclein protofibrils bound both the 26 S proteasome and substrates of the 26 S proteasome. Accordingly we propose that the inhibitory effect of alpha-synuclein protofibrils on 26 S proteasomal degradation might result from impairing substrate translocation by binding the proteasome or sequestrating proteasomal substrates by binding the substrates.     

Unsaturated lipid peroxidation-derived aldehydes activate autophagy in vascular smooth-muscle cells

Proteins modified by aldehydes generated from oxidized lipids accumulate in cells during oxidative stress and are commonly detected in diseased or aged tissue. The mechanisms by which cells remove aldehyde-adducted proteins, however, remain unclear. Here, we report that products of lipid peroxidation such as 4-HNE (4-hydroxynonenal) and acrolein activate autophagy in rat aortic smooth-muscle cells in culture. Exposure to 4-HNE led to the modification of several proteins, as detected by anti-protein-4-HNE antibodies or protein-bound radioactivity in [3H]4-HNE-treated cells. The 4-HNE-modified proteins were gradually removed from cells. The removal of 4-HNE-modified proteins was not affected by the oxidized protein hydrolase inhibitor, acetyl leucine chloromethyl ketone, or lactacystin, although it was significantly decreased by PSI (proteasome inhibitor I), the lysosome/proteasome inhibitor MG-132 (carbobenzoxy-L-leucyl-L-leucyl-leucinal), insulin or the autophagy inhibitor 3-MA (3-methyladenine). Pre-incubation of cells with rapamycin accelerated the removal of 4-HNE-modified proteins. Treatment with 4-HNE, nonenal and acrolein, but not nonanal or POVPC (1-palmitoyl-2-oxovaleroyl phosphatidyl choline), caused a robust increase in LC3-II (microtubule-associated protein 1 light chain 3-II) formation, which was increased also by rapamycin, but prevented by insulin. Electron micrographs of 4-HNE-treated cells showed extensive vacuolization, pinocytic body formation, crescent-shaped phagophores, and multilamellar vesicles. Treatment with 3-MA and MG-132, but not proteasome-specific inhibitors, induced cell death in 4-HNE-treated cells. Collectively, these results show that lipid peroxidation-derived aldehydes stimulate autophagy, which removes aldehyde-modified proteins, and that inhibition of autophagy precipitates cell death in aldehyde-treated cells. Autophagy may be an important mechanism for the survival of arterial smooth-muscle cells under conditions associated with excessive lipid peroxidation.     

HIV-1 encoded virus protein U (Vpu) solution structure of the 41-62 hydrophilic region containing the phosphorylated sites Ser52 and Ser56

Degradation of the HIV receptor CD4 by the proteasome, mediated by the HIV-1 protein Vpu, is crucial for the release of fully infectious virions. To promote CD4 degradation Vpu has to be phosphorylated on a motif DSGXXS, which is conserved in several signalling proteins known to be degraded by the proteasome upon phosphorylation. Such phosphorylation is required for the interaction of Vpu with the ubiquitin ligase SCF-beta-TrCP that triggers CD4 degradation by the proteasome. In the present work, we used two peptides of 22 amino acids between residues 41 and 62 of Vpu. Vpu41-62 was predicted to form an alpha-helix-flexible-alpha-helix including the phosphorylation motif DS52GNES56 and Vpu_P41-62 was phosphorylated at the two sites Ser52 and Ser56. We analysed the conformational change induced by the phosphorylation of this peptide on the residues Ser52 and Ser56. Homo- and heteronuclear NMR techniques were used to assess the structural influence of phosphorylation. The spectra of the free peptides, Vpu_P41-62 and Vpu41-62, in both H2O (at pH 3.5 and 7.2) and a 1:1 mixture of H2O and trifluoroethanol were completely assigned by a combined application of several two-dimensional proton NMR methods. Analysis of the short- and medium-range NOE connectivities and of the secondary chemical shifts indicated that the peptide segment (42-49) shows a less well-defined helix propensity. The Vpu_P41-62 domain of residues 50-62 forms a loop with the phosphate group pointing away, a short beta-strand and a flexible extended 'tail' of residues 60-62. Residues 50-60 exhibit alpha-proton NMR secondary chemical shift changes from random coil toward more beta-like structure with the combined (temperature, solvent and pH) NMR and molecular calculation experiments. Differences in this molecular region 50-62 suggest that conformational changes of Vpu_P play an important role in Vpu_P-induced degradation of CD4 molecules.     

Insulin and analogue effects on protein degradation in different cell types. Dissociation between binding and activity

In adult animals, the major effect of insulin on protein turnover is inhibition of protein degradation. Cellular protein degradation is under the control of multiple systems, including lysosomes, proteasomes, calpains, and giant protease. Insulin has been shown to alter proteasome activity in vitro and in vivo. We examined the inhibition of protein degradation by insulin and insulin analogues (Lys(B28),Pro(B29)-insulin (LysPro), Asp(B10)-insulin (B10), and Glu(B4),Gln(B16),Phe(B17)-insulin (EQF)) in H4, HepG2, and L6 cells. These effects were compared with receptor binding. Protein degradation was examined by release of trichloroacetic acid-soluble radioactivity from cells previously labeled with [(3)H]leucine. Short- and intermediate-lived proteins were examined. H4 cells bound insulin with an EC(50) of 4.6 x 10(-9) m. LysPro was similar. The affinity of B10 was increased 2-fold; that of EQF decreased 15-fold. Protein degradation inhibition in H4 cells was highly sensitive to insulin (EC(50) = 4.2 x 10(-11) and 1.6 x 10(-10) m, short- and intermediate-lived protein degradation, respectively) and analogues. Despite similar binding, LysPro was 11- to 18-fold more potent than insulin at inhibiting protein degradation. Conversely, although EQF showed lower binding to H4 cells than insulin, its action was similar. The relative binding potencies of analogues in HepG2 cells were similar to those in H4 cells. Examination of protein degradation showed insulin, LysPro, and B10 were equivalent while EQF was less potent. L6 cells showed no difference in the binding of the analogues compared with insulin, but their effect on protein degradation was similar to that seen in HepG2 cells except B10 inhibited intermediate-lived protein degradation better than insulin. These studies illustrate the complexities of cellular protein degradation and the effects of insulin. The effect of insulin and analogues on protein degradation vary significantly in different cell types and with different experimental conditions. The differences seen in the action of the analogues cannot be attributed to binding differences. Post-receptor mechanisms, including intracellular processing and degradation, must be considered.     

Proteolytic degradation of tyrosine nitrated proteins

Tyrosine nitration is a covalent posttranslational protein modification that has been detected under several pathological conditions. This study reports that nitrated proteins are degraded by chymotrypsin and that protein nitration enhances susceptibility to degradation by the proteasome. Chymotrypsin cleaved the peptide bond between nitrated-tyrosine 108 and serine 109 in bovine Cu,Zn superoxide dismutase. However, the rate of chymotryptic cleavage of nitrated peptides was considerably slower than control. In contrast, nitrated bovine Cu,Zn superoxide dismutase was degraded at a rate 1. 8-fold faster than that of control by a gradient-purified 20S/26S proteasome fraction from bovine retina. Exposure of PC12 cells to a nitrating agent resulted in the nitration of tyrosine hydroxylase and a 58 +/- 12.5% decline in the steady-state levels of the protein 4 h after nitration. The steady-state levels of tyrosine hydroxylase were restored by selective inhibition of the proteasome activity with lactacystin. These data indicate that nitration of tyrosine residue(s) in proteins is sufficient to induce an accelerated degradation of the modified proteins by the proteasome and that the proteasome may be critical for the removal of nitrated proteins in vivo.     

Covalent modification of epithelial fatty acid-binding protein by 4-hydroxynonenal in vitro and in vivo. Evidence for a role in antioxidant biology

4-Hydroxynonenal (4-HNE) is a cytotoxic alpha,beta-unsaturated acyl aldehyde that is naturally produced from lipid peroxidation and cleavage in response to oxidative stress and aging. Such reactive lipids covalently modify cellular target proteins, thereby affecting biological structure and function. Herein we report the identification of the epithelial fatty acid-binding protein (E-FABP) as a molecular target for 4-HNE modification both in vitro and in vivo. 4-HNE covalently modified (t(12) < 60 s) E-FABP in vitro, as revealed by a combination of matrix-assisted laser desorption ionization-time of flight mass spectrometry and immunochemical reactivity using antibodies directed to 4-HNE-protein conjugates. Identification of Cys-120 as the major site of modification was determined through tandem mass spectral sequencing of tryptic peptides, as well as analysis of E-FABP mutants C120A, C127A, and C120A/C127A. The in vitro modification of Cys-120 by 4-HNE was relatively insensitive to pH (6.4-8.4), and temperature (4-37 degrees C) but was markedly potentiated by noncovalently bound fatty acids. 4-HNE-modified E-FABP was more stable than unmodified E-FABP to chemical denaturation by guanidine hydrochloride, as assessed by changes in intrinsic tryptophan fluorescence. Analysis of soluble protein extracts from rat retina with antibodies directed to 4-HNE-protein conjugates revealed immunoreactivity with a 15-kDa protein that was identified by electrospray ionization and matrix-assisted laser desorption ionization-time of flight mass spectrometry as E-FABP. Evaluation of retinal pigment epithelial cell extracts derived from E-FABP null mice by two-dimensional gel electrophoresis using anti-4-HNE antibodies revealed increased modification in the null cells relative to those from wild type cells. These results indicate that E-FABP is a molecular target for 4-HNE modification and the hypothesis that E-FABP functions as an antioxidant protein by scavenging reactive lipids through covalent modification of Cys-120.     

Modification of tyrosine residues of the lactose repressor protein.

Reaction of the lactose repressor protein from Escherichia coli with high molar excesses (up to 800 fold) of tetranitromethane resulted in modification of tyrosine residues in the amino-terminal and core regions of the molecule. Tyrosines 7 and 17 exhibit significant reactivity at low levels (5-10 fold molar excess) of tetranitromethane. The loss of operator binding activity upon nitration at these low concentrations of reagent indicates involvement of these two tyrosines in the binding process. Inducer binding activity was maintained at approx. 90% of unreacted repressor for all excesses of reagent studied. Addition of inducer to the repressor prior to reaction resulted in decreased modification of tyrosines in the core region, but anti-inducers did not affect the reaction significantly. The effect of inducers on the pattern of reaction apparently reflects the conformational change which occurs upon binding of these ligands. Acetylation of the repressor protein with N-acetylimidazole modified lysines and tyrosines with complete loss of operator binding activity and retention of 75-80% of inducer binding activity.     

The 3-D structure of a zinc metallo-beta-lactamase from Bacillus cereus reveals a new type of protein fold.

The 3-D structure of Bacillus cereus (569/H/9) beta-lactamase (EC 3.5.2.6), which catalyses the hydrolysis of nearly all beta-lactams, has been solved at 2.5 A resolution by the multiple isomorphous replacement method, with density modification and phase combination, from crystals of the native protein and of a specially designed mutant (T97C). The current model includes 212 of the 227 amino acid residues, the zinc ion and 10 water molecules. The protein is folded into a beta beta sandwich with helices on each external face. To our knowledge, this fold has never been observed. An approximate internal molecular symmetry is found, with a 2-fold axis passing roughly through the zinc ion and suggesting a possible gene duplication. The active site is located at one edge of the beta beta sandwich and near the N-terminal end of a helix. The zinc ion is coordinated by three histidine residues (86, 88 and 149) and a water molecule. A sequence comparison of the relevant metallo-beta-lactamases, based on this protein structure, highlights a few well-conserved amino acid residues. The structure shows that most of these residues are in the active site. Among these, aspartic acid 90 and histidine 210 participate in a proposed catalytic mechanism for beta-lactam hydrolysis.     

Amino acid sequence and characterization of a protein inhibitor of protein kinase C

The complete primary structure has been determined for an inhibitor protein of protein kinase C. The bovine brain-derived inhibitor has a pI of 6 and its N-terminal alanine residue is blocked by acetylation. Fragments obtained by chemical and enzymatic cleavage of the purified inhibitor were analyzed by Edman degradation, fast atom bombardment mass spectrometry, and tandem mass spectrometry. The results establish that the protein has a calculated average molecular mass of 13,690 daltons and contains 125 amino acid residues with the following sequence: (sequence: see text) The inhibitor does not show significant homology with any other known protein. Circular dichroism of the freshly prepared apoprotein indicated a secondary structural content of 23% alpha-helix, 31% beta-sheet, and 11% beta-turn. Immobilization on nitrocellulose followed by exposure to a 65Zn2(+)-containing overlay solution showed that, like protein kinase C itself, the inhibitor is a zinc-binding protein, although the sequence does not reveal a "zinc finger" structure. Competition with 10-fold molar excess Ca2+ or Mg2+ did not reduce the zinc-binding specificity of this inhibitor.     

Oxidized LDLs alter the activity of the ubiquitin-proteasome pathway: potential role in oxidized LDL-induced apoptosis.

Oxidized low-density lipoproteins (oxLDL) play a role in the genesis of atherosclerosis. OxLDL are able to induce apoptosis of vascular cells, which is potentially involved in the formation of the necrotic center of atherosclerotic lesions, plaque rupture, and subsequent thrombotic events. Because oxLDL may induce structural modifications of cell protein and altered proteins may impair cell viability, the present work aimed to evaluate the extent of protein alterations, the degradation of modified proteins through the ubiquitin-proteasome system (a major degradative pathway for altered and oxidatively modified proteins) and their role during apoptosis induced by oxLDL. This paper reports the following: 1) oxLDL induce derivatization of cell proteins by 4-hydroxynonenal (4-HNE) and ubiquitination. 2) Toxic concentrations of oxLDL elicit a biphasic effect on proteasome activity. An early and transient activation of endogenous proteolysis is followed rapidly by a subsequent decay (resulting probably from the 26S proteasome inhibition) and followed later by the inhibition of the 20S proteasome (as assessed by inhibition of sLLVY-MCA hydrolysis). 3) Specific inhibitors of proteasome (lactacystin and proteasome inhibitor I) potentiated considerably the toxicity of oxLDL (nontoxic doses of oxLDL became severely toxic). The defect of the ubiquitination pathway (in temperature-sensitive mutants) also potentiated the toxicity of oxLDL. This suggests that the ubiquitin-proteasome pathway plays a role in the cellular defenses against oxLDL-induced toxicity. 4) Dinitrophenylhydrazine (DNPH), an aldehyde reagent, prevented both the oxLDL-induced derivatization of cell proteins and subsequent cytotoxicity. Altogether, the reported data suggest that both derivatization of cell proteins (by 4-HNE and other oxidized lipids) and inhibition of the proteasome pathway are involved in the mechanism of oxLDL-induced apoptosis.     

Posttranslational modification and regulation of glutamate-cysteine ligase by the α,β-unsaturated aldehyde 4-hydroxy-2-nonenal

4-Hydroxy-2-nonenal (4-HNE) is a lipid peroxidation product formed during oxidative stress that can alter protein function via adduction of nucleophilic amino acid residues. 4-HNE detoxification occurs mainly via glutathione (GSH) conjugation and transporter-mediated efflux. This results in a net loss of cellular GSH, and restoration of GSH homeostasis requires de novo GSH biosynthesis. The rate-limiting step in GSH biosynthesis is catalyzed by glutamate-cysteine ligase (GCL), a heterodimeric holoenzyme composed of a catalytic (GCLC) and a modulatory (GCLM) subunit. The relative levels of the GCL subunits are a major determinant of cellular GSH biosynthetic capacity and 4-HNE induces the expression of both GCL subunits. In this study, we demonstrate that 4-HNE can alter GCL holoenzyme formation and activity via direct posttranslational modification of the GCL subunits in vitro. 4-HNE directly modified Cys553 of GCLC and Cys35 of GCLM in vitro, which significantly increased monomeric GCLC enzymatic activity, but reduced GCL holoenzyme activity and formation of the GCL holoenzyme complex. In silico molecular modeling studies also indicate these residues are likely to be functionally relevant. Within a cellular context, this novel posttranslational regulation of GCL activity could significantly affect cellular GSH homeostasis and GSH-dependent detoxification during periods of oxidative stress.     

Primary structure of avian hepatic rhodanese

Rhodanese (thiosulfate:cyanide sulfurtransferase, EC 2.8.1.1.) was purified from chicken livers and its amino acid sequence was determined. The enzyme has a specific activity of 676 IU and a molecular weight of 32,255. The primary structure of 289 amino acids was solved by sequential Edman degradation of overlapping peptides obtained by selected enzymatic and chemical cleavages. The amino terminus was blocked, and the carboxy-terminus was heterogeneous. Comparison of the primary structure with bovine liver rhodanese showed 212 identically matched amino acids, and the majority of amino acid differences were conservative substitutions. Reaction of the enzyme with a 1.4-fold molar excess of [2-¹⁴C]iodoacetate led to inactivation of the enzyme and carboxymethylation of Cys-244; this modification was blocked by the substrate thiosulfate.     

Metabolism of 4-hydroxynonenal by rat Kupffer cells

Kupffer cells are known to participate in the early events of liver injury involving lipid peroxidation. 4-Hydroxy-2,3-(E)-nonenal (4-HNE), a major aldehydic product of lipid peroxidation, has been shown to modulate numerous cellular systems and is implicated in the pathogenesis of chemically induced liver damage. The purpose of this study was to characterize the metabolic ability of Kupffer cells to detoxify 4-HNE through oxidative (aldehyde dehydrogenase; ALDH), reductive (alcohol dehydrogenase; ADH), and conjugative (glutathione S-transferase; GST) pathways. Aldehyde dehydrogenase and GST activity was observed, while ADH activity was not detectable in isolated Kupffer cells. Additionally, immunoblots demonstrated that Kupffer cells contain ALDH 1 and ALDH 2 isoforms as well as GST A4-4, P1-1, Ya, and Yb. The cytotoxicity of 4-HNE on Kupffer cells was assessed and the TD50 value of 32.5+/-2.2 microM for 4-HNE was determined. HPLC measurement of 4-HNE metabolism using suspensions of Kupffer cells incubated with 25 microLM 4-HNE indicated a loss of 4-HNE over the 30-min time period. Subsequent production of 4-hydroxy-2-nonenoic acid (HNA) suggested the involvement of the ALDH enzyme system and formation of the 4-HNE-glutathione conjugate implicated GST-mediated catalysis. The basal level of glutathione in Kupffer cells (1.33+/-0.3 nmol of glutathione per 10(6) cells) decreased significantly during incubation with 4-HNE concurrent with formation of the 4-HNE-glutathione conjugate. These data demonstrate that oxidative and conjugative pathways are primarily responsible for the metabolism of 4-HNE in Kupffer cells. However, this cell type is characterized by a relatively low capacity to metabolize 4-HNE in comparison to other liver cell types. Collectively, these data suggest that Kupffer cells are potentially vulnerable to the increased concentrations of 4-HNE occurring during oxidative stress.