Radical sequestration by protein-bound 3,4-dihydroxyphenylalanine

Protein-bound 3,4-dihydroxyphenylalanine (PB-DOPA), a redox-active product of protein oxidation, is capable of functioning as both a pro- and antioxidant. A number of in vitro and in vivo studies have demonstrated a toxic, non-toxic or even beneficial effect of free DOPA, however little investigation has examined the physiological activity of PB-DOPA. Being the major treatment available for Parkinson's disease, most studies have focused on the effect of DOPA within neurological cells or tissues, although the presence of PB-DOPA in other locations, for example within atherosclerotic plaques, suggests that broader research is needed to fully understand the physiological effects of both free and PB-DOPA. We hypothesise that the generation of PB-DOPA can trigger an enhancement of the cellular antioxidant defence system, thus enabling PB-DOPA to restrict and potentially terminate the initiating oxidative stress, minimising the level of oxidative damage. Using luminol-enhanced chemiluminescence, we demonstrate that free DOPA is capable of direct peroxyl radical scavenging, even in the presence of competing scavengers, and has a different effect to that of the parent amino acid, tyrosine. Furthermore, we show that both free and PB-DOPA, in combination or individually, were able to protect monocytes and macrophages from peroxyl radical-induced oxidative stress in vitro. These results confirm a role for both free and PB-DOPA in cellular antioxidant defences and suggest the possibility of using DOPA as a potential therapeutic for the treatment of diseases involving oxidative stress or the accumulation of oxidative damage.     

Biosynthesis and turnover of DOPA-containing proteins by human cells

Protein-bound 3,4-dihydroxyphenylalanine (PB-DOPA) is a major product of hydroxyl radical attack on tyrosine residues of proteins. Levels of PB-DOPA in cells and tissues have been shown to be greatly elevated in age-related diseases. We demonstrate for the first time that l-DOPA (levodopa) can be biosynthetically incorporated into cell proteins by human cells (THP-1 monocytes and monocyte-derived macrophages). The DOPA-containing proteins generated were selectively visualized on PVDF membranes using a redox-cycling staining method. Many cell proteins contained DOPA and seemed to be synthesized as their full-length forms. The cellular removal of DOPA-containing proteins by THP-1 cells was by proteolysis involving both the proteasomal and the lysosomal systems. The rate of cellular proteolysis of DOPA-containing proteins increased at lower levels of DOPA incorporation but decreased at higher levels of DOPA incorporation. The decreased rate of degradation was accompanied by an increase in the activity of cathepsins B and L but the activity of cathepsin S increased only at lower levels of DOPA incorporation. These data raise the possibility that PB-DOPA could be generated in vivo from l-DOPA, which is the most widely used treatment for Parkinson disease.     

Free and peptide-bound DOPA can inhibit initiation of low density lipoprotein oxidation

Hydroxyl radicals have been shown to convert free tyrosine to 3,4-dihydroxyphenyl-alanine (DOPA) which has reducing properties. During protein or peptide oxidation such reducing species are also formed from tyrosine residues. Free DOPA or peptide-bound DOPA (PB-DOPA) is able to promote radical-generating events, facilitating the damage of biomolecules such as nucleic acids. Radical induced lipid oxidation in low density lipoprotein (LDL) transforms the lipoprotein into an atherogenic particle. As PB-DOPA has been found in atherosclerotic plaques, we tested the ability of free and PB-DOPA to influence LDL oxidation. Free DOPA, in contrast to tyrosine had strong inhibitory action on both, the copper-ion initiated and metal ion independent (AAPH-induced) lipid oxidation. Free DOPA also inhibited LDL oxidation induced by the copper transport protein ceruloplasmin. To test if PB-DOPA was also able to inhibit LDL oxidation, DOPA residues were generated enzymatically in the model peptides insulin and tyr-tyr-tyr, respectively. PB-DOPA formation substantially increased the ability of both molecules to inhibit LDL oxidation by copper or AAPH. We hypothesize that DOPA-peptides and -proteins may have the potential to act as efficacious antioxidants in the atherosclerotic plaque.     

Histidine and Proline are Important Sites of Free Radical Damage to Proteins

Our hypothesis that proline and histidine are major sites of damage during radical attack upon proteins, becoming respectively glutamate and aspartate. was investigated using proteins biosynthetically labelled with radioactive proline or histidine as targets. Free radicals were generated by copper and H₂O₂, or by gamma radiolysis. Protein-bound histidine was substantially converted into aspartate. Much proline was modified during radical attack, but it was not converted into glutamate. We conclude that histidine and proline are important sites of protein attack by radicals; protein cleavage may result from these reactions.     

Role of oxygen free radicals in carcinogenesis and brain ischemia

Even though oxygen is necessary for aerobic life, it can also participate in potentially toxic reactions involving oxygen free radicals and transition metals such as Fe that damage membranes, proteins, and nucleic acids. Oxygen free radical reactions and oxidative damage are in most cases held in check by antioxidant defense mechanisms, but where an excessive amount of oxygen free radicals are produced or defense mechanisms are impaired, oxidative damage may occur and this appears to be important in contributing to several pathological conditions including aging, carcinogenesis, and stroke. Several newer methods, such as in vivo spin-trapping, have become available to monitor oxygen free radical flux and quantitate oxidative damage. Using a combination of these newer methods collectively focused on one model, recent results show that oxidative damage plays a key role in brain injury that occurs in stroke. Subtle changes, such as oxidative damage-induced loss of glutamine synthetase activity, may be a key event in stroke-induced brain injury. Oxygen free radicals may play a key role in carcinogenesis by mediating formation of base adducts, such as 8-hydroxyguanine, which can now be quantitated to very low levels. Evidence is presented that a new class of free radical blocking agents, nitrone spin-traps, may help not only to clarify if free radical events are involved, but may help prevent the development of injury in certain pathological conditions.     

Protein hydroperoxides are a major product of low density lipoprotein oxidation during copper, peroxyl radical and macrophage-mediated oxidation

Damage to apoB100 on low density lipoprotein (LDL) has usually been described in terms of lipid aldehyde derivatisation or fragmentation. Using a modified FOX assay, protein hydroperoxides were found to form at relatively high concentrations on apoB100 during copper, 2,2'-azobis(amidinopropane) dihydrochloride (AAPH) generated peroxyl radical and cell-mediated LDL oxidation. Protein hydroperoxide formation was tightly coupled to lipid oxidation during both copper and AAPH-mediated oxidation. The protein hydroperoxide formation was inhibited by lipid soluble alpha-tocopherol and the water soluble antioxidant, 7,8-dihydroneopterin. Kinetic analysis of the inhibition strongly suggests protein hydroperoxides are formed by a lipid-derived radical generated in the lipid phase of the LDL particle during both copper and AAPH mediated oxidation. Macrophage-like THP-1 cells were found to generate significant protein hydroperoxides during cell-mediated LDL oxidation, suggesting protein hydroperoxides may form in vivo within atherosclerotic plaques. In contrast to protein hydroperoxide formation, the oxidation of tyrosine to protein bound 3,4-dihydroxyphenylalanine (PB-DOPA) or dityrosine was found to be a relatively minor reaction. Dityrosine formation was only observed on LDL in the presence of both copper and hydrogen peroxide. The PB-DOPA formation appeared to be independent of lipid peroxidation during copper oxidation but tightly associated during AAPH-mediated LDL oxidation.     

A sensitive fluorometric assay for protein-bound DOPA and related products of radical-mediated protein oxidation

Oxidative attack on proteins results in the hydroxylation of tyrosyl residues to protein-bound DOPA (3,4-dihydroxyphenylalanine). Existing methods for assaying protein-bound DOPA have poor sensitivity and numerous possible interferences, such that accurate determination (especially of very low DOPA concentrations) has required time-consuming acid hydrolysis and HPLC analysis with fluorometric detection. This work presents a sensitive and selective assay for peptide or protein-bound o-benzoquinones derived from DOPA based on fluorometric detection of ethylenediamine derivatives. Detection limits for protein-bound DOPA are in tbe range 0.53–4.70 ng/mL for the assay mixture, corresponding to sample DOPA concentrations of 0.59–5.30 ng/mL (representing a minimum of 6–54 pmole detected), depending on the particular protein/peptide under study. The assay response increases linearly with DOPA concentration, and also with the extent of radical exposure of the protein. The assay is a simple and fast way to assess DOPA formation and thus oxidative damage in a protein.     

Protein Hydroperoxides are a Major Product of Low Density Lipoprotein Oxidation During Copper,Peroxyl Radical and Macrophage-mediated Oxidation

Damage to apoB100 on low density lipoprotein (LDL) has usually been described in terms of lipid aldehyde derivatisation or fragmentation. Using a modified FOX assay, protein hydroperoxides were found to form at relatively high concentrations on apoB100 during copper, 2,2′-azobis(amidinopropane) dihydrochloride (AAPH) generated peroxyl radical and cell-mediated LDL oxidation. Protein hydroperoxide formation was tightly coupled to lipid oxidation during both copper and AAPH-mediated oxidation. The protein hydroperoxide formation was inhibited by lipid soluble α-tocopherol and the water soluble antioxidant, 7,8-dihydroneopterin. Kinetic analysis of the inhibition strongly suggests protein hydroperoxides are formed by a lipid-derived radical generated in the lipid phase of the LDL particle during both copper and AAPH mediated oxidation. Macrophage-like THP-1 cells were found to generate significant protein hydroperoxides during cell-mediated LDL oxidation, suggesting protein hydroperoxides may form in vivo within atherosclerotic plaques. In contrast to protein hydroperoxide formation, the oxidation of tyrosine to protein bound 3,4-dihydroxyphenylalanine (PB-DOPA) or dityrosine was found to be a relatively minor reaction. Dityrosine formation was only observed on LDL in the presence of both copper and hydrogen peroxide. The PB-DOPA formation appeared to be independent of lipid peroxidation during copper oxidation but tightly associated during AAPH-mediated LDL oxidation.     

Oxyl radicals, redox-sensitive signalling cascades and antioxidants

Oxidative stress is an increase in the reduction potential or a large decrease in the reducing capacity of the cellular redox couples. A particularly destructive aspect of oxidative stress is the production of reactive oxygen species (ROS), which include free radicals and peroxides. Some of the less reactive of these species can be converted by oxidoreduction reactions with transition metals into more aggressive radical species that can cause extensive cellular damage. In animals, ROS may influence cell proliferation, cell death (either apoptosis or necrosis) and the expression of genes, and may be involved in the activation of several signalling pathways, activating cell signalling cascades, such as those involving mitogen-activated protein kinases. Most of these oxygen-derived species are produced at a low level by normal aerobic metabolism and the damage they cause to cells is constantly repaired. The cellular redox environment is preserved by enzymes and antioxidants that maintain the reduced state through a constant input of metabolic energy. This review summarizes current studies that have been regarding the production of ROS and the general redox-sensitive targets of cell signalling cascades.     

Lipid peroxidation associated protein damage in rat brain crude synaptosomal fraction mediated by iron and ascorbate

In crude synaptosomal fractions from rat brain exposed to iron and ascorbate, enhanced lipid peroxidation (more than 3-fold compared to control), loss of protein thiols up to the extent of 40% compared to control, increased incorporation of carbonyl groups into proteins (more than 4.5-fold compared to control) and non-disulphide covalent cross-linking of membrane proteins have been observed. The phenomena are not inhibited by catalase or hydroxyl radical scavengers like mannitol or dimethyl sulphoxide. However, chain breaking antioxidants like alpha-tocopherol and butylated hydroxytoluene prevent both lipid peroxidation and accompanying protein oxidation. It is suggested that in this system lipid peroxidation propagated by the decomposition of preformed lipid hydroperoxides by iron and ascorbate is the primary event and products of the peroxidation process cause secondary protein damage. In view of high ascorbate content of brain and availability of several transition metals, such ascorbate mediated oxidative damage may be relevant in the aetiopathogenesis of several neurodegenerative disorders as well as ageing of brain.     

A new method of identifying the site of tyrosyl radicals in proteins

Protein-bound tyrosyl radicals catalyze many important enzymatic reactions. They can also initiate oxidative damage to cells. Here we report a new method of computer simulation of tyrosyl radical electron paramagnetic resonance spectra. The method enables the determination of the rotational conformation of the phenoxyl ring in a radical with unprecedented accuracy (approximately 2 degrees ). When coupled with a new online database, all tyrosine residues in a protein can be screened for that particular conformation. For the first time we show relationships between the spin density on atom C1 (rho(C1)) and the principal g-factors measured by electron paramagnetic resonance spectroscopy (rho(C1) on g(x) is shown to be linear). The new method enables the accurate determination of rho(C1) in all known tyrosyl radicals, evaluates the likelihood of a hydrogen bond, and determines the possibility of a rho(C1) distribution in the radicals. This information, together with the accurately determined rotational conformation, is frequently sufficient to allow for an unambiguous identification of the site of radical formation. The possibility of a similar relationship between rho(C) and g(x) in other radicals, e.g., tryptophanyl, is discussed.     

A site-specific mechanism for free radical induced biological damage: the essential role of redox-active transition metals

The metal-mediated site-specific mechanism for free radical-induced biological damage is reviewed. According to this mechanism, cooper- or iron-binding sites on macromolecules serve as centers for repeated production of hydroxyl radicals that are generated via the Fenton reaction. The aberrations induced by superoxide, ascorbate, isouramil, and paraquat are summarized. An illustrative example is the enhancement of double-strand breaks by ascorbate/copper. Prevention of the site-specific free radical damage can be accomplished by using selective chelators for iron and copper, by displacing these redox-active metals with other redox-inactive metals such as zinc, by introducing high concentrations of hydroxyl radicals scavengers and spin trapping agents, and by applying protective enzymes that remove superoxide or hydrogen peroxide. Histidine is a special agent that can intervene in free radical reactions in variety of modes. In biological systems, there are traces of copper and iron that are at high enough levels to catalyze free-radical reactions, and account for such deleterious processes. In the human body Fe/Cu = 80/1 (w/w). Nevertheless, both (free) copper and iron are soluble enough, and the rate constants of their reduced forms with hydrogen peroxide are sufficiently high to suggest that they might be important mediators of free radical toxicity.     

Reactive Oxygen Species and the Central Nervous System

Radicals are species containing one or more unpaired electrons, such as nitric oxide (NO.). The oxygen radical superoxide (O2.-) and the nonradical hydrogen peroxide (H2O2) are produced during normal metabolism and perform several useful functions. Excessive production of O2.- and H2O2 can result in tissue damage, which often involves generation of highly reactive hydroxyl radical (.OH) and other oxidants in the presence of "catalytic" iron or copper ions. An important form of antioxidant defense is the storage and transport of iron and copper ions in forms that will not catalyze formation of reactive radicals. Tissue injury, e.g., by ischemia or trauma, can cause increased metal ion availability and accelerate free radical reactions. This may be especially important in the brain because areas of this organ are rich in iron and CSF cannot bind released iron ions. Oxidative stress on nervous tissue can produce damage by several interacting mechanisms, including increases in intracellular free Ca2+ and, possibly, release of excitatory amino acids. Recent suggestions that free radical reactions are involved in the neurotoxicity of aluminum and in damage to the substantia nigra in patients with Parkinson's disease are reviewed. Finally, the nature of antioxidants is discussed, it being suggested that antioxidant enzymes and chelators of transition metal ions may be more generally useful protective agents than chain-breaking antioxidants. Careful precautions must be used in the design of antioxidants for therapeutic use.     

Biosynthetic incorporation of oxidized amino acids into proteins and their cellular proteolysis

We demonstrate that oxidized amino acids can be incorporated into proteins by protein synthesis. The level of incorporation into protein was dependent on the concentration of oxidized amino acid supplied to the cells. At low levels of incorporation, the oxidized amino acids examined increased the degradation rate of the cell proteins. Degradation of certain proteins containing high levels of DOPA (but not ortho or meta tyrosine) was decreased to below the basal degradation rates suggesting that DOPA may contribute to proteins becoming resistant to proteolysis. Changes in the degradation rates of the oxidized amino acid-containing proteins was shown to have no impact on the degradation rates of native proteins, indicating that the activity of the degradative machinery was not affected. We demonstrate that oxidized proteins are selectively degraded by the proteasomes and provide evidence to suggest that the proteasomes and the endosomal-lysosomal systems may act in sequence as well as in parallel. The incorporation approach, unlike cell studies in which an exogenous oxidant is used, allows the degradation rates of the oxidatively modified proteins to be selectively measured, offering a greater sensitivity as well as greatly reducing toxicity to the cell and avoiding oxidative modification of other cell components.     

Oxidative DNA and protein damage in metal-induced toxicity and carcinogenesis

This review discusses the relevance of oxidative damage to metal-induced toxicity and carcinogenesis. Presented are important facts and mechanistic concepts on the capacity of selected transition metals, mainly Ni, but also Cu, Co, Cr, and briefly several others, to generate active oxygen species and other reactive intermediates under physiological conditions. These metals are known to be toxic and/or carcinogenic contaminants of the occupational and general environments. Their redox activity may underlay the mechanism of mediation of oxidative damage to cell constituents. The presentation is focused on selected issues relative to genetic and epigenetic toxicity and illustrated with examples of metal-mediated oxidative damage to the principal components of chromatin, i.e., DNA, histones, and protamines.     

The catecholic metal sequestering agent 1,2-dihydroxybenzene-3,5-disulfonate confers protection against oxidative cell damage.

Tiron (1,2-dihydroxybenzene-3,5-disulfonate), a nontoxic chelator of a variety of metals, is used to alleviate acute metal overload in animals. It is also oxidized to the EPR-detectable semiquinone radical by various biologically relevant oxidants, such as .OH, O2-., alkyl, and alkoxyl radicals. Since Tiron reacts with potentially toxic intracellular species and is also a metal chelator, we evaluated its protective effects in V79 cells subjected to various types of oxidative damage and attempted to distinguish the protection due to direct detoxification of intracellular radicals from that resulting from chelation of redox-active transition metals. We found that Tiron protects Chinese hamster V79 cells against both O2.(-)-induced (and H2O2 via dismutation of O2.-) and H2O2-induced cytotoxicity as measured by clonogenic assays. In experiments where Tiron was incubated with V79 cells and rinsed prior to exposure to HX/XO or H2O2, cytoprotection was observed, indicating that it protects against intracellular oxidative damage. On the other hand, Tiron did not protect V79 cells against the damage caused by ionizing radiation under aerobic conditions, which is predominantly mediated by H., .OH, and hydrated electrons in a metal-independent fashion. We demonstrate also that in in vitro studies, Tiron protects supercoiled DNA from metal-mediated superoxide-dependent strand breaks. We conclude that Tiron is a potentially useful protecting agent against the lethal effects of oxidative stress and suggest that it offers protection by chelating redox-active transition metal ions, in contrast to earlier reports where the protection by this compound in cellular systems subjected to oxidative damage has been interpreted as due to radical scavenging alone.     

Effects of dietary transition metals on oxidative DNA lesions in neonatal rats

Bulky endogenous oxidative lesions (type II I-compounds) reflect DNA damage associated with oxidative stress. As shown by 32P-postlabeling, their levels are enhanced by pro-oxidant genotoxins and also shortly after normal birth in several rat tissues as a function of time and the maternal diet. In order to elucidate which dietary components contribute to postnatal DNA damage, we have focused, herein, on the possible role of transition metals (iron, copper, and nickel). Pregnant Fischer 344 (F344) rats were fed AIN-93G purified diet containing different amounts of iron, copper, and nickel, or Purina-5001 natural-ingredient diet (which contains relatively high concentrations of these metals). Type II I-compounds were estimated by nuclease P1-enhanced 32P-postlabeling in liver and lung DNA of fetuses and at 24h and day 9 post-partum. Increased postnatal oxidative damage was detected in liver but not lung DNA of neonates exposed to higher amounts of dietary transition metals. There were significant positive linear correlations between maternal transition metal intake and neonatal, but not fetal and maternal type II I-compound levels. The results show that transition metals in the maternal diet affect perinatal oxidative DNA damage, presumably via a Fenton-type reaction. They also provide evidence for optimal levels in the maternal diet of transition metals, which on one hand, are essential for life, but on the other, can cause potentially deleterious DNA alterations in the offspring.     

Identification of damaged proteins in human serum using modified Ehrlich’s reagent to target protein-bound pyrroles

Protein-bound pyrroles are a sign of oxidative damage. Here we report a specific method for detecting pyrrole-containing proteins using biotin-labeled Ehrlich’s reagent (ER-B). After treatment of either human serum or isolated human serum proteins with various oxidizing agents, damaged, biotin-labeled components could be detected by blotting. Combining the use of ER-B with proteomic techniques allowed human serum proteins susceptible to oxidative damage to be detected and then identified by LC/MS/MS. Identification of such proteins in different human conditions such as obesity, diabetes, and cardiovascular disease should lead to the discovery of new biomarkers and the development of specific assays to monitor health status.