Metabolism of protein-bound DOPA in mammals

Protein-bound 3,4-dihydroxyphenylalanine (DOPA) can be generated in mammalian cells by both controlled enzymatic pathways, and by uncontrolled radical reactions. Protein-bound DOPA (PB-DOPA) has reducing activity and the capacity to inflict secondary damage on other important biomolecules such as DNA. This may be mediated through replenishment of transition metals or from catechol-quinone-catechol redox cycles in the presence of cellular components such as ascorbate or cysteine, resulting in amplification of radical damaging events. The generation of PB-DOPA confers on protein the ability to chelate transition metals generating protein 'oxychelates'; this may be amongst the factors, which localise such damage. Tissue levels of PB-DOPA are increased in a number of age-related pathologies such as atherosclerosis and cataract formation. We discuss the detoxification, and the subsequent proteolysis and excretion of components of PB-DOPA. We contrast the fact that in marine organisms, and particularly in extracellular proteins, PB-DOPA and other DOPA-polymers can play important functional roles in adhesion and the provision of tensile properties.     

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.     

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.     

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.     

The phylogeny and chemical diversity of quinone-tanned glues and varnishes

1. 3,4-Dihydroxyphenyl-L-alanine (DOPA)-containing proteins are widely distributed throughout the animal kingdom and appear to serve chiefly as waterproof adhesives and varnishes. 2. The unique chemical and physical stability of these adhesives and varnishes is imparted by quinone-tanning, an oxidative process that leads to the polymerization of DOPA-containing and other proteins. 3. Recent advances in the biochemistry of DOPA-containing proteins suggest that most consist of tandemly repeated sequence motifs. Each motif contains DOPA, a basic amino acid (usually lysine), and abundant glycine or proline. 4. The DOPA residues undergo catechol oxidase-catalyzed conversion to o-quinones at the onset of quinone-tanning. 5. The complexity of quinone chemistry is discussed with regard to quinone-tanning.     

Differentiation in brain and liver DOPA/5HTP decarboxylase activity after L-DOPA administration with or without pyridoxine in cats.

Abstract— Pyridoxine (50mg/kg, per os) given for 7 consecutive days did not modify the content of dopamine, noradrenaline, and serotonin in the neostriatum of the brain 3, 6 and 18 h after the last dose, but significantly increased DOPA/5HTP decarboxylase activity in both the neostriatum and liver. The administration of l-DOPA and pyridoxine (100 and 50mg/kg, per os, respectively) together for 7 days increased DOPA/5HTP decarboxylase activity in the brain to the same extent as did l-DOPA and pyridoxine given individually. Liver DOPA/5HTP decarboxylase activity remained normal when both drugs were administered together. However it decreased significantly after l-DOPA administration for 7 days but not after pyridoxine treatment. In cats under treatment with l-DOPA for 7 days, actinomycin D given for the final 3 days prevented the increased DOPA/5HTP decarboxylase activity induced by l-DOPA in the neostriatum and mesencephalon but had no effect on the enzymatic activity in the liver. These findings indicate that differences exist between brain and liver DOPA/SHTP decarboxylase activity in uivo. In addition, denatured supernatant from livers of animals treated with l-DOPA contained a dialysable compound which inhibits DOPA/SHTP decarboxylase activity in the supernatant from livers of untreated cats. In animals who received pyridoxine along with l-DOPA, no such inhibitor was found. These results may explain the mechanism by which l-DOPA exerts its beneficial effects and why pyridoxine administered with l-DOPA reduces the therapeutic effectiveness of l-DOPA in Parkinson's disease. These findings are consistent with the possibility that a tetrahydro-isoquinoline derivative formed in vivo in the liver after l-DOPA therapy for 7 days might affect DOPA/5HTP decarboxylase activity in the liver but not in brain. A tetrahydroisoquinoline derivative did not appear to be formed when l-DOPA and pyridoxine were administrated together suggesting that pyridoxine protected the enzyme and favored a more rapid degradation of l-DOPA peripherally with less l-DOPA available for the CNS.     

Effects of dithiothreitol on dopa oxidase activity from potato tubers

A filtrate, prepared from potato tuber by grinding in an isotonic medium, has been separated into a particulate and a ‘soluble’ fraction by ultracentrifugation. Following dialysis and lyophilization, both fractions catalysed the oxidation of l-DOPA, with approximately 30% of the l-DOPA: oxygen-oxidoreductase (EC 1.14.18.1; DOPA oxidase) activity being associated with the particulate fraction. When dithiothreitol (DTT, 10^?2M was included in the grinding medium, much lower yields of DOPA oxidase were obtained and 80% appeared to be associated with the particulate fraction. DTT proved to be a powerful inhibitor of DOPA oxidase. With concentrations of DTT causing only partial inhibition, the kinetics of the inhibited rate of dopachrome formation from l-DOPA were complex. When oxygen consumption was measured inhibition was not transient. The degree of inhibition was inversely related to the DOPA oxidase activity, indicating interaction of a product of this activity with DTT. Direct determination of -SH groups in DTT using 5,5′-dithiobis(2-nitrobenzoic acid (DTNB) showed that they were all oxidised during the initial phase of inhibition of dopachrome formation. It is concluded that the first phase of inhibition involves oxidation of DTT by an intermediate between l-DOPA and dopachrome. The second phase of inhibition also appeared to require -SH groups initially, since trans-4,5-dihydroxy-1,2-dithiane (oxidized DTT) caused very little inhibition at all.     

Involvement of caveolin-1 in cholesterol enrichment of high density lipoprotein during its assembly by apolipoprotein and THP-1 cells

High density lipoprotein (HDL) is assembled by interaction of apolipoprotein A-I with human monocytic leukemia cell line THP-1 by removing cellular cholesterol and phospholipid. Although the HDL formed with undifferentiated THP-1 cells contained only phosphatidylcholine and almost no cholesterol, the cells differentiated with phorbol 12-myristate 13-acetate (PMA) generated HDL enriched in cholesterol. The extent of cholesterol enrichment related to the cellular cholesterol level in the differentiated cells, but only weakly in the undifferentiated cells. In contrast, the differentiation had no influence on the diffusion-mediated cellular cholesterol efflux. The undifferentiated cells expressed the messages of ATP-binding cassette transporter 1 and caveolin-1, at low levels, and the PMA-induced differentiation resulted in substantial expression of both messages. Caveolin-1 protein expression was also highly induced by the PMA treatment of THP-1 cells. When the cells were treated with the antisense DNA of caveolin-1 and differentiated, both caveolin-1 synthesis and cholesterol incorporation into the HDL were reduced in parallel to generate the cholesterol-poor HDL.We concluded that caveolin-1 is involved in enrichment with cholesterol of the HDL generated by the apolipoprotein-cell interaction. This function is independent of the assembly of HDL particles with cellular phospholipid and of nonspecific, diffusion-mediated efflux of cellular cholesterol.     

DOPA and tyrosine decarboxylase activity in tissues of Periplanet a americana in relation to cuticle formation and ecdysis

DOPA decarboxylase activity in haemolymph and integument was low in last instar and early pharate adult Periplaneta americana, but began to increase shortly before ecdysis. Decarboxylation rates of l-DOPA, about 10 times the larval level by the start of ecdysis, reached a peak about 6 hr afterward, coinciding with the main period of cuticular sclerotization. Activity decreased rapidly during the next 18 hr, then decreased gradually for several days. Haemolymph DOPA decarboxylase activity was about four times greater than the integument, based on tissue dry weights. The fat body and gut tissues had low DOPA decarboxylase activity in all ages tested, and this did not increase at ecdysis. Tyrosine decarboxylase activity was significant only in the haemolymph and at consistently low levels.DOPA decarboxylase, therefore, apparently plays a major rôle in production of catecholamine derivatives for cuticular sclerotization in P. americana, while tyrosine decarboxylation is minor. Both haemolymph and integument appear to be important sites of dopamine biosynthesis.     

The impact of specific oxidized amino acids on protein turnover in J774 cells

Oxidized protein deposition and accumulation have been implicated in the aetiology of a wide variety of age-related pathologies. Protein oxidation in vivo commonly results in the in situ modification of amino acid side chains, generating new oxidized amino acid residues in proteins. We have demonstrated previously that certain oxidized amino acids can be (mis)incorporated into cell proteins in vitro via protein synthesis. In the present study, we show that incorporation of o- and m-tyrosine resulted in increased protein catabolism, whereas dopa incorporation generated proteins that were inefficiently degraded by cells. Incorporation of higher levels of L-dopa into proteins resulted in an increase in the activity of lysosomal cathepsins, increased autofluorescence and the generation of high-molecular-mass SDS-stable complexes, indicative of protein aggregation. These effects were due to proteins containing incorporated L-dopa, since they were not seen with the stereoisomer D-dopa, which enters the cell and generates the same reactive species as L-dopa, but cannot be incorporated into proteins. The present study highlights how the nature of the oxidative modification to the protein can determine the efficiency of its removal from the cell by proteolysis. Protection against the generation of dopa and other species that promote resistance to proteolysis might prove to be critical in preventing toxicity from oxidative stress in pathologies associated with protein deposition, such as atherosclerosis, Alzheimer's disease and Parkinson's disease.     

Protein engineering for covalent immobilization and enhanced stability through incorporation of multiple noncanonical amino acids

In this study, we demonstrate the application of multiple functional properties of proteins generated through coupling of residue-specific and site-specific incorporation method. With green fluorescent protein (GFP) as a model protein, we constructed multifunctional GFP through sitespecific incorporation of L-3,4-dihydroxyphenylalanine (DOPA) and residue-specific incorporation of (2S, 4S)-4- fluoroproline (4S-FP) or L-homopropargylglycine (hpg). Fluorescence analysis revealed a conjugation efficiency of approximately 20% for conjugation of DOPA-containing variants GFPdopa, GFPdp[4S-FP], and GFPdphpg onto chitosan. While incorporation of 4S-FP improved protein folding and stability, hpg incorporation into GFP allowed conjugation with fluorescent dye/polyethylene glycol (PEG). In addition, the modification of GFPhpg and GFPdphpg with PEG through Cu(I)-catalyzed click reaction increased protein thermal stability by about two-fold of the wild-type GFP.     

OxLDL induced cell death is inhibited by the macrophage synthesised pterin, 7,8-dihydroneopterin, in U937 cells but not THP-1 cells

The atherosclerotic plaque is an inflammatory site where macrophage cells are exposed to cytotoxic oxidised low density lipoprotein (oxLDL). Interferon-gamma released from T-cells results in macrophage synthesis of 7,8-dihydroneopterin which has antioxidant and cytoprotective activity. Using the human derived monocyte-like U937 and THP-1 cell lines, we examined whether 7,8-dihydroneopterin could inhibit the cytotoxic effect of oxLDL. In U937 cells, oxLDL caused a dramatic loss of cellular glutathione and caspase independent cell death associated with phosphatidylserine exposure on the plasma membrane. 7,8-Dihydroneopterin completely blocked the cytotoxic effect of oxLDL. In contrast, oxLDL initiated THP-1 cell apoptosis with reduction in cellular thiols, caspase-3 activation and plasma membrane phosphatidylserine exposure. 7,8-Dihydroneopterin was unable to alter these processes or restore the THP-1 cellular thiol content. 7,8-Dihydroneopterin did provide some protection to both THP-1 cells and U937 cells from AAPH derived peroxyl radicals. The preincubation of oxLDL with 7,8-dihydroneopterin did not reduce cytotoxicity, suggesting that 7,8-dihydroneopterin may be acting in U937 cells by scavenging intracellular oxidants generated by the oxLDL. The data show that muM levels of 7,8-dihydroneopterin may prevent oxLDL mediated cellular death within atherosclerotic plaques.     

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.     

Effects of ferumoxides-protamine sulfate labeling on immunomodulatory characteristics of macrophage-like THP-1 cells

Superparamagnetic Iron Oxide (SPIO) complexed with cationic transfection agent is used to label various mammalian cells. Labeled cells can then be utilized as an in vivo magnetic resonance imaging (MRI) probes. However, certain number of in vivo administered labeled cells may be cleared from tissues by the host's macrophages. For successful translation to routine clinical application of SPIO labeling method it is important that this mode of in vivo clearance of iron does not elicit any diverse immunological effects. The purpose of this study was to demonstrate that SPIO agent ferumoxides-protamine sulfate (FePro) incorporation into macrophages does not alter immunological properties of these cells with regard to differentiation, chemotaxis, and ability to respond to the activation stimuli and to modulate T cell response. We used THP-1 cell line as a model for studying macrophage cell type. THP-1 cells were magnetically labeled with FePro, differentiated with 100 nM of phorbol ester, 12-Myristate-13-acetate (TPA) and stimulated with 100 ng/ml of LPS. The results showed 1) FePro labeling had no effect on the changes in morphology and expression of cell surface proteins associated with TPA induced differentiation; 2) FePro labeled cells responded to LPS with slightly higher levels of NFkappaB pathway activation, as shown by immunobloting; TNF-alpha secretion and cell surface expression levels of CD54 and CD83 activation markers, under these conditions, were still comparable to the levels observed in non-labeled cells; 3) FePro labeling exhibited differential, chemokine dependent, effect on THP-1 chemotaxis with a decrease in cell directional migration to MCP-1; 4) FePro labeling did not affect the ability of THP-1 cells to down-regulate T cell expression of CD4 and CD8 and to induce T cell proliferation. Our study demonstrated that intracellular incorporation of FePro complexes does not alter overall immunological properties of THP-1 cells. The described experiments provide the model for studying the effects of in vivo clearance of iron particles via incorporation into the host's macrophages that may follow after in vivo application of any type of magnetically labeled mammalian cells. To better mimic the complex in vivo scenario, this model may be further exploited by introducing additional cellular and biological, immunologically relevant, components.     

Biosynthesis and Genetic Incorporation of 3,4-Dihydroxy-L-Phenylalanine into Proteins in Escherichia coli

While 20 canonical amino acids are used by most organisms for protein synthesis, the creation of cells that can use noncanonical amino acids (ncAAs) as additional protein building blocks holds great promise for preparing novel medicines and for studying complex questions in biological systems. However, only a small number of biosynthetic pathways for ncAAs have been reported to date, greatly restricting our ability to generate cells with ncAA building blocks. In this study, we report the creation of a completely autonomous bacterium that utilizes 3,4-dihydroxy-L-phenylalanine (DOPA) as its 21st amino acid building block. Like canonical amino acids, DOPA can be biosynthesized without exogenous addition and can be genetically incorporated into proteins in a site-specific manner. Equally important, the protein production yields of DOPA-containing proteins from these autonomous cells are greater than those from cells exogenously fed with 9 mM DOPA. The unique catechol moiety of DOPA can be used as a versatile handle for site-specific protein functionalizations via either oxidative coupling or strain-promoted oxidation-controlled cyclooctyne-1,2-quinone (SPOCQ) cycloaddition reactions. We further demonstrate the use of these autonomous cells in preparing fluorophore-labeled anti-human epidermal growth factor 2 (HER2) antibodies for the detection of HER2 expression on cancer cells.     

Co-regulation of melanin precursors and tyrosinase in human pigment cells: roles of cysteine and glutathione.

Glutathione (GSH) and cysteine (CysH) have both been implicated in the biogenesis of the pheomelanin precursor 5-S-cysteinyldopa (5-S-CD). However, recent studies have shown that only CysH is transported across the membrane of isolated melanosomes, and that the positive regulation of CysH in pigment cells leads to an increased production of 5-S-CD. In the present study, the question was examined as to whether melanin precursors and tyrosinase could be coregulated by cellular thiols. To address this issue, the levels of CysH and GSH were varied in normal melanocytes and melanoma cells using buthionine sulfoximine (BSO), an inhibitor of GSH biosynthesis. Treatment with 50-100 microM BSO decreased GSH levels to less than 10% of control, and increased CysH levels between two- and five-fold in both cell types. Concomitant with this, an increase in the ratio of 5-S-CD to DOPA and a decrease in the pigment content of the cells were observed. The decrease in cell pigmentation was associated with strong decreases in tyrosine hydroxylase activity and 14C-melanin production. Only melanoma cells showed a modified tyrosinase isozyme pattern on Western immunoblots in response to BSO, while the mRNA expression of tyrosinase and TRP-1 were unchanged in both cell types. These results suggest that the balance between CysH and GSH, which is partly determined by the rate of utilization of CysH for GSH biosynthesis, regulates not only the levels of 5-S-CD and DOPA but also the melanogenic activity of pigment cells. Since DOPA functions as a cofactor in the monophenolase reaction of tyrosinase, it is proposed that the ratio of 5-S-CD to DOPA may be an important factor in the regulation of tyrosinase activity in situ.     

Adhesion a la moule

Mussels owe their sessile way of life in the turbulent intertidalzone to adaptive adjustments in the process and biochemistryof permanent attachment. These have understandably attractedscientific interest given that the attachment is rapid, versatile,tough and not subverted by the presence of water. The adhesivepads of mussel byssus contain at least six different proteinsall of which possess the peculiar amino acid 3, 4-dihydroxyphenylalanine(DOPA) at concentrations ranging from 0.1 to 30 mol %. Studiesof protein distribution in the plaque indicate that proteinswith the highest levels of DOPA, such as mefp-3 (20 mol %) andmefp-5 (30 mol %), appear to predominate at or near the interfacebetween the plaque and substratum. Although the presence ofDOPA in proteins has traditionally been associated with cross-linkingvia chelate-mediated or covalent coupling, recent experimentswith natural and synthetic DOPA-containing polypeptides suggestthat cross-link formation is not the only fate for DOPA. IntactDOPA, particularly near the interface, may be essential forgood chemisorption to polar surfaces. Uniformly high DOPA oxidationto cross-links leads to interfacial failure but high cohesivestrength, while low DOPA oxidation results in better adhesionat the expense of cohesion. Defining the adaptations involvedin balancing these two extremes is crucial to understandingmarine adhesion.     

Effect of matrix composition on chemotaxis response of monocytes stimulated by monocyte chemoattractant protein-1

MCP-1-stimulated chemotaxic response of monocytic cell line THP-1 and peripheral blood monocytes were investigated through extra cellular matrix proteins fibronectin, fibrinogen and fibrinogen degradation products. Cellular migration was significantly decreased in the presence of fibrinogen as compared with fibronectin. Fibrinogen proteolysis with plasmin generating D and E degradation products, resulted in increase of the chemotaxic response.     

Photo-oxidation of cells generates long-lived intracellular protein peroxides

Singlet oxygen is generated by several cellular, enzymatic, and chemical reactions as well as by exposure to UV or visible light in the presence of a sensitizer. Consequently, this oxidant has been proposed to be a damaging agent many pathologies. Proteins are major targets for singlet oxygen as a result of their abundance and high rate constants for reaction. In this study, we show that illumination of viable rose bengal-loaded THP-1 (human monocyte-like) cells with visible light gives rise to intracellular protein-derived peroxides. The peroxide yield increases with illumination time, requires the presence of rose bengal, is enhanced in D(2)O, and is decreased by azide, consistent with the mediation of singlet oxygen. The concentration of peroxides detected, which is not affected by glucose or ascorbate loading of the cells, corresponds to about 1.5 nmoles peroxide per 10(6) cells, or 10 nmoles/mg cell protein, and account for up to approximately 15% of the O(2) consumed by the cells. Similar peroxides have been detected on isolated cellular proteins exposed to light in the presence of rose bengal and oxygen. After cessation of illumination, cellular protein peroxide levels decrease with t(1/2) about 4 h at 37 degrees C. Decomposition of protein peroxides formed within cells, or on isolated cellular proteins, by metal ions gives rise to radicals as detected by EPR spin trapping. These studies demonstrate that exposure of intact cells to visible light in the presence of a sensitizer leads to novel long-lived, but reactive, intracellular protein peroxides via singlet oxygen-mediated reactions.