Oxidation of Amino Acids Peptides and Proteins by Ozone a Review

J Physiol. 2001 February 15; 531(Pt one): one–xi.

Regulation of cell part by methionine oxidation and reduction

Toshinori Hoshi

^*Section of Physiology and Biophysics, The University of Iowa, BSB 5-660, Iowa City, IA 52242, United states of america

Stefan H Heinemann

^†Research Unit of measurement Molecular and Cellular Biophysics, Medical Faculty of the Friedrich Schiller University Jena, Drackendorfer Straße ane, D-07747 Jena, Germany

Received 2000 Oct thirty; Accepted 2000 Nov 28.

Abstruse

Reactive oxygen species (ROS) are generated during normal cellular activity and may exist in excess in some pathophysiological conditions, such every bit inflammation or reperfusion injury. These molecules oxidize a multifariousness of cellular constituents, but sulfur-containing amino acid residues are specially susceptible. While reversible cysteine oxidation and reduction is function of well-established signalling systems, the oxidation and the enzymatically catalysed reduction of methionine is just emerging equally a novel molecular mechanism for cellular regulation. Here nosotros hash out how the oxidation of methionine to methionine sulfoxide in signalling proteins such as ion channels affects the office of these target proteins. Methionine sulfoxide reductase, which reduces methionine sulfoxide to methionine in a thioredoxin-dependent manner, is therefore not just an enzyme important for the repair of historic period- or degenerative disease-related protein modifications. It is too a potential missing link in the mail-translational modification cycle involved in the specific oxidation and reduction of methionine residues in cellular signalling proteins, which may give rise to activeness-dependent plastic changes in cellular excitability.

Reactive oxygen species

Reactive oxygen species (ROS; different definitions of reactive oxygen species, free radicals and oxidants exist, encounter Halliwell & Gutteridge, 1999), such every bit the superoxide anion (O²⁻·) and hydrogen peroxide (H_twoO_ii), are generated every bit part of the normal aerobic cellular being and these reactive species in plough promote the production of many other molecules capable of inducing oxidative stress in cells. A delicate overall residue is normally maintained between the production and elimination of these oxidants using a multifariousness of non-enzymatic and enzymatic processes. Every bit shown beneath, nevertheless, it is becoming increasingly evident that cells may apply small and/or local changes in oxidants/ROS concentrations as signals in cellular signal transduction (Suzuki et al. 1997; Fukagawa, 1999; Finkel, 2000).

Many ROS are free radicals with unpaired electrons, which are ofttimes very reactive and take very short half-life times. For example, starting from superoxide, the Fenton reaction produces H_twoO₂ and and so hydroxyl radical (OH⁻·) using transition element ions such as Fe^three+/Atomic number 26²⁺. The hydroxyl radical is considered to exist involved in the oxidative damage of various biomolecules. Although very powerful, these reactive radicals are expected to take small improvidence abiding values, limiting their effective range. The hydroxyl radical has a life-time of simply 2 ns and its diffusion radius is only 2 nm (Haugland, 1996). Less reactive species, however, may exert long-range effects within or even betwixt cells. For example, NO, a weak radical, functions every bit an intercellular and an intracellular messenger (Jaffrey & Snyder, 1995; Yun et al. 1996; Squadrito & Pryor, 1998).

ROS, especially in the presence of other cofactors such as certain metal ions, are capable of oxidatively modifying a variety of cellular constituents (Halliwell & Gutteridge, 1999). The oxidative stress induced by these reactive agents could lead to lipid peroxidation, DNA damage and poly ADP-ribose synthetase activation, carbohydrate and protein damage. Lipid peroxidation resulting from oxidation of cholesterol and fatty acids may compromise the cell membrane integrity, and Dna impairment may eventually lead to prison cell death or abnormal cell growth. The oxidant-mediated damages to Dna, lipids and proteins are likely to contribute to ageing, historic period-associated changes, and age-related degenerative diseases (Stadtman & Berlett, 1998).

Oxidation of amino acids

Amino acrid residues in proteins represent ane of the major targets of ROS and cellular oxidants. All amino acids tin be oxidized, at least experimentally. These oxidative modifications include the polypeptide backbone as well every bit the amino acrid side chain. Oxidative abstraction of a hydrogen atom from the α carbon cantlet could lead to peptide bond cleavage (Stadtman & Berlett, 1999). Side chains of amino acids in proteins are readily oxidized to markedly alter the overall properties of the amino acids, thus potentially modifying protein function. A comprehensive list of the oxidatively modified amino acids is constitute elsewhere (Berlett & Stadtman, 1997; Halliwell & Gutteridge, 1999; Stadtman & Berlett, 1999). Different amino acids differ markedly in how easily their side chains are oxidatively modified. The sulfur-containing amino acids, cysteine and methionine, are particularly sensitive to ROS-mediated oxidation, although the side chains of arginine, lysine, proline, histidine, tryptophan, and tyrosine are too known to be oxidatively modified (Berlett & Stadtman, 1997; Stadtman & Berlett, 1999). The overall extent of protein oxidation is often estimated past measuring the carbonyl content (Levine et al. 1994); however, some confounding problems have been raised regarding this analysis (Halliwell & Gutteridge, 1999). A pregnant fraction of the total protein may be oxidized in humans (Stadtman, 1992).

Sulfur-containing amino acids: cysteine and methionine

Cysteine and methionine possess reactive sulfur-containing side chains that represent prime targets of ROS. Oxidation of cysteine and methionine residues in proteins are noteworthy in that the reactions can be physiologically reversible.

Oxidation of the thiol-containing cysteine, frequently promoted by the presence of trace amounts of metallic ions such as Cu²⁺, Fe^two+, Co²⁺ and Mn²⁺, leads to a variety of products including the sulfenic ion, disulfide and sulfonic ion (Finkel, 2000). Physiologically, the disulfide germination may be the most probable consequence of cysteine oxidation (Creighton, 1993). Disulfides can be hands reduced dorsum to thiols using glutathione in vivo or dithiothreitol (DTT) in vitro. Reversible oxidation of cysteine has been postulated to work equally an of import cellular redox sensor in some proteins (Finkel, 2000). Stronger experimental oxidants may produce sulfonic and eventually sulfenic acrid. Functional modulation of proteins in cellular excitability by cysteine oxidation has been suggested in many unlike experimental systems. Modulation of Due north-blazon inactivation of voltage-dependent potassium channels exemplifies a fast and reversible regulatory phenomenon mediated by oxidation of a specific cysteine residue in the amino-terminus of the channel protein (Kv1.4) (Ruppersberg et al. 1991) or the associated β-subunits (Rettig et al. 1994; Heinemann et al. 1995). The sensitivity of NMDA receptors in the brain to glutamate and H⁺ is also modulated by oxidation of two cysteine residues in NR1 subunits (Sullivan et al. 1994).

Oxidation of methionine

Methionine is oxidized to methionine sulfoxide (MetO, MeSOX, MetSO, or MsX) by the add-on of an extra oxygen atom (Fig. ane). The presence of methionine sulfoxide has been documented in native proteins (eastward.m. Gao et al. 1998), indicating that oxidation of the methionine side chain is a physiologically relevant miracle. Unfortunately, the lack of an antibody specific to methionine sulfoxide has slowed elucidation of tissue distributions of methionine sulfoxide. In the presence of a strong oxidant, MetO is further oxidized to grade methionine sulfone (MetO₂). However, the formation of MetO₂ may be of pathophysiological and/or experimental relevance only. Changes in the physical backdrop of the methionine side chain induced by oxidation are profound and are expected to alter protein office. The side chain of normal methionine is long, flexible, and non-polar (Richardson & Richardson, 1989). Although many methionine residues are excluded from the surface, some proteins may comprise multiple exposed methionine residues (Levine et al. 1996). The side chain of methionine sulfoxide with the extra oxygen atom is stiffer and more polar than that of the methionine side chain. The hydrophobicity index of methionine sulfoxide has been estimated to be similar to that of lysine, a positively charged amino acid (Black & Mould, 1991). If one considers only the hydrophobicity aspect, this may be analogous to substitution of methionine with a charged amino acid. It should exist noted, however, that the charge consideration alone is not likely to explain all the functional changes caused past methionine oxidation (Yin et al. 1999). The specific oxidation and reduction of methionine residues in proteins is expected to have profound consequences for protein function and may constitute a mechanism for poly peptide regulation (meet beneath). Furthermore, it has been suggested that the extent of cellular methionine oxidation is underestimated in part because the amino acid assay based on the acrid digestion is not suited for detection of methionine sulfoxide (Squier & Bigelow, 2000).

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Oxidation and reduction of methionine residues

The amino acid methionine (Met) is hands oxidized to methionine sulfoxide (MetO) in the presence of balmy oxidants. A second oxidation step, requiring stronger oxidants such as chloramine-T, results in methionine sulfone (MetO_two). While MetO₂ is stable under physiological weather condition, MetO can exist reduced back to Met by ways of the enzyme peptide methionine sulfoxide reductase (MSRA). To maintain catalytic activity, MSRA needs an electron acceptor. Under physiological conditions MSRA is coupled via thioredoxin, thioredoxin reductase, and NADPH to the cellular redox system. The activity of MSRA may likewise be bailiwick to cellular regulation past thus far unidentified cofactors.

Methionine side bondage are oxidized past a range of different ROS, such every bit O²⁻·, H₂O₂, peroxynitrite (ONOO⁻), or ·OH. Experimentally, effects of methionine oxidation are often examined using oxidizing reagents that promote oxidation beyond the 'basal' level. Many methionine-specific reagents and oxidizing reactions have been reported in the literature. For example, dimethyl sulfoxide is a very specific methionine oxidizer, provided that at least 0.i Thousand and preferably ane Grand HCl is nowadays (Shechter et al. 1975). Unfortunately, many of these reaction conditions are non readily compatible with typical physiological investigations. Chloramine-T (Ch-T), H₂O_ii and t-butyl hydroperoxide take been used to infer the furnishings of methionine oxidation in physiological systems (see below). H₂O_two and t-butyl hydroperoxide could be used as specific methionine oxidizers specially if the halide concentration is negligible (Keck, 1996). H₂O_ii may be considered equally a relatively physiological oxidizer since it may mimic the methionine oxidation pattern found in vivo (Gao et al. 1998; Squier & Bigelow, 2000). Some data about the target methionine residues could exist obtained by comparing the effects of H₂O₂ and t-butyl hydroperoxide. t-Butyl hydroperoxide may specifically modify exposed surface methionine residues whereas H_iiO_two attacks both exposed and buried methionine residues (Keck, 1996). In addition to methionine, these agents may also oxidize cysteine, and some caution is warranted when interpreting the results. It may also be prudent to carefully command the concentrations of contaminating divalent and trivalent metallic ions when performing the experiments using these oxidizing agents since production of radicals may depend on the availability of these metallic ions. Seemingly conflicting results could be explained past the presence of different concentrations of contaminating ions.

The changes in the physical and chemical backdrop associated with oxidation of methionine summarized to a higher place could lead to discernible changes in poly peptide part and cell physiology. These changes include loss of office (degeneration) and regulation of cell function. Some examples to illustrate these changes are discussed later in this commodity. We volition emphasize the function of methionine oxidation as a regulator of prison cell function. However, there are many proteins that harbour methionine residues at their surface and oxidation of these residues does non seem to impair office. Therefore, it can be speculated that the cyclic oxidation/reduction of such methionine residues may also constitute an endogenous arrangement with local antioxidative chapters (Levine et al. 1996).

Methionine sulfoxide reductase (MSRA)

As is the instance with reduction of oxidized cysteine, MetO can be physiologically reduced dorsum to methionine. Unlike reduction of disulfides, the reducing reaction of MetO to methionine is catalysed by the enzyme peptide methionine sulfoxide reductase (MSRA) using thioredoxin in vivo or DTT in vitro (Moskovitz et al. 1996; Fig. one). A recent study suggests that MSRA may preferentially reduce L-methionine sulfoxide (Sharov et al. 1999). MSRA is a relatively small cytosolic enzyme constitute in a variety of organisms from leaner (Moskovitz et al. 1995) to plants (Sadanandom et al. 2000) and mammals (Moskovitz et al. 1996), including humans (Kuschel et al. 1999). The amino acid sequence is well conserved amongst dissimilar species; the Escherichia coli and human MSRA amino acid sequences are approximately lx % identical with notable differences occurring in the distal N- and C-last segments. The crystal structure of MSRA has become available recently (Lowther et al. 2000b; Tete-Favier et al. 2000) and the active site of this enzyme has been identified past mutagenesis (Lowther et al. 2000a; Moskovitz et al. 2000). In humans, one msrA gene located on chromosome 8 is known; however, no information is available well-nigh the genomic organization of the gene. Such information volition be undoubtedly helpful in the investigation of any potential role of MSRA in age-related changes. The results obtained from plants propose that multiple genes could exist (Sadanandom et al. 2000).

MSRA is differentially expressed amidst different tissues, indicating that the enzyme may have specific physiological functions. In rats, high immunocytochemical staining was found in liver, kidney, centre and encephalon, especially in the cerebellum (Moskovitz et al. 1996). In developed human tissues, a high MSRA mRNA level is observed in liver, kidney, center and brain (Kuschel et al. 1999). High expression in liver and kidney is consequent with the notion that MSRA may participate as an anti-oxidant enzyme to repair 'aged' proteins as these detoxifying organs are steadily exposed to oxidative stress. The overall expression level in the brain is also high and the heterogeneous expression design is evident inside the encephalon. MSRA RNA is almost abundantly present in the cerebellum, followed by the hippocampus and the temporal lobe. In contrast, piddling RNA was detected in pons and substantia nigra. It is interesting to notation that, in Parkinson'southward illness, the neurons in the substantia nigra are selectively lost and that ROS is often cited every bit a contributing gene (e.one thousand. Cohen, 1999). The presence of MSRA in selected regions of the encephalon suggests that methionine oxidation may have a role in neuronal role.

Comparison of the RNA tissue distribution in human adult and embryonic tissues indicates that expression or activity of MSRA may be developmentally regulated (Gabbita et al. 1999; Kuschel et al. 1999). In general, fetal tissue appears to limited much less MSRA mRNA than the corresponding adult tissue. A notable exception is liver, where an expression level in the fetal tissue similar to that of the adult tissue is observed. This ascertainment correlates with the fact that fetal liver is fully functional before term. As explored more fully below, in that location are some indications that the MSRA action may decrease in some conditions often associated with ageing. Still, currently there is no systematic information available regarding how the MSRA expression levels in different tissues change with age.

Interestingly, the MSRA mRNA is non readily detected in tumour cell lines (Kuschel et al. 1999). For example, leukaemia or lymphoma cell lines do non express mRNA coding for MSRA, whereas normal peripheral claret leukocytes express this gene. It is not clear whether the absence of MSRA in these neoplasm cells represents a cause or result of the cancerogeneity. Further work is obviously required to elucidate this intriguing question.

Although it is established that MSRA is a cytoplasmic protein, its subcellular distribution has not been demonstrated. It is reasonable to suspect that MSRA may be localized in those areas where the ROS concentrations may be high, such as mitochondria. However, no published written report exists that addresses this effect. In plants, 2 variants of MSRA with different subcellular localization patterns are known to exist; one form is distributed diffusely in the cytoplasm and the other appears to be localized in plastids (Sadanandom et al. 2000).

Implications in pathophysiological phenomena

The irreversible oxidation of methionine residues in proteins to MetO₂ should atomic number 82 in many cases to the loss of function and therefore to pathophysiological situations. Similarly, methionine oxidation to MetO in combination with an insufficient reduction capacity should have similar consequences. Therefore, methionine oxidation is ofttimes discussed as 1 of the sources for physiological dysfunctions in several age-associated changes and degenerative diseases. In improver, oxidation of methionine residues resulting in transient or long-lasting alterations of protein functions is expected to occur nether situations of acute local production of backlog ROS.

Acute processes

All processes that atomic number 82 to an excess production of gratuitous radicals could event in the oxidation of methionine residues in proteins. Several such processes are described, but only in some cases has the direct involvement of methionine oxidation been documented. One case with important clinical relevance is reperfusion injury (Chan, 1996). Subsequent to ischaemic episodes, in well-nigh all organs but prominently in brain and cardiac tissue, reperfusion results in the excess generation of ROS and cell damage. Protein damage by oxidation as well plays an important part in inflammatory processes (Winrow et al. 1993). The oxidative bursts produced by neutrophils and macrophages in the allowed response are supposed to inactivate pathogens, but chronic activity of this defence force organisation, as in rheumatoid arthritis and inflammatory bowel disease, can cause cell damage and pain. Role of the destructive power of oxidative stress in rheumatoid arthritis (Chidwick et al. 1991) as well as in emphysema (Janoff et al. 1979; Johnson & Travis, 1979) may arise from the inhibition of α1-antiproteinase. A conserved methionine residue is responsible for this oxidation-dependent inactivation; incubation of oxidized α-ane protease inhibitor with MSRA restores its activity to suppress proteases (Mohsenin & Gee, 1989).

Long-term degenerative effects and ageing

In various systems, the intracellular level of oxidized protein increases with age (for review see Stadtman & Berlett, 1999). Examples are the human brain (Carney et al. 1991; Smith et al. 1991), human eye lens (Garland et al. 1988; Garland, 1991) and human being erythrocytes (Oliver et al. 1987). The total corporeality of oxidatively modified proteins is estimated to exist up to 50 % for an lxxx-year-sometime human (Starke-Reed & Oliver, 1989; Stadtman, 1992). Creature models show that former animals are more than susceptible to oxidative stress and the life span of animals correlates with the amount of oxidized protein (Yu et al. 1998). The latter aspect could be related to methionine oxidation since a yeast strain overexpressing MSRA was shown to exhibit a higher resistance against oxidative stress. In addition, T-lymphocytes are more resistant to H₂O₂ after overexpression of MSRA (Moskovitz et al. 1998).

While the oxidative damage of proteins during the process of ageing or in historic period-related changes is well established, it remains a speculation whether or not the enzyme-mediated decrease of the oxidation level volition alleviate the issues associated with age-related changes and extended life span in human beings. Experimental findings indicate that this may indeed be possible. In model animals, over-expression/ activation of 'anti-oxidant' enzymes, such every bit superoxide dismutase, does increment the life span (Parkes et al. 1998; Sun & Tower, 1999; Belfry, 2000; Melov et al. 2000). However, even if the systematic reduction of the oxidation level, e.g. past the intake of antioxidants, does not overcome apoptotic processes which may ultimately determine the life span, they may increase the quality of life of the elderly past reducing mutual age-related changes. Older gerbils with more oxidized proteins in the brain perform poorly in a maze test, but a costless radical scavenger decreases the oxidized protein level and likewise improves the maze performance (Carney et al. 1991). Several degenerative diseases take been discussed in relation to oxidation of proteins such as Parkinson's disease (Cohen, 1999), Alzheimer's disease (Smith et al. 1996) and eye lens cataract (Garland et al. 1988; Garland, 1991). In such processes the oxidation and reduction of methionine and the expression of MSRA may play an important function. In fact, in patients with Alzheimer's disease decreased levels of MSRA were establish in brain samples (Gabbita et al. 1999). These results suggest that overexpression of MSRA may lead to benign consequences.

Modulation of cellular excitability past methionine oxidation

Information technology is merely recently that some examples of the modulatory potential of methionine oxidation in the regulation of cellular excitability accept been demonstrated. Here, two cases involving voltage-gated K⁺ channels and calmodulin, both of which are involved in cellular excitability, are discussed. Voltage-gated G⁺ channels play critical roles in cellular excitability, more often than not exerting an inhibitory influence. These channels are often a major determinant of the activeness potential threshold and the shape of the action potential. Drosophila Shaker channels, which give rise to transient A-blazon Chiliad⁺ currents, were the first voltage-gated K⁺ channels whose DNA sequences were determined. ShC/B channels represent one of the many variants of the Shaker aqueduct. When heterologously expressed in Xenopus oocytes by injection of in vitro transcribed RNA, the macroscopic inactivation time course mediated past the ball and chain N-type inactivation of ShC/B channels is extremely variable (Fig. ii; Aldrich et al. 1990; Ciorba et al. 1997; Ciorba et al. 1999; Kuschel et al. 1999). Other variants of the Shaker aqueduct such as ShB exercise not showroom similar variability. Big variability like that observed with ShC/B channels often hinders biophysical investigations of ion channels. Yet, the presence of variability does betoken that a regulatory mechanism is operative. At the single-channel level, ii modes of inactivation gating are often observed from one channel protein. A single ShC/B channel may display very rapid N-type inactivation in response to some pulses only it may also show very slow or no inactivation. The North-type inactivation kinetics of ShC/B channels was slowed by application of the oxidant Ch-T or H₂O₂, and mutagenesis indicated that substitution of a methionine residue at position iii in the N-concluding ball region of the channel with leucine, which is less readily oxidized, largely eliminated the inactivation variability and reduced the oxidant sensitivity. The distal Northward-terminal segment of the Shaker channel stabilizes the Due north-type inactivated land via hydrophobic interactions and introduction of a polar residue destabilizes the inactivated country (Hoshi et al. 1990; Zagotta et al. 1990; Murrell-Lagnado & Aldrich, 1993). Oxidation of Met3 to MetO, which is considerably more than polar than Met, is expected to destabilize the inactivated state. Using the synthetic peptide arroyo that allows the defined incorporation of not-natural amino acids, such as MetO, Ciorba et al. (1997) found that the inactivation time class was drastically slowed past the presence of MetO at position 3.

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Regulation of potassium channels past methionine oxidation and reduction

A, schematic diagram of a potassium aqueduct circuitous indicating the N-terminal ends of three of the four α-subunits that form in some aqueduct types inactivating structures, i.e. protein segments that occlude the permeation pore upon channel activation. Recent studies suggest that the Northward-terminal segment of the α-subunit may also contain a construction that could exist described as a hanging gondola (Gulbis et al. 2000; Kobertz et al. 2000) but for the sake of simplicity the gondola-like structure is not included in the diagram. B, in Shaker C/B channels the amino acid rest at position three is methionine. With this balance in the reduced form, the channels exhibit rapid N-type inactivation; upon oxidation to MetO rapid inactivation is impaired (Ciorba et al. 1997). C, superposition of current traces obtained from different Xenopus oocytes after heterologous expression of Shaker C/B channels; depolarization to +40 mV. The fourth dimension course of inactivation obtained in whole cells shows a very potent scatter indicating jail cell-to-prison cell variability of the amount of oxidized methionine. D, upon coexpression with human MSRA the time course of inactivation is much faster and the variability is diminished.

Furthermore, coexpression of the ShC/B aqueduct with bovine or human MSRA drastically reduced the inactivation variability and accelerated the overall inactivation time course (Ciorba et al. 1997; Kuschel et al. 1999). Incubation with MSRA likewise restored the ability of the inactivation peptide with MetO at position 3 to induce inactivation (Ciorba et al. 1997). These observations are consistent with the notion that MSRA acts as a disquisitional regulator of the ShC/B channel inactivation kinetics.

Many ROS and RNS (reactive nitrogen species) are capable of oxidizing methionine to MetO. The weak radical NO may react with O⁻· to course ONOO⁻ and may promote methionine oxidation (Vogt, 1995). Indeed, ONOO⁻ oxidizes methionine residues in glutamine synthetase and bovine serum albumin to MetO in a CO_two- and pH-dependent mode (Tien et al. 1999). Application of NO donors to ShC/B channels or activation of nNOS (neuronal nitric oxide synthase) slows the inactivation fourth dimension course in a fashion similar to that induced by Ch-T (Ciorba et al. 1999) and suggests that methionine oxidation could be ane of the mechanisms by which NO regulates its effectors.

Chen et al. (2000) showed that another kinetic holding of Shaker channels was also regulated by methionine oxidation. In many voltage-gated Thousand⁺ channels, a distinct, often slower, inactivation process termed 'P/C-type inactivation' exists (Hoshi et al. 1991; Loots & Isacoff, 1998). This inactivation involves constriction of the external mouth of the aqueduct pore (Yellen, 1998). Chen et al. (2000) institute that the time grade of P/C-type inactivation in a Shaker aqueduct without N-type inactivation (ShBΔ6-46:T449S) had ii kinetic components and that their relative fractions were quite variable amidst different patches. Application of the oxidant H₂O₂, patch excision and loftier O₂ up-regulated the fast component, accelerating the overall inactivation kinetics. Substitution of a methionine residue in the pore segment of the channel with less readily oxidized leucine essentially eliminated the oxidant sensitivity, suggesting that oxidation of this methionine residue acts as a control switch for the ii components in P/C-type inactivation.

1 of the logical questions is, of class, whether other channels and transporters, specially in humans, are regulated by oxidation of methionine. In that location are many indications in the literature that suggest that this is indeed the case. Numerous studies have shown that awarding of oxidants, such as H_twoO_ii, has dramatic furnishings on functional backdrop of ion channels and transporters. Some of these effects are not easily explained by reversible oxidation of cysteine. For example, redox regulation of Na⁺-Ca^two+ exchangers does not announced to involve cysteine (Santacruz-Toloza et al. 2000). Large-conductance Ca²⁺-activated M⁺ channels are likewise redox regulated; some studies showed that oxidation enhanced while others showed that oxidation decreased the aqueduct action (Dichiara & Reinhart, 1997; Thuringer & Findlay, 1997; Wang et al. 1997; Barlow & White, 1998; Ahern et al. 1999). Information technology is possible that these furnishings may represent the combined effects of oxidation of cysteine and methionine residues. Using Ch-T as an oxidizing agent, Quinonez et al. (1999) suggest that at least two methionine residues in voltage-gated Na⁺ channels could be oxidized to alter fast inactivation. In Na⁺ channels, the short segment located between the domain Iii-Iv linker (IFM) plays an important office in inactivation (Catterall, 2000). The methionine rest located in this segment is considered to stabilize the inactivation state via hydrophobic interactions (Rohl et al. 1999). It may be speculated that oxidation of this methionine to MetO, which disrupts the hydrophobic interactions, will take a noticeable impact on the inactivation of Na⁺ channels and this could account for the observation that Ch-T slowed the inactivation time course (Quinonez et al. 1999).

Some other set of important examples of oxidative regulation of cellular excitability concerns the Ca^two+-bounden poly peptide calmodulin (CaM). This protein is involved in many cellular processes as information technology controls the function of a large number of enzymes, ion channels, pumps, and other signalling proteins, many of them in a Ca²⁺-dependent mode. CaM loses its conformational stability upon Met oxidation (Gao et al. 1998), but the 'repair' of oxidized CaM by MSRA can restore functionality (e.g. Sun et al. 1999). Thus, by this machinery, the selective methionine oxidation of CaM (human CaM does not have Cys residues) and its reduction past MSRA constitutes a regulatory system by which the activity of numerous cellular signalling systems can be controlled. The best studied is the function of Ca²⁺-ATPases, which are sensitive to oxidative stress past means of CaM interactions (Gao et al. 1998; Squier & Bigelow, 2000). CaM with the C-terminal methionine residues oxidized loses the power to activate the plasma membrane Ca²⁺-ATPase (Yao et al. 1996). Recent studies have shown that the Ca²⁺-sensitivity of many ion channels is conferred past CaM (Levitan, 1999), e.g. NMDA-activated channels (Zhang et al. 1998), modest-conductance and intermediate-conductance Ca²⁺-activated K⁺ channels (Xia et al. 1998; Fanger et al. 1999), voltage-dependent Ca²⁺ channels (Lee et al. 1999; Peterson et al. 1999), and ether à go-become Grand⁺ channels (Schönherr et al. 2000). Therefore, methionine oxidation could potentially modulate these channels indirectly via CaM.

Action-dependent modulation via oxidation

The examples discussed above propose that the reversible oxidation of amino acid residues could have a marked impact on poly peptide function. Because that functionally active cells are likely to be metabolically active, leading to a greater production of ROS, it tin can be postulated that amino acid oxidation could be used to mediate activity-dependent modulation of cellular part (Fig. 3). For case, a burst of electrical activity in a neuron may increase intracellular Ca²⁺ concentration and may stimulate the metabolism, leading to a higher ROS level. Activation of NMDA receptors may also result in the product of superoxide (Lafon-Cazal et al. 1993). These ROS may in plough oxidize the susceptible cysteine and methionine residues in cellular proteins. The oxidized cysteine residues may be reduced as soon every bit the cellular redox state is restored. In contrast, the affected methionine residues stay oxidized until reduced by the action of MSRA. Thus, cysteine oxidation is well suited to mediate short-term modulation while methionine oxidation may mediate longer-lasting modulation. Yermalaieva et al. (2000) showed that oxidation could human activity as a coincidence sensor to enhance neuronal Ca²⁺ signalling in an activeness-dependent manner. It was but when depolarization and oxidative stress were coupled that subsequent Ca²⁺ signals induced by depolarization were enhanced.

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Action-dependent oxidative regulation

Simplified scheme illustrating activeness-dependent regulation of cellular excitability. Increased cellular activeness requires a college ATP consumption and therefore results in an increased production of O²⁻· in the mitochondrial respiratory concatenation. O²⁻· is dismutated to form H_twoO₂ by the superoxide dismutase (SOD). H_iiO₂ is degraded past antioxidant enzymes such as catalase (True cat) or glutathione peroxidase. In addition, ·OH radicals are formed from H₂O_ii via the Fenton reaction in the presence of transitional metal ions (Me). Stimulated past Caⁱⁱ⁺-CaM and the activation of calcineurin, nitric oxide synthase (NOS) generates NO· from L-arginine. NO· is combined with O^two−· to class the highly reactive peroxynitrite (ONOO⁻). In addition, the highly diffusible gas NO· can affect neighbouring cells and therefore acts, for case, every bit a retrograde messenger. The reactive oxygen and nitrogen species (ROS, RNS, darker blue shading) tin now effect in protein oxidation or nitration. Of detail interest are signalling proteins that are coupled to the intracellular Caⁱⁱ⁺ level or the membrane voltage, i.e. Ca²⁺-permeable ion channels, voltage-gated Chiliad⁺ channels, Ca²⁺-ATPases or proteins that are functionally regulated by CaM. Cyclic oxidation and reduction of methionine residues in such proteins may close feedback loops in which increased cellular activity stimulates either increased or decreased cellular excitability.

The link betwixt the cellular electrical activeness and ROS may be provided by mitochondria. They synthesize ATP to run into cellular energy requirements and thereby represent a major source of cellular ROS (Halliwell & Gutteridge, 1999). Mitochondria are also postulated to actively participate in the regulation of cytosolic Ca^two+, contributing to the regulation of neurotransmitter release (Rahamimoff et al. 1999; Berridge et al. 2000). The synthesis of ROS by mitochondria is increased by, amid others, an increase in cytosolic Caⁱⁱ⁺ (Dykens, 1994; Kowaltowski et al. 1995). Therefore, influx of Ca²⁺ into the cytoplasm from the external medium, such equally that expected during a flare-up of action potentials, increases the overall cellular ROS and oxidant levels. The ROS/oxidant production in mitochondria is expected to reflect, at least to some extent, the functional activity history of the prison cell. This may preferentially exist manifested by the methionine oxidation of proteins in or at mitochondria.

The regulation of protein part by oxidation of methionine to MetO and the reverse reaction catalysed past MSRA may have features analogous to phosphorylation/ dephosphorylation mediated past various kinases and phosphatases. In phosphorylated proteins, some consensus amino acrid sequence motifs with some predictive ability could be divers. At present, no such consensus sequence for methionine oxidation is known. Apparently, exposed residues are more likely to be oxidized and it is plausible that those methionine residues well-nigh metal bounden sites are preferentially oxidized (Yao et al. 1996). Another potential machinery of methionine oxidation specificity may be clustering of the target proteins with ROS-generating elements. For example, NOS is found to colocalize with several other proteins, including K⁺ channels and glutamate receptors (Kim et al. 1995; Brenman et al. 1996; Niethammer et al. 1996; Sheng, 1996). Since NO is capable of promoting methionine oxidation, those proteins located about NOS are more than probable to exist regulated by methionine oxidation. The availability of certain metal ions, such every bit Fe²⁺ and Cu^two+, constitutes another machinery to confer specificity. The reduction machinery mediated by MSRA is also subject to further regulation. Every bit stated above, at that place may be multiple variants of the enzyme with different subcellular and tissue distributions. Developmental regulation of the MSRA activeness is already noted to a higher place. Since MSRA reduces MetO in a thioredoxin-dependent manner, those factors that alter the thioredoxin availability could indirectly regulate the MSRA activeness.

Conclusion

Besides the prominent role of methionine oxidation and enzyme-mediated reduction in ageing and age-related degenerative diseases, increasing evidence is being compiled supporting the role of methionine oxidation and reduction in the regulation of cell function under physiological conditions. Several crucial signalling proteins are functionally contradistinct by methionine oxidation and reduction, giving rise to activity-dependent long-lasting mail-translational modifications. Thus, the functional roles of the oxidation of methionine residues and their reduction, catalysed past methionine sulfoxide reductase, need to be examined as a potential regulator of cellular function in a multifariousness of physiological systems.

Acknowledgments

T.H. was supported in part by NIH grants GM 57654, HL 64645 and HL 14388, and S.H.H. was supported in part by DFG (He2993/i). We thank A. Hansel for comments on the manuscript.

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