Certain metals trigger fibrillation of methionine-oxidized alpha-synuclein

The aggregation and fibrillation of alpha-synuclein has been implicated as a key step in the etiology of Parkinson's disease and several other neurodegenerative disorders. In addition, oxidative stress and certain environmental factors, including metals, are believed to play an important role in Parkinson's disease. Previously, we have shown that methionine-oxidized human alpha-synuclein does not fibrillate and also inhibits fibrillation of unmodified alpha-synuclein (Uversky, V. N., Yamin, G., Souillac, P. O., Goers, J., Glaser, C. B., and Fink, A. L. (2002) FEBS Lett. 517, 239-244). Using dynamic light scattering, we show that the inhibition results from stabilization of the monomeric form of Met-oxidized alpha-synuclein. We have now examined the effect of several metals on the structural properties of methionine-oxidized human alpha-synuclein and its propensity to fibrillate. The presence of metals induced partial folding of both oxidized and non-oxidized alpha-synucleins, which are intrinsically unstructured under conditions of neutral pH. Although the fibrillation of alpha-synuclein was completely inhibited by methionine oxidation, the presence of certain metals (Ti3+, Zn2+, Al3+, and Pb2+) overcame this inhibition. These findings indicate that a combination of oxidative stress and environmental metal pollution could play an important role in triggering the fibrillation of alpha-synuclein and thus possibly Parkinson's disease.     

Agrin binds alpha-synuclein and modulates alpha-synuclein fibrillation

Recent studies have begun to investigate the role of agrin in brain and suggest that agrin's function likely extends beyond that of a synaptogenic protein. Particularly, it has been shown that agrin is associated with the pathological lesions of Alzheimer's disease (AD) and may contribute to the formation of beta-amyloid (Abeta) plaques in AD. We have extended the analysis of agrin's function in neurodegenerative diseases to investigate its role in Parkinson's disease (PD). Alpha-synuclein is a critical molecular determinant in familial and sporadic PD, with the formation of alpha-synuclein fibrils being enhanced by sulfated macromolecules. In the studies reported here, we show that agrin binds to alpha-synuclein in a heparan sulfate-dependent (HS-dependent) manner, induces conformational changes in this protein characterized by beta-sheet structure, and enhances insolubility of alpha-synuclein. We also show that agrin accelerates the formation of protofibrils by alpha-synuclein and decreases the half-time of fibril formation. The association of agrin with PD lesions was also explored in PD human brain, and these studies shown that agrin colocalizes with alpha-synuclein in neuronal Lewy bodies in the substantia nigra of PD brain. These studies indicate that agrin is capable of accelerating the formation of insoluble protein fibrils in a second common neurodegenerative disease. These findings may indicate shared molecular mechanisms leading to the pathophysiology in these two neurodegenerative disorders.     

Sequence determinants regulating fibrillation of human alpha-synuclein

α-Synuclein is a neural protein that comprises the fibrillar core of Lewy bodies, a histologically defining lesion of Parkinson’s disease. To investigate the role of each specific residue of the α-synuclein molecule in fibril formation, amino acid substitutions were introduced throughout the molecule. Incorporation of proline, especially in the region spanning residues 37-89, drastically retarded fibril formation. Substitutions with polar residues showed that the hydrophobicity of the central hydrophobic region is also important in fibrillation regulation. In the N-terminal repeated region, increasing the number of negative charges interfered with fibrillation. In contrast, single amino acid substitutions in the C-terminal acidic region of α-synuclein had only minimal effects on fibrillation. More than 20 different single amino acid substitutions that were sufficient to prevent fibrillation of α-synuclein were obtained, and most of them were impaired in both nucleation and fibril elongation. Identification of sequence determinants regulating fibrillation of amyloidogenic proteins may provide valuable information for designing peptide analog drugs to prevent protein amyloidosis.     

Characterization of fibrillation process of alpha-synuclein at the initial stage

α-Synuclein is the major component of the filamentous Lewy bodies and Lewy-related neurites, neuropathological hallmarks of Parkinson’s disease. Although numerous studies on α-synuclein fibrillation have been reported, the molecular mechanisms of aggregation and fibrillation at the initial stage are still unclear. In the present study, structural properties and propensities to form fibrils of α-synuclein at the initial stage were investigated using 2D ¹H-¹⁵N NMR spectroscopy, electron microscope, and small angle X-ray scattering (SAXS). Observation of the 2D ¹H-¹⁵N HSQC spectra indicated significant attenuation of many cross peak intensities in the regions of KTKEGV-type repeats and the non-Aβ component of Alzheimer’s disease amyloid (NAC), suggesting that these regions contributed fibril formation. Oligomerization comprising heptamer was successfully monitored at the initial stage using the time-dependent SAXS measurements.     

Polycation-induced oligomerization and accelerated fibrillation of human alpha-synuclein in vitro

The aggregation and fibrillation of alpha-synuclein has been implicated as a causative factor in Parkinson's disease and several other neurodegenerative disorders known as synucleinopathies. The effect of different factors on the process of fibril formation has been intensively studied in vitro. We show here that alpha-synuclein interacts with different unstructured polycations (spermine, polylysine, polyarginine, and polyethyleneimine) to form specific complexes. In addition, the polycations catalyze alpha-synuclein oligomerization. The formation of alpha-synuclein-polycation complexes was not accompanied by significant structural changes in alpha-synuclein. However, alpha-synuclein fibrillation was dramatically accelerated in the presence of polycations. The magnitude of the accelerating effect depended on the nature of the polymer, its length, and concentration. The results illustrate the potential critical role of electrostatic interactions in protein aggregation, and the potential role of naturally occurring polycations in modulating alpha-synuclein aggregation.     

Mechanism of cleavage of alpha-synuclein by the 20S proteasome and modulation of its degradation by the RedOx state of the N-terminal methionines

Alpha-synuclein is a small protein implicated in the pathophysiology of Parkinson's disease (PD). We have investigated the mechanism of cleavage of alpha-synuclein by the 20S proteasome. Alpha-synuclein interacts with the C8 (α7) subunit of the proteasome. The N-terminal part of alpha-synuclein (amino acids 1–60) is essential for its proteasomal degradation and analysis of peptides released from proteasomal digestion allows concluding that initial cleavages occur within the N-terminal region of the molecule. Aggregated alpha-synucleins are also degraded by the proteasome with a reduced rate, likely due to Met oxidation. In fact, mild oxidation of alpha-synuclein with H₂O₂ resulted in the inhibition of its degradation by the proteasome, mainly due to oxidation of Met 1 and 5 of alpha-synuclein. The inhibition was reversed by treatment of the oxidized protein with methionine sulfoxide reductases (MsrA plus MsrB). Similarly, treatment with H₂O₂ of N2A cells transfected with alpha-synuclein resulted in the inhibition of its degradation that was also reverted by co-transfection of MsrA plus MsrB. These results clearly indicate that oxidative stress, a common feature of PD and other synucleinopathies, promotes a RedOx change in the proteostasis of alpha-synuclein due to Met oxidation and reduced proteasomal degradation; compromised reversion of those oxidative changes would result in the accumulation of oxidative damaged alpha-synuclein likely contributing to the pathogenesis of PD.     

Conserved methionines in chloroplasts

Heat shock proteins counteract heat and oxidative stress. In chloroplasts, a small heat shock protein (Hsp21) contains a set of conserved methionines, which date back to early in the emergence of terrestrial plants. Methionines M49, M52, M55, M59, M62, M67 are located on one side of an amphipathic helix, which may fold back over two other conserved methionines (M97 and M101), to form a binding groove lined with methionines, for sequence-independent recognition of peptides with an overall hydrophobic character. The sHsps protect other proteins from aggregation by binding to their hydrophobic surfaces, which become exposed under stress. Data are presented showing that keeping the conserved methionines in Hsp21 in a reduced form is a prerequisite to maintain such binding. The chloroplast generates reactive oxygen species under both stress and unstressed conditions, but this organelle is also a highly reducing cellular compartment. Chloroplasts contain a specialized isoform of the enzyme, peptide methionine sulfoxide reductase, the expression of which is light-induced. Recombinant proteins were used to measure that this reductase can restore Hsp21 methionines after sulfoxidation. This paper also describes how methionine sulfoxidation-reduction can be directly assessed by mass spectrometry, how methionine-to-leucine substitution affects Hsp21, and discusses the possible role for an Hsp21 methionine sulfoxidation-reduction cycle in quenching reactive oxygen species.     

Effect of reparation of repeat sequences in the human alpha-synuclein on fibrillation ability

The aggregation and fibrillation of alpha-synuclein has been implicated as a causative factor in the Parkinson's disease. The hexamer motif KTKEGV is found in each of the seven imperfect repeat sequences in the N-terminal half of alpha-synuclein. The motif is not fully conserved in the sixth and seventh repeats. We created mutants in which the motif was repaired to be fully conserved in either (Rep6 and Rep7) or both (Rep67) of these two repeats. The Rep6 and Rep67 mutants showed a greatly reduced propensity to aggregate and fibrillate while all three mutants showed greater resistance to HFIP-induced formation of the alpha-helix intermediate. Resistance to formation in the partially folded intermediate may repress the folding of alpha-synuclein, consequently interfering with the aggregation and fibril formation. These results demonstrated that KTKEGV repeats may have a significant role in keeping native unfolded status of alpha-synuclein.     

GM1 specifically interacts with alpha-synuclein and inhibits fibrillation

The aggregation of alpha-synuclein is believed to be a key step in the etiology of Parkinson's disease. Alpha-synuclein is found in the cytosol and is associated with membranes in the presynaptic region of neurons and has recently been reported to be associated with lipid rafts and caveolae. We examined the interactions between several brain sphingolipids and alpha-synuclein and found that alpha-synuclein specifically binds to ganglioside GM1-containing small unilamellar vesicles (SUVs). This results in the induction of substantial alpha-helical structure and inhibition or elimination of alpha-synuclein fibril formation, depending on the amount of GM1 present. SUVs containing total brain gangliosides, gangliosides GM2 or GM3, or asialo-GM1 had weak inhibitory effects on alpha-synuclein fibrillation and induced some alpha-helical structure, while all other sphingolipids studied showed negligible interaction with alpha-synuclein. alpha-Synuclein binding to GM1-containing SUVs was accompanied by formation of oligomers of alpha-synuclein. The familial mutant A53T alpha-synuclein interacted with GM1-containing SUVs in an analogous manner to wild type, whereas the A30P mutant showed minimal interaction. This is the first detailed report showing a direct association between GM1 and alpha-synuclein, which is attributed to specific interaction between helical alpha-synuclein and both the sialic acid and carbohydrate moieties of GM1. The recruitment of alpha-synuclein by GM1 to caveolae and lipid raft regions in membranes could explain alpha-synuclein's localization to presynaptic membranes and raises the possibility that perturbation of GM1/raft association could induce changes in alpha-synuclein that contribute to the pathogenesis of PD.     

Seed-dependent accelerated fibrillation of alpha-synuclein induced by periodic ultrasonication treatment

alpha-Synuclein is the major component of Lewy bodies and responsible for the amyloid deposits observed in Parkinson's disease. Ordered filamentous aggregate formation of the natively unfolded a-synuclein was investigated in vitro with the periodic ultrasonication. The ultrasonication induced the fibrillation of a-synuclein, as the random structure gradually converted into a beta-sheet structure. The resulting fibrils obtained at the stationary phase appeared heterogeneous in their size distribution, with the average length and height of 0.28 Mm+/-0.21 Mm and 5.6 nm+/-1.9 nm, respectively. After additional extensive ultrasonication in the absence of monomeric a-synuclein, the equilibrium between the fibril formation and its breakdown shifted to the disintegration of the preexisting fibrils. The resulting fragments served as nucleation centers for the subsequent seed-dependent accelerated fibrillation under a quiescent incubation condition. This self-seeding amplification process depended on the seed formation and subsequent alterations in their properties by the ultrasonication to a state that accretes the monomeric soluble protein more effectively than their reassociation of the seeds back to the original fibrils. Since many neurodegenerative disorders have been considered to be propagated via the seed-dependent amyloidosis, this study would provide a novel aspect of the significance of the seed structure and its properties leading to the accelerated amyloid formation.     

Role of different regions of alpha-synuclein in the assembly of fibrils

Elucidating the details of the assembly of amyloid fibrils is a key step to understanding the mechanism of amyloid deposition diseases including Parkinson's disease. Although several models have been proposed, based on analyses of polypeptides and short peptides, a detailed understanding of the structure and mechanism of alpha-synuclein fibrillation remains elusive. In this study, we used trypsin and endoproteinase GluC to digest intact alpha-synuclein fibrils and to analyze the detailed morphology of the resultant fibrils/remnants. We also created three mutants of alpha-synuclein, in which the N-terminal and C-terminal regions were removed, both individually and in combination, and investigated the detailed morphology of the fibrils from these mutants. Our results indicate that the assembly of mature alpha-synuclein fibrils is hierarchical: protofilaments --> protofibrils --> mature fibrils. There is a core region of approximately 70 amino acids, from residues approximately 32 to 102, which comprises the beta-rich core of the protofilaments and fibrils. In contrast, the two terminal regions show no evidence of participating in the assembly of the protofilament core but play a key role in the interactions between the protofilaments, which is necessary for the fibril maturation.     

Role of alpha-synuclein carboxy-terminus on fibril formation in vitro

Alpha-synuclein (alpha-syn) is the major component of intracellular inclusions in several neurodegenerative diseases, and the conversion of soluble alpha-syn into filamentous aggregates may contribute to disease pathogenesis. Since mechanisms leading to the formation of alpha-syn inclusions are unclear, in vitro models of alpha-syn aggregation may yield insights into this process. To that end, we examined the consequences on the progressive deletion of the carboxy-terminus of alpha-syn in regulating fibril formation, and we show here that carboxy-terminal truncated alpha-syn proteins aggregate faster than the full-length molecule. Protease digestion and immunoelectron microscopy indicate that the alpha-syn amino- and carboxy-termini are more solvent exposed than the central core and that filaments formed from carboxy-terminal truncated alpha-syn are narrower in diameter than the full-length molecule. Moreover, seeding experiments under conditions where full-length alpha-syn did not readily aggregate revealed that carboxy-truncated alpha-syn extending from amino acids 1-102 and 1-110 but not 1-120 were efficient in seeding full-length alpha-syn aggregation over a range of concentrations. Using site-directed mutagenesis, the negatively charged residues 104, 105 and 114, 115 in the carboxy-terminus were implicated in this reduced aggregation and the lack of seeding of full-length alpha-syn fibrillogenesis by 1-120. Our data support the view that the middle region of alpha-syn forms the core of alpha-syn filaments and that negative charges in the carboxy-terminus counteract alpha-syn aggregation. Thus, the carboxy-terminus of alpha-syn may regulate aggregation of full-length alpha-syn and determine the diameter of alpha-syn filaments.     

The flavonoid baicalein inhibits fibrillation of alpha-synuclein and disaggregates existing fibrils

The aggregation of alpha-synuclein has been implicated as a critical step in the development of Parkinson's disease. Parkinson's disease is a progressive neurodegenerative disorder caused by the loss of dopaminergic neurons from the substantia nigra; currently, no cure exists. Baicalein is a flavonoid with antioxidant properties; upon oxidation, it forms several products including quinones. We show here that low micromolar concentrations of baicalein, and especially its oxidized forms, inhibit the formation of alpha-synuclein fibrils. In addition, existing fibrils of alpha-synuclein are disaggregated by baicalein. The product of the inhibition reaction is predominantly a soluble oligomer of alpha-synuclein, in which the protein molecules have been covalently modified by baicalein quinone to form a Schiff base with a lysine side chain in alpha-synuclein. The binding of baicalein was abolished by conversion of the Tyr residues into Phe, demonstrating that Tyr is involved in the interaction of alpha-synuclein with baicalein. In disaggregation baicalein causes fragmentation throughout the length of the fibril. These observations suggest that baicalein and similar compounds may have potential as therapeutic leads in combating Parkinson's disease and that diets rich in flavonoids may be effective in preventing the disorder.     

An altered mode of calcium coordination in methionine-oxidized calmodulin

Oxidation of methionine residues in calmodulin (CaM) lowers the affinity for calcium and results in an inability to activate target proteins fully. To evaluate the structural consequences of CaM oxidation, we used infrared difference spectroscopy to identify oxidation-dependent effects on protein conformation and calcium liganding. Oxidation-induced changes include an increase in hydration of α-helices, as indicated in the downshift of the amide I′ band of both apo-CaM and Ca²⁺-CaM, and a modification of calcium liganding by carboxylate side chains, reflected in antisymmetric carboxylate band shifts. Changes in carboxylate ligands are consistent with the model we propose: an Asp at position 1 of the EF-loop experiences diminished hydrogen bonding with the polypeptide backbone, an Asp at position 3 forms a bidentate coordination of calcium, and an Asp at position 5 forms a pseudobridging coordination with a calcium-bound water molecule. The bidentate coordination of calcium by conserved glutamates is unaffected by oxidation. The observed changes in calcium ligation are discussed in terms of the placement of methionine side chains relative to the calcium-binding sites, suggesting that varying sensitivities of binding sites to oxidation may underlie the loss of CaM function upon oxidation.     

Role of protein-water interactions and electrostatics in alpha-synuclein fibril formation

Deposition of misfolded alpha-synuclein is a critical factor in several neurodegenerative disorders. Filamentous alpha-synuclein is the major component of Lewy bodies and Lewy neurites, the intracellular inclusions in the dopaminergic neurons of the substantia nigra, which are considered the pathological hallmark of Parkinson's disease. We show here that anions induce partial folding of alpha-synuclein at neutral pH, forming a critical amyloidogenic intermediate, which leads to significant acceleration of the rate of fibrillation. The magnitude of the accelerating effect generally followed the position of the anions in the Hofmeister series, indicating a major role of protein-water-anion interactions in the process at salt concentrations above 10 mM. Below this concentration, electrostatic effects dominated in the mechanism of anion-induced fibrillation. The acceleration of fibrillation by anions was also dependent on the cation. Moderate concentrations of anions affected both the rates of nucleation and the elongation of alpha-synuclein fibrillation, primarily via their effect on the interaction of the protein with water.     

Impact of Tyr to Ala mutations on alpha-synuclein fibrillation and structural properties

Substantial evidence suggests that the fibrillation of alpha-synuclein is a critical step in the development of Parkinson's disease. In vitro, alpha-synuclein forms fibrils with morphologies and a staining characteristic similar to those extracted from disease-affected brain. Monomeric alpha-synuclein is an intrinsically disordered protein, with three Tyr residues in the C-terminal region, one in the N-terminus, and lacking Trp. It is thought that interactions between the C-terminus and the central portion of the molecule may prevent or minimize aggregation/fibrillation. To test this hypothesis we examined the importance of the Tyr residues on the propensity for alpha-synuclein to fibrillate in vitro. Fibril formation of alpha-synuclein was completely inhibited, in the timescale over which measurements were made, by replacing the three C-terminal Tyr residues with Ala. In addition, substitution of Tyr133 by Ala also resulted in the absence of fibrillation, whereas the individual Y125A and Y136A mutants showed limited inhibition. Replacement of Tyr39 by Ala also resulted in substantial inhibition of fibrillation. Structural analysis showed that the Y133A mutant had a substantially different conformation, rich in alpha-helical secondary structure, as compared with the wild-type and other mutants, although the formation of any tertiary structure has not been observed as can be judged from near-UV-CD spectra. These observations suggest that the long-range intramolecular interactions between the N- and C-termini of alpha-synuclein are likely to be crucial to the fibrillation process.     

Role of alpha-synuclein in autophagy modulation of primary human T lymphocytes

It has been demonstrated that α-synuclein can aggregate and contribute to the pathogenesis of some neurodegenerative diseases and it is capable of hindering autophagy in neuronal cells. Here, we investigated the implication of α-synuclein in the autophagy process in primary human T lymphocytes. We provide evidence that: (i) knocking down of the α-synuclein gene resulted in increased autophagy, (ii) autophagy induction by energy deprivation was associated with a significant decrease of α-synuclein levels, (iii) autophagy inhibition by 3-methyladenine or by ATG5 knocking down led to a significant increase of α-synuclein levels, and (iv) autophagy impairment, constitutive in T lymphocytes from patients with systemic lupus erythematosus, was associated with abnormal accumulation of α-synuclein aggregates. These results suggest that α-synuclein could be considered as an autophagy-related marker of peripheral blood lymphocytes, potentially suitable for use in the clinical practice.     

Free-energy simulations of the oxidation of c-terminal methionines in calmodulin

In the course of aging or under conditions of oxidative stress, methionine residues of calmodulin undergo oxidation, leading to loss of biological activity of the protein. We have performed free-energy simulations of the effects of C-terminal methionine side-chain oxidation on the properties of calmodulin. The simulation results indicate that oxidation should have a destabilizing effect on all three protein functional states: calcium free, calcium loaded, and with both calcium and target peptide bound. Because the different states are destabilized by different amounts, this leads to a more complex pattern in the observable effects on protein thermal stability, calcium affinity, and binding of a target peptide. The influence of oxidation on the free energy of CaM unfolding is estimated by comparing the free-energy cost of oxidizing a Met residue in a Gly-Met-Gly peptide and in the protein. The protein thermal stability of the oxidized forms is lowered by a moderate amount 1-3 kcal/mol, in qualitative agreement with experimental results of 0.3 kcal/mol. The calculated changes in affinity for calcium and for the target peptide show opposing trends. Oxidation at position 144 is predicted to enhance peptide binding and weaken calcium binding, whereas oxidation at 145 weakens peptide binding and enhances affinity for calcium. The lower affinity of Met 145-oxidized calmodulin toward the target peptide correlates with experimentally observed lowering of calmodulin-activated Ca-ATPase activity when oxidized calmodulin from aged rat brains is used. Thus, our simulations suggest that Met 145 is the oxidation site in the C-terminal fragment of calmodulin. The microscopic mechanism behind the calculated free energy changes appears to be a greater affinity for water of the oxidized Met side-chain relative to normal Met. Structures with Met exposed to solvent had consistently lower free energies than those with buried Met sidechains.     

Characterization of oligomeric intermediates in alpha-synuclein fibrillation: FRET studies of Y125W/Y133F/Y136F alpha-synuclein

The aggregation of alpha-synuclein is believed to be a critical step in the etiology of Parkinson's disease. A variety of biophysical techniques were used to investigate the aggregation and fibrillation of alpha-synuclein in which one of the four intrinsic Tyr residues was replaced by Trp, and two others by Phe, in order to permit fluorescence resonance energy transfer (FRET) between residues 39 (Tyr) and 125 (Trp). The mutant Y125W/Y133F/Y136F alpha-synuclein (one Tyr, one Trp) showed fibrillation kinetics similar to that of the wild-type, as did the Y125F/Y133F/Y136F (one Tyr, no Trp) and Y39F/Y125W/Y133F/Y136F (no Tyr, one Trp) mutants. Time-dependent changes in FRET, Fourier transform infrared, Trp fluorescence, dynamic light-scattering and other probes, indicate the existence of a transient oligomer, whose population reaches a maximum at the end of the lag time. This oligomer, in which the alpha-synuclein is in a partially folded conformation, is subsequently converted into fibrils, and has physical properties that are distinct from those of the monomer and fibrils. In addition, another population of soluble oligomers was observed to coexist with fibrils at completion of the reaction. The average distance between Tyr39 and Trp125 decreases from 24.9A in the monomer to 21.9A in the early oligomer and 18.8A in the late oligomer. Trp125 remains solvent-exposed in both the oligomers and fibrils, indicating that the C-terminal domain is not part of the fibril core. No FRET was observed in the fibrils, due to quenching of Tyr39 fluorescence in the fibril core. Thus, aggregation of alpha-synuclein involves multiple oligomeric intermediates and competing pathways.     

Role of N-terminal methionine residues in the redox activity of copper bound to alpha-synuclein

Amyloid aggregation of α-synuclein (AS) is one of the hallmarks of Parkinson’s disease. The interaction of copper ions with the N-terminal region of AS promotes its amyloid aggregation and metal-catalyzed oxidation has been proposed as a plausible mechanism. The AS(1–6) fragment represents the minimal sequence that models copper coordination to this intrinsically disordered protein. In this study, we evaluated the role of methionine residues Met1 and Met5 in Cu(II) coordination to the AS(1–6) fragment, and in the redox activity of the Cu–AS(1–6) complex. Spectroscopic and electronic structure calculations show that Met1 may play a role as an axial ligand in the Cu(II)–AS(1–6) complex, while Met5 does not participate in metal coordination. Cyclic voltammetry and reactivity studies demonstrate that Met residues play an important role in the reduction and reoxidation processes of this complex. However, Met1 plays a more important role than Met5, as substitution of Met1 by Ile decreases the reduction potential of the Cu–AS(1–6) complex by ~80 mV, causing a significant decrease in its rate of reduction. Reoxidation of the complex by oxygen results in oxidation of the Met residues to sulfoxide, being Met1 more susceptible to copper-catalyzed oxidation than Met5. The sulfoxide species can suffer elimination of methanesulfenic acid, rendering a peptide with no thioether moiety, which would impair the ability of AS to bind Cu(I) ions. Overall, our study underscores the important roles that Met1 plays in copper coordination and the reactivity of the Cu–AS complex.