Peroxidase Mechanism of Lipid-dependent Cross-linking of Synuclein with Cytochrome c: PROTECTION AGAINST APOPTOSIS VERSUS DELAYED OXIDATIVE STRESS IN PARKINSON DISEASE*

Damage of presynaptic mitochondria could result in release of proapoptotic factors that threaten the integrity of the entire neuron. We discovered that α-synuclein (Syn) forms a triple complex with anionic lipids (such as cardiolipin) and cytochrome c, which exerts a peroxidase activity. The latter catalyzes covalent hetero-oligomerization of Syn with cytochrome c into high molecular weight aggregates. Syn is a preferred substrate of this reaction and is oxidized more readily than cardiolipin, dopamine, and other phenolic substrates. Co-localization of Syn with cytochrome c was detected in aggregates formed upon proapoptotic stimulation of SH-SY5Y and HeLa cells and in dopaminergic substantia nigra neurons of rotenone-treated rats. Syn-cardiolipin exerted protection against cytochrome c-induced caspase-3 activation in a cell-free system, particularly in the presence of H₂O₂. Direct delivery of Syn into mouse embryonic cells conferred resistance to proapoptotic caspase-3 activation. Conversely, small interfering RNA depletion of Syn in HeLa cells made them more sensitive to dopamine-induced apoptosis. In human Parkinson disease substantia nigra neurons, two-thirds of co-localized Syn-cytochrome c complexes occurred in Lewy neurites. Taken together, these results indicate that Syn may prevent execution of apoptosis in neurons through covalent hetero-oligomerization of cytochrome c. This immediate protective function of Syn is associated with the formation of the peroxidase complex representing a source of oxidative stress and postponed damage.Lewy bodies (LBs),3 mitochondrial impairment, and oxidative stress are cardinal features of Parkinson disease (PD) and several related neurodegenerative disorders (1, 2). Aggregation of α-synuclein (Syn), an abundant protein in synaptic terminals, plays a major role in the formation of LBs (3, 4). Neither the mechanisms of LB production nor their pathogenic or protective roles in neurodegeneration are well understood.In nigrostriatal dopaminergic synaptic terminals, mitochondria, harboring a host of death-initiating factors, are in peril of damage by reactive oxygen species generated by disrupted electron transport and/or oxidative metabolism of dopamine (DA). Because cytochrome c (cyt c)-dependent formation of apoptosomes and activation of caspases designates a point of no return in the apoptotic program, release of proapoptotic factors from synaptic mitochondria could threaten the integrity of the entire neuron. How neurons protect themselves against inadvertent release of death signals from damaged synaptic mitochondria is not known.The N-terminal fragment of Syn contains six variants of an 11-amino acid consensus motif that include an apolipoprotein-like class A2 helix participating in binding of different lipids, particularly anionic phospholipids (5). This domain is believed to be important for Syn functions in regulation of neuronal lipid metabolism, particularly turnover of a mitochondria-specific phospholipid, cardiolipin (CL) (6). However, the relevance of the Syn lipid binding capacity in regulating neuronal injury (apoptotic) responses has not been established.It is believed that oxidative stress participates in the accumulation of LB and Lewy neurites (LN) through yet to be identified pathways (7). Reportedly, Syn is co-localized with cyt c in LBs (8), indicating a potential interaction between the two proteins. Because cyt c is a redox-active hemeprotein (9, 10), its presence in the LBs in conjunction with Syn may also provide a mechanistic link of LBs with oxidative stress. We have recently reported that cyt c interacts with CL in mitochondria early in apoptosis and with phosphatidylserine (PS) in the plasma membrane after its release into the cytosol (11, 12). In both cases, this results in redox activation of cyt c and the production of complexes with high peroxidase activity that effectively catalyze peroxidation of the respective phospholipids (13).Based on these facts, we hypothesize and provide experimental evidence that Syn acts as a sacrificial scavenger of cytosolic cyt c inadvertently released from synaptic mitochondria to prevent its migration into the soma, i.e. spread of the proapoptotic signal and cell death. This vital function is realized through the emergence of a peroxidase activity of the cyt c-Syn-phospholipid complex that cross-links its components and yields covalently conjugated protein-lipid hetero-oligomers. The latter maintain lingering peroxidase activity. Thus protection against acute apoptotic cell death comes with a penalty of Syn-cyt c aggregation into a peroxidase complex capable of inducing protracted oxidative stress. Our results present a novel biochemical mechanism likely involved in Lewy body formation and explain a known paradox of a dual protective and deleterious role that Syn plays in neuronal cells.