Dopaminergic neurons in the SNpc are vulnerable to 6-OHDA-induced OS, since they present high baseline ROS levels and low levels of glutathione peroxidase, an enzyme that converts hydrogen peroxide to water to prevent ROS damage.49 Dopamine, in turn, is highly susceptible to auto-oxidation and conversion to neuromelanin, which promotes the formation of hydroxyl radicals (OH−). When neuromelanin combines with iron, which normally accumulates at high concentrations in dopaminergic neurons,50,51 it affects their ability to remove OH. However, not all dopaminergic neurons in the SNpc are vulnerable to 6-OHDA toxicity; the SNpc contains subpopulations of dopaminergic neurons that express such calcium-binding proteins as calretinin (CR) and calbindin (CB), both of which reduce the accumulation of intracellular calcium, preventing glutamate excitotoxicity and ultimately inhibiting the cytotoxic effects of 6-OHDA.52,53 The precise number of neurons constituting these dopaminergic subpopulations within the SNpc is as yet unknown; presence of these subpopulations has been suggested to explain the presence of 10%23 dopaminergic neurons in the SNpc after treatment with 6-OHDA, regardless of the dose and site of injection of the neurotoxic compound.22

According to several in vivo studies, OS mediates the cytotoxic effects of 6-OHDA. Microdialysis and HPLC studies of the caudate nucleus of adult rats show that perfusion of 100μM 6-OHDA through a microdialysis probe for 60 minutes increases production of free radicals. Under these conditions, the DNA of SNpc dopaminergic neurons is also damaged.54 Recent studies have shown that intrastriatal injection with 6 μg 6-OHDA in rats causes a time-dependent increase in the indices of protein oxidation and lipid peroxidation.55 It has therefore been suggested that these biochemical processes originated by mitochondrial OS lead to both neuroinflammation and cell death by apoptosis.1

Neuroinflammation has been evaluated using such glial cell markers as GFAP for astrocytes56,57 and OX-42 for microglia.58,59 6-OHDA-induced activation of these glial populations has been found to occur from the third day after the lesion22 up to the third week postlesion.57 Neuroinflammation has been shown to precede death of nigral dopaminergic neurons (2 weeks after the lesion),57 probably to minimise cell damage. Other studies suggest that increased activation of glial cells and subsequent release of proinflammatory and anti-inflammatory cytokines at the site of the lesion may increase 6-OHDA cytotoxicity.60 Studying neuroinflammation in 6-OHDA models is essential to determine alternative therapeutic targets in PD.

Tyrosine hydroxylase (TH), the rate-limiting enzyme of dopamine synthesis, is a marker for dopaminergic phenotypes.23 The hypothesis that 6-OHDA injection causes death of dopaminergic neurons in the SNpc is based on the decrease in the number of TH+ neurons.19,61 Most researchers using 6-OHDA in vivo assert that this neurotoxic compound causes cell death22,62–65; a smaller number of researchers, in contrast, have detected no markers of cell death,23,66 which may suggest loss of phenotype. However, this depends on the dose and the lesion model used.

Cell death is the final result of 6-OHDA-induced cytotoxicity. Some studies try to demonstrate activation of apoptosis in the SNpc using silver staining or terminal deoxynucleotidyl transferase-mediated dUTP nick end labelling (TUNEL) staining after intrastriatal administration of 6-OHDA.64,67,68 However, these studies do not use other markers of apoptosis in addition to TUNEL staining to support the hypothesis that 6-OHDA induces apoptosis. Furthermore, TUNEL staining also identifies necrotic cells; therefore, we cannot conclude that 6-OHDA causes apoptosis based on the results of this technique, especially in the light of in vitro studies showing that the dose of 6-OHDA frequently used in vivo causes necrosis.69,70 According to a recent study with rats, in addition to TH loss, 6-OHDA injections to the striatum cause also loss of cytoskeleton integrity in dopaminergic neurons of the SNpc,22 which demonstrates cell death by apoptosis. Although many authors agree that apoptosis is the main type of cell death in 6-OHDA models, necrosis and autophagy71–73 have also been analysed in the context of in vivo 6-OHDA cell death. Given the variety of experimental models, it is not possible to determine the percentage of dopaminergic neurons in the SNpc affected by one or another type of death. However, convergence of several types of death may explain activation of the neuroinflammatory process, a topic that merits further study.

Apoptosis is a process of programmed cell death triggered by 2 signalling pathways: the intrinsic and the extrinsic pathways.74 The intrinsic pathway involves mitochondrial damage and subsequent cytochrome C release, which promotes the activation of proapoptotic proteins. The extrinsic pathway requires the activation of death receptors in the cell membrane and the subsequent activation of a complex signalling cascade.11,74 Though independent, these 2 pathways converge in the activation of effector caspases-3, -6, or -7.75,76

Caspase-3 is the main effector caspase in neurons and its activation has been demonstrated by the in vitro and in vivo administration of neurotoxic compounds.75,77,78 In vivo studies have detected caspase-3 activation one week after instrastriatal administration of 6-OHDA to rats.55,57 Most in vivo studies demonstrate caspase-3 expression in different models of cell death, suggesting that caspase- 3 activation is involved in programmed cell death in neurons of the SNpc.78–80 However, recent studies have failed to confirm activation of caspase-3 or caspase-9, concluding that these caspases are not involved in apoptosis of dopaminergic neurons in the SNpc.81,82 There is even greater controversy in the light of recent evidence that caspase-3 is involved in non-apoptotic functions, such as microglial activation.83,84 Although most authors agree that caspase-3 participates in 6-OHDA-induced neurodegeneration, the question remains whether its expression leads to neuronal death only. Other markers of apoptosis are therefore necessary; in this context, we should mention the study of glycogen synthase kinase 3β (GSK-3β).

GSK-3β is involved in the signalling pathway of neuronal apoptosis triggered by OS,85 a pivotal factor in the pathogenesis of PD.86 GSK-3β is activated by phosphorylation of tyrosine 216 residue (Y216), located in the kinase domain, and inactivated by phosphorylation of serine 9 (S9).85 A recent study showed that caspase-3 and GSK-3β are involved in the apoptotic process induced by 6-OHDA in vivo.22 A single 20 μg dose administered to a rat's striatum was observed to cause loss of cytoskeleton integrity, decreased TH immunoreactivity, and a progressive decrease in immunoreactivity to NeuN (a marker of neuronal lineage) in dopaminergic neurons in the SNpc.22

Furthermore, Kim et al.82 observed atrophy and progressive death of dopaminergic neurons which was dependent on nuclear translocation of apoptosis-inducing factor (AIF), but found no signs of apoptosis in the form of caspase-3 activation or cytoplasmic release of cytochrome C. These researchers also showed that death induced by 6-OHDA in dopaminergic neurons is mediated by Bax-dependent AIF activation.82 In their study, AIF activation suggested the involvement of regulated necrosis. The controversy on whether death is dependent on or independent from caspase-3 may be explained by the different doses, experimental models, and lesion sites used in the literature.

Although most evidence suggests that caspase-3 is involved in 6-OHDA-induced apoptosis, other studies suggest that 6-OHDA may also cause neuronal death by apoptosis (independent from caspase-3) or other cell death processes (necrosis and autophagy) in vivo.