Cystatin B Deficiency Sensitizes Neurons to Oxidative Stress in Progressive Myoclonus Epilepsy, EPM1

Results

We investigated the potential role of Cystatin B in regulating redox homeostasis and oxidative stress responses in cerebellar granule neurons. We first used a plasmid-based method of RNA interference (RNAi) to acutely knockdown Cystatin B. The expression of Cystatin B hairpin RNAs (hpRNAs) dramatically reduced expression of Cystatin B in 293T cells and primary rat cerebellar granule neurons (Fig. 1A,B). We then assessed the functional effect of Cystatin B knockdown on oxidatively stressed neurons. Rat granule neurons were transfected with the Cystatin B hpRNA or control plasmid together with a plasmid encoding β-galactosidase. After transfection, neurons were exposed to oxidative stress, and cell survival was assessed in transfected β-galactosidase-positive neurons based on the integrity of neuronal processes and nuclear morphology. Cystatin B knockdown robustly increased the ability of hydrogen peroxide to induce cell death in granule neurons (Fig. 1C). High concentrations of glutamate (10 mm) induce oxidative stress internally in neurons (Ratan et al., 2002). Cystatin B knockdown neurons were also sensitized to glutamate-induced cell death (Fig. 1D). Together, these data suggest that Cystatin B protects neurons in response to oxidative stress.

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Figure 1.

Cystatin B deficiency sensitizes neurons to oxidative stress. A, Lysates of 293T cells transfected with the rat FLAG—Cystatin B expression vector or control plasmid together with the Cystatin B hpRNA, Cdk2 hpRNA, or control U6 plasmid were immunoblotted with the Cystatin B and β-tubulin antibodies. B, Immunocytochemical analysis of rat granule neurons transfected with FLAG—Cystatin B and DsRed expression plasmids together with the Cystatin B hpRNA, Cdk2 hpRNA, or control U6 plasmid. Cystatin B RNAi reduced FLAG–Cystatin B expression in an average of 63.2% of transfected cells (n = 2). C, Rat granule neurons were transfected with the Cystatin B hpRNA or control U6 plasmid together with the β-galactosidase expression plasmid. After 72 h, cultures were treated with H₂O₂ for 24 h. Percentage cell death in transfected β-galactosidase-positive neurons is represented as mean ± SEM. Cystatin B knockdown sensitized neurons to H₂O₂-induced cell death (ANOVA; p < 0.05; n = 3). D, Rat granule neurons transfected with the Cystatin B hpRNA or control U6 plasmid together with the β-galactosidase expression plasmid were treated with 10 mm glutamate for 24 h and analyzed as in Figure 1C. Cystatin B RNAi sensitized neurons to glutamate-induced cell death (ANOVA; p < 0.05; n = 3). E, Lysates of 293T cells transfected with the mouse (m) Cystatin B expression vector or control plasmid together with the Cystatin B hpRNA or control U6 plasmid were immunoblotted with the Cystatin B and β-tubulin antibodies. F, Rat granule neurons transfected with the rat (r)FLAG–Cystatin B or mCystatin B expression plasmid and the β-galactosidase expression vector together with the Cystatin B RNAi plasmid were treated with H₂O₂ and analyzed as in C. Mouse Cystatin B rescued neurons from rat Cystatin B RNAi sensitization to H₂O₂-induced death (ANOVA; p < 0.001; n = 3). G, Left panels, Lysates of wildtype and Cystatin B−/− mouse granule neurons were immunoblotted with the Cystatin B or β-tubulin antibodies. Right panels, Cultures of Cystatin B−/− and wild-type control granule neurons were treated with increasing amounts of H₂O₂ and analyzed as in C. Cell death significantly increased in Cystatin B−/− neurons during H₂O₂ treatment compared with control (ANOVA; p < 0.0001; n = 3). H, Left panels, Cystatin B−/− granule neurons transfected with the mouse Cystatin B or control plasmid together with the β-galactosidase expression plasmid were treated with H₂O₂ and analyzed as in C. Cystatin B expression in Cystatin B−/− neurons rescued neurons from oxidative stress sensitivity (ANOVA; p < 0.01; n = 3). Right panels, Arrowheads denote representative images of neurons scored for survival.

We next performed a rescue experiment in which we expressed mouse Cystatin B in the background of rat Cystatin B RNAi. The Cystatin B hpRNAs target a sequence in rat Cystatin B mRNA that differs from the mouse Cystatin B mRNA by five base pairs such that mouse Cystatin B was resistant to Cystatin B RNAi (Fig. 1E). Expression of mouse Cystatin B in rat granule neurons reversed the ability of Cystatin B RNAi to sensitize neurons to stress-induced cell death (Fig. 1F). These results indicate that Cystatin B RNAi sensitizes neurons to hydrogen peroxide via specific knockdown of Cystatin B rather than off-target effects of Cystatin B RNAi or nonspecific activation of the RNAi machinery.

We also tested whether primary granule neurons isolated from Cystatin B-deficient mice are sensitive to oxidative stress. Consistent with the RNAi experiments in rat granule neurons (Fig. 1A–F), hydrogen peroxide induced significantly greater levels of cell death in Cystatin B−/− than wild-type mouse granule neurons (Fig. 1G). Importantly, Cystatin B expression rescued Cystatin B−/− neurons from oxidative stress-induced death, suggesting that the sensitivity of these neurons to oxidative stress is not attributable to nonspecific alteration in Cystatin B knock-out neurons independent of their genotype (Fig. 1H). Together, these results establish an essential function for Cystatin B in protecting neurons from oxidative stress.

Since Cystatin B deficiency sensitized granule neurons to oxidative stress, we reasoned that Cystatin B-deficient cerebella might incur oxidative damage in vivo that contributes to the pathogenesis of EPM1. To test this hypothesis, we performed an extensive redox analysis of Cystatin B−/− and wild-type control brains. We measured the levels of antioxidants including superoxide dismutase (SOD), glutathione (GSH), and catalase, the deregulation of which have been associated with neurodegeneration (Chong et al., 2005). SOD dismutates superoxide to hydrogen peroxide, whereas GSH and catalase reduce hydroperoxides (Lehtinen and Bonni, 2006). We observed a significant reduction in SOD activity and GSH levels specifically in the cerebellum but not in other regions of the brain, including the telencephalon and diencephalon, in Cystatin B knock-out animals compared with wild-type animals (Table 1; supplemental Table 1, available at www.jneurosci.org as supplemental material). Accordingly, the ratio of oxidized to reduced glutathione (GSSG:GSH) was increased in the cerebellum, a hallmark of oxidative damage (Table 1; supplemental Table 1, available at www.jneurosci.org as supplemental material). No differences in the overall glutathione reductase activity were observed in the brains of Cystatin B−/− mice compared with control (data not shown), suggesting that decreased GSH levels were not attributable to impaired glutathione reductase activity. No change in catalase activity was found in the cerebellum or other brain regions in Cystatin B knock-out animals (data not shown). Together, these data demonstrate that Cystatin B deficiency leads to impaired antioxidant capacity in the cerebellum.

Accumulating free radicals can promote damage to cells via reactions with macromolecules including lipids, proteins, and DNA (Chong et al., 2005). Although we did not observe significant changes in oxidative damage to proteins or DNA in Cystatin B knock-out animals (data not shown), we found a dramatic increase in oxidative damage to lipids in Cystatin B knock-out animals using an assay for 8-epi prostaglandin Fα (8-epi-PGF2α), an established and specific marker of lipid peroxidation. Lipid peroxidation was increased in the cerebellum but not the telencephalon or diencephalon of Cystatin B−/− mice when compared with wild-type mice (Table 1; supplemental Table 1, available at www.jneurosci.org as supplemental material) (data not shown). Importantly, lipid peroxidation accelerated with age, increasing from baseline at 2 months, to nearly fivefold in 6-month-old mice compared with wild-type controls (Table 1; supplemental Table 1, available at www.jneurosci.org as supplemental material) (data not shown). Consistent with these observations, the activity of glutathione peroxidase, an enzyme that reduces lipid hydroperoxides, was increased in Cystatin B−/− cerebella compared with wild-type controls (Table 1), suggesting a cellular adaptation to oxidative lipid damage in these animals. Our findings suggest that Cystatin B deficiency increases cerebellar susceptibility to oxidative damage and specifically to lipid peroxidation.

Identification of a function for Cystatin B in protecting neurons against oxidative stress led us to determine the mechanisms regulating Cystatin B-mediated neuronal survival. We first measured Cystatin B levels in neurons in response to oxidative stress. Exposure of granule neurons to hydrogen peroxide stimulated a robust increase in Cystatin B protein (Fig. 2A) and RNA levels (expressed as fold change: control = 1.0; H₂O₂ = 1.8 ± 0.4; t test: p < 0.01; n = 3). The hydrogen peroxide-induced upregulation of Cystatin B was blocked by the transcriptional inhibitor actinomycin D (supplemental Fig. 1, available at www.jneurosci.org as supplemental material), suggesting that oxidative stress induces Cystatin B transcription.

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Figure 2.

Oxidative stress induces Cystatin B expression. A, Lysates of rat granule neurons treated with increasing concentrations of H₂O₂ (50–80 μm) for 24 h were immunoblotted with Cystatin B and β-tubulin antibodies. B, Granule neurons were transfected with an expression vector encoding Sp1, the dominant interfering form of Sp1, Sp1–ZnF, or control vector together with the Cystatin B firefly luciferase gene. A Renilla luciferase reporter gene was cotransfected to control for transfection efficiency. Sp1–ZnF inhibited Cystatin B luciferase activity compared with control and Sp1 (ANOVA; p < 0.05; n = 5). C, Oxidative stress stimulates Sp1-mediated Cystatin B transcription. Left panel, Granule neurons were transfected with an expression vector encoding Sp1 together with the Cystatin B firefly luciferase gene and a Renilla luciferase reporter gene. Granule neurons were left untreated or treated with H₂O₂ for 16 h. Data are expressed as (Cystatin B luciferase plus Sp1)/(Cystatin B luciferase plus control). H₂O₂ induced Cystatin B (ANOVA; p < 0.01; n = 3). Right panel, Granule neurons were transfected with an Sp1 expression vector together with a Cystatin B firefly luciferase gene harboring an EPM1-like dodecamer repeat expansion and treated as in the left panel. Data are expressed as (EPM1 luciferase plus Sp1)/(EPM1 luciferase plus control). H₂O₂ failed to induce EPM1-linked Cystatin B.

The transcription factor Sp1 binds the Cystatin B promoter (Alakurtti et al., 2000). Expression of a dominant interfering form of Sp1 containing the DNA-binding domain but lacking the transactivation domain (Sp1-ZnF) in neurons impaired the expression of a luciferase reporter gene controlled by the Cystatin B promoter (Fig. 2B) (Chapman and Perkins, 2000; Ryu et al., 2003), suggesting that Sp1 drives Cystatin B transcription. Since Sp1 has been implicated in oxidative stress-induced transcriptional responses (Dunah et al., 2002; Ryu et al., 2003), we tested if oxidative stress might stimulate Sp1-mediated Cystatin B transcription. Hydrogen peroxide induced the ability of Sp1 to activate the expression of the Cystatin B-luciferase reporter gene (Fig. 2C). The predominant mutation that predisposes patients to EPM1 is the expansion of a dodecamer repeat (5′-ccccgccccgcg-3′) in the Cystatin B promoter (Lafrenière et al., 1997; Lalioti et al., 1997). In contrast to Sp1 induction of the wild-type Cystatin B promoter during exposure to hydrogen peroxide, Sp1 failed to activate a Cystatin B promoter harboring an EPM1-related dodecamer repeat expansion (Alakurtti et al., 2000) in granule neurons (Fig. 2C). These results suggest that oxidative stress induces Sp1-dependent Cystatin B transcription in neurons, and the EPM1-linked dodecamer repeat expansion in the Cystatin B promoter impairs the oxidative stress-induced Cystatin B transcriptional response.

Cystatin B inhibits the activity of the lysosomal protease Cathepsin B (Turk and Bode, 1991). Cathepsin B activity is upregulated in EPM1 patients (Rinne et al., 2002). In agreement with this result, Cathepsin B activity is enhanced in cultures of Cystatin B-deficient cerebellar granule neurons [relative Cathepsin B activity: 34.4 ± 3.07 (Cystatin B+/+); 42.6 ± 1.97 (Cystatin B−/−); t test: p < 0.05; n = 4 (+/+), n = 3 (−/−)]. Since granule neuron degeneration is reduced in Cystatin B–Cathepsin B double knock-out mice compared with Cystatin B knock-out mice (Houseweart et al., 2003), these observations raised the possibility that Cystatin B might protect neurons against oxidative stress-induced cell death by inhibiting Cathepsin B. Consistent with the hypothesis that Cathepsin B plays an intimate role in oxidative stress responses in neurons, hydrogen peroxide robustly induced the expression of Cathepsin B RNA (expressed as fold change: Control = 1.0; H₂O₂ = 1.96 ± 0.1; t test: p < 0.01; n = 3) and protein in neurons (Fig. 3A). Importantly, hydrogen peroxide stimulated the enzymatic activity of Cathepsin B in neurons (Fig. 3B). We next assessed Cathepsin B function in neurons. Overexpression of Cathepsin B sensitized neurons to hydrogen peroxide-induced death (Fig. 3C). Conversely, Cathepsin B knockdown protected neurons from oxidative stress-induced death (Fig. 3D; supplemental Fig. 2, available at www.jneurosci.org as supplemental material). Importantly, whereas Cystatin B deficiency sensitized neurons to oxidative stress-induced death (Figs. 1C,D,G, 3E), Cathepsin B RNAi rescued Cystatin B knockdown neurons from hydrogen peroxide-induced death (Fig. 3E). Together, these findings suggest that Cathepsin B may signal downstream of Cystatin B to promote neuronal death under oxidative stress conditions.

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Figure 3.

Cathepsin B mediates oxidative stress-induced neuronal death downstream of Cystatin B. A, Lysates of granule neurons treated with increasing concentrations of H₂O₂ (25–50 μm) for 18 h were immunoblotted with Cathepsin B and β-tubulin antibodies. B, Granule neurons treated with H₂O₂ for 14 h were assayed for Cathepsin B activity. H₂O₂ promoted Cathepsin B activity (ANOVA; p < 0.01; n = 5). C, Neurons transfected with Cathepsin B or control plasmid together with the β-galactosidase expression vector were treated with H₂O₂ and analyzed as in Figure 1C. Cathepsin B sensitized neurons to H₂O₂-induced death (ANOVA; p < 0.005; n = 3). D, Granule neurons transfected with the Cathepsin B hpRNA or control U6 plasmid together with the β-galactosidase expression plasmid were treated and analyzed as in Figure 1C. Cathepsin B RNAi protected neurons from H₂O₂-induced cell death (ANOVA; p < 0.001; n = 4). E, Granule neurons transfected with the Cystatin B hpRNA, Cathepsin B hpRNA, and/or control U6 plasmid together with the β-galactosidase expression plasmid were treated and analyzed as in Figure 1C. Cathepsin B RNAi protected neurons from Cystatin B–RNAi-induced H₂O₂ sensitivity (ANOVA; p < 0.001; n = 6 and n = 4, respectively).