The Oxygen Free Radicals Originating from Mitochondrial Complex I Contribute to Oxidative Brain Injury Following Hypoxia–Ischemia in Neonatal Mice

The model of unilateral HI brain injury and study design.

The research protocol was reviewed and approved by the Institutional Animal Care and Use Committee. We used the Rice-Vannucci model of HI brain injury adapted to p9–p10 neonatal mice of both sexes (Ten et al., 2003, 2004). The model consisted of a permanent ligation of the right carotid artery followed by hypoxic exposure. Briefly, surgical intervention was performed under isoflurane anesthesia. At 1.5 h of recovery pups were exposed to hypoxia (8% O₂ balanced N₂) for 20 min. The ambient temperature during hypoxia was maintained at 37.0–37.5°C by placing the hypoxic chamber in a neonatal isolette (Air-Shields). Following hypoxic exposure pups were returned to their dams. To minimize a temperature-related variability in the extent of brain injury, during initial 12 h of reperfusion mice were kept in an isolette at the ambient t = 32°C. To highlight a pathogenic role of the C-I in HI brain injury mice were exposed to a C-I-specific inhibitor, pyridaben. Pyridaben was injected intraperitoneally (2 μg/g) at 60 min before HI and a second dose (2 μg/g) was given immediately after HI. Tested at 2 h after initiation of treatment in naive p10 mice, this dose and regimen of pyridaben exposure resulted in a moderate (∼25%) inhibition of C-I-dependent (substrate-malate-glutamate) mitochondrial phosphorylating respiration (vehicle = 469 ± 23 nmol O₂/mg/min vs pyridaben = 358 ± 19 nmol O₂/mg/min, n = 4, p = 0.001) associated with significant (p = 0.006) decrease in C-I enzymatic activity (vehicle = 276.8 ± 25.2 nmol NADH/min/mg and pyridaben = 194.1 ± 10.5 nmol NADH/min/mg, n = 3). A stock solution of pyridaben was 0.2 mg/ml (2% DMSO in normal saline; NS). The 2% DMSO in NS was used as a vehicle.

To determine whether the ROS originating from the C-I contribute to the oxidative injury during early reperfusion, in separate cohort of HI mice an oxidative stress was intentionally augmented by the exposure of animals to 100% oxygen for the initial 60 min of reperfusion at the ambient t = 32°C. This experimental maneuver was based on reports that the rate of mitochondrial ROS generation increases dramatically in response to elevation of environmental O₂ content (Boveris and Chance, 1973; Hoffman et al., 2007). In a similar mouse model of neonatal HI supraphysiological hyperoxemia maintained for 60 min of reperfusion significantly exacerbated oxidative brain damage and neurological deficit compared with the normoxemia-reperfused littermates (Koch et al., 2008). Thus, if the ROS from the C-I contribute to the oxidative injury during reperfusion, then partial inhibition of C-I in the pyridaben-exposed mice should limit the exacerbation of brain damage caused by post-HI hyperoxia. In contrast, in the vehicle-treated mice hyperoxia should result in a significant exacerbation of brain injury.

Assessment of the HI brain injury.

At 24 h and at 7 d of reperfusion mice were killed by decapitation. Brains were harvested, sectioned into 1-mm-thick coronal slices and stained with 2% triphenyl-tetrazolium chloride (TTC). Digital images of infarcted (pale-white) and viable (brick-red) areas of brains were traced (Adobe Photoshop 4.0.1) and analyzed (NIH image 1.62) by an investigator “blinded” to a study groups. The extent of brain injury (direct infarct volume) was expressed as a percentage of the hemisphere ipsilateral to the carotid artery ligation side. At 7 d after HI, in a separate cohort of animals, brains were harvested, fixed in 4% paraformaldehyde (PFA), paraffin-embedded, coronally sectioned (10 μm every 500 μm), and Nissl stained. Digital images were traced and processed as described above. The extent of injury was defined by the preservation of cerebral tissue in the ipsilateral hemisphere and expressed as a percentage in relation to the corresponding contralateral hemisphere (100%).

The extent of oxidative brain damage was analyzed by visual detection and semiquantification of markers for lipid peroxidation (4-hydroxy-nonenal; 4HNE) and protein nitration (3-nitrotyrosine; 3NT). In brief, at 5 h of reperfusion brains were harvested from the randomly selected mice treated with pyridaben or vehicle, fixed in 4% PFA, and soaked in 30% sucrose overnight. The 20-μm-thick coronal sections were blocked (10% donkey serum) and incubated with rabbit polyclonal anti-4HNE (1:500) and anti-3NT antibodies (1:100) as described previously (Zhu et al., 2007). Samples were examined using the Bio-Rad 2000 confocal laser-scanning device attached to a Nikon E800 microscope. The images were captured at the resolution 1024 × 1024 pixels with 40× objective, counting frame 295 × 295 μm. Z-sectioned merged images were obtained from a stack of adjacent five sections (step = 1 μm). The 4HNE and 3NT immunoreactivity was analyzed by the count of immunopositive cells in five nonadjacent fields of injured cortex at three different bregma levels (−1.0, 0, +1.0 mm). Fifteen areas of cortex were analyzed for each mouse and a mean number of the immunopositive cells per millimeter squared in each mouse were used for analysis.

Ex vivo study.

At 0, 30 min, and 5 h of reperfusion cerebral nonsynaptosomal mitochondria were isolated from the ipsilateral hemisphere in pyridaben- or vehicle-treated HI mice as described previously (Caspersen et al., 2008; Ten et al., 2010). Because the mean infarct volume comprised ≈ 40% of the ipsilateral hemisphere, mitochondria were isolated only from the posterolateral cortex and subcortical structures (part of the hippocampus, striatum, and thalamus) of the ipsilateral hemisphere, i.e., the regions that reproducibly damaged in this model. Cerebral specimens from three to four mice were pulled for mitochondrial isolation to obtain the sample sufficient for measurements of mitochondrial respiration rates using nicotinamide adenine dinucleotide (NAD)- or flavin adenine dinucleotide (FAD)-linked substrates, ROS emission rates, and Ca²⁺ buffering capacity. All data were compared between study groups and matched to that in naive littermates.

In vitro study.

Cerebral nonsynaptosomal mitochondria were isolated from naive p10 mice and exposed to hyperoxia (incubation in the buffer prebubbled with 100% O₂) for 2 min. The mean value of partial O₂ tension in the hyperoxic buffer (5 ml) measured following 20 s of bubbling (60 ml/min) with 100% O₂ reached 472 ± 34 mmHg. The buffer [10 mm 3-(N-morpholino) propanesulfonic acid (MOPS)-Tris, pH 7.4, 120 mm KCl, KH₂PO₄ 1 mm, EGTA 10 μm] contained 5 mm succinate and glutamate as substrates. Mitochondrial ROS emission rate and Ca²⁺ threshold for mPTP opening were assessed in normoxic (control) and hyperoxic conditions in the presence or absence of rotenone (C-I inhibitor, 1 μm) or catalase (150 U/ml). Rotenone is the most commonly used C-I inhibitor and, like pyridaben, has the same inhibitory effect on C-I in cerebral mitochondria (Sherer et al., 2007). Hyperoxia results in accelerated generation of ROS from the respiratory chain in the brain and heart mitochondria (Castello et al., 2007; Hoffman et al., 2007), which mimics postischemic, reoxygenation-accelerated mitochondrial ROS generation.

Mitochondrial respiration was measured using a Clark-type electrode (Oxytherm; Hansatech). Mitochondria (0.05 mg of protein) were added to 0.5 ml respiration buffer composed of 200 mm sucrose, 25 mm KCl, 2 mm K₂HPO_4, 5 mm HEPES, pH 7.2, 5 mm MgCl₂, 0.2 mg/ml of BSA, 30 μm Ap₅A [P¹,P⁵-di(adenosine 5′)-pentaphosphate; an inhibitor of adenylate kinase], 10 mm glutamate, and 5 mm malate or 5 mm succinate and 5 mm glutamate at t = 32°C. To initiate a phosphorylating respiration (State 3) 100 nmol of ADP was added to the mitochondrial suspension. Rates of O₂ consumption were expressed in nmol O₂/mg mitochondrial protein/min. The respiratory control ratio was calculated as the ratio of the State 3 respiration rate to the resting respiration rate (State 4) recorded after the phosphorylation of ADP has been completed. 2′-4′Dinitro-phenol (DNP; 35 nm) was used to initiate uncoupled respiration which directly defines an activity of the respiratory chain.

Measurement of mitochondrial H₂O₂ emission.

The rate of H₂O₂ emission from mitochondria was estimated by a fluorescence assay with Hitachi 7000 spectrofluorimeter set at 555 nm excitation and 581 nm emission as described earlier (Starkov and Fiskum, 2003). Briefly, mitochondria (0.05 mg) were placed in 1 ml of respiration buffer as described above and supplemented with 5 mm succinate, 10 μm Amplex Ultrared (Invitrogen), and 4 U/ml horse radish peroxidase (HRP). After recording the fluorescence for 400 s, samples were supplemented with 1 μm rotenone and after another ∼200 s with 1 μg/ml antimycin A. The calibration curve was obtained by adding several 100 nmol aliquots of freshly made H₂O₂ to the cuvette containing the respiration buffer, Amplex Ultrared, and HRP. The rates (total and originated from C-I) of H₂O₂ emission in pmolH₂O₂/mg/min were expressed as a percentage of that measured in control (naive mice) organelles tested in each experiment. The rate of H₂O₂ generation by C-I was estimated by subtraction of the rate recorded after supplementation of rotenone from the spontaneous (total) rate of H₂O₂ emission.

The rationale for assessment of mitochondrial ROS emission on the FAD-linked substrate, succinate, was based on studies that demonstrated ∼300% increase in succinate concentration in the rat brain following 5 min of ischemia (Folbergrová et al., 1974; Benzi et al., 1979). In contrast, the same ischemia resulted in a profound (8- to 10-fold) decrease in the concentration of all mitochondrial NAD-linked substrates. In mature rats forebrain ischemia and 6 h of reperfusion resulted in significant inhibition of mitochondrial respiration tested on NAD-linked substrates. However, no significant differences from the control values were detected when the same mitochondria respired on succinate (Sims, 1991), suggesting that following HI the activity of C-II is better preserved compared with the C-I activity. To determine how critical a succinate-driven (C-II-dependent) mitochondrial respiration for post-HI cerebral recovery is, a separate cohort of mice was subjected to C-II inhibitor, 3-nitropropionic acid (3-NP; (20 μg/g at 60 min before and immediately after HI insult), or vehicle (0.9% NaCl), followed by a comparison of the extent of brain injury. The selected dose and regimen of 3-NP exposure in naive p10 mice resulted in ∼30% inhibition of succinate-supported mitochondrial-phosphorylating respiration rate (vehicle = 674 ± 41.2 nmol O₂/mg/min and 3-NP = 476.5 ± 30.6 nmol O₂/mg/min, n = 4, p = 0.001) which was comparable to the inhibitory effect of pyridaben on NAD-linked respiration.

Mitochondrial aconitase activity was measured as described previously (Morrison, 1954). Frozen-thawed mitochondria were mixed with the reaction buffer (50 mm Tris-HCl, pH 7.4, 0.6 mm MnSO₄, 5 mm Na citrate, 0.5 mm NADP, 1 U/ml iso-citrate dehydrogenase) in a 96-well plate, and the absorbance changes at 340 nm were followed for 10 min with a plate reader (Tecan Infinity 200). The aconitase activity was expressed in mU/min/mg of mitochondrial protein.

Mitochondrial C-I activity was measured spectrophotometrically as rotenone-sensitive NADH:Q₁ reductase. Reaction buffer was composed of 20 mm HEPES, pH 7.8, 75 μm NADH, 40 μm coenzyme Q₁, 1 mm KCN (final concentration). Frozen-thawed mitochondria were mixed with the reaction buffer in a 96-well plate and the absorbance changes at 340 nm were followed for 15 min with a plate reader (Tecan Infinity 200). In control the buffer was supplemented with 10 μm rotenone (final concentration). The activity of C-I was calculated as the difference between the rates of NADH oxidation (E³⁴⁰mm = 6.22 cm⁻¹) in the absence and in the presence of rotenone and presented in nmol NADH/min/mg of protein.

Mitochondrial Ca²⁺ buffering capacity was measured as described previously (Fontaine et al., 1998; Wang et al., 2009) with minimal modifications. In brief, mitochondria (0.05 mg/ml) were incubated in 10 mm Tris-MOPS buffer, pH 7.4, containing 120 mm KCl, 1 mm KH₂PO₄, 10 μm EGTA, 10 μm calcium green, 5 mm succinate and glutamate. The buffer for mitochondrial Ca²⁺ buffering capacity assay was changed, because it has been shown that in the sucrose-based buffer, as opposite to the KCl-based media, isolated mitochondria are insensitive to cyclosporine A during mPTP opening (Chávez et al., 2003). Following 30 s of steady-state fluorescence, organelles were repeatedly supplemented with 10 nmol of CaCl₂ every 50 s until Ca²⁺ was spontaneously released, indicating an opening of mPTP. The amount of Ca²⁺ required to open mPTP was normalized per milligram of mitochondrial protein and expressed as mitochondrial Ca²⁺ buffering capacity. An opening of a cyclosporine A-sensitive mPTP was confirmed by the detection of cytochrome c release from mitochondria into a buffer following Ca²⁺ challenge (data not shown).

Assessment of cytochrome c release was performed using Western blot analysis. Cerebral samples from the injured ipsilateral hemispheres were collected into isolation buffer (50 mm Tris-HCl, pH 7.4, 320 mm sucrose, 1 mm dithiothreitol, 3 mm EDTA, 0.5% protease inhibitor mixture), homogenized and centrifuged at 1000 × g for 5 min at 4°C. The supernatant was further centrifuged at 10,000 × g for 15 min at 4°C. Cytosolic and crude mitochondrial fraction were collected and stored at −80°C. Samples were run on 10% BisTris gels (NuPAGE; Invitrogen) and transferred to nitrocellulose membranes. After blocking the membranes were incubated with mouse anti-cytochrome c (1:2000; BD Pharmigen), mouse monoclonal anti-β-actin (1:50,000; Sigma), and mouse monoclonal [20E8] anti-COX IV (1:5000; Abcam) primary antibodies. Peroxidase-conjugated donkey anti-mouse antibodies were added for 1 h and bands were visualized using ECL plus the Western blotting detection system (GE Healthcare).