The Effect of Glycine and N-Acetylcysteine on Oxidative Stress in the Spinal Cord and Skeletal Muscle After Spinal Cord Injury

In this study, a total of 50 female Sprague–Dawley (SD) rats (female rats were selected as their urethra is short and wide, which facilitates their care after SCI), 10 weeks old, weighing 220 ± 20 g, were purchased from Specific Biotechnology Co., Ltd (Beijing, China; License No.: SCXK[Beijing]2019-0010). The animals were randomly divided into 3 groups—a control group (no treatment, n = 10), a SCI group (modeling of severe SCI at the T10 level, n = 20), and a GlyNAC+SCI group (modeling of severe SCI at the T10 level plus GlyNAC intervention by gavage, n = 20) (Fig. 1).

Glycine (Catalog No. 410225) and N-acetylcysteine (Catalog No. A7250) were purchased from Sigma-Aldrich Trading Co., Ltd. (Shanghai, China). Glycine and N-acetylcysteine were dissolved in the daily drinking water of the rats. The glycine stock solution was stored at room temperature and the N-acetylcysteine stock solution was stored at 4 °C. The two solutions were mixed in a 1:1 ratio 10 min before use.

The rats were anesthetized with isoflurane and were placed flat in a prone position on an insulating mat. After shaving and sterilizing, the skin and muscles in the back of the animal at the level of T10 were cut longitudinally to fully expose the vertebral plates and pedicles of T9–T11. The T10 vertebral plate was excised to expose the spinal cord of the T10 segment, which was then rinsed and moistened with saline. The T9 and T11 vertebral plates of the rats were subsequently clamped, and the rats were placed on a spinal cord percussion device (Precision Systems and Instrumentation IH Spinal Cord Percussion Device, USA) with the percussion force set to 250 kdynes, resulting in a moderate SCI model. Spasticity in the tail swing of the rats could be observed after the blow, following which the surgical incision was sutured, and 1.5 mL of saline, as well as 1 mL of penicillin solution, was injected subcutaneously for rehydration and antimicrobial treatment. After surgery, the rats were placed in an incubator and were returned to the rearing cage box when they woke up.

GlyNAC intervention (200 mg/kg, pre-experimentally determined) started at 10:00 h on postoperative day 1. After mixing, the GlyNAC solution was administered via a gavage needle (Zhongke Hengtian, Beijing China). Body weight was assessed once a week and the dosage was adjusted according to the change in body weight. Gavage was performed for 4 weeks in total. Bladder care was carried out once every 12 h and the rats were helped with urination for approximately 1–2 weeks. If the rats had hematuria, penicillin injection was continued and the animals were closely monitored (Fig. 1).

The BBB score ranged from 0 to 21. Locomotor function in the model rats was assessed using BBB scores on days 1 and 3 after modeling. If the rats showed any movement of the lower limbs (score > 0), they were excluded from the experiment. Two observers blinded to the experimental grouping were selected to evaluate the BBB scores and complete the recordings after modeling. The rats were allowed to move freely in an open field for 15 min and the two observers scored and recorded the scores once a week for 8 consecutive weeks (Fig. 1).

The body weights of the rats were assessed before modeling (day 0) and for 8 consecutive weeks after modeling. Changes in body weight were calculated by subtracting the preoperative body weight from the body weight assessed in each postoperative week. During the first 4 weeks, the dosage of the intervention was adjusted for each rat according to the change in body weight of each of the postoperative rats.

Mechanical pain in rats was assessed using the Von Frey method. The rats were individually placed in a plastic cage with a metal mesh floor and the tests were performed after 15 min of acclimatization. The bottom of the rat’s hind paw was stimulated with Von Frey hairs of different thicknesses and the pain response was scored on the Von Frey Mechanical Pain Scale. If the rats had a violent reaction, such as foot shrinkage, foot lifting, and foot licking, then the rats were considered to have developed pain, which was labeled as “O”; otherwise, the rats were considered to have not developed a pain reaction, which was labeled as “X.” The interval between each stimulus was 5–10 min. For thermal pain, the hot plate method was used (Bioseb, Pinellas Park, FL, USA), in which the rats were placed on a plate heated to 50 °C and the time it took for the rats to lift or lick their feet was recorded. The thermal pain test was stopped if the time exceeded 30 s to prevent the paw from being burned. The average of three recordings was obtained for each (left and right) hind paw, with an interval of 10 min between each recording.

We applied the hydroxylamine method to measure SOD activity. SOD activity was measured in T10 spinal cord samples on days 28 and 56 after injury using a SOD kit (A001-1, Nanjing Jianjian Bioengineering Institute, Nanjing, China) according to the manufacturer’s instructions. Once homogenized samples had been thoroughly mixed with the reagents, the samples were incubated in a water bath at a constant temperature of 37 °C for 40 min. The color developer was then added and the OD value of the supernatant was measured at 550 nm using a microplate reader (Epoch, BioTeK). The protein concentrations of the spinal cord samples were also determined and a standard curve was plotted to calculate relative SOD activity.

T-AOC was measured in gastrocnemius muscle samples on days 28 and 56 after injury using a T-AOC kit (A015-2, Nanjing Jianjian Bioengineering Institute) and the ABTS method. The tissue was first homogenized and lysed, and, after standing, the supernatant was added to the reagent and left to stand at room temperature for 6 min. Subsequently, the OD of the supernatant at 405 nm was detected in a spectrophotometer. Simultaneously, the protein concentrations of the gastrocnemius muscle samples were measured to calculate the T-AOC.

For the determination of GSH concentration, we used the microplate test method. GSH concentrations were measured in gastrocnemius muscle and T10 spinal cord samples on days 28 and 56 after injury using a GSH kit (A015-2, Nanjing Jianjian Bioengineering Institute) and the ABTS method. Once the tissues had been homogenized and lysed, the reagents were mixed and centrifuged at 3500 rpm for 10 min. The supernatant and the other reagents were then mixed and left to stand for 5 min. The OD of the supernatant at 405 nm was detected using a microplate reader, and the protein concentrations of the spinal cord and gastrocnemius muscle samples were determined to calculate the GSH concentration using the following formula: \(GSH\ concentration=\left(assay\ OD\ value-blank\ OD\ value\right)\)\(/\left(standard\ OD\ value-blank\ OD\ value\right)\)\(*standard\ tube\ concentration \left(20\ \upmu \mathrm{mol}/\mathrm{L}\right)\)\(*sample\ pretreatment\ dilution \left(2\times \right)\)\(\div\ protein\ concentration\ of\ the\ homogenate\ to\ be\ measured\ (\mathrm{g\ protein}/\mathrm{L})\).

Gastrocnemius muscle samples were homogenized in RIPA lysis buffer (ServiceBio, Wuhan, China) containing a 50× protease inhibitor cocktail (ServiceBio, Wuhan, China). The protein concentrations of the tissue samples were determined using a BCA protein quantification kit. After denaturing in a boiling water bath, the proteins were separated by SDS–polyacrylamide gel electrophoresis (SDS–PAGE), transferred to a PVDF membrane, blocked with 5% milk in TBST for 30 min at room temperature, and then incubated with primary antibody at 4 °C overnight with shaking. After primary antibody recovery and three washes with TBST, the membranes were incubated with secondary antibody (GB23303, HRP-conjugated goat anti-rabbit IgG, 1:5000; Servicebio) at room temperature for 30 min. The protein bands were revealed with a chemiluminescence reagent. The absolute OD and the relative OD were determined using AIWBwell analysis software.

Fresh rat gastrocnemius muscle tissues were cryopreserved at −80 °C and OCT-embedded 8 weeks after injury for sampling and sectioning. Frozen sections were rewarmed at room temperature; the tissue was circled with a histochemical pen, incubated with autofluorescence quenching agent (G1221, ServiceBio, Wuhan, China) for 5 min, and then rinsed. ROS stain (D7008, Sigma-Aldrich) was added dropwise within the circled area of the tissues, and the sections were incubated under light for 30 min (pH 7.4) three times, 5 min each. Then, the samples were counterstained with DAPI staining solution for 10 min at room temperature shielded from light, washed three times with PBS (pH 7.4), and sealed with an anti-fluorescence quenching agent. Finally, the ROS-positive cell rate, the area proportion, and the fluorescence intensity of ROS-positive cells were observed and analyzed with a fluorescence microscope (Eclipse C1, Nikon, Tokyo, Japan).

Statistical analysis was performed using SPSS version 19.0 (IBM, Armonk, NY, USA). Independent samples t-tests were used for comparisons between two groups and one-way ANOVA followed by Bonferroni’s post hoc test was employed for comparisons among multiple groups. Data are shown as means ± standard deviation. P values < 0.05 were considered significant. GraphPad Prism version 9.3.0.463 (LLC, San Diego, CA, USA) was used for graphing.

The changes in BBB scores of rats in the control, SCI, and GlyNAC+SCI groups over the 8 weeks after SCI are shown in Fig. 2a. SCI model rats developed complete paralysis of the lower limbs, with a BBB score of 0 on day 1, after which they slowly began to recover. The BBB scores of rats in the SCI and GlyNAC+SCI groups differed significantly by day 7 post-injury (P = 0.0161), and this difference gradually increased thereafter until week 8 (P = 0.0049). These results suggested that GlyNAC treatment improved the motor function of the model rats to some degree.

Figure 2b shows the body weight changes in rats of the SCI and GlyNAC+SCI groups. The differences between the body weights at 2, 4, 6, and 8 weeks and the pre-injury body weights were determined and the average of the differences in body weight change of the rats in each group at each time point was plotted as a line graph. A comparison was made between the two groups at each time point. The results showed that from the second week, the body weight of the GlyNAC+SCI group was significantly lower than that of the SCI group (P = 0.027); additionally, from week 6, the body weight of rats in the GlyNAC+SCI group tended to be greater than that observed pre-injury (P = 0.0116), whereas that of rats in the SCI group was still lower at week 8 than before modeling (P = 0.007). These findings indicated that GlyNAC can effectively promote weight recovery in rats after SCI, and further reflects that GlyNAC can improve the nutritional and metabolic status of SCI rats, as well as contribute to the maintenance of a good nutritional status.

The differences in thermal and mechanical pain responses between rats in the SCI and GlyNAC+SCI groups and those in the control group are shown in Fig. 3. The results showed that 4 weeks post-injury, the mechanical pain scores for rats in the SCI and GlyNAC+SCI groups were lower than those recorded for control animals (P = 0.0003; P = 0.0002); moreover, no difference in mechanical pain scores was recorded between the SCI and GlyNAC+SCI groups (P = 0.9682). However, rats in the GlyNAC+SCI group showed greater sensitivity to thermal pain stimulation compared with rats in the SCI group (P = 0.0016). After 8 weeks, the mechanical pain scores of rats in both the SCI and GlyNAC+SCI groups showed a significant decrease, with no significant difference being detected between the two groups (P = 0.2857); meanwhile, rats in the SCI group still showed a slower response to thermal hyperalgesia compared with rats in the GlyNAC+SCI group, but the difference was not significant (P = 0.0721). This suggested that GlyNAC may have a transient promotive effect on sensitivity to thermal pain in rats following SCI.

The morphology of the spinal cord of rats in the control, SCI, and GlyNAC+SCI groups 4 and 8 weeks after SCI is shown in Fig. 4a and e. It can be seen that the spinal cord in the injured area of rats in the SCI and GlyNAC+SCI groups showed different degrees of atrophy and glial scarring at both time points. However, in the GlyNAC+SCI group, the spinal cord in the middle region of the injury was morphologically more intact, and atrophy and glial scarring were less severe; this implied that GlyNAC exerts a neuroprotective effect after SCI, at least to some extent. The levels of GSH, MDA, and SOD in rats of the three groups were measured at 4 and 8 weeks post-injury. At the 4-week sampling point, the GSH levels in both the SCI and GlyNAC+SCI groups were markedly decreased compared with that in the control group (P = 0.0008; P = 0.0242); however, the level of GSH in the GlyNAC+SCI group was still significantly higher than that in the SCI group (P = 0.0242). Additionally, the level of MDA in the SCI group was significantly higher than that in both the control group (P = 0.0048) and the GlyNAC+SCI group (P = 0.0107). Meanwhile, SOD activity was significantly decreased in both the SCI (P = 0) and the GlyNAC+SCI (P = 0.0045) groups relative to that recorded in the control group; nevertheless, SOD activity was higher in the GlyNAC+SCI group than in the SCI group (P = 0.0045) (Fig. 4b–d). At 8 weeks post-injury, the GSH levels in SCI model rats were significantly decreased in comparison with those in control animals (P = 0.0152); however, no significant difference in GSH content was detected between rats in the GlyNAC+SCI group and those in the SCI group (P = 0.4566). The MDA level in the SCI group was significantly higher than that in both the control group (P = 0.0002) and the GlyNAC+SCI group (P = 0.0003). Finally, SOD activity was significantly decreased in the SCI group (P = 0.046) compared with that in the control group; in contrast, there was no significant difference in SOD activity between the GlyNAC+SCI group and the SCI group (P = 0.6737) (Fig. 4f–h). The above results indicated that GlyNAC can, to a certain extent, improve antioxidant capacity, reduce oxidative stress-induced damage, and exert neuroprotective effects in spinal cord tissues of rats after SCI.

Figure 5a shows the differences in the morphology of the gastrocnemius muscle between the SCI group and the GlyNAC+SCI group 8 weeks post-injury. A morphological observation indicated that the gastrocnemius muscle of rats in the GlyNAC+SCI group was fuller and appeared to be larger. Accordingly, we next determined the gastrocnemius wet weight ratio in the control, SCI, and GlyNAC+SCI groups at 4 and 8 weeks after SCI. We found that compared with the control group, the gastrocnemius wet weight ratios of the SCI and GlyNAC+SCI groups were significantly decreased at both 4 (P = 0.0000032919; P = 0.0011) weeks and 8 (P = 0; P = 0.0045) weeks after injury. Additionally, the gastrocnemius wet weight ratio in the SCI group was significantly lower than that in the GlyNAC+SCI group at 4 weeks (P = 0.0006) and 8 weeks (P = 0.0045) post-injury (Fig. 5b, c). This suggested that GlyNAC has a protective effect against skeletal muscle atrophy. Next, we further examined the oxidative stress-related indexes in the gastrocnemius muscle in the three groups. At 4 weeks post-SCI, no significant difference in GSH concentration was detected among the three groups (control vs SCI, P = 0592; control vs SCI+GlyNAC, P = 0.2091; SCI vs SCI+GlyNAC, P = 0.6916). However, T-AOC in the SCI group was significantly decreased compared with that in the control group (P = 0.0102) and the GlyNAC+SCI group (P = 0.0498) (Fig. 5d, e); at the 8-week sampling time point, meanwhile, the GSH concentration was significantly lower in the SCI group (P = 0.0035) and the GlyNAC+SCI group (P = 0.0074) than in the control group; there was no significant difference in T-AOC among the three groups (Fig. 5f, g). Meanwhile, we undertook an immunofluorescence staining analysis of ROS levels in gastrocnemius muscle tissue at 8 weeks post-SCI (Fig. 5h). ROS fluorescence intensity, the percentage of ROS-positive area, and the ROS-positive cell rate were compared among the three groups. The results showed that ROS fluorescence intensity was significantly higher in the SCI (P = 0) and GlyNAC+SCI (P = 0.0036) groups than in the control group and was also significantly higher in the SCI group than in the GlyNAC+SCI group (P = 0.0076) (Fig. 5i). The percentage of ROS-positive area was significantly higher in the SCI group (P = 0) and the GlyNAC+SCI group (P = 0.0036) than in the control group and was significantly higher in the SCI group than in the GlyNAC+SCI group (P = 0.0076) (Fig. 5j). The ROS-positive cell rate was significantly higher in the SCI (P = 0.0007) and GlyNAC+SCI (P = 0.0064) groups than in the control group; however, no significant difference in the ROS-positive cell rate was recorded between the SCI and the GlyNAC+SCI groups (P = 0.2658) (Fig. 5k). The above results suggested that GlyNAC administration exerts a protective effect against oxidative stress-induced damage in gastrocnemius muscle tissue after SCI.

PGC-1α expression in gastrocnemius muscle of the control, SCI, and GlyNAC+SCI groups at 4 and 8 weeks post-SCI as determined by western blot is shown in Fig. 6a and c. Statistical analysis of protein levels revealed that there was no significant difference in the expression level of PGC-1α in skeletal muscle tissue between the three groups at either 4 (control vs SCI, P = 0.4595; control vs SCI+GlyNAC, P = 0.9764; SCI vs SCI+GlyNAC, P = 0.364) or 8 (control vs SCI, P = 0.128; control vs SCI+GlyNAC, P = 0.6638; SCI vs SCI+GlyNAC, P = 0.3856) weeks post-injury (Fig. 6b, d).