Introduction
Low back pain (LBP) is a common orthopedic disease over the world and has become the greatest cause of disability globally [
12], resulting in huge financial and social burdens [
13]. About 540 million patients are given the diagnostic code reflective of spinal osteoarthritis. LBP is defined as pain and discomfort located to lumbar region and/or gluteal region, anatomically from the 12th thoracic vertebra to the gluteal sulcus with or without radiating pain [
14]. In most cases, it is difficult to identify the specific structural cause of pain [
15]. At present, surgery has not have a satisfactory long-term effect despite the main clinical treatment for IDD. Based on this, many studies turn to non-invasive alternatives for IDD [
16]. More and more Chinese medicines have been dug that they have an amazing treatment on IDD [
17‐
20]. Shensuitongzhi formula (SSTZF) is a drug commonly used in clinical treatment for orthopedic diseases such as fracture [
21], osteoarthritis [
21] and osteoporosis. It has been suggested that IDD shows similarity changing in cartilage with articular cartilage degeneration [
20]. At the same time, it has been found that SSTZF can also have a good treatment for IDD [
22]. But the exact mechanism has not been clarified, which limits the further development and application of SSTZF.
LBP is closely related to lifestyle and living conditions, such as obesity, poor sleep, stress and smoking [
23]. The etiology of LBP remains unclearly. Extensive imaging and histopathology studies have found that lumbar intervertebral disc degeneration (IDD) is an important cause of LBP [
24]. Physiologically, the intervertebral disc (IVD), an important part of the spine [
25], consists of three major tissues: nucleus pulposus (NP), cartilaginous endplate (CEP) and annulus fibrosus (AF) [
26]. The pathogenesis of IDD has not been fully elucidated which is characterized as losing and producing insufficiency of extracellular matrix (ECM) because of the decrease in number and function of NP cells [
27,
28]. Type II collagen (Col II) and proteoglycan (PG) are the main components in ECM [
16]. In the process of IDD, there are not only an obvious imbalance between the anabolism and catabolism of ECM [
11] but also producing a large number of inflammatory factors such as TNF-α and IL-1β which promote the reduction of matrix by directly inhibiting the expression of matrix genes or by increasing the expression of collagen and aggregator lyase [
29].
Previous studies have mainly focused on the nucleus pulposus which is the core structure of IVD and shows obvious changes in X-ray, while changes in the cartilage endplate are rarely reported [
30,
31]. CEP is a thin layer of hyaline cartilage that not only separates the vertebral body from disc [
32,
33], but also residues mechanical forces from intravertebral disc pressure [
34]. The CEP is a semi-permeable barrier by which nutrients entering the disc and metabolites expelled. Therefore, CEP degeneration not only changes the mechanical function of CEP, but also affects the bio-transport function of CEP [
35,
36]. Chondrocyte apoptosis and endplate calcification are considered as two decisive manifestations of cartilage endplate degeneration [
37,
38]. Therefore, protection against CEP degeneration is a potential treatment strategy for maintaining IVD health and preventing spinal disease.
The nuclear factor-κB (NF-κB) signaling pathway plays a key regulatory role in inflammatory response and immune response [
31]. The importance of NF-κB signaling pathway in the cause and treatment of IDD has been reported in many studies. For example, Wang et al. [
39] found that the activation of NF-κB can promote the overexpression of MMPs and then lead to the over-decomposition of ECM, thus leading to IDD. Meanwhile, NF-κB signaling pathway activation can increase many inflammatory mediators and chemokine expression levels, resulting in a vicious cycle that further accelerates the progression of IDD [
9,
30,
40]. Studies using losing function approaches confirmed the importance of NFκB in IDD [
40,
41]. In addition, a large number of studies have found that TCM which has efficacy on tonifying kidney and promoting blood circulation can alleviate IDD through NF-κB pathway [
42]. Many studies have focused on the action mechanism of NF-kB in NP [
30,
31]. However, the effect of NF-κB signaling on cartilage endplates is unknown.
Based on the above-mentioned studies, we hypothesized that SSTZF could ameliorate the pathological changes in inflammation-associated chondrocytes with potential drug therapy for IDD. In the present study, we evaluated the therapeutic effect of SSTZF on IDD and investigated the potential mechanism of action with in vivo and in vitro experiments.
Materials and methods
Preparation of SSTZF
SSTZF whole formula consists of rehmanniae, eucommia, saponaria, wolfberry, cinnamon, cornelian, peach kernel, safflower, yam and licorice (Table
1). Specific concoction method is divided into two parts: water extraction and alcohol extraction. Water extraction part: firstly eight Chinese herbal beverages of rehmanniae, eucommia, saponaria, wolfberry, cornelian, safflower, yam and licorice were soaked in pure water for 1 h, and 12 times the volume of pure water was added to the Chinese herbal beverages for reflux extraction, for a total of three times, 1.5 h each time. Then, 95% ethanol (final alcohol content of 60%) was added to alcohol precipitation for 24 h, and ethanol was recovered under reduced pressure. Alcohol extraction part: soak cinnamon and peach kernel in 10 times the volume of 60% ethanol for 1 h, extract at reflux for three times, 1.5 h each time, and recover the ethanol under reduced pressure. Finally, the extracts of the above two parts were combined and concentrated under reduced pressure to a raw drug concentration of 2 g/mL. The prepared herbs were stored in -30℃ refrigerator for subsequent experiments.
Table 1
Compositions of SSTZF
Tao ren | Prunus persica (Batsch.) | Peach | Fruit | 11.8 |
Rou gui | Cinnamomum cassia (Presl) | Cassia Bark Tree | Bark | 5.9 |
Fu zi | Aconitum carmichaeli (Debx.) | Monkshood | Root | 11.8 |
Du zhong | Eucommia ulmoides (Oliv.) | Eucommia | Bark | 11.8 |
Gou qi | Lycium barbarum (L.) | Matrimony Vine | Fruit | 11.8 |
Shan yao | Dioscoreae opposite (Thunb.) | Common Yam | Root | 11.8 |
Hong hua | Carthamus tinctorius (L.) | False Saffron | Corolla | 5.9 |
Shan zhu yu | Cornus officinalis (Sieb.) | Medical Dogwood | Fruit | 5.9 |
Gan cao | Glycyrrhiza uralensis (Fisch.) | Ural Licorice | Root | 5.9 |
Shu di huang | Rehmannia glutinosa(Liboscb) | Rehmannia | Root | 17.4 |
Preparation of SSTZF-containing serum
Twenty SD rats were randomly divided into two groups, blank group and SSTZF group, and the dose was converted with reference to the ratio of body surface area of experimental rats to that of adults, once daily for 7 days, and the blank group was given an equal amount of distilled water. The blood was collected from the abdominal aorta 1 h after the last dose, left to stand for 1 h and then centrifuged at 3000 rpm/min for 10 min. Finally, the upper serum was aspirated for complement extinguishing, filtered, sterilized and then stored at − 80 ℃.
Experimental animals
Ten-week-old male C57BL/6 J mice were provided by the Animal Center of Zhejiang University of Traditional Chinese Medicine (Hangzhou, China). All mice were housed in the pathogen-free laboratory of the Animal Center of Zhejiang University of Traditional Chinese Medicine (Hangzhou, China), with six mice per cage and free access to clean food and water. All experiments were conducted after approval by the Animal Experimentation Ethics Committee of Zhejiang University of Traditional Chinese Medicine (LZ12H27001).
Experimental grouping and drug administration treatment
The experimental mice were randomly divided into sham group, model group and SSTZF group, in which mice in both model and SSTZF groups underwent lumbar disc degeneration model surgery. Twelve mice in each group were sampled at 4 weeks and 8 weeks postoperatively, six mice in each time point. According to previous studies, the lumbar degeneration surgery was taken to induce IDD in the lumbar instability mouse model [
1,
2]. Briefly, pentobarbital sodium-anesthetized mice were positioned prone, and the supraspinous ligament, interspinous ligament and spinous process between their second lumbar and sixth lumbar vertebrae were freed, and then, the supraspinous ligament, interspinous ligament and spinous process between the third and fifth lumbar vertebrae were clipped with curved scissors. Meanwhile, only the paravertebral muscle tissue was removed from the mice in the sham group. Finally, the incision was sutured and antibiotics were administered to prevent infection and put back into the mouse cage.
Micro-CT(μCT) analysis
Spinal tissues were collected from the thirteenth thoracic vertebra to the first sacral vertebra of mice after 4 weeks and 8 weeks postoperatively, and the muscle tissues around the spine were stripped clean and then fixed in 4% cellular tissue fixative for three days. The fixed end tissue samples were placed in the micro-CT mouse bed in the sagittal direction for X-ray scanning. After scanning, 3D reconstruction and 3D image creation were performed using on-board NRecon reconstruction software and CTvox graphics software to observe the lumbar disc tissue gap size and endplate ossification formation. Finally, the region of interest (ROI) was quantitatively analyzed using the airborne bone micromorphometric analysis software CTAn [
1].
Histomorphological staining
After rinsing the residual fixative from the surface with running water at the end of fixation, the samples were submerged in 14% EDTA solution for 14 days for decalcification. Then, the surface decalcification solution was rinsed under running water and placed in gradient alcohol for dehydration and subsequent paraffin embedding. Paraffin tissues were stained in sections of 3 μm thickness. After the sections were dewaxed and rehydrated, the lumbar disc tissues were morphologically observed with Alcian blue/hematoxylin and orange G staining (ABH staining). Based on the results of ABH staining and the histological assessment scale for lumbar disc tissue, data were evaluated for each histological variable in the disc structure and cartilage endplate structure, respectively [
3].
Tartrate-resistant acid phosphatase (TRAP) staining
Tissue sections from each experimental group were stained by tartrate-resistant acid phosphatase (TRAP) to detect the activity of osteoclasts in the endplate of the lumbar disc cartilage in mice and to quantify the number of osteoclasts (N.Oc/TA) as previously described. Briefly, anhydrous sodium acetate, sodium tartrate and glacial acetic acid were prepared into a 200-mL base working solution and preheated at 37 °C. The slices were dewaxed and rehydrated into the base working solution with naphthol AS-BI phosphate and baked at 37 °C for 1 h. Then, transfer to another base working solution mixed with sodium nitrite and basic magenta and incubate for 5–10 min; the color appears to terminate the staining. Finally, alcohol-free hematoxylin staining was used as the background color.
Immunohistochemical staining
For immunohistochemical (IHC) assays, the sections were treated with 0.01 M citrate buffer (Solarbio, Beijing, China) for 4 h at 60 °C as antigen repair after dewaxing and rehydration was completed. Next, the sections were incubated in Col2, Mmp13, IL-1β, TNF-α and p-P65 primary antibodies overnight at 4 °C. The next day after incubation with the cognate secondary antibody for 20 min, diaminobenzidine (DAB) solution was applied to detect positive staining, while hematoxylin was applied for counterstaining. Positive staining was assessed semi-quantitatively using Image-Pro Plus software (Media Cybernetics, Silver Spring, USA).
Cell culture
Primary chondrocytes were obtained from two-week-old C57BL/6 J mice. The mice were executed and sterilized by immersion in 75% alcohol, and lumbar endplate cartilage was isolated aseptically. Then, phosphate buffer was washed three times and digested with 0.25% collagenase dissolved in F12/ DMEM medium in a cell culture incubator overnight. The following day, the digested primary chondrocytes were cultured in DMEM/F12 medium containing 10% FBS and 1% streptomycin/penicillin and incubated in an incubator at 37 °C and 5% CO2 for subsequent experiments.
Real-time quantitative PCR assay
Lumbar vertebral bone tissue stored in − 80 °C refrigerator was ground into powder form with liquid nitrogen, and then, a portion was added to 1 mL of Trizol solution. The primary chondrocytes cultured in vitro were added to 500μLTrizol solution. Bone tissue RNA was extracted and reverse transcribed according to the operating instructions of RNeasy Mini Kit (QIAGEN) and All-in-One cDNA Synthesis SuperMix (Bimake). The qPCR assay was then performed with 2 × SYBR Green qPCR Master Mix (Low ROX) (Bimake) reagent. And β-actin was used as a control gene for quantitative analysis. The target gene primer sequences were as follows:
IL-1β Forward | GCAACTGTTCCTGAACTCAACT |
IL-1β Reverse | ATCTTTTGGGGTCCGTCAACT |
TNFα Forward | CCCTCACACTCAGATCATCTTCT |
TNFα Reverse | GCTACGACGTGGGCTACAG |
Mmp13 Forward | TTTGAGAACACGGGGAAGA |
Mmp13 Reverse | ACTTTGTTGCCAATTCCAGG |
Col2 Forward | TGGTCCTCT GGGCATCTCAGGC |
Col2 Reverse | GGTGAACCTGCTGTTGCCCTCA |
RELA Forward | AGGCTTCTGGGCCTTATGTG |
RELA Reverse | TGCTTCTCTCGCCAGGAATAC |
β-actin Forward | GGAGATTACTGCCCTGGCTCCTA |
β-actin Reverse | GACTCATCGTACTCCTGCTTGCTG |
Western Blot assay
Another portion of the above ground powdered bone tissue and in vitro cultured primary chondrocytes were added to the appropriate amount of RIPA lysis solution (containing protease inhibitor, ready to use) and lysed by repeated shaking on ice for 30 min. Then, place in a centrifuge at 4 °C for 10 min at 12,000 rpm and aspirate the supernatant into a new 1.5-mL centrifuge tube. The protein concentration of each group was first measured by the BCA protein quantification kit, and then, a certain volume of 5 × loading buffer was added to the remaining protein supernatant (so that the final concentration was 1 ×), and finally denatured by boiling at 100 ℃ for 5 min. Next, proteins were separated on 8% SDS–PAGE gels (20 μg/lane) and transferred to NC membranes. After incubation with 5% skim milk for 1 h, the primary antibodies were incubated with Col2 (1:1000 dilution, Abcam), Mmp13 (1:1000 dilution, Huaan), p65 (1:1000 dilution, Cell Signaling Technology), p-P65 (1:1000 dilution, Cell Signaling Technology) and β-actin (1:10,000 dilution, Sigma-Aldrich) for 16 h at 4 °C. After that, the protein bands were visualized by incubation with the corresponding cognate secondary antibodies for 1 h at room temperature and finally with Image Quant LAS 4000 (EG, USA). Using β-actin as an internal reference, the grayscale values of the protein bands were calculated using ImageJ software to analyze the expression of the target protein between groups.
Statistical analysis
All experimental data in this subject were statistically analyzed using SPSS 25.0 software, and the statistical results of the measures were expressed as mean ± standard deviation. One-way analysis of variance (one-way ANOVA) was used for comparison between different groups, and if the variance was not equal, Dunnett's T3 test was used. The difference was statistically significant at P < 0.05.
Discussion
For the first time, we proof the effect of SSTZF on the progression of IDD in animal models and explore its mechanism preliminarily. Histological and μCT results showed that SSTZF effectively delayed the degradation of cartilage matrix, inhibited the expression of LSI-induced inflammatory factors and protected the cartilaginous endplate calcification and intervertebral disc degeneration of LSI-induced mice. SSTZF was also demonstrated to delay IDD progression by inhibiting NF-κB signaling pathway in vivo and in vitro. These data provides a new and reliable evidence for the clinical treatment of LBP by SSTZF.
SSTZF, a traditional Chinese Herbal formula, has many function on different disease not only orthopedic disease but also internal disease [
43].Our previous study had demonstrated that SSTZF may decelerate osteoarthritic cartilage degeneration [
44] via reducing the expressional level of MMP13 in cartilage of DMM-induced mice [
45]. In addition, it was been reported that had an effective treatment on fracture [
21]. The recent results showed that SSTZF modulates NP cell proliferation and ECM remodeling in IDD [
30]. As the same results as we has, in our experiment, SSTZF has the also function on IDD through restoring the metabolic balance of ECM. In this study, we used the LSI mouse model to simulate the human IDD process. μCT and ABH staining results were similar to those previously reported [
46]. Reduced disc height, vertebral endplate sclerosis and decreased IVD volume were observed in LSI mice. However, mice treated with SSTZF showed the opposite result to the model group at 4 and 8 weeks after LSI surgery, suggesting that SSTZF delays disc degeneration and IDD progression by reducing cartilaginous endplate calcification.
Recent studies have shown that cartilage endplate degeneration is also a key factor in the pathogenesis of IDD [
47]. The CEP is a thin layer of hyaluronic cartilage that acts as a semi-permeable barrier which not only delivers nutrients but also be a cushion for mechanical load [
33]. In the IDD process, the balance between ECM anabolism which mainly include col2 and catabolism which mainly include Mmp13 is broken [
11]. In intervertebral disc degeneration, Mmp13 expression quantity significantly increases in IDD as well as in arthritis [
20]. As a result, Col2 expression quantity decreased and Mmp13 expression quantity increased in LSI group. The expression of Col2 and Mmp13 in the SSTZF group was significantly increased compared with LSI group. Therefore, SSTZF can maintain the normal integrity of cartilage endplate by restoring the metabolic balance of ECM, delaying the calcification and degeneration of the endplate.
During the IDD process, a large number of inflammatory factors, such as TNF-α and IL-1β, are produced in ECM. These cytokines promote matrix degradation, chemokines production and cell phenotypic change [
48], leading to the dysmetabolism of ECM. In the previous report, inflammatory cytokines are closely related to NF-κB signaling pathway [
49]. Also, it has been demonstrated that NF-κB is involved in IDD by regulating ECM degradation, oxidative stress, aging and cell death [
31]. NF-κB exists as a dimer which is a member of the Rel protein family. Common Rel proteins are Rel A (p65), RelB, c-Rel, p50 and p52 [
50]. Rel A (p65) is one of the most widespread proteins in eukaryotic cells and has the most vital regulatory roles [
51]. Also, phosphorylation and nuclear translocation of P65 are the classical activation of the NF-κB [
52]. Therefore, the expression of p-P65 was detected. Compared with the model group, the expression of p-P65 in the SSTZF group was significantly reduced. These results suggest that SSTZF may delay IDD progression by inhibiting the activation of NF-κB. Previous studies have shown that SSTZF has a wide range of favorable therapeutic effects on orthopedic diseases, many of which are achieved through anti-inflammatory and regulation of internal stromal metabolic status. This is the first time that our results demonstrated that SSTZF can reduce inflammatory response and regulates stromal homeostasis in the treatment of IDD through inhibiting the activation of NF-κB.
However, the shortcoming of our present study is that we have not detected the molecular pharmacological mechanism of the active SSTZF. Investigating the possible biological processes of SSTZF may be beneficial for further research and help us using the SSTZF more effectively.
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