瘦素增强M1巨噬细胞极化并损害肩袖修复中肌腱-骨愈合:大鼠模型
Leptin Enhances M1 Macrophage Polarization and Impairs Tendon-Bone Healing in Rotator Cuff Repair: A Rat Model.
作者信息
Li Yinghao, Yao Lei, Huang Yizhou, Pang Long, Zhang Chunsen, Li Tao, Wang Duan, Zhou Kai, Li Jian, Tang Xin
机构信息
Sports Medicine Center, West China Hospital, Sichuan University, Chengdu, PR China.
Department of Orthopedic Surgery and Orthopedic Research Institute, West China Hospital, Sichuan University, Chengdu, PR China.
出版信息
Clin Orthop Relat Res. 2025 May 1;483(5):939-951. doi: 10.1097/CORR.0000000000003428. Epub 2025 Feb 19.
BACKGROUND
Rotator cuff tears are common, affecting more than 60% of individuals older than 80 years, and they have been implicated in 70% of patients with shoulder pain. M1 polarization-related inflammation has been reported to be associated with poor healing outcomes of rotator cuff injury, and leptin, an adipokine, has been reported to be a potential activator of inflammation. However, whether leptin affects rotator cuff repair remains unknown.
QUESTIONS/PURPOSES: Using in vitro cell experiments and an in vivo rat rotator cuff tear model, we therefore asked: (1) Does leptin promote the M1 polarization of macrophages in vitro and in vivo? (2) Does leptin impair biomechanical strength, the histologic structure of the tendon-bone interface, bone mineral density (BMD), or gait in the rotator cuff tear scenario? (3) Does leptin promote M1 polarization by upregulating the tumor necrosis factor (TNF) pathway?
METHODS
The impact of leptin on M1 macrophage polarization in vitro was determined by reverse transcription-polymerase chain reaction (RT-PCR), the Western blot test, and immunofluorescence staining. The effect of leptin on tendon-bone healing was assessed in an in vivo rat rotator cuff tear model by comparing a leptin group with a suture group in terms of gait, biomechanical tensile strength, the histologic structure of the tendon-bone interface, and BMD. In the in vivo experiments, 8-week-old male Sprague Dawley rats were used, adapting a previously developed rat rotator cuff tear model. The supraspinatus tendon was resected from the greater tuberosity bilaterally, and then the tendon was secured to its anatomical footprint using the transosseous single-row technique. In total, 30 rats were randomized into two groups (suture, leptin) by drawing lots (15 rats in each group). They were assessed at 2, 4, and 8 weeks after the surgery. In the suture group, 100 µL of normal saline was injected into the subacromial space after the deltoid muscle was restitched to the original position. In the leptin group, 100 µL of leptin solution (200 ng/mL) was injected into the subacromial space after the deltoid muscle was restitched to the original position. Biomechanical properties including maximal failure load, stiffness, and tensile failure stress were determined to assess the biomechanical strength at 4 and 8 weeks after the surgery. Histologic staining was conducted to compare the structure of the tendon-bone interface between treatment groups. Micro-MRI and micro-CT assessments were conducted to compare the overall healing outcome and BMD between treatment groups. Gait analysis was conducted to compare the stride length and strength between treatment groups. M1 macrophage polarization in vivo at the tendon-bone interface was assessed by immunofluorescence staining. Finally, to explore the underlying mechanism of the effects of leptin, Necrostatin-1 (Nec-1) was used to block the TNF signaling pathway in the in vitro macrophage study, and RT-PCR and Western blot were used to explore the underlying mechanism.
RESULTS
Leptin enhanced LPS-induced M1 polarization of macrophages in vitro, showing increased gene expression of CD86, Nos2, and TNF-α as well as increased protein expression of CD86, TNF-α, interleukin-6 (IL-6), and inducible NO synthase (iNOS). The in vivo polarization showed that the M1 polarization of macrophages at the tendon-bone interface was promoted. At 2 weeks postoperatively, there were more M1 cells in the leptin group (53 ± 5 versus 77 ± 8, mean difference 24 [95% confidence interval (CI) 11 to 37]; p = 0.002), although the proportion of M1 cells (ratio of the number of M1 cells to the total number of macrophages) was not higher (18.6% ± 2.9% versus 21.5% ± 1.7%, mean difference 2.9% [95% CI -2.8% to 8.7%]; p = 0.36). At 4 weeks postoperatively, the leptin group exhibited more M1 cells (31 ± 4 versus 50 ± 6, mean difference 19 [95% CI 6 to 32]; p = 0.008) and at a higher proportion (16.4% ± 2.6% versus 23.0% ± 3.0%, mean difference 6.6% [95% CI 0.8% to 12.4%]; p = 0.03). The in vivo experiments showed that leptin impaired tendon-bone healing. At 4 weeks postoperatively, the biomechanical properties of both groups were not different in terms of maximal failure load (12.7 ± 1.6 N versus 12.4 ± 1.8 N, mean difference -0.3 N [95% CI -2.6 to 1.8]; p = 0.91), stiffness (5.1 ± 0.7 N/mm versus 4.6 ± 0.8 N/mm, mean difference -0.5 N/mm [95% CI -1.3 to 0.5]; p = 0.44), and tensile failure stress (2.0 ± 0.3 N/mm 2 versus 2.0 ± 0.3 N/mm 2 , mean difference 0.0 N/mm 2 [95% CI -0.4 to 0.4]; p = 0.99). At 8 weeks postoperatively, the leptin group showed worse maximal failure load (17.6 ± 1.4 N versus 14.1 ± 1.4 N, mean difference -3.5 N [95% CI -5.7 to -1.3]; p = 0.002), stiffness (7.0 ± 0.6 N/mm versus 5.2 ± 0.6 N/mm, mean difference -1.8 N/mm [95% CI -2.7 to -0.9]; p < 0.001), and tensile failure stress (3.4 ± 0.3 N/mm 2 versus 2.8 ± 0.4 N/mm 2 , mean difference -0.6 N/mm 2 [95% CI -1.0 to -0.2]; p = 0.007). Results of histologic staining, image assessments, and gait analysis also demonstrated that leptin impaired the healing process. In vitro experiments showed that leptin upregulated the gene expression of molecules in the TNF pathway, including CCL2 and receptor-interacting protein kinase 1 (RIPK1), and M1 markers, such as TNF-α, CD86, and Nos2; the addition of Nec-1 neutralized the effect of leptin on macrophage polarization, reducing the expression of M1 markers, including TNF-α, CD86, and Nos2, and blocking the TNF signaling pathway, including CCL2 and RIPK. The protein expression exhibited similar trends.
CONCLUSION
Based on the results of this study, leptin appears to impair tendon-bone healing in a rat model of rotator cuff tear, promote M1 macrophage polarization at the tendon-bone interface, and upregulate the TNF signaling pathway in macrophages to promote M1 polarization.
CLINICAL RELEVANCE
Obesity and fatty infiltration of the rotator cuff muscle are associated with poor healing of rotator cuff tears. In this study, the effect of leptin, an adipose factor, on tendon-bone healing and the underlying mechanism were explored. Future studies might focus on developing novel approaches to improve the tendon-bone healing in patients with obesity by targeting leptin or the TNF signaling pathway with the aid of biomaterials.
背景
肩袖撕裂很常见,在80岁以上的人群中,发病率超过60%,且70%的肩部疼痛患者与之相关。据报道,与M1极化相关的炎症与肩袖损伤的愈合不良有关,而瘦素作为一种脂肪因子,据报道是炎症的潜在激活剂。然而,瘦素是否影响肩袖修复仍不清楚。
问题/目的:因此,我们利用体外细胞实验和体内大鼠肩袖撕裂模型,提出以下问题:(1)瘦素在体外和体内是否促进巨噬细胞的M1极化?(2)在肩袖撕裂的情况下,瘦素是否会损害生物力学强度、肌腱-骨界面的组织结构、骨密度(BMD)或步态?(3)瘦素是否通过上调肿瘤坏死因子(TNF)途径促进M1极化?
方法
通过逆转录-聚合酶链反应(RT-PCR)、蛋白质免疫印迹试验和免疫荧光染色,确定瘦素对体外M1巨噬细胞极化的影响。在体内大鼠肩袖撕裂模型中,通过比较瘦素组和缝合组在步态、生物力学拉伸强度、肌腱-骨界面的组织结构和骨密度方面的差异,评估瘦素对肌腱-骨愈合的影响。在体内实验中,使用8周龄的雄性Sprague Dawley大鼠,采用先前开发的大鼠肩袖撕裂模型。双侧从大结节处切除冈上肌腱,然后采用经骨单排技术将肌腱固定于其解剖足迹处。通过抽签将30只大鼠随机分为两组(缝合组、瘦素组)(每组15只)。在术后2、4和8周对它们进行评估。在缝合组中,将三角肌重新缝合至原位后,向肩峰下间隙注射100μL生理盐水。在瘦素组中,将三角肌重新缝合至原位后,向肩峰下间隙注射100μL瘦素溶液(200ng/mL)。在术后4周和8周测定包括最大破坏载荷、刚度和拉伸破坏应力在内的生物力学性能,以评估生物力学强度。进行组织学染色,比较各治疗组之间肌腱-骨界面的结构。进行微型MRI和微型CT评估,比较各治疗组之间的整体愈合结果和骨密度。进行步态分析,比较各治疗组之间的步幅长度和力量。通过免疫荧光染色评估体内肌腱-骨界面处的M1巨噬细胞极化。最后,为了探究瘦素作用的潜在机制,在体外巨噬细胞研究中使用Necrostatin-1(Nec-1)阻断TNF信号通路,并采用RT-PCR和蛋白质免疫印迹法探究潜在机制。
结果
瘦素在体外增强了LPS诱导的巨噬细胞M1极化,表现为CD86、Nos2和TNF-α的基因表达增加,以及CD86、TNF-α、白细胞介素-6(IL-6)和诱导型一氧化氮合酶(iNOS)的蛋白质表达增加。体内极化显示,肌腱-骨界面处的巨噬细胞M1极化得到促进。术后2周,瘦素组的M1细胞更多(53±5比77±8,平均差异24[95%置信区间(CI)11至37];p=0.002),尽管M1细胞的比例(M1细胞数量与巨噬细胞总数的比值)并不更高(18.6%±2.9%比21.5%±1.7%,平均差异2.9%[95%CI -2.8%至8.7%];p=0.36)。术后4周,瘦素组的M1细胞更多(31±4比50±6,平均差异19[95%CI 6至32];p=0.008),且比例更高(16.4%±2.6%比23.0%±3.0%,平均差异6.6%[95%CI 0.8%至12.4%];p=0.03)。体内实验表明,瘦素损害肌腱-骨愈合。术后4周,两组的生物力学性能在最大破坏载荷(12.7±1.6N比12.4±1.8N,平均差异-0.3N[95%CI -2.6至1.8];p=0.91)、刚度(5.1±0.7N/mm比4.6±0.8N/mm,平均差异-0.5N/mm[95%CI -1.3至0.5];p=0.44)和拉伸破坏应力(2.0±0.3N/mm²比2.0±0.3N/mm²,平均差异0.0N/mm²[95%CI -0.4至0.4];p=0.99)方面无差异。术后8周,瘦素组的最大破坏载荷(17.6±1.4N比14.1±1.4N,平均差异-3.5N[95%CI -5.7至-1.3];p=0.002)、刚度(7.0±0.6N/mm比5.2±0.6N/mm,平均差异-1.8N/mm[95%CI -2.7至-0.9];p<0.001)和拉伸破坏应力(3.4±0.3N/mm²比2.8±0.4N/mm²,平均差异-0.6N/mm²[95%CI -1.0至-0.2];p=0.007)更差。组织学染色、图像评估和步态分析的结果也表明,瘦素损害愈合过程。体外实验表明,瘦素上调了TNF途径中分子的基因表达,包括CCL2和受体相互作用蛋白激酶1(RIPK1),以及M1标志物,如TNF-α、CD86和Nos2;添加Nec-1可中和瘦素对巨噬细胞极化的影响,降低包括TNF-α、CD86和Nos2在内的M1标志物的表达,并阻断包括CCL2和RIPK在内的TNF信号通路。蛋白质表达呈现相似趋势。
结论
基于本研究结果,瘦素似乎会损害大鼠肩袖撕裂模型中的肌腱-骨愈合,促进肌腱-骨界面处的M1巨噬细胞极化,并上调巨噬细胞中的TNF信号通路以促进M1极化。
临床意义
肥胖和肩袖肌肉的脂肪浸润与肩袖撕裂的愈合不良有关。在本研究中,探讨了脂肪因子瘦素对肌腱-骨愈合的影响及其潜在机制。未来的研究可能集中于借助生物材料,通过靶向瘦素或TNF信号通路,开发新的方法来改善肥胖患者的肌腱-骨愈合。
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