Targeting endoplasmic reticulum stress-induced lymphatic dysfunction for mitigating bisphosphonate-related osteonecrosis

IF 7.9 1区 医学 Q1 MEDICINE, RESEARCH & EXPERIMENTAL Clinical and Translational Medicine Pub Date : 2024-11-09 DOI:10.1002/ctm2.70082
Ziyue Qin, Hanyu Xie, Pengcheng Su, Zesheng Song, Rongyao Xu, Songsong Guo, Yu Fu, Ping Zhang, Hongbing Jiang
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Abstract

Background

Bisphosphonates (BPs) are the first-line treatment to stop bone resorption in diseases, including osteoporosis, Paget's disease, multiple myeloma and bone metastases of cancer. However, BPs-related osteonecrosis of the jaw (BRONJ), characterized by local inflammation and jawbone necrosis, is a severe intractable complication. The cumulative inflammatory burden often accompanies impaired lymphatic drainage, but its specific impact on BRONJ and the underlying mechanisms remain unclear.

Methods

The mouse BRONJ model was established to assess the integrity and drainage function of lymphatic vessels by tissue clearing techniques, injected indocyanine green lymphatic clearance assay, flow cytometry analysis and histopathological staining. RNA sequencing, metabolome analysis, transmission electron microscopy and Western blotting were utilized to analyze the impacts of Zoledronate acid (ZA) on endoplasmic reticulum stress (ERS) and function of lymphatic endothelial cells (LECs). By constructing Lyve1creERT; SIRT6f/f and Lyve1creERT; ATG5f/f mice, we evaluated the role of ERS-induced LECs apoptosis in the progression of BRONJ. Additionally, we developed a nanoparticle-loaded ZA and rapamycin (ZDPR) to enhance autophagy and evaluated its potential in mitigating BRONJ.

Results

The mouse BRONJ model displayed impaired lymphatic drainage, accompanied by significant local inflammation and bone necrosis. The prolonged stimulation of ZA resulted in the extension of ERS and the inhibition of autophagy in LECs, ultimately leading to apoptosis. Mechanistically, ZA activated XBP1s through the NAD+/SIRT6 pathway, initiating ERS-induced apoptosis in LECs. The conditional knockout mouse models demonstrated that the deletion of SIRT6 or ATG5 significantly worsened lymphatic drainage and inflammatory infiltration in BRONJ. Additionally, the innovative nanoparticle ZDPR alleviated ERS-apoptosis in LECs and enhanced lymphatic function, facilitating inflammation resolution.

Conclusion

Our study has elucidated the role of the NAD+/SIRT6/XBP1s pathway in ERS-induced apoptosis in ZA-treated LECs, and further confirmed the therapeutic potential of ZDPR in restoring endothelial function and improving lymphatic drainage, thereby effectively mitigating BRONJ.

Key points

  • Bisphosphonate-induced lymphatic drainage impairment exacerbates bone necrosis.
  • Zoledronate acid triggers endoplasmic reticulum stress and apoptosis in lymphatic endothelial cells via the NAD+/SIRT6/XBP1s pathway.
  • Novel nanoparticle-loaded Zoledronate acid and rapamycin enhances autophagy, restores lymphatic function, and mitigates bisphosphonates-related osteonecrosis of the jaw progression.

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针对内质网应激诱导的淋巴功能障碍,减轻与双磷酸盐相关的骨坏死。
背景:双膦酸盐(BPs)是阻止骨吸收疾病的一线治疗药物,包括骨质疏松症、帕吉特氏病、多发性骨髓瘤和癌症骨转移。然而,与 BPs 相关的颌骨坏死(BRONJ)以局部炎症和颌骨坏死为特征,是一种严重的难治性并发症。累积性炎症负担往往伴随着淋巴引流受损,但其对 BRONJ 的具体影响和潜在机制仍不清楚:方法:建立小鼠 BRONJ 模型,通过组织清除技术、注射吲哚菁绿淋巴清除试验、流式细胞仪分析和组织病理学染色评估淋巴管的完整性和引流功能。利用RNA测序、代谢组分析、透射电子显微镜和Western印迹分析了唑来膦酸盐(ZA)对淋巴管内皮细胞(LECs)内质网应激(ERS)和功能的影响。通过构建 Lyve1creERT; SIRT6f/f 和 Lyve1creERT; ATG5f/f 小鼠,我们评估了 ERS 诱导的 LECs 凋亡在 BRONJ 进展中的作用。此外,我们还开发了一种纳米载体ZA和雷帕霉素(ZDPR)来增强自噬,并评估了其在缓解BRONJ方面的潜力:结果:小鼠BRONJ模型显示淋巴引流受损,并伴有明显的局部炎症和骨坏死。ZA的长期刺激导致淋巴细胞内ERS的延长和自噬的抑制,最终导致淋巴细胞凋亡。从机制上讲,ZA通过NAD+/SIRT6途径激活了XBP1s,启动了ERS诱导的LECs凋亡。条件性基因敲除小鼠模型表明,SIRT6或ATG5的缺失会显著恶化BRONJ的淋巴引流和炎症浸润。此外,创新性纳米粒子ZDPR缓解了LECs的ERS-凋亡,增强了淋巴功能,促进了炎症的消退:我们的研究阐明了 NAD+/SIRT6/XBP1s 通路在 ERS 诱导的 ZA 处理 LECs 细胞凋亡中的作用,并进一步证实了 ZDPR 在恢复内皮功能和改善淋巴引流方面的治疗潜力,从而有效缓解 BRONJ:要点:双磷酸盐诱导的淋巴引流障碍会加剧骨坏死。唑来膦酸通过 NAD+/SIRT6/XBP1s 途径引发淋巴内皮细胞内质网应激和凋亡。新型纳米载体唑来膦酸和雷帕霉素能增强自噬、恢复淋巴功能并缓解与双膦酸盐相关的颌骨坏死进展。
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来源期刊
CiteScore
15.90
自引率
1.90%
发文量
450
审稿时长
4 weeks
期刊介绍: Clinical and Translational Medicine (CTM) is an international, peer-reviewed, open-access journal dedicated to accelerating the translation of preclinical research into clinical applications and fostering communication between basic and clinical scientists. It highlights the clinical potential and application of various fields including biotechnologies, biomaterials, bioengineering, biomarkers, molecular medicine, omics science, bioinformatics, immunology, molecular imaging, drug discovery, regulation, and health policy. With a focus on the bench-to-bedside approach, CTM prioritizes studies and clinical observations that generate hypotheses relevant to patients and diseases, guiding investigations in cellular and molecular medicine. The journal encourages submissions from clinicians, researchers, policymakers, and industry professionals.
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