二甲双胍通过纠正失调的 AMPK-mTOR 信号传导和破骨细胞分化,防止小鼠加速衰老模型中的下颌骨骨质流失

IF 5.9 1区 医学 Q1 ORTHOPEDICS Journal of Orthopaedic Translation Pub Date : 2024-05-01 DOI:10.1016/j.jot.2024.03.001
Boyang Liu , Jiao Zhang , Jinge Zhang , Xiaolei Ji , Rong Wang , Aixiu Gong , Dengshun Miao
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引用次数: 0

摘要

背景与年龄有关的下颌骨骨质疏松症经常导致老年人牙齿松动、进食困难和毁容。骨骼加速老化的 Bmi1-/- 小鼠是测试预防颌骨过早流失干预措施的有用模型。作为一种抗衰老药物,二甲双胍可改善导致骨质疏松症发病机制的分子功能障碍。我们探讨了 Bmi1-/- 小鼠下颌骨骨质疏松的机制以及二甲双胍治疗的预防方法。下颌骨表型通过 X 光、显微 CT、组织学和免疫组化进行评估。对颌骨组织中的AMPK-mTOR通路分析、衰老标记物、成骨细胞和破骨细胞基因表达进行了评估。结果与野生型对照组相比,Bmi1 缺失会降低下颌骨骨密度,同时颌骨组织中的 AMPK 活性降低、mTOR 信号转导增加、细胞衰老。与此同时,成骨细胞功能受损,破骨细胞生成标志物上调。服用二甲双胍后,AMPK-mTOR 平衡、氧化应激和衰老信号转导趋于正常,从而显著改善了 Bmi1-/- 小鼠的下颌骨结构。在培养过程中,二甲双胍通过纠正失调的 AMPK-mTOR-p53 通路活性和抑制新型促破骨细胞生成因子 Stfa1,减轻了 Bmi1-/- 骨髓前体的过度破骨细胞分化。转化潜力Bmi1-/-小鼠表现出的明显下颌骨骨质疏松代表了人类衰老过程中观察到的颌骨退化加速模型。我们的研究发现,二甲双胍能在这种早衰模型中保持下颌骨的完整性,这具有重要的临床意义。二甲双胍是一种廉价的口服药物,已被广泛用于控制糖尿病,因此有望转化为缓解老年性骨质疏松症的药物。下颌骨对咀嚼、吞咽、语言和面部结构至关重要,但随着年龄的增长,下颌骨的骨量和强度会逐渐丧失,严重影响老年人的营养、身体功能和自我形象。我们的研究结果表明,二甲双胍具有纠正细胞能量失衡、氧化应激和破骨细胞过度活跃的能力,这可能有助于老年人保持颌骨健康。鉴于二甲双胍具有多方面的生物学特性,并且通过不同途径对骨骼进行调节,因此还需要进一步的研究。不过,这项临床前研究为临床试验提供了强有力的依据,临床试验将专门研究接受二甲双胍标准治疗的老年糖尿病或糖尿病前期患者的下颌骨健康状况。确定二甲双胍补充剂是否能预防或延缓日益增长的老年人口中因衰老性颌骨丧失而导致的口腔残疾和毁容,是一项重要的公共卫生优先事项。总之,我们在遗传小鼠模型中的机理研究结果表明,二甲双胍值得进行严格的人体研究,以减轻与年龄相关的下颌骨骨质疏松症的发病率。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Metformin prevents mandibular bone loss in a mouse model of accelerated aging by correcting dysregulated AMPK-mTOR signaling and osteoclast differentiation

Background

Age-related mandibular osteoporosis frequently causes loose teeth, difficulty eating, and disfiguration in elders. Bmi1−/− mice displaying accelerated skeletal aging represent a useful model for testing interventions against premature jaw bone loss. As an anti-aging agent, metformin may ameliorate molecular dysfunction driving osteoporosis pathogenesis. We explored the mechanisms of mandibular osteopenia in Bmi1−/− mice and prevention by metformin treatment.

Methods

Three mouse groups were utilized: wild-type controls, untreated Bmi1−/−, and Bmi1−/− receiving 1 g/kg metformin diet. Mandibular bone phenotype was assessed by X-ray, micro-CT, histology, and immunohistochemistry. AMPK-mTOR pathway analysis, senescence markers, osteoblast and osteoclast gene expression were evaluated in jaw tissue. Osteoclast differentiation capacity and associated signaling molecules were examined in cultured Bmi1−/− bone marrow mononuclear cells ± metformin.

Results

Bmi1 loss reduced mandible bone density concomitant with decreased AMPK activity, increased mTOR signaling and cellular senescence in jaw tissue versus wild-type controls. This was accompanied by impaired osteoblast function and upregulated osteoclastogenesis markers. Metformin administration normalized AMPK-mTOR balance, oxidative stress and senescence signaling to significantly improve mandibular bone architecture in Bmi1−/− mice. In culture, metformin attenuated excessive osteoclast differentiation from Bmi1−/− marrow precursors by correcting dysregulated AMPK-mTOR-p53 pathway activity and suppressing novel pro-osteoclastogenic factor Stfa1.

Conclusions

Our study newly demonstrates metformin prevents accelerated jaw bone loss in a premature aging murine model by rectifying molecular dysfunction in cellular energy sensors, redox state, senescence and osteoclastogenesis pathways. Targeting such age-associated mechanisms contributing to osteoporosis pathogenesis may help maintain oral health and aesthetics in the growing elderly population.

Translational potential

The pronounced mandibular osteopenia exhibited in Bmi1−/− mice represents an accelerated model of jaw bone deterioration observed during human aging. Our finding that metformin preserves mandibular bone integrity in this progeroid model has important clinical implications. As an inexpensive oral medication already widely used to manage diabetes, metformin holds translational promise for mitigating age-related osteoporosis. The mandible is essential for chewing, swallowing, speech and facial structure, but progressively loses bone mass and strength with advancing age, significantly impacting seniors' nutrition, physical function and self-image. Our results suggest metformin's ability to rectify cellular energy imbalance, oxidative stress and osteoclast overactivity may help maintain jaw bone health into old age. Further research is still needed given metformin's multifaceted biology and bone regulation by diverse pathways. However, this preclinical study provides a strong rationale for clinical trials specifically examining mandibular outcomes in elderly subjects receiving standard metformin treatment for diabetes or prediabetes. Determining if metformin supplementation can prevent or delay oral disability and disfigurement from senescent jaw bone loss in the growing aged population represents an important public health priority. In summary, our mechanistic findings in a genetic mouse model indicate metformin merits investigation in rigorous human studies for alleviating morbidity associated with age-related mandibular osteoporosis.

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来源期刊
Journal of Orthopaedic Translation
Journal of Orthopaedic Translation Medicine-Orthopedics and Sports Medicine
CiteScore
11.80
自引率
13.60%
发文量
91
审稿时长
29 days
期刊介绍: The Journal of Orthopaedic Translation (JOT) is the official peer-reviewed, open access journal of the Chinese Speaking Orthopaedic Society (CSOS) and the International Chinese Musculoskeletal Research Society (ICMRS). It is published quarterly, in January, April, July and October, by Elsevier.
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