Supplemental magnesium gluconate recovers osteoblastic Wntless ablation-induced degenerative bone complications.

IF 2.4 3区医学 Q3 ENDOCRINOLOGY & METABOLISM

Journal of Bone and Mineral Metabolism Pub Date : 2025-04-04 DOI:10.1007/s00774-025-01599-7

Govinda Bhattarai, Ju-Hyeon An, Shankar Rijal, Junil Lee, Junhyeok Kim, Sung-Ho Kook, Jeong-Chae Lee, Eui-Sic Cho

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引用次数: 0

Abstract

Introduction: Although numerous studies have highlighted the involvement of Wnt-mediated signaling in Mg ion-enhanced bone healing, whether Wnt-stimulated signaling is essential for the Mg ion-triggered bone repair and mass accrual is not yet completely understood.

Materials and methods: We generated Wls^fl/fl wild-type (WT) control and their corresponding mutant (MT), Col2.3-Cre;Wls^fl/fl mice of osteoblastic Wntless (Wls) ablation and explored how supplemental magnesium gluconate (MgG) affects bone mass accrual and defected bone healing in relation to the Wls ablation.

Results: Osteoblastic Wls ablation impaired bone mass accrual and bone healing along with age-related degenerative complications in bone marrow (BM) and BM cells. Oral supplementation of WT mice with MgG did not change natural bone mass accrual, but enhanced regenerative bone healing in femoral defects and the functionalities of BM cells. Supplemental MgG suppressed the Wls ablation-related bone loss and also stimulated new bone formation in the defects of MT mice. The MgG-induced beneficial effects in the MT mice were orchestrated with its potencies to ameliorate senescence, oxidative damage, and functional loss of BM and BM adherent cells, as well as to stimulate osteogenic activity.

Conclusion: This study demonstrates that supplemental MgG is able to improve bone homeostatic maintenance by recovering age-related degenerative complications even at the lack of osteoblastic Wnt-stimulated signaling.

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补充葡萄糖酸镁可恢复成骨细胞消融引起的退行性骨并发症。

虽然大量研究强调了wnt介导的信号参与镁离子增强骨愈合，但wnt刺激的信号是否对镁离子触发的骨修复和肿块积累至关重要尚不完全清楚。材料和方法：我们生成成骨细胞Wntless （Wls）消融的Wlsfl/fl野生型（WT）对照及其对应的突变体（MT） Col2.3-Cre；Wlsfl/fl小鼠，并探讨补充葡萄糖酸镁（MgG）如何影响与Wls消融相关的骨量增加和骨愈合缺陷。结果：成骨细胞壁消融损害了骨髓（BM）和骨髓细胞的骨量积累和骨愈合，并伴有年龄相关的退行性并发症。口服MgG对WT小鼠的自然骨量积累没有改变，但增强了股骨缺损的再生骨愈合和骨髓细胞的功能。补充MgG抑制Wls消融相关的骨丢失，并刺激MT小鼠缺损的新骨形成。mgg在骨髓基质小鼠中诱导的有益作用与其改善骨髓基质和骨髓粘附细胞的衰老、氧化损伤和功能丧失以及刺激成骨活性的能力相协调。结论：本研究表明，即使在缺乏成骨细胞wnt刺激信号的情况下，补充MgG也能通过恢复年龄相关的退行性并发症来改善骨稳态维持。

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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来源期刊

Journal of Bone and Mineral Metabolism 医学-内分泌学与代谢

CiteScore

6.30

自引率

3.00%

发文量

审稿时长

6-12 weeks

期刊介绍： The Journal of Bone and Mineral Metabolism (JBMM) provides an international forum for researchers and clinicians to present and discuss topics relevant to bone, teeth, and mineral metabolism, as well as joint and musculoskeletal disorders. The journal welcomes the submission of manuscripts from any country. Membership in the society is not a prerequisite for submission. Acceptance is based on the originality, significance, and validity of the material presented. The journal is aimed at researchers and clinicians dedicated to improvements in research, development, and patient-care in the fields of bone and mineral metabolism.