一种新型的多功能辐射防护策略,使用P7C3作为对抗电离辐射引起的骨质流失的对策。

IF 14.3 1区 医学 Q1 CELL & TISSUE ENGINEERING Bone Research Pub Date : 2023-06-29 DOI:10.1038/s41413-023-00273-w
Fei Wei, Zewen Kelvin Tuong, Mahmoud Omer, Christopher Ngo, Jackson Asiatico, Michael Kinzel, Abinaya Sindu Pugazhendhi, Annette R Khaled, Ranajay Ghosh, Melanie Coathup
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引用次数: 1

摘要

放射治疗是癌症治疗的重要组成部分,但可能导致周围和其他健康骨骼的骨质疏松症和病理性不全性骨折。目前,没有有效的对策存在,电离辐射引起的骨损伤仍然是疼痛和发病率的重要来源。本研究的目的是研究一种名为P7C3的小分子氨基丙基咔唑作为一种新的辐射防护策略。我们的研究表明,P7C3在体外抑制电离辐射(IR)诱导的破骨细胞活性,抑制脂肪生成,促进成骨细胞生成和矿物质沉积。我们还证明,啮齿类动物暴露于临床等效的低分割水平的体内IR会导致骨质疏松。然而,给药P7C3显著抑制破骨细胞活性、脂质形成和骨髓脂肪,减轻组织损失,使骨保持其面积、结构和机械强度。我们的研究结果显示,细胞大分子代谢过程、髓细胞分化以及lrp4、TAGLN、ILK和Tollip蛋白显著增强,GDF-3、SH2B1和CD200下调。这些蛋白在支持成骨细胞而非脂肪祖细胞分化、细胞基质相互作用、形状和运动、促进炎症解决和抑制破骨细胞生成方面发挥关键作用,可能通过Wnt/β-catenin信号传导。一个问题是P7C3是否对癌细胞有类似的保护作用。初步发现,在相同的保护性P7C3剂量下,体外三阴性乳腺癌和骨肉瘤细胞代谢活性显著降低。总之,这些结果表明P7C3是以前未被发现的脂肪-成骨祖细胞谱系承诺的关键调节因子,可能作为一种新的多功能治疗策略,使IR成为有效的临床工具,同时降低IR后不良并发症的风险。我们的数据揭示了一种预防辐射引起的骨损伤的新方法,需要进一步研究其选择性驱动癌细胞死亡的能力。
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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A novel multifunctional radioprotective strategy using P7C3 as a countermeasure against ionizing radiation-induced bone loss.

Radiotherapy is a critical component of cancer care but can cause osteoporosis and pathological insufficiency fractures in surrounding and otherwise healthy bone. Presently, no effective countermeasure exists, and ionizing radiation-induced bone damage continues to be a substantial source of pain and morbidity. The purpose of this study was to investigate a small molecule aminopropyl carbazole named P7C3 as a novel radioprotective strategy. Our studies revealed that P7C3 repressed ionizing radiation (IR)-induced osteoclastic activity, inhibited adipogenesis, and promoted osteoblastogenesis and mineral deposition in vitro. We also demonstrated that rodents exposed to clinically equivalent hypofractionated levels of IR in vivo develop weakened, osteoporotic bone. However, the administration of P7C3 significantly inhibited osteoclastic activity, lipid formation and bone marrow adiposity and mitigated tissue loss such that bone maintained its area, architecture, and mechanical strength. Our findings revealed significant enhancement of cellular macromolecule metabolic processes, myeloid cell differentiation, and the proteins LRP-4, TAGLN, ILK, and Tollip, with downregulation of GDF-3, SH2B1, and CD200. These proteins are key in favoring osteoblast over adipogenic progenitor differentiation, cell matrix interactions, and shape and motility, facilitating inflammatory resolution, and suppressing osteoclastogenesis, potentially via Wnt/β-catenin signaling. A concern was whether P7C3 afforded similar protection to cancer cells. Preliminarily, and remarkably, at the same protective P7C3 dose, a significant reduction in triple-negative breast cancer and osteosarcoma cell metabolic activity was found in vitro. Together, these results indicate that P7C3 is a previously undiscovered key regulator of adipo-osteogenic progenitor lineage commitment and may serve as a novel multifunctional therapeutic strategy, leaving IR an effective clinical tool while diminishing the risk of adverse post-IR complications. Our data uncover a new approach for the prevention of radiation-induced bone damage, and further work is needed to investigate its ability to selectively drive cancer cell death.

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来源期刊
Bone Research
Bone Research CELL & TISSUE ENGINEERING-
CiteScore
20.00
自引率
4.70%
发文量
289
审稿时长
20 weeks
期刊介绍: Established in 2013, Bone Research is a newly-founded English-language periodical that centers on the basic and clinical facets of bone biology, pathophysiology, and regeneration. It is dedicated to championing key findings emerging from both basic investigations and clinical research concerning bone-related topics. The journal's objective is to globally disseminate research in bone-related physiology, pathology, diseases, and treatment, contributing to the advancement of knowledge in this field.
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