骨折愈合过程中骨痂细胞外基质蛋白质组的时间序列分析。

Christopher B Erickson, Ryan Hill, Donna Pascablo, Galateia Kazakia, Kirk Hansen, Chelsea Bahney
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引用次数: 2

摘要

虽然大多数骨骼完全自愈,但某些疾病需要同种异体骨移植来协助骨折愈合。同种异体骨移植由于其成骨特性,为此类骨折的治疗提供了希望。然而,目前由脱细胞骨细胞外基质(ECM)制成的同种异体骨移植物失败率高,因此需要改善骨折愈合效果的移植物。了解正常骨折愈合过程中ECM蛋白质组的具体变化将有助于鉴定可用于增强同种异体骨移植成骨性的关键蛋白。在这里,我们对小鼠骨折愈伤组织进行了时间序列分析,以研究骨折愈合关键阶段ECM的蛋白质组学和矿化变化。我们发现ECM蛋白质组的变化在很大程度上与骨折愈合的不同阶段相吻合。基底膜蛋白(AGRN, COL4, LAMA),软骨蛋白(COL2A1, ACAN)和胶原交联酶(LOXL, PLOD, ITIH)最初上调,随后是骨特异性蛋白聚糖和胶原(IBSP, COL1A1)。各种组织蛋白酶(MMP2、9、13、14;CTSK、CTSG、ELANE)在骨折愈合过程中表达水平不同。这些变化与骨折骨痂矿化相协调,骨痂矿化在愈合初期急剧增加。有趣的是,较晚的时间点的特点是伤口愈合反应和凝血因子的高表达(F2, 7,9,10)。我们发现ELANE和ITIH2是组织重塑酶,之前没有发现它们与骨折愈合有关。这些数据可以进一步挖掘,以确定再生蛋白增强骨移植设计。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

A timeseries analysis of the fracture callus extracellular matrix proteome during bone fracture healing.

A timeseries analysis of the fracture callus extracellular matrix proteome during bone fracture healing.

A timeseries analysis of the fracture callus extracellular matrix proteome during bone fracture healing.

While most bones fully self-heal, certain diseases require bone allograft to assist with fracture healing. Bone allografts offer promise as treatments for such fractures due to their osteogenic properties. However, current bone allografts made of decellularized bone extracellular matrix (ECM) have high failure rates, and thus grafts which improve fracture healing outcomes are needed. Understanding specific changes to the ECM proteome during normal fracture healing would enable the identification of key proteins that could be used enhance osteogenicity of bone allograft. Here, we performed a timeseries analysis of the fracture callus in mice to investigate proteomic and mineralization changes to the ECM at key stages of fracture healing. We found that changes to the ECM proteome largely coincide with the distinct phases of fracture healing. Basement membrane proteins (AGRN, COL4, LAMA), cartilage proteins (COL2A1, ACAN), and collagen crosslinking enzymes (LOXL, PLOD, ITIH) were initially upregulated, followed by bone specific proteoglycans and collagens (IBSP, COL1A1). Various tissue proteases (MMP2, 9, 13, 14; CTSK, CTSG, ELANE) were expressed at different levels throughout fracture healing. These changes coordinated with mineralization of the fracture callus, which increased steeply during the initial stages of healing. Interestingly the later timepoint was characterized by a response to wound healing and high expression of clotting factors (F2, 7, 9, 10). We identified ELANE and ITIH2 as tissue remodeling enzymes having no prior known involvement with fracture healing. This data can be further mined to identify regenerative proteins for enhanced bone graft design.

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