Matricellular Protein CCN1 促进心肌梗死后胶原排列和疤痕完整性

IF 4.5 1区 生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY Matrix Biology Pub Date : 2024-08-02 DOI:10.1016/j.matbio.2024.08.001
Annalara G. Fischer , Erin M. Elliott , Kenneth R. Brittian , Lauren Garrett , Ghazal Sadri , Julia Aebersold , Richa A. Singhal , Yibing Nong , Andrew Leask , Steven P. Jones , Joseph B. Moore IV
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引用次数: 0

摘要

与野生型对照组相比,Ccn1 基因敲除动物的死亡率和心肌梗死后的心脏破裂率升高,胶原瘢痕的宽度或质量没有显著差异。然而,详细的结构分析表明,疤痕胶原拓扑发生了改变,包括 ECM 结构复杂性增加和胶原排列减弱。这些变化与成纤维细胞-基质相互作用减少有关,表明CCN1通过增强这些相互作用影响胶原排列:结论:内源性CCN1通过协调成熟瘢痕中胶原成分的排列,从而塑造瘢痕的机械性能和结构稳定性,在心肌梗死后的瘢痕形成过程中发挥着关键作用。虽然CCN1在调节对疤痕完整性至关重要的胶原结构属性方面的适应性作用显而易见,但长期表达可能会导致非梗死区域的胶原结构复杂性和顺应性降低,从而凸显出其潜在的长期不良影响。
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Matricellular protein CCN1 promotes collagen alignment and scar integrity after myocardial infarction

Background

Members of the cellular communication network family (CCN) of matricellular proteins, like CCN1, have long been implicated in the regulation of cellular processes underlying wound healing, tissue fibrogenesis, and collagen dynamics. While many studies suggest antifibrotic actions for CCN1 in the adult heart through the promotion of myofibroblast senescence, they largely relied on exogenous supplementation strategies in in vivo models of cardiac injury where its expression is already induced—which may confound interpretation of its function in this process. The objective of this study was to interrogate the role of the endogenous protein on fibroblast function, collagen structural dynamics, and its associated impact on cardiac fibrosis after myocardial infarction (MI).

Methods/results

Here, we employed CCN1 loss-of-function methodologies, including both in vitro siRNA-mediated depletion and in vivo fibroblast-specific knockout mice to assess the role of the endogenous protein on cardiac fibroblast fibrotic signaling, and its involvement in acute scar formation after MI. In vitro depletion of CCN1 reduced cardiac fibroblast senescence and proliferation. Although depletion of CCN1 decreased the expression of collagen processing and stabilization enzymes (i.e., P4HA1, PLOD1, and PLOD2), it did not inhibit myofibroblast induction or type I collagen synthesis. Alone, fibroblast-specific removal of CCN1 did not negatively impact ventricular performance or myocardial collagen content but did contribute to disorganization of collagen fibrils and increased matrix compliance. Similarly, Ccn1 ablated animals subjected to MI showed no discernible alterations in cardiac structure or function one week after permanent coronary artery ligation, but exhibited marked increases in incidence of mortality and cardiac rupture. Consistent with our findings that CCN1 depletion does not assuage myofibroblast conversion or type I collagen synthesis in vitro, Ccn1 knockout animals revealed no measurable differences in collagen scar width or mass compared to controls; however, detailed structural analyses via SHG and TEM of scar regions revealed marked alterations in their scar collagen topography—exhibiting changes in numerous macro- and micro-level collagen architectural attributes. Specifically, Ccn1 knockout mice displayed heightened ECM structural complexity in post-MI scar regions, including diminished local alignment and heightened tortuosity of collagen fibers, as well as reduced organizational coherency, packing, and size of collagen fibrils. Associated with these changes in ECM topography with the loss of CCN1 were reductions in fibroblast-matrix interactions, as evidenced by reduced fibroblast nuclear and cellular deformation in vivo and reduced focal-adhesion formation in vitro; findings that ultimately suggest CCN1’s ability to influence fibroblast-led collagen alignment may in part be credited to its capacity to augment fibroblast-matrix interactions.

Conclusions

These findings underscore the pivotal role of endogenous CCN1 in the scar formation process occurring after MI, directing the appropriate arrangement of the extracellular matrix's collagenous components in the maturing scar—shaping the mechanical properties that support its structural stability. While this suggests an adaptive role for CCN1 in regulating collagen structural attributes crucial for supporting scar integrity post MI, the long-term protracted expression of CCN1 holds maladaptive implications, potentially diminishing collagen structural complexity and compliance in non-infarct regions.

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来源期刊
Matrix Biology
Matrix Biology 生物-生化与分子生物学
CiteScore
11.40
自引率
4.30%
发文量
77
审稿时长
45 days
期刊介绍: Matrix Biology (established in 1980 as Collagen and Related Research) is a cutting-edge journal that is devoted to publishing the latest results in matrix biology research. We welcome articles that reside at the nexus of understanding the cellular and molecular pathophysiology of the extracellular matrix. Matrix Biology focusses on solving elusive questions, opening new avenues of thought and discovery, and challenging longstanding biological paradigms.
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