Restoration versus reconstruction: cellular mechanisms of skin, nerve and muscle regeneration compared.

IF 2
Regenerative Medicine Research Pub Date : 2013-10-01 eCollection Date: 2013-12-01 DOI:10.1186/2050-490X-1-4
Dario Coletti, Laura Teodori, Zhenlin Lin, Jean Francois Beranudin, Sergio Adamo
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引用次数: 23

Abstract

In tissues characterized by a high turnover or following acute injury, regeneration replaces damaged cells and is involved in adaptation to external cues, leading to homeostasis of many tissues during adult life. An understanding of the mechanics underlying tissue regeneration is highly relevant to regenerative medicine-based interventions. In order to investigate the existence a leitmotif of tissue regeneration, we compared the cellular aspects of regeneration of skin, nerve and skeletal muscle, three organs characterized by different types of anatomical and functional organization. Epidermis is a stratified squamous epithelium that migrates from the edge of the wound on the underlying dermis to rebuild lost tissue. Peripheral neurons are elongated cells whose neurites are organized in bundles, within an endoneurium of connective tissue; they either die upon injury or undergo remodeling and axon regrowth. Skeletal muscle is characterized by elongated syncytial cells, i.e. muscle fibers, that can temporarily survive in broken pieces; satellite cells residing along the fibers form new fibers, which ultimately fuse with the old ones as well as with each other to restore the previous organization. Satellite cell asymmetrical division grants a reservoir of undifferentiated cells, while other stem cell populations of muscle and non-muscle origin participate in muscle renewal. Following damage, all the tissues analyzed here go through three phases: inflammation, regeneration and maturation. Another common feature is the occurrence of cellular de-differentiation and/or differentiation events, including gene transcription, which are typical of embryonic development. Nonetheless, various strategies are used by different tissues to replace their lost parts. The epidermis regenerates ex novo, whereas neurons restore their missing parts; muscle fibers use a mixed strategy, based on the regrowth of missing parts through reconstruction by means of newborn fibers. The choice of either strategy is influenced by the anatomical, physical and chemical features of the cells as well as by the extracellular matrix typical of a given tissue, which points to the existence of differential, evolutionary-based mechanisms for specific tissue regeneration. The shared, ordered sequence of steps that characterize the regeneration processes examined suggests it may be possible to model this extremely important phenomenon to reproduce multicellular organisms.

Abstract Image

Abstract Image

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修复与重建:比较皮肤、神经和肌肉再生的细胞机制。
在以高更新或急性损伤为特征的组织中,再生取代受损细胞,并参与对外部信号的适应,导致许多组织在成年生活中保持稳态。对组织再生机制的理解与基于再生医学的干预措施高度相关。为了探讨组织再生的主因,我们比较了皮肤、神经和骨骼肌这三个器官在细胞方面的再生,这三个器官具有不同的解剖和功能组织类型。表皮是一层鳞状上皮,从伤口边缘迁移到真皮下层,重建失去的组织。外周神经元是细长的细胞,其神经突在结缔组织的神经内膜内成束组织;它们要么死于损伤,要么经历重塑和轴突再生。骨骼肌的特征是细长的合胞细胞,即肌肉纤维,可以暂时在碎片中存活;沿着纤维的卫星细胞形成新的纤维,最终与旧的纤维融合,并彼此融合,以恢复以前的组织。卫星细胞的不对称分裂提供了未分化细胞的储存库,而其他肌肉和非肌肉来源的干细胞群参与肌肉更新。损伤后,这里分析的所有组织都要经历三个阶段:炎症、再生和成熟。另一个共同特征是细胞去分化和/或分化事件的发生,包括基因转录,这是胚胎发育的典型特征。尽管如此,不同的组织使用不同的策略来替换失去的部分。表皮再生,而神经元则恢复其缺失的部分;肌肉纤维使用混合策略,基于通过新生纤维重建缺失部分的再生。这两种策略的选择都受到细胞的解剖、物理和化学特征以及特定组织的典型细胞外基质的影响,这表明存在着不同的、基于进化的特定组织再生机制。所研究的再生过程的共有的、有序的步骤序列表明,有可能模拟这一极其重要的现象来繁殖多细胞生物。
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
Regenerative Medicine Research
Regenerative Medicine Research MEDICINE, RESEARCH & EXPERIMENTAL-
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