Prenatal murine skeletogenesis partially recovers from absent skeletal muscle as development progresses.

IF 3.2 3区 医学 Q3 CELL & TISSUE ENGINEERING
V Sotiriou, Y Huang, S Ahmed, H Isaksson, N C Nowlan
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Abstract

Skeletal muscle contractions are critical for normal skeletal growth and morphogenesis but it is unclear how the detrimental effects of absent muscle on the bones and joints change over time. Joint shape and cavitation as well as rudiment length and mineralisation were assessed in multiple rudiments at two developmental stages [Theiler stage (TS)24 and TS27] in the splotch-delayed "muscle-less limb" mouse model and littermate controls. Chondrocyte morphology was quantified in 3D in the distal humerus at the same stages. As development progressed, the effects of absent muscle on all parameters except for cavitation become less severe. All major joints in muscle-less limbs were abnormally shaped at TS24, while, by TS27, most muscle-less limb joint shapes were normal or nearly normal. In contrast, any joints that were fused at TS24 did not cavitate by TS27. At TS24, chondrocytes in the distal humerus were significantly smaller in the muscle-less limbs than in controls, while by TS27, chondrocyte volume was similar between the two groups, offering a cell-level mechanism for the partial recovery in shape of muscle-less limbs. Mineralisation showed the most pronounced changes over gestation. At TS24, all muscle-less rudiments studied had less mineralisation than the controls, while at TS27, muscle-less limb rudiments had mineralisation extents equivalent to controls. In conclusion, the effects of muscle absence on prenatal murine skeletogenesis reduced in severity over gestation. Understanding how mammalian bones and joints continue to develop in an environment with abnormal fetal movements provides insights into conditions including hip dysplasia and arthrogryposis.

随着发育的进展,产前小鼠骨骼生成部分从缺失的骨骼肌中恢复。
骨骼肌收缩对正常骨骼生长和形态发生至关重要,但目前尚不清楚肌肉缺失对骨骼和关节的有害影响如何随时间变化。在斑点延迟的“无肌肉肢体”小鼠模型和窝鼠对照中,在两个发育阶段[Theiler阶段(TS)24和TS27]的多个雏形中评估了关节形状和空化以及雏形长度和矿化。在同一阶段,对肱骨远端软骨细胞形态进行三维量化。随着发育的进展,肌肉缺失对除空化外的所有参数的影响变得不那么严重。在TS24时,无肌肢体各主要关节形态均出现异常,到TS27时,无肌肢体关节形态大部分正常或接近正常。相比之下,任何在TS24融合的关节都没有被TS27空化。在TS24时,无肌肢体的肱骨远端软骨细胞明显小于对照组,而在TS27时,两组之间的软骨细胞体积相似,为无肌肢体的部分形状恢复提供了细胞水平的机制。矿化在妊娠期表现出最明显的变化。在TS24时,所有研究的无肌肉基础都比对照组矿化程度低,而在TS27时,无肌肉肢体基础的矿化程度与对照组相当。总之,肌肉缺失对产前小鼠骨骼形成的影响在妊娠期间的严重程度有所降低。了解哺乳动物骨骼和关节如何在胎儿运动异常的环境中继续发育,有助于了解髋关节发育不良和关节挛缩等疾病。
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来源期刊
European cells & materials
European cells & materials 生物-材料科学:生物材料
CiteScore
6.00
自引率
6.50%
发文量
55
审稿时长
1.5 months
期刊介绍: eCM provides an interdisciplinary forum for publication of preclinical research in the musculoskeletal field (Trauma, Maxillofacial (including dental), Spine and Orthopaedics). The clinical relevance of the work must be briefly mentioned within the abstract, and in more detail in the paper. Poor abstracts which do not concisely cover the paper contents will not be sent for review. Incremental steps in research will not be entertained by eCM journal.Cross-disciplinary papers that go across our scope areas are welcomed.
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