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利用南极小须鲸(Balaenoptera bonaerensis)的桡骨研究无骨髓腔鲸类长骨的发育过程和内稳态。

Developmental process and homeostasis of whale long bones lacking medullary cavity using the radius of Antarctic minke whales, Balaenoptera bonaerensis.

作者信息

Izu Yayoi, Ishikawa Hajime, Soeta Satoshi

机构信息

Laboratory of Comparative Cellular Biology, Nippon Veterinary and Life Science University, Tokyo, Japan.

Department of Laboratory Animal Science, The Faculty of Veterinary Medicine, Okayama University of Science, Ehime, Japan.

出版信息

J Vet Med Sci. 2025 Apr 1;87(4):336-348. doi: 10.1292/jvms.24-0430. Epub 2025 Feb 13.

DOI:10.1292/jvms.24-0430
PMID:39938892
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11964860/
Abstract

Whales, Earth's largest mammals and live in water, form long bones without marrow cavities. Body size and mechanical stress impact the bone formation and homeostasis, yet the specific developmental processes remain unclear. Here, we demonstrate the histological changes in whale long bones from fetal to mature stages using the radius of Antarctic minke whales in comparison with domestic cats and cattle. Through intramembranous ossification and remodeling, long bones enlarge their diameters and marrow cavities, respectively. It has been demonstrated that relatively small animals, such as cats, develop the radially arranged "primary osteonal bone," whereas larger animals, including cattle, form "laminar bone" initiated by the formation of circumferentially arranged hypercalcified lines during intramembranous ossification. Here, we demonstrated that whales form laminar bones, transitioning from circumferential in the fetus to radial during postnatal growth, and thereafter cortical bones become compact. After maturation, bone remodeling primarily occurs in the lateral and medial regions of long bones, while the bone layers in the cranial-caudal region never undergo complete resorption. As a result, these layers remain as a wire-netting structure composed of thin bone layers, without forming an open medullary cavity. These data suggest that whales enlarge their long bones through laminar bone formation and form long bones without a marrow cavity by regulating bone resorption areas during the developmental process and in maintaining homeostasis.

摘要

鲸鱼是生活在水中的地球上最大的哺乳动物,其长骨没有骨髓腔。身体大小和机械应力会影响骨骼形成和体内平衡,但具体的发育过程仍不清楚。在这里,我们以南极小须鲸的桡骨为例,与家猫和牛进行比较,展示了鲸鱼长骨从胎儿期到成熟期的组织学变化。通过膜内成骨和重塑,长骨分别增大其直径和骨髓腔。已经证明,相对较小的动物,如家猫,会发育出径向排列的“初级骨单位骨”,而较大的动物,包括牛,在膜内成骨过程中会形成由周向排列的高度钙化线的形成引发的“板层骨”。在这里,我们证明鲸鱼形成板层骨,从胎儿期的周向骨过渡到出生后生长期间的径向骨,此后皮质骨变得致密。成熟后,骨重塑主要发生在长骨的外侧和内侧区域,而头尾区域的骨层从未经历完全吸收。结果,这些层保留为由薄骨层组成的铁丝网结构,没有形成开放的髓腔。这些数据表明,鲸鱼通过板层骨形成来增大其长骨,并通过在发育过程中调节骨吸收区域和维持体内平衡来形成没有骨髓腔的长骨。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/0743/11964860/3784747b5d86/jvms-87-336-g011.jpg
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