SNX10 regulates osteoclastogenic cell fusion and osteoclast size in mice.

IF 5.1 1区 医学 Q1 ENDOCRINOLOGY & METABOLISM Journal of Bone and Mineral Research Pub Date : 2024-09-26 DOI:10.1093/jbmr/zjae125
Maayan Barnea-Zohar, Merle Stein, Nina Reuven, Sabina Winograd-Katz, Sooyeon Lee, Yoseph Addadi, Esther Arman, Jan Tuckermann, Benjamin Geiger, Ari Elson
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Abstract

Bone-resorbing osteoclasts (OCLs) are formed by differentiation and fusion of monocyte precursor cells, generating large multinucleated cells. Tightly regulated cell fusion during osteoclastogenesis leads to formation of resorption-competent OCLs, whose sizes fall within a predictable physiological range. The molecular mechanisms that regulate the onset of OCL fusion and its subsequent arrest are, however, largely unknown. We have previously shown that OCLs cultured from mice homozygous for the R51Q mutation in the vesicle trafficking-associated protein sorting nexin 10, a mutation that induces autosomal recessive osteopetrosis in humans and in mice, display deregulated and continuous fusion that generates gigantic, inactive OCLs. Fusion of mature OCLs is therefore arrested by an active, genetically encoded, cell-autonomous, and SNX10-dependent mechanism. To directly examine whether SNX10 performs a similar role in vivo, we generated SNX10-deficient (SKO) mice and demonstrated that they display massive osteopetrosis and that their OCLs fuse uncontrollably in culture, as do homozygous R51Q SNX10 (RQ/RQ) mice. OCLs that lack SNX10 exhibit persistent presence of DC-STAMP protein at their periphery, which may contribute to their uncontrolled fusion. To visualize endogenous SNX10-mutant OCLs in their native bone environment, we genetically labeled the OCLs of WT, SKO, and RQ/RQ mice with enhanced Green Fluorescent Protein (EGFP), and then visualized the 3D organization of resident OCLs and the pericellular bone matrix by 2-photon, confocal, and second harmonics generation microscopy. We show that the volumes, surface areas and, in particular, the numbers of nuclei in the OCLs of both mutant strains were on average 2-6-fold larger than those of OCLs from WT mice, indicating that deregulated, excessive fusion occurs in the mutant mice. We conclude that the fusion of OCLs, and consequently their size, is regulated in vivo by SNX10-dependent arrest of fusion of mature OCLs.

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SNX10 可调节小鼠破骨细胞的融合和破骨细胞的大小。
骨吸收破骨细胞(OCLs)是由单核细胞前体细胞分化融合形成的大型多核细胞。在破骨细胞生成过程中,严格调控的细胞融合会形成具有吸收能力的破骨细胞,其大小在可预测的生理范围内。然而,调控 OCL 融合开始和随后停止的分子机制在很大程度上还不为人所知。我们之前已经证明,从囊泡运输相关蛋白分选 nexin 10(一种在人类和小鼠中诱发常染色体隐性骨质软化症的突变基因)发生 R51Q 突变的同源小鼠中培养出的 OCL 显示出失调和持续的融合,从而产生巨大的、无活性的 OCL。因此,成熟 OCL 的融合是通过一种活跃的、基因编码的、细胞自主的和依赖 SNX10 的机制来阻止的。为了直接检验 SNX10 是否在体内发挥类似的作用,我们产生了 SNX10 缺失(SKO)小鼠,结果表明它们表现出大量骨质坏死,其 OCLs 在培养过程中会不受控制地融合,同型 R51Q SNX10(RQ/RQ)小鼠也是如此。缺乏SNX10的OCL外围持续存在DC-STAMP蛋白,这可能是导致其无法控制融合的原因。为了观察原生骨环境中的内源性 SNX10 突变 OCL,我们用 EGFP 对野生型、SKO 和 RQ/RQ 小鼠的 OCL 进行了基因标记,然后通过双光子、共聚焦和二次谐波发生显微镜观察了常驻 OCL 和细胞外骨基质的三维组织。我们发现,两个突变品系的 OCL 的体积、表面积,尤其是细胞核的数量,平均比野生型小鼠的 OCL 大 2-6 倍,这表明突变小鼠体内发生了失调的过度融合。我们的结论是,OCLs 的融合及其大小在体内受 SNX10 依赖性抑制成熟 OCLs 融合的调节。
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来源期刊
Journal of Bone and Mineral Research
Journal of Bone and Mineral Research 医学-内分泌学与代谢
CiteScore
11.30
自引率
6.50%
发文量
257
审稿时长
2 months
期刊介绍: The Journal of Bone and Mineral Research (JBMR) publishes highly impactful original manuscripts, reviews, and special articles on basic, translational and clinical investigations relevant to the musculoskeletal system and mineral metabolism. Specifically, the journal is interested in original research on the biology and physiology of skeletal tissues, interdisciplinary research spanning the musculoskeletal and other systems, including but not limited to immunology, hematology, energy metabolism, cancer biology, and neurology, and systems biology topics using large scale “-omics” approaches. The journal welcomes clinical research on the pathophysiology, treatment and prevention of osteoporosis and fractures, as well as sarcopenia, disorders of bone and mineral metabolism, and rare or genetically determined bone diseases.
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