Molecular anatomy of emerging Xenopus left-right organizer at successive developmental stages.

IF 2 3区 生物学 Q2 ANATOMY & MORPHOLOGY Developmental Dynamics Pub Date : 2024-06-27 DOI:10.1002/dvdy.722
Natalia Petri, Alexandra Vetrova, Nikoloz Tsikolia, Stanislav Kremnyov
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Abstract

Background: Vertebrate left-right symmetry breaking is preceded by formation of left-right organizer. In Amphibian, this structure is formed by gastrocoel roof plate, which emerges from superficial suprablastoporal cells. GRP is subdivided into medial area, which generates leftward flow by rotating monocilia and lateral Nodal1 expressing areas, which are involved in sensing of the flow. After successful symmetry breaking, medial cells are incorporated into a deep layer where they contribute to the axial mesoderm, while lateral domains join somitic mesoderm.

Results: Here, we performed detailed analysis of spatial and temporal gene expression of important markers and the corresponding morphology of emerging GRP. Endodermal marker Sox17 and markers of superficial mesoderm display complementary patterns at all studied stages. At early stages, GRP forms Tekt2 positive epithelial domain clearly separated from underlying deep layers, while at later stages, this separation disappears. Marker of early somitic mesoderm MyoD1 was absent in emerging GRP and was induced together with Nodal1 during early neurulation. Decreasing morphological separation is accompanied by lateral to medial covering of GRP by endoderm.

Conclusion: Our data supports continuous link between superficial mesoderm at the start of gastrulation and mature GRP and suggests late induction of somitic fate in lateral GRP.

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在连续发育阶段新出现的章鱼左右组织器的分子解剖。
背景:脊椎动物左右对称的打破是在左右组织器形成之前发生的。在两栖动物中,这种结构由胃肠顶板形成,胃肠顶板由浅表的口上细胞产生。胃肠顶板细分为内侧区域和外侧 Nodal1 表达区域,内侧区域通过旋转单纤毛产生向左的流动,外侧区域则参与流动的感应。在成功打破对称后,内侧细胞被纳入深层,在那里它们为轴中胚层做出贡献,而外侧区域则加入体细胞中胚层:在此,我们详细分析了重要标记的时空基因表达以及新出现的 GRP 的相应形态。在所有研究阶段,内胚层标记 Sox17 和表层中胚层标记显示出互补模式。在早期阶段,GRP 形成的 Tekt2 阳性上皮域与下层深部明显分离,而在晚期阶段,这种分离消失了。早期体细胞中胚层的标志物 MyoD1 在新出现的 GRP 中缺失,在早期神经形成过程中与 Nodal1 一起被诱导。伴随着形态分离的减少,内胚层从外侧向内侧覆盖 GRP:结论:我们的数据支持胃形成初期表层中胚层与成熟 GRP 之间的连续联系,并表明侧向 GRP 中体细胞命运的后期诱导。
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来源期刊
Developmental Dynamics
Developmental Dynamics 生物-发育生物学
CiteScore
5.10
自引率
8.00%
发文量
116
审稿时长
3-8 weeks
期刊介绍: Developmental Dynamics, is an official publication of the American Association for Anatomy. This peer reviewed journal provides an international forum for publishing novel discoveries, using any model system, that advances our understanding of development, morphology, form and function, evolution, disease, stem cells, repair and regeneration.
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