蝴蝶眼斑颜色图案的形成需要蛹翅上皮细胞与细胞外物质的物理接触,以传播形态发生信号。

Q2 Biochemistry, Genetics and Molecular Biology
Joji M Otaki
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引用次数: 0

摘要

背景:蝴蝶翅膀上眼斑颜色图案的形成对物理损伤、物理扭曲以及蛹期翅膀上皮组织表面与物质的物理接触非常敏感。接触介导的眼斑颜色图案变化可能意味着细胞外基质在形态发生信号传播中的发育作用。在此,我们研究了眼点对各种接触材料的反应,重点是蓝三色堇蝴蝶(Junonia orithya)的后翅后眼点:结果:与各种材料(包括非生物材料和生物材料)接触都会引起眼点扩大、缩小或眼点大小不变,而且每种材料都有其独特的反应特征。例如,硅胶玻璃纸几乎总能诱导眼斑明显缩小,而玻璃板最常诱导眼斑扩大,塑料板一般不会产生任何变化。这里测试的生物材料(纤连蛋白、聚赖氨酸、I 型胶原蛋白和明胶)导致了不同的反应,但聚赖氨酸引起的扩大情况更多,与玻璃板类似。从材料的化学成分无法预测材料的反应曲线,但与材料表面的水接触角(憎水性)显著相关,这表明材料的表面物理化学是眼斑大小的决定因素。当预期眼点的近端覆盖了可缩小尺寸的材料(硅胶玻璃纸),远端和组织器覆盖了很少引起尺寸缩小的材料(塑料薄膜)时,眼点近端与远端相比尺寸缩小了,这表明硅胶玻璃纸抑制了信号传播,但没有抑制组织器的活动:这些结果表明,组织器发出的形态发生信号需要与适当的疏水表面进行物理接触才能正常传播。上皮顶端表面与对立面的结合可能为信号传播提供了机械支持。除了传统的分子形态发生器之外,根据蝶翅颜色图案形成的变形假说,机械传播的上皮细胞机械变形有可能作为一种非分子形态发生器,诱导随后的分子变化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Butterfly eyespot color pattern formation requires physical contact of the pupal wing epithelium with extracellular materials for morphogenic signal propagation.

Butterfly eyespot color pattern formation requires physical contact of the pupal wing epithelium with extracellular materials for morphogenic signal propagation.

Butterfly eyespot color pattern formation requires physical contact of the pupal wing epithelium with extracellular materials for morphogenic signal propagation.

Butterfly eyespot color pattern formation requires physical contact of the pupal wing epithelium with extracellular materials for morphogenic signal propagation.

Background: Eyespot color pattern formation on butterfly wings is sensitive to physical damage and physical distortion as well as physical contact with materials on the surface of wing epithelial tissue at the pupal stage. Contact-mediated eyespot color pattern changes may imply a developmental role of the extracellular matrix in morphogenic signal propagation. Here, we examined eyespot responses to various contact materials, focusing on the hindwing posterior eyespots of the blue pansy butterfly, Junonia orithya.

Results: Contact with various materials, including both nonbiological and biological materials, induced eyespot enlargement, reduction, or no change in eyespot size, and each material was characterized by a unique response profile. For example, silicone glassine paper almost always induced a considerable reduction, while glass plates most frequently induced enlargement, and plastic plates generally produced no change. The biological materials tested here (fibronectin, polylysine, collagen type I, and gelatin) resulted in various responses, but polylysine induced more cases of enlargement, similar to glass plates. The response profile of the materials was not readily predictable from the chemical composition of the materials but was significantly correlated with the water contact angle (water repellency) of the material surface, suggesting that the surface physical chemistry of materials is a determinant of eyespot size. When the proximal side of a prospective eyespot was covered with a size-reducing material (silicone glassine paper) and the distal side and the organizer were covered with a material that rarely induced size reduction (plastic film), the proximal side of the eyespot was reduced in size in comparison with the distal side, suggesting that signal propagation but not organizer activity was inhibited by silicone glassine paper.

Conclusions: These results suggest that physical contact with an appropriate hydrophobic surface is required for morphogenic signals from organizers to propagate normally. The binding of the apical surface of the epithelium with an opposing surface may provide mechanical support for signal propagation. In addition to conventional molecular morphogens, there is a possibility that mechanical distortion of the epithelium that is propagated mechanically serves as a nonmolecular morphogen to induce subsequent molecular changes, in accordance with the distortion hypothesis for butterfly wing color pattern formation.

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来源期刊
BMC Developmental Biology
BMC Developmental Biology 生物-发育生物学
自引率
0.00%
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0
审稿时长
>12 weeks
期刊介绍: BMC Developmental Biology is an open access, peer-reviewed journal that considers articles on the development, growth, differentiation and regeneration of multicellular organisms, including molecular, cellular, tissue, organ and whole organism research.
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