Differential effects of type I, III, and V collagens on mammary epithelial development in vitro

IF 2.5 4区生物学 Q1 ANATOMY & MORPHOLOGY

Tissue & cell Pub Date : 2025-09-29 DOI:10.1016/j.tice.2025.103165

Kazuki Ninomiya, Yuki Yasui, Liang Han, Tamaki Uehara, Takanori Nishimura, Ken Kobayashi

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引用次数: 0

Abstract

During pregnancy, mammary epithelial cells (MECs) and myoepithelial cells proliferate and develop ductal networks and alveolar bud structures that extend into the surrounding stroma. In the mammary stroma, type I, III, and V collagens form fibrillar structures and dynamically alter their expression patterns. While type I collagen is known to influence ductal elongation and alveolar bud formation, the specific roles of type III and V collagen in mammary epithelial morphogenesis remain unclear. This study aimed to create three-dimensional (3D) cultures by embedding mammary organoids in Matrigel with type I, III, and V collagen to explore their distinct roles in mammary duct elongation and alveolar bud formation in vitro. We prepared 3D organoid cultures of MECs and myoepithelial cells within type I, III, and V collagen gels to reproduce ductal elongation and alveolar bud formation. Type I collagen promoted ductal elongation and alveolar bud formation in a density-dependent manner. In contrast, type III collagen suppressed these morphogenetic processes compared to type I collagen. Type V collagen induced the formation of narrow ducts and swollen alveolar-like structures. Type III and V collagens reduced cell proliferation and attenuated Akt and ERK signaling relative to type I collagen. Myoepithelial cells were absent from ductal and alveolar regions in type I and V collagen gels but encircled the organoids in type III collagen gels. Scanning electron microscopy revealed distinct fibrillar architectures among the three collagen types. These findings demonstrate that collagens I, III, and V exert distinct regulatory effects on mammary epithelial morphogenesis during pregnancy.

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I型、III型和V型胶原对乳腺上皮细胞体外发育的不同影响。

在怀孕期间，乳腺上皮细胞（MECs）和肌上皮细胞增殖并形成导管网络和肺泡芽结构，并延伸到周围的基质中。在乳腺间质中，I型、III型和V型胶原形成纤维状结构并动态改变其表达模式。虽然已知I型胶原会影响导管伸长和肺泡芽形成，但III型和V型胶原在乳腺上皮形态发生中的具体作用尚不清楚。本研究旨在通过将乳腺类器官与I型、III型和V型胶原蛋白包埋在基质中建立三维（3D）培养，探索它们在体外乳腺导管延伸和肺泡芽形成中的独特作用。我们在I型、III型和V型胶原凝胶中制备了MECs和肌上皮细胞的三维类器官培养物，以复制导管伸长和肺泡芽形成。I型胶原蛋白以密度依赖的方式促进导管伸长和肺泡芽的形成。相比之下，与I型胶原相比，III型胶原抑制了这些形态发生过程。V型胶原诱导狭窄导管的形成和肺泡样结构的肿胀。与I型胶原相比，III型和V型胶原可降低细胞增殖，减弱Akt和ERK信号。在I型和V型胶原凝胶中，导管和肺泡区没有肌上皮细胞，而在III型胶原凝胶中，肌上皮细胞环绕在类器官周围。扫描电子显微镜显示三种胶原蛋白类型中不同的纤维结构。这些发现表明，胶原I、III和V对妊娠期间乳腺上皮形态发生具有不同的调节作用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Tissue & cell 医学-解剖学与形态学

CiteScore

3.90

自引率

0.00%

发文量

234

期刊介绍： Tissue and Cell is devoted to original research on the organization of cells, subcellular and extracellular components at all levels, including the grouping and interrelations of cells in tissues and organs. The journal encourages submission of ultrastructural studies that provide novel insights into structure, function and physiology of cells and tissues, in health and disease. Bioengineering and stem cells studies focused on the description of morphological and/or histological data are also welcomed. Studies investigating the effect of compounds and/or substances on structure of cells and tissues are generally outside the scope of this journal. For consideration, studies should contain a clear rationale on the use of (a) given substance(s), have a compelling morphological and structural focus and present novel incremental findings from previous literature.