Weaver V M, Fischer A H, Peterson O W, Bissell M J
Ernest Orlando Lawrence Berkeley National Laboratory, Berkeley, CA 94720, USA.
Biochem Cell Biol. 1996;74(6):833-51. doi: 10.1139/o96-089.
The extracellular matrix (ECM) is a dominant regulator of tissue development and homeostasis. "Designer microenvironments" in culture and in vivo model systems have shown that the ECM regulates growth, differentiation, and apoptosis in murine and human mammary epithelial cells (MEC) through a hierarchy of transcriptional events involving the intricate interplay between soluble and physical signaling pathways. Furthermore, these studies have shown that these pathways direct and in turn are influenced by the tissue structure. Tissue structure is directed by the cooperative interactions of the cell-cell and cell-ECM pathways and can be modified by stromal factors. Not surprisingly then, loss of tissue structure and alterations in ECM components are associated with the appearance and dissemination of breast tumors, and malignancy is associated with perturbations in cell adhesion, changes in adhesion molecules, and a stromal reaction. Several lines of evidence now support the contention that the pathogenesis of breast cancer is determined (at least in part) by the dynamic interplay between the ductal epithelial cells, the microenvironment, and the tissue structure (acini). Thus, to understand the mechanisms involved in carcinogenesis, the role of the microenvironment (ECM as well as the stromal cells) with respect to tissue structure should be considered and studied. Towards this goal, we have established a unique human MEC model of tumorigenesis, which in concert with a three-dimensional assay, recapitulates many of the genetic and morphological changes observed in breast in cancer in vivo. We are currently using this system to understand the role of the microenvironment and tissue structure in breast cancer progression.
细胞外基质(ECM)是组织发育和内环境稳态的主要调节因子。培养和体内模型系统中的“设计微环境”表明,ECM通过一系列转录事件调节小鼠和人乳腺上皮细胞(MEC)的生长、分化和凋亡,这些转录事件涉及可溶性和物理信号通路之间的复杂相互作用。此外,这些研究表明,这些通路起指导作用,反过来又受组织结构的影响。组织结构由细胞-细胞和细胞-ECM通路的协同相互作用决定,并可被基质因子改变。因此毫不奇怪,组织结构的丧失和ECM成分的改变与乳腺肿瘤的出现和扩散相关,而恶性肿瘤与细胞黏附的扰动、黏附分子的变化以及基质反应相关。现在有几条证据支持这样的观点,即乳腺癌的发病机制(至少部分)由导管上皮细胞、微环境和组织结构(腺泡)之间的动态相互作用决定。因此,为了理解致癌作用所涉及的机制,应该考虑并研究微环境(ECM以及基质细胞)相对于组织结构的作用。为了实现这一目标,我们建立了一种独特的人MEC肿瘤发生模型,该模型与三维分析相结合,概括了在体内乳腺癌中观察到的许多遗传和形态学变化。我们目前正在使用这个系统来理解微环境和组织结构在乳腺癌进展中的作用。