Use of αv Integrin Linked to GFP to Image Molecular Dynamics in Trafficking Cancer-Cell Emboli

Human osteosarcoma cells with an α_v integrin green fluorescent protein (GFP) fusion gene were previously established and imaged in vitro and in vivo. In the present study, we imaged the interaction of α_v integrin-GFP in osteosarcoma cells and collagen fibers in vascular-trafficking osteosarcoma emboli in nude mice. Human 143B osteosarcoma cells, expressing α_v integrin-GFP, were injected by a vascular route in an abdominal skin flap in nude mice. Osteosarcoma cells were fluorescently imaged in the epigastric cranialis vein in the abdominal skin flap by confocal microscopy. Collagen fibers were imaged in reflectance mode. At early stages of tumor embolus-formation, cancer cells adhered firmly to each other, diffusely expressing α_v integrin-GFP. Two weeks after injection, collagen fiber scaffolds were visualized at the margins of tumor emboli or within them. Four weeks after injection, cancer cells invading from emboli were strongly expressing α_v integrin-GFP, and were aligned along collagen fibers. The results suggest α_v integrin and collagen fiber scaffolds are important for tumor embolus formation, which are potential seeds of metastasis. J. Cell. Biochem. 118: 26-30, 2017. © 2016 Wiley Periodicals, Inc.

3-dimensional tissue is formed from cancer cells in vitro on Gelfoam®, but not on Matrigel™

Cell and tissue culture can be performed on different substrates such as on plastic, in Matrigel™, and on Gelfoam(®), a sponge matrix. Each of these substrates consists of a very different surface, ranging from hard and inflexible, a gel, and a sponge-matrix, respectively. Folkman and Moscona found that cell shape was tightly coupled to DNA synthesis and cell growth. Therefore, the flexibility of a substrate is important for cells to maintain their optimal shape. Human osteosarcoma cells, stably expressing a fusion protein of α(v) integrin and green fluorescent protein (GFP), grew as a simple monolayer without any structure formation on the surface of a plastic dish. When the osteosarcoma cells were cultured within Matrigel™, the cancer cells formed colonies but no other structures. When the cancer cells were seeded on Gelfoam(®), the cells formed three-dimensional tissue-like structures. The behavior of 143B osteosarcoma cells on Gelfoam(®) in culture is remarkably different from those of these cells in monolayer culture or in Matrigel™. Tissue-like structures were observed only in Gelfoam(®) culture. The data in this report suggest a flexible structural substrate such as Gelfoam(®) provides a more in vivo-like culture condition than monolayer culture or Matrigel(TM) and that Matrigel(TM) does not result in actual three-dimensional culture.