An Orthotopic Model for Human Uveal Melanoma in SCID Mice

Abstract

The microcirculation of primary uveal melanomas, their precursors, and their metastases is distinctive. Medium-sized and even large primary uveal melanomas typically lack significant zones of necrosis, suggesting that either these tumors are relatively well perfused or they are capable of growth in a severely blood-deprived microenvironment. In addition to normal choroidal vessels that are incorporated into nevi and most primary uveal melanomas, aggressive primary and metastatic uveal melanomas tend to contain patterns of extracellular matrix that surround spheroidal or cylindrical packets of tumor cells. Some components of this branching, looping, and interconnected system of matrix may be perfused. It is now known that the generation of this patterning is a characteristic of genetically dysregulated melanoma cells (nonaggressive tumor cells do not form these patterns and melanomas lacking branching, looping, or interconnected matrix patterns tend to follow a relatively indolent course). We developed an orthotopic model of an aggressive human uveal melanoma by injecting suspensions of the primary human choroidal melanoma cell line (OCM1) into the subretinal space of one eye of 20 SCID mice. All mice were examined daily for tumor growth and tumors developed in every eye within 3 weeks of injection. The tumors were characterized by extraocular extension and the development of looping matrix patterns characteristic of those seen in aggressive human uveal melanoma. As in human uveal melanomas, these patterns were perfused by blood in areas. The orthotopic injection of human uveal melanoma cells into the SCID mouse eye generates a model reproducing the matrix-associated microcirculatory patterns of aggressive primary human uveal melanomas. This model can be used to explore the molecular pathogenesis and modulation of this novel circulation in vivo, to facilitate our understanding of the blood flow to these tumors providing insight into perfusion and drug delivery, to enable testing of pharmacologic modulation of pattern formation and intratumoral blood flow, and to refine noninvasive methods such as confocal scanning laser ophthalmoscopy to detect the presence of these patterns by which ophthalmologists might assess the biological behavior of tumors as noninvasive substitute for biopsy.