Melanoma Spheroids Research Articles

Release of Vascular Endothelial Growth Factor from a Human Melanoma Cell Line, WM35, Is Induced by Hypoxia but Not Ultraviolet Radiation and Is Potentiated by Activated Ras Mutation

Angiogenesis, the formation of blood vessels, is a major factor influencing tumor growth and metastatic capacity, and VEGF is the prototype angiogenic factor. VEGF expression is also found in the dermis and tumor stroma during the course of melanoma progression. Various oncogenes such as c-Src, v-Raf, and Ras, and multiple environmental stimuli, including hypoxia and ultraviolet radiation (UVR), can regulate VEGF expression under certain conditions. We have constructed several cell lines from a radial growth phase, primary human melanoma cell line, WM35. We have stably transfected WM35 cells with mutant activated H-ras, N-ras, dominant negative p53, or empty vector. In this report, we determined how VEGF expression and release from these melanoma cell lines were affected by the following important factors associated with melanoma initiation and progression: hypoxia, UVR, activated Ras, dominant negative p53, and culture conditions mimicking radial growth phase melanoma (monolayer culture) and vertical growth phase melanoma (spheroid culture). We found that hypoxia, but not UVR, up-regulates VEGF mRNA expression and protein release in these melanoma cells. In addition, activated Ras and dominant negative p53 enhances the hypoxia-induced VEGF protein release. We propose that hypoxia-induced VEGF release promotes tumor progression, especially in melanomas with Ras or p53 mutations.

Fractal dimension of K1735 mouse melanoma clones and spheroid invasion in vitro.

An in vitro tumour-host confrontation method to investigate the invasion behaviour of cancer has been applied to K1735 mouse melanomas. Fluorescently labelled spheroids of cancer cells and host cells were confronted and the temporal course of cancer invasion into the host was investigated using confocal laser scanning microscopy. To improve the quantitative data of this method, the boundary images of the fluorescently labelled confrontation pairs were treated as fractals. The physical and mathematical framework for determination of the fractal capacity dimension is widely used in biology and medicine and has proved to be a very useful tool for describing the cancer invasion process. The fractal capacity dimension determination was carried out by dilation of the binary boundaries of the objects, which were treated as an estimate of the Minkowski-Bouligand dimension. The fractal dimension correlated well with the degree of invasion of the K1735-M2 clone. Control experiments, with host-host confrontations and various K1735 clones with reduced invasiveness, support these results.

Oxygen consumption rate and mitochondrial density in human melanoma monolayer cultures and multicellular spheroids

Rate of oxygen consumption per cell has been shown in previous studies to decrease with increasing depth in the viable rim of multicellular spheroids initiated from rodent cells, human colon-carcinoma cells, and human glioma cells, due to progressive accumulation of quiescent cells during spheroid growth. The purpose of our work was to determine oxygen-consumption profiles in human melanoma spheroids. Monolayer cultures of 4 lines (BEX-c, COX-c, SAX-c, and WIX-c) and spheroid cultures of 2 lines (BEX-c and WIX-c) were subjected to investigation. Spheroids were initiated from monolayer cell cultures and grown in spinner flasks. Rate of oxygen consumption was measured with a Clarke-type electrode. Mitochondrial density was determined by stereological analysis of transmission electron micrographs. Thickness of viable rim and cell packing density were assessed by light microscopy of central spheroid sections. Cell-cycle distribution was determined by analysis of DNA histograms measured by flow cytometry. Cell volume was measured by an electronic particle counter. Rate of oxygen consumption per cell differed by a factor of approximately 1.8 between the 4 cell lines and was positively correlated to total volume of mitochondria per cell. Rate of oxygen consumption per cell and total volume of mitochondria per cell were equal for monolayer cell cultures, 600-microns spheroids and 1,200-microns spheroids of the same line. Mitochondrial density and location in the cell did not differ between cells at the spheroid surface, in the middle of the viable rim and adjacent to the central necrosis. Cell-cycle distribution, cell volume, and cell-packing density in the outer and inner halves of the viable rim were not significantly different. Consequently, the rate of oxygen consumption per cell in inner regions of the viable rim was probably equal to that at the spheroid surface, suggesting that oxygen diffusion distances may be shorter in some melanomas than in many other tumor types.

Penetration and binding of L- and D-carboranylalanine in human melanoma spheroids.

The principle of boron neutron capture therapy (BNCT) is that a cell-specific 10B-containing substance binds to tumour cells and irradiation with thermal neutrons is performed when the 10B concentration, in relation to the levels in critical normal tissues, is at a maximum. Some boron compounds have recently been proposed for BNCT of malignant melanomas; the synthesized L- and D- forms of carboranylalanine and the previously tested compound L-p-boronophenylalanine are candidates. Human melanoma, IGR1, spheroids were used as models of melanoma nodules in this study. The spheroids developed central necrosis when they were about 480 microns in diameter and the volume doubling time was 2.6 +/- 0.3 days. The tritiated thymidine labelling index decreased rapidly as a function of distance from the periphery and was, at a depth of 175 microns, close to zero. The penetration patterns showed, for L- and D-carboranylalanine and L-p-boronophenylalanine, a homogeneous distribution of 10B throughout the spheroids by 5 min. L-Carboranylalanine gave a more or less even binding of 10B throughout the spheroids and large amounts were present also in the central necrotic regions. D-Carboranylalanine also gave a homogeneous 10B binding in the viable cell layers while the binding in the central necrotic area was lower and a similar, but somewhat lower, binding was found for L-p-boronophenylalanine. Thus, there were no penetration barriers for the boron compounds and binding of 10B was found also in the deeper regions of the viable cell layers. The results showed that the new carboranylalanine compounds are of interest for further analysis, including toxicological and pharmacological studies in vivo.

Radiosensitivity of human melanoma spheroids influenced by growth rate

The radiosensitivity of human melanoma cell line BRO was investigated using the multicellular tumor spheroid system. By adding different concentrations of bovine serum to the tissue culture medium, two different growth rates could be obtained. Spheroids (200–250 μm) were irradiated with graded single doses of X rays (2–8 Gy). The radiation response was quantified using specific growth delay, clonogenic cell survival, and spheroid cure. All three assays showed a growth rate dependent radiation response. At both growth rates the spheroid growth fraction and critical cell number were of comparable magnitude. There was a strong correlation between the radiation response of spheroid regenerating units and clonogenic cells from dispersed spheroids. Cell survival curves indicated a decreased ability to accumulate sublethal damage in fast growing multicellular tumor spheroids. From this study it appears that the intrinsic radiosensitivity of human melanoma cell line BRO cells in multicellular spheroids is modulated by intratumoral conditions.

Quantitative Evaluation of Melanoma Cell Invasion in Three-Dimensional Confrontation Cultures In Vitro Using Automated Image Analysis

Tumor invasion is a crucial feature of tumor growth in vivo. Confrontation cultures of multicellular melanoma spheroids and embryonic chick heart fragments provide a model for invasive growth in vitro. We have developed an image analysis method, which facilitates the objective measurement of tumor cell invasion in this model. Cryostat sections of confrontation cultures were immunohistochemically stained with an antiserum directed against the stromal component for automated recognition of the stroma tissue. The slides were automatically processed by a grey level based computerized image analysis system. On Spearman's rank correlation test, 25 out of 39 parameters correlated with the reference value of invasion, which was derived from the subjective evaluation of five independent observers. Two parameters combining the stroma margin and the total amount of stroma tissue completely reproduced the judgement of the morphologists in our test set. The quantitative evaluation of tumor invasion in vitro by automated image analysis may be helpful in pharmacologic and pathogenetic studies of tumor growth.