Human melanoma cells expressing the alphavbeta3 integrin are partially protected from necrotic cell death induced by dynamic matrix detachment.

Anchorage-independence is a hallmark of metastatic cancer cells. In previous studies we characterized a novel model for anchorage-independence employing dynamic matrix detachment (DMD) using rotation in low shear stress conditions. We observed that in contrast to the classical apoptosis-inducing static matrix detachment (SMD) model, the venous circulation-mimicking DMD model induced necrosis in transformed cells. In the current study we revisited the mechanism of DMD-induced cell death and evaluated the contribution of alphavbeta3 integrin overexpression in human melanoma cells to anchorage-independence in DMD. DMD cell culture induced primarily necrosis in the melanoma cells studied. alphavbeta3, but not the control related alphaIIbbeta3 integrin, could confer survival advantage in DMD. While apoptosis was unaffected, constitutive, unligated alphavbeta3 overexpression was associated with attenuation of necrosis in DMD. alphavbeta3 overexpressing melanoma cells manifested AKT activation that was independent of DMD conditions. Furthermore, while a small molecular inhibitor of AKT phosphorylation induced apoptosis in adherent cells, in DMD conditions it had no effect on cell outcome. Thus, alphavbeta3-overexpressing melanoma cells are partially protected from DMD-induced cell death in an apoptosis-independent mechanism. This finding may be one of the factors accounting for anchorage-independence in circulating metastatic melanoma cells.

A novel system to study adenovirus tropism to normal and malignant colon tissues.

We describe here a new organ culture system for the evaluation of viral tropism to colon carcinomas and normal colon tissues. Organ cultures of mouse and human colon retained viability for several days and thus facilitated studies of viral tropism. Two adenoviral vectors (AD) were compared in the study: AD5, that utilizes the CAR receptor, demonstrated poor infectivity to both normal and carcinoma tissues, while a capsid-modified-AD, recognizing haparan-sulfate receptor, demonstrated efficient infectivity of both tissues. Immunohistochemistry analysis demonstrated different viral tropism; while AD5 infected only the colon epithelia, the capsid-modified-adeno infected both the epithelia and mesothelial layers. To investigate other determinants in the tissue that influence viral tropism, human cancer tissues were pretreated with collagenase and infected with the AD viruses. Increased infectivity and altered tropism were noted in the treated tumor tissue. Taken together, this ex vivo system indicated that receptor utilization and extracellular-matrix components influence AD viral tropism in solid tissues.

Fibrin microbeads (FMB) as a 3D platform for kidney gene and cell therapy.

Cell and gene therapy may alter the outcome of renal diseases, such as hereditary nephropathies, acute and chronic glomerulonephritis and allograft nephropathy. However, owing to blockade of many viral and cellular vehicles by the complex glomerular architecture, the exact nature of gene and cell delivery into specific renal compartments remains currently unknown. To study the interaction of viral vectors with a variety of renal cells and mesenchymal stem cells (MSCs), we employed a novel biological three-dimensional (3D) matrix comprised of fibrin microbeads (FMB) in comparison to monolayer cell culture. Our studies showed that renal cells of both established and primary lines can grow efficiently on FMB and differentiate into epithelial structures, as shown by electron microscopy. Gene delivery into renal cells in 3D was observed for several viral vectors and growth in 3D on FMB conferred resistance to renal cancer cells in the context of oncolytic adenoviruses. Finally, MSCs from various rodent species attached to FMB, grew robustly, survived for several weeks and could efficiently be transduced on FMB. Thus, on the basis of growth, differentiation and transduction of renal cells in 3D, FMB emerge as a novel 3D cellular microenvironment that differs substantially from monolayer cell cultures.