SRC regulates actin dynamics and invasion of malignant glial cells in three dimensions.

Malignant glioma is the major brain tumor in adults and has a poor prognosis. The failure to control invasive cell subpopulations may be the key reason for local glioma recurrence after radical tumor resection and may contribute substantially to the failure of the other treatment modalities such as radiation therapy and chemotherapy. As a model for this invasion, we have implanted spheroids from a human glioma cell line (U251) in three-dimensional collagen type I matrices, which these cells readily invade. We first observed that the Src family kinase-specific pharmacologic inhibitors PP2 and SU6656 significantly inhibited the invasion of the cells in this assay. We confirmed this result by showing that expression of two inhibitors of Src family function, dominant-negative-Src and CSK, also suppressed glioma cell invasion. To characterize this effect at the level of the cytoskeleton, we used fluorescent time-lapse microscopy on U251 cells stably expressing a YFP-actin construct and observed a rapid change in actin dynamics following addition of PP2 in both two-dimensional and three-dimensional cultures. In monolayer cultures, PP2 caused the disappearance of peripheral membrane ruffles within minutes. In three-dimensional cultures, PP2 induced the loss of actin bursting at the leading tip of the invadopodium. The inhibition of Src family activity is thus a potential therapeutic approach to treat highly invasive malignant glioma.

Evidence for a secreted chemorepellent that directs glioma cell invasion.

Secreted chemotropic cues guide the migration of neuronal and glial cell precursors during neural development. It is not known if chemotropism contributes to directing the invasion of brain tissue by glioma cells. A model system has been developed that allows quantification of invasive behavior using gliomas spheroids embedded in collagen gels. Here we provide evidence that glioma spheroids secrete a chemorepellent factor(s) that directs cells away from the spheroid and into the collagen matrix. The relationship between total invasion, cell number, and implantation distance suggests that glioma cells respond to a gradient of the chemorepellent cue(s) that is well established at 48 h. C6 astrocytoma cells normally invade the collagen at an angle perpendicular to the spheroid edge. In contrast, an adjacent spheroid causes cells to turn away from their normal trajectory and slow their rate of invasion. Astrocytoma cells are repelled by an adjacent glioma spheroid but rapidly infiltrate astrocyte aggregates, indicating that astrocytes do not express the repellent cue. Uniform concentrations of repellent factor(s) in spheroid conditioned medium overwhelm endogenous gradients and render glioma cells less able to exhibit this chemotropic response. Concentration gradients of spheroid conditioned medium in cell migration assays also demonstrate the chemorepellent cue(s)'s tropic effect. Our findings indicate that glioma spheroids produce a secreted diffusible cue(s) that promotes glioma cell invasion. Identification of this factor(s) may advance current therapies that aim to limit tumor cell invasion.

Spheroid preparation from hanging drops: characterization of a model of brain tumor invasion.

BACKGROUND: The use of three-dimensional in vitro models of brain tumor invasion has provided a system for reconstructing some of the cellular microenvironments present in the tumor mass. While spheroids of murine and human astrocytoma cells can be prepared using spinning cultures, spheroid preparation using many cell lines is not amenable to this method. We have developed a reproducible system of creating implantable spheroids that is applicable to different cell lines, and is independent of cell line characteristics. METHODS: For murine and human brain tumor cell lines, 20 microl drops containing predetermined cell concentrations were suspended from the lids of culture dishes and the resulting aggregates were transferred to culture dishes base-coated with agar. The two-dimensional aggregates formed three-dimensional spheroids on the non-permissive agar substrate, and were then implanted into three-dimensional collagen I gels and the invasive activity assessed. The invasive activity of C6 and U251 spheroids prepared by hanging drops was compared to spheroids of similar size prepared by spinner culture. RESULTS: The hanging drop method produced implantable spheroids capable of sustained invasion using all cell lines tested. Most cell lines required initial hanging drop cell concentrations of 45,000 cells/drop, suspension times of 48, and 72 h on agar. C6 spheroids had the same invasive capacity regardless of the model utilized, however U251 spheroids produced by hanging drops had significantly increased invasion compared to those prepared by spinner culture. Only spheroids prepared by spinner culture showed histological evidence of central necrosis. CONCLUSIONS: This model represents a reproducible approach to the preparation of implantable spheroids with invasive potential that compares with those produced using spinner culture. The use of hanging drops broadens the applicability of three-dimensional in vitro assays examining brain tumor invasiveness.