Library

Notes: Abstract Since the extracellular matrix (ECM) has a role in regulating cell proliferation it has been hypothesized that unregulated growth of transformed cells results from an inability of cells to interpret the constraints on growth as dictated by the ECM. The most likely candidate to communicate the restraint on growth to the nucleus is the cytoskeleton because it is the only cytoplasmic structure to physically connect the nucleus and plasma membrane. The purpose of this study was to determine whether the cytoskeleton, specifically the microfilaments (MF), of the C6-glioma cell line prossesses the ability to respond to changes in the ECM. The C6-glioma cell line was chosen as a model because it exhibits the characteristics of a tumor cell, both in vivo and in vitro. In this study cells were grown on bare glass, Matrigel, laminin and type IV collagen prior to staining with phalloidin tetramethylrhodamine B isothiocyanate or antibodies specific to vinculin to visualize MF and adhesion plaques, respectively. On the basis of MF orientation, network complexity and location of adhesion plaques, this study reports that the cytoskeletal arrangements of C6 cells grown on various substrates are distinctly different. Each distinct organization pattern may reflect a change of cell behavior promoted by the different culture conditions. The significance of this study is that it demonstrates that the process of transformation in C6-glioma cells has not interfered with the cells ability to recognize, interpret and adapt to changes in the ECM.

Notes: Summary Brain tumors, benign and malignant, are characteristically more permeable to various types of tracer molecules than the neuropil in which they are embedded. Impermeability of brain neuropil capillaries is imparted by the blood-brain barrier, the anatomic basis of which is the network of interendothelial zonulae occludentes that seal capillary endothelial cells. To explore both the vascular elements of brain neoplasms and the route of tracer extravasation from them, as well as the possible effects of brain tumors on the permeability of peritumoral neuropil capillaries, brain tumors were induced in newborn Wistar rats by intracerebral (i.c.) injection of C-6 astrocytoma cells. The protein tracer horseradish peroxidase (HRP) was injected systemically into both normal and tumorbearing rats to mark the pathway along which it flowed into the tumor parenchyma tissue spaces, and to signal any concomitant tracer loss from the tumor extracellular compartment or peritumoral brain capillaries, into the neuropil extracellular milieu. Electron-microscopic examination on thin plastic sections of tumor and peritumoral neuropil revealed massive extravasation of tracer into the tumor tissue spaces, but none was seen outside of the capillaries in the surrounding brain neuropil. Zonulae occludentes of both tumor capillary endothelium and brain capillary endothelium were devoid of tracer and judged tight (sealed). Tracer was seen in pinocytotic vesicles in the highly attenuated endothelium of tumor capillaries and also in cytoplasmic vesicles within the tumor cells. The peritumoral and contralateral neuropil capillary endothelium exhibited reaction product-filled pinocytotic vesicles and vesiculo-tubular conduits. Often, one end of a HRP-filled vesiculo-tubular channel appeared continuous with either the luminal or abluminal plasmalemma. High-voltage electron microscopy of these conduits often showed them to be continuous with both luminal and abluminal surfaces of the endothelium, thus forming a continuum across the capillary wall. In addition, these transendothelial channels, clearly constituted as chains of fused vesicles, were often seen in close proximity to, or fused with, dense bodies in the endothelial cytoplasm. In spite of the presence of HRP-filled structures in the peritumoral neuropil capillary endothelium of tumor-bearing rats, no evidence of tracer extravasation from these vessels was apparent. These results suggest that although peritumoral and contralateral neuropil capillaries possess the machinery for extravasation of tracer, likely as a response to the presence of the neoplasm, tracer is not lost but, instead, is degraded by endothelial enzymes. The extensive flooding of the tumor extracellular compartment with tracer may be achieved by transport of HRP across the very thin walls of tumor capillaries by single cytoplasmic vesicles which structurally and functionally play the role of transendothelial channels. Based on the results of this study, it is unlikely that molecules delivered systemically to treat brain neoplasms, will leak into the peritumor or contralateral neuropil, either from their own capillaries, or from the extracellular compartment of the tumor parenchyma.