The ability of gliomas to invade the brain limits the efficacy of standard therapies. In this study, we have examined glioma migration in living brain tissue by using two novel in vivo model systems. Within the brain, glioma cells migrate like nontransformed, neural progenitor cells-extending a prominent leading cytoplasmic process followed by a burst of forward movement by the cell body that requires myosin II. In contrast, on a two-dimensional surface, glioma cells migrate more like fibroblasts, and they do not require myosin II to move. To explain this phenomenon, we studied glioma migration through a series of synthetic membranes with defined pore sizes. Our results demonstrate that the A and B isoforms of myosin II are specifically required when a glioma cell has to squeeze through pores smaller than its nuclear diameter. They support a model in which the neural progenitor-like mode of glioma invasion and the requirement for myosin II represent an adaptation needed to move within the brain, which has a submicrometer effective pore size. Furthermore, the absolute requirement for myosin II in brain invasion underscores the importance of this molecular motor as a potential target for new anti-invasive therapies to treat malignant brain tumors.
INTRODUCTIONMalignant gliomas are a group of primary brain tumors that have remained resistant to therapy and that have a dismal prognosis (Buckner et al., 2007;Stupp et al., 2007). Part of the reason for this state of affairs is that although gliomas rarely metastasize outside the CNS, they are capable of spreading long distances within the brain (Sherer, 1940;Burger and Kleihues, 1989;Hoelzinger et al., 2007). This invasive behavior limits the effectiveness of local therapies and contributes to the high mortality rate seen in these tumors (Lim et al., 2007). Preventing glioma invasion therefore has the potential to convert this highly malignant tumor into a focal disease, which could then be effectively treated with focal therapies, such as radiation and surgery. Realizing this outcome, however, will require a detailed understanding how gliomas invade normal brain.Gliomas typically invade the brain by migrating long distances through white matter tracts and by infiltrating cortex and subcortical gray matter structures. Brain parenchyma (neuropil) is composed of tightly packed neuronal and glial processes, and it is characterized by extracellular spaces that are in the submicrometer range (Thorne and Nicholson, 2006). This environment therefore represents a particular mechanical challenge to motile cells, such as gliomas, that need to insinuate themselves through a highly constraining brain matrix to migrate. Unfortunately, there is very little information about how glioma cells accomplish this process in vivo. Some insight is provided by studies of embryonic and early postnatal brain, where neural progenitor cells migrate along radial glial cells, and to some extent through the white matter and cortex before stopping and differentiating into mature neurons and glia. Ti...
