EGFRvIII escapes down-regulation due to impaired internalization and sorting to lysosomes.

EGFRvIII is a mutant variant of the epidermal growth factor receptor (EGFR) found exclusively in various cancer types. EGFRvIII lacks a large part of the extracellular domain and is unable to bind ligands; however, the receptor is constitutively phosphorylated and able to activate downstream signaling pathways. Failure to attenuate signaling by receptor down-regulation could be one of the major mechanisms by which EGFRvIII becomes oncogenic. Using a cell system expressing either EGFR or EGFRvIII with no expression of other EGFR family members and with endogenous levels of key degradation proteins, we have investigated the down-regulation of EGFRvIII and compared it to that of EGFR. We show that, in contrast to EGFR, EGFRvIII is inefficiently degraded. EGFRvIII is internalized, but the internalization rate of the mutated receptor is significantly less than that of unstimulated EGFR. Moreover, internalized EGFRvIII is recycled rather than delivered to lysosomes. EGFRvIII binds the ubiquitin ligase c-Cbl via Grb2, whereas binding via phosphorylated tyrosine residue 1045 seems to be limited. Despite c-Cbl binding, the receptor fails to become effectively ubiquitinylated. Thus, our results suggest that the long lifetime of EGFRvIII is caused by inefficient internalization and impaired sorting to lysosomes due to lack of effective ubiquitinylation.

High-density growth arrest in Ras-transformed cells: low Cdk kinase activities in spite of absence of p27(Kip) Cdk-complexes.

The ras oncogene transforms immortalized, contact-inhibited non-malignant murine fibroblasts into cells that are focus forming, exhibit increased saturation density, and are malignant in suitable hosts. Here, we examined changes in cell cycle control complexes as normal and Ras-transformed cells ceased to grow exponentially, to reveal the molecular basis for Ras-dependent focus formation. As normal cells entered density-dependent arrest, cyclin D1 decreased while cyclin D2 was induced and replaced D1 in Cdk4 complexes. Concomitantly, p27(Kip1) levels rose and the inhibitor accumulated in both Cdk4 and Cdk2 complexes, as these kinases were inactivated. Ras-transformed cells failed to arrest at normal saturation density and showed no significant alterations in cell control complexes at this point. Yet, at an elevated density the Ras-transformed cells ceased to proliferate and entered a quiescent-like state with low Cdk4 and Cdk2 activity. Surprisingly, this delayed arrest was molecularly distinct from contact inhibition of normal cells, as it occurred in the absence of p27(Kip1) induction and cyclin D1 levels remained high. This demonstrates that although oncogenic Ras efficiently disabled the normal response to contact inhibition, a separate back-up mechanism enforced cell cycle arrest at higher cell density.

Suppression of integrin activation by activated Ras or Raf does not correlate with bulk activation of ERK MAP kinase.

The rapid modulation of ligand-binding affinity ("activation") is a central property of the integrin family of cell adhesion receptors. The Ras family of small GTP-binding proteins and their downstream effectors are key players in regulating integrin activation. H-Ras can suppress integrin activation in fibroblasts via its downstream effector kinase, Raf-1. In contrast, to H-Ras, a closely related small GTP-binding protein R-Ras has the opposite activity, and promotes integrin activation. To gain insight into the regulation of integrin activation by Ras GTPases, we created a series of H-Ras/R-Ras chimeras. We found that a 35-amino acid stretch of H-Ras was required for full suppressive activity. Furthermore, the suppressive chimeras were weak activators of the ERK1/2 MAP kinase pathway, suggesting that the suppression of integrin activation may be independent of the activation of the bulk of ERK MAP kinase. Additional data demonstrating that the ability of H-Ras or Raf-1 to suppress integrin activation was unaffected by inhibition of bulk ERK1/2 MAP kinase activation supported this hypothesis. Thus, the suppression of integrin activation is a Raf kinase induced regulatory event that can be mediated independently of bulk activation of the ERK MAP-kinase pathway.

R-Ras C-terminal sequences are sufficient to confer R-Ras specificity to H-Ras.

Activated versions of the similar GTPases, H-Ras and R-Ras, have differing effects on biological phenotypes: Activated H-Ras strongly transforms many fibroblast cell lines causing dramatic changes in cell shape and cytoskeletal organization. In contrast, R-Ras transforms fewer cell lines and the transformed cells display only some of the morphological changes associated with H-Ras transformation. H-Ras cells can survive in the absence of serum whereas R-Ras cells seem to die by an apoptotic-like mechanism in response to removal of serum. H-Ras can suppress integrin activation and R-Ras specifically antagonizes this effect. To map sequences responsible for these differences we have generated and investigated a panel of H-Ras and R-Ras chimeras. We found that the C-terminal 53 amino acids of R-Ras were necessary and sufficient to specify the contrasting biological properties of R-Ras with respect to focus morphology, reactive oxygen species (ROS) production and reversal of H-Ras-induced integrin suppression. Surprisingly, we found chimeras in which the focus formation and integrin-mediated phenotypes were separated, suggesting that different effectors could be involved in mediating these responses. An integrin profile of H-Ras and R-Ras cell pools showed no significant differences; both activated H-Ras and R-Ras expressing cells were found to have reduced beta(1) activity, suggesting that the activity state of the beta(1) subunit is not sufficient to direct an H-Ras transformed cell morphology.

Ras-inducible immortalized fibroblasts: focus formation without cell cycle deregulation.

The Ras oncogene transforms cultured murine fibroblasts into malignant, focus-forming cells, whose lack of contact inhibition is evidenced by high saturation densities. In order to investigate the reversibility of Ras transformation, as well as the kinetics of Ras-induced changes, cell lines that conditionally express oncogenic Ras were constructed. Both focus formation and increased saturation density were inducible and fully reversible. In exponentially growing cells, oncogenic Ras-expression had no effect on proliferation rates, Erk phosphorylation, or the level of cyclin D1, and Ras-induction did not confer serum-independent growth. As expected, growth to high density in uninduced cells led to quiescence with a low level of cyclin D1 and no active Erk; in this setting, Ras induction prevented full downregulation of cyclin D1 and inactivation of Erk. Our results show that Ras expression to a level sufficient for transformation leads to relatively subtle effects on known downstream targets, and that the focus formation and increased saturation density growth induced by Ras is not a result of growth factor independence.