Loss of Matrix Adhesion Triggers Rapid Transformation-Selective Apoptosis in Fibroblasts

Cell–matrix and cell–cell adhesion are recognized physiological determinants of cell growth and survival. In epithelial and endothelial cell systems, oncogenic transformation has in several cases been shown to confer resistance to apoptosis upon depriving cells of substrate adhesion. We examined the effects of oncogenic transformation in adherent versus adhesion- deprived primary embryonic fibroblasts. Whereas untransformed early passage fibroblasts undergo cell cycle arrest, their Myc/Ras- or E1A/Ras-transformed counterparts rapidly enter apoptosis when placed into suspension. This phenomenon also occurs upon incubation with a soluble, RGD-containing integrin ligand and is blocked by a peptide antagonist to ICE family proteases or by aggregation of cells plated at high density. Loss of wild-type p53 modulates the kinetics but does not abrogate this death pathway. Transformation with activated Src rather than Ras rendered fibroblasts selectively resistant to adhesion-dependent apoptosis, an effect likely related to Src's role in integrin signaling, while simultaneously sensitizing the cells to radiation-induced apoptosis. Thus cell adhesion events regulate transformation-selective apoptosis in fibroblasts and provide potentially important targets for understanding and interfering with tumor cell viability.     

Down-regulation of statin,a nonproliferation-specific nuclear protein,and up-regulation of c-myc after initiation of programmed cell death in mouse fibroblasts

Deprivation of growth factors has been shown to induce programmed cell death in many cell types, including mouse 3T3 fibroblasts. Programmed cell death (apoptosis) is an active process of self-destruction which is thought to require the expression of unique genes. Recently, the expression of cell cycle genes such as c-fos and c-myc, and re-entrance to cell cycle traverse, are thought to be necessary to induce programmed cell death. Previous work in this laboratory has shown that statin is a nonproliferation-specific nuclear protein present in the nuclei of young quiescent or senescent human fibroblasts, as well as in growth-arrested mouse 3T3 fibroblasts; we have reported that statin disappears rapidly after the blockage of growth arrest is removed and cells are allowed to resume cell cycle traverse. In this report we address the question of whether cells induced to enter the programmed cell death process also lose the expression of statin. We studied density-arrested quiescent mouse 3T3 cells, which undergo rapid cell death by apoptosis upon serum deprivation. Our results suggest that c-myc expression is induced, as previously reported in other systems of apoptotic death. Interestingly, we also find that statin indeed disappears after the induction of programmed cell death is initiated. These results further support the notion that when apoptosis is induced, cells behave as though released from replication arrest, and experience some part of the G₁ phase of the cell cycle. The difference between this event and normal cell cycle traverse is that this experience of the G₁ phase in the apoptotic process is an abortive one, with the end result of cell demise. © 1995 Wiley-Liss, Inc.     

Fas-mediated apoptosis of proliferating, transiently growth-arrested, and senescent normal human fibroblasts

Previous studies suggest that apoptotic signaling may require proteins that are critical to cellular proliferation and cell cycle regulation. To further examine this question, proliferating, transiently growth-arrested, and senescent normal human fibroblasts were induced to undergo apoptosis in response to two distinct mediators of apoptosis-Fas (APO-1/CD95) death receptor and staurosporine. Ligation of the Fas receptor in the presence of cycloheximide or actinomycin D resulted in apoptosis of proliferating cells, cells transiently growth arrested by gamma-irradiation or serum starvation (i.e., G(0) arrest), and permanently growth-arrested senescent fibroblasts. Proliferating and G(0)-arrested cells were also susceptible to staurosporine-mediated apoptosis. Surprisingly, gamma-irradiated cells did not undergo staurosporine-mediated apoptosis, and remained viable for a prolonged time. Fas-mediated apoptosis of senescent fibroblasts was evidenced by chromosome condensation and by activation of caspase-8 and -3, proteases crucial for the execution of the Fas apoptosis pathway. In addition, ligation of the Fas receptor in G(0)-arrested cells did not result in the activation of p34(cdc2) kinase, arguing that activation of this kinase is not essential in this apoptotic process. From these studies we conclude that proliferating, transiently growth-arrested, and senescent normal human fibroblasts are susceptible to apoptotic signals and that apoptosis is not necessarily dependent upon cell cycle or proliferative state of the cell.     

Cellular senescence induced by p53-ras cooperation is independent of p21waf1 in murine embryo fibroblasts

Oncogenic activation in primary murine fibroblasts initiates a senescence-like cell cycle arrest that depends on the p53 tumor suppressor pathway. Conditional p53 activation efficiently induced a reversible cell cycle arrest but was unable to induce features of senescence. In contrast, coexpression of oncogenic ras with p53 produced an irreversible cell cycle arrest that displayed features of cellular senescence. Introduction of a conditional murine p53 allele (p53val135) into double p53/p21-null mouse embryonic fibroblasts showed that p21waf1 was not required for this effect, since p53-/-;p21-/- double-null cells undergo terminal growth arrest with features of senescence following coexpression of oncogenic Ras and p53. Our results indicate that oncogenic activation of the Ras pathway in murine fibroblasts converts p53 into a senescence inducer through a p21waf1-independent mechanism.     

p53 Deficiency rescues neuronal apoptosis but not differentiation in DNA polymerase beta-deficient mice

In mammalian cells, DNA polymerase beta (Polbeta) functions in base excision repair. We have previously shown that Polbeta-deficient mice exhibit extensive neuronal cell death (apoptosis) in the developing nervous system and that the mice die immediately after birth. Here, we studied potential roles in the phenotype for p53, which has been implicated in DNA damage sensing, cell cycle arrest, and apoptosis. We generated Polbeta(-/-) p53(-/-) double-mutant mice and found that p53 deficiency dramatically rescued neuronal apoptosis associated with Polbeta deficiency, indicating that p53 mediates the apoptotic process in the nervous system. Importantly, proliferation and early differentiation of neuronal progenitors in Polbeta(-/-) p53(-/-) mice appeared normal, but their brains obviously displayed cytoarchitectural abnormalities; moreover, the mice, like Polbeta(-/-) p53(+/+) mice, failed to survive after birth. Thus, we strongly suggest a crucial role for Polbeta in the differentiation of specific neuronal cell types.     

RASSF2 is a novel K-Ras-specific effector and potential tumor suppressor

Ras proteins regulate a wide range of biological processes by interacting with a broad assortment of effector proteins. Although activated forms of Ras are frequently associated with oncogenesis, they may also provoke growth-antagonistic effects. These include senescence, cell cycle arrest, differentiation, and apoptosis. The mechanisms that underlie these growth-inhibitory activities are relatively poorly understood. Recently, two related novel Ras effectors, NORE1 and RASSF1, have been identified as mediators of apoptosis and cell cycle arrest. Both of these proteins exhibit many of the properties normally associated with tumor suppressors. We now identify a novel third member of this family, designated RASSF2. RASSF2 binds directly to K-Ras in a GTP-dependent manner via the Ras effector domain. However, RASSF2 only weakly interacts with H-Ras. Moreover, RASSF2 promotes apoptosis and cell cycle arrest and is frequently down-regulated in lung tumor cell lines. Thus, we identify RASSF2 as a new member of the RASSF1 family of Ras effectors/tumor suppressors that exhibits a specificity for interacting with K-Ras.