ABSTRACT
Clonal variants of mouse epidermal JB6 cells that are genetically susceptible (P+) or resistant (P-) to tumor promoter-induced neoplastic transformation exhibit differential activator protein-1 (AP-1) response. Transactivation of AP-1 appears to be necessary but not sufficient to promote transformation in JB6 cells. Inhibition of AP-1 is invariably accompanied by inhibition of nuclear factor-kappaB (NF-kappaB) when transformation is suppressed, suggesting that NF-kappaB may also play a role in neoplastic transformation. We report here that transactivation of NF-kappaB is inducible by tumor promoters in P+ but not in P- JB6 cells. Inhibition of NF-kappaB using a nondegradable mutant of IkappaBalpha suppressed inducible anchorage-independent transformation of P+ JB6 cells, suggesting that NF-kappaB activation is required for tumor promotion. Induced degradation of IkappaBalpha occurred in both P+ and P- JB6 cells, indicating that failure to activate NF-kappaB in P- JB6 cells cannot be attributed to failure to degrade IkappaBalpha. Slightly higher levels of nuclear p65 were seen in P+ than in P- JB6 cells. The p65-specific DNA binding activity was also higher in P+ cells upon induction by tumor necrosis factor-alpha, suggesting that differential NF-kappaB activation may be attributable to changes in p65 activity. Transactivation of p65 protein was substantially higher in P+ than in P- JB6 cells, as determined by assay of Gal4-p65 fusion constructs. Thus activated, p65 may be a limiting factor for NF-kappaB activation and transformation responses. Stable expression of p65 in P- JB6 cells conferred not only inducible NF-kappaB and AP-1 activation but also transformation response to tumor promoters. Therefore, p65/NF-kappaB appears to be not only necessary for but also sufficient to confer tumor promotion response. Although stable expression of p65 in P- cells produced p65 increases in whole cell extracts, only the transfectants exhibiting increased nuclear p65 showed transformation response. Thus, elevation of nuclear p65 appears to be a necessary step for a transformation response. The P-/p65 transfectants showing acquired transformation response also showed elevated p65-specific transactivation response, thus recapitulating the NF-kappaB phenotypes seen in P+ cells. Expression of a transactivation-deficient mutant of Jun or dominant-negative extracellular signal-regulated kinase suppressed both AP-1 activation and p65-specific transactivation in JB6 cells, suggesting that AP-1 activity is needed for p65 transactivation and consequently for NF-kappaB activation. Thus, the transformation nonresponsive P- JB6 cells owe their resistance to lack of NF-kappaB activation and p65 transactivation that appears in turn to be attributable to insufficient AP-1 activation.
