The Mitogen Activated Protein Kinase (MAPK) module operates downstream of Ras to convey cell surface signals to the nucleus via the nuclear translocation of p42/p44 MAPKs. We have previously established that MAPK activation is obligatory and must persist in the G1 phase to allow resting fibroblasts to exit from G0 (Pagès et al., Proc. Natl. Acad. Sci.1993, 90, 8319-8323). It remained to be established whether MAPK activation was sufficient to trigger cell proliferation. To this aim, we generated and expressed in Chinese hamster lung fibroblasts, constitutively active mutants of hamster MAP kinase kinase (MAPKK). Three mutants: S218D, S222D and S218D/S222D in which we substituted the Raf1/MAPKKK-dependent regulatory phosphorylation sites by aspartic acid residues, displayed increased basal activity when expressed in fibroblasts. Two of them, S218D and S218D/S222D which have a basal activity higher than serum-stimulated wild type-MAPKK (respectively 2- and 5-fold), induced activation of p42 MAPK in growth factor-deprived cells. Interestingly, only these two mutants led to a growth factor-independent state as judged by early gene transcription (activation of the fos promoter), increased sensitivity to growth factors for reinitiation of DNA synthesis, autonomous cell cycling and rapid tumor formation in nude mice. Therefore we conclude that the downstream elements of the growth factor signalling cascade, MAPKK-MAPK, are both necessary and sufficient to promote growth factor signals and autonomous cell cycling in fibroblasts.