Alteration of expression or phosphorylation status of tob, a novel tumor suppressor gene product, is an early event in lung cancer.

Tob is a member of the Tob/BTG family, a novel class of anti-proliferative proteins. To investigate the involvement of tob as a tumor suppressor gene in human lung cancer, we analyzed the expression of tob mRNA and protein in lung cancer tissue and adjacent normal lung tissue. Immunohistochemical analysis using anti-Tob antibody showed decreased expression of Tob in 72% (31/43) of lung cancer tissues. Furthermore, 95% (19/20) of squamous cell carcinoma patients showed an apparent decrease in Tob in cancer tissues, associated with smoking status. The phosphorylated form of Tob, an inactive form of Tob, was detected in 76% (16/21) of cancer tissues of adenocarcinoma patients, but not in normal alveolar epithelial cells. Either a decrease in Tob expression or an accumulation of phosphorylated Tob was observed from early clinical stages, even in bronchial dysplasia, a premalignant lesion of squamous cell carcinoma. The above findings suggest that the disruption of anti-proliferative Tob plays a distinct part in the early stage of lung carcinogenesis.

Phosphorylation of three regulatory serines of Tob by Erk1 and Erk2 is required for Ras-mediated cell proliferation and transformation.

tob is a member of an emerging family of genes with antiproliferative function. Tob is rapidly phosphorylated at Ser 152, Ser 154, and Ser 164 by Erk1 and Erk2 upon growth-factor stimulation. Oncogenic Ras-induced transformation and growth-factor-induced cell proliferation are efficiently suppressed by mutant Tob that carries alanines but not glutamates, mimicking phosphoserines, at these sites. Wild-type Tob inhibits cell growth when the three serine residues are not phosphorylated but is less inhibitory when the serines are phosphorylated. Because growth of Rb-deficient cells was not affected by Tob, Tob appears to function upstream of Rb. Intriguingly, cyclin D1 expression is elevated in serum-starved tob(-/-) cells. Reintroduction of wild-type Tob and mutant Tob with serine-to-alanine but not to glutamate mutations on the Erk phosphorylation sites in these cells restores the suppression of cyclin D1 expression. Finally, the S-phase population was significantly increased in serum-starved tob(-/-) cells as compared with that in wild-type cells. Thus, Tob inhibits cell growth by suppressing cyclin D1 expression, which is canceled by Erk1- and Erk2-mediated Tob phosphorylation. We propose that Tob is critically involved in the control of early G(1) progression.