1027

CDKN1B

CDKN4|KIP1|MEN1B|MEN4|P27KIP1;cyclin-dependent kinase inhibitor 1B (p27, Kip1);CDKN1B;cyclin-dependent kinase inhibitor 1B (p27, Kip1)

cyclin-dependent kinase inhibitor 1B

12p13.1-p12

protein-coding

Cyclin E and p27(Kip1) are key regulators for cyclin-dependent kinases (Cdks) acting at the G1-/S-phase transition of the cell cycle. Whereas cyclin E is required for the activation of Cdk2, p27(Kip1) is a specific Cdk inhibitor and can block cell division. High levels of cyclin E and low levels of p27(Kip1) expression have been associated with malignant lymphomas in humans; the level of p27(Kip1) is even considered of prognostic significance. However, mice that lack p27(Kip1) do not develop any malignant lymphomas despite a pronounced lymphoid hyperplasia in thymus and spleen. We have previously described transgenic mice that carry a construct in which the cyclin E cDNA is under the control of the CD2 promoter/enhancer region and thus express high levels of cyclin E in the T-cell compartment (CD2-cyclin E). These animals are not predisposed for T-cell lymphomas in the absence of other cooperating events. Here we show that T-cells from CD2-cyclin E mice that at the same time are deficient for p27(Kip1) show a significantly higher Cdk2 activity than cells from wild-type or single mutant animals. Accordingly, a higher percentage of T cells in S/G2/M phase is found in CD2-cyclin E/p27(Kip1-/-) mice. After a long latency period of over 200 days, these animals develop spontaneous monoclonal T cell lymphoma whereas none of the single CD2-cyclin E transgenic or the p27(Kip1)-deficient mice showed any sign of lymphoid malignancies. Our findings demonstrate that a deregulation of control mechanisms at the G1/S transition by the combination of high cyclin E levels in the absence of p27(Kip1) is sufficient to predispose mice to develop lymphoid malignancies and further support a role of p27(Kip1) as a tumor suppressor and of cyclin E as a dominant oncogene.

We have created two knock-in mouse models to study the mechanisms that regulate p27 in normal cells and cause misregulation of p27 in tumors: p27(S10A), in which Ser10 is mutated to Ala; and p27(CK-), in which point mutations abrogate the ability of p27 to bind cyclins and CDKs. These two mutant alleles identify steps in a pathway that controls the proteasomal degradation of p27 uniquely in quiescent cells: Dephosphorylation of p27 on Ser10 inhibits p27 nuclear export and promotes its assembly into cyclin-CDK complexes, which is, in turn, necessary for p27 turnover. We further show that Ras-dependent lung tumorigenesis is associated with increased phosphorylation on Ser10 and cytoplasmic mislocalization of p27. Indeed, we find that p27(S10A) is refractory to Ras-induced cytoplasmic translocation and that p27(S10A) mice are tumor resistant. Thus, phosphorylation of p27 on Ser10 is an important event in the regulation of the tumor suppressor function of p27.

Effects of p27Kip1 inactivation on tumorigenesis vary from promotion to prevention dependent on the mouse models used. When p27 inactivation has a positive effect on tumorigenesis, de-regulated activation of cyclin-dependent kinases (Cdks) is generally believed to be the underlying mechanism since the function of p27 as an inhibitor of Cdks is firmly established. Here, we determined the effects of p27 inactivation on disease progression and Cdk activation in mouse liver tumorigenesis that originates from hepatocyte regenerative proliferation in response to chronic liver injury, an established etiology in most human liver cancer. Our results show that inactivation of p27 did not affect early-stage hepatocyte regenerative proliferation but promoted tumor cell proliferation and progression in the late stage of the disease. Interestingly, Cdc2 over-expression was observed in all and cyclin E1 was over-expressed in half of the late-stage tumors regardless of p27 status; and p27 inactivation led to significant activation of Cdk2 or Cdc2 only in half of the p27-deficient tumors. These results reveal a tumor suppressor role of p27 in chronic hepatocyte injury-induced liver tumorigenesis and, at the same time, the need to further study the mechanisms for tumor promotion by p27 inactivation.

The biochemical function of p27Kip1 as an inhibitor of cyclin-dependent kinases is well-established, but the role of p27 as a tumor suppressor depends on specific cellular contexts. Previous studies using p27 knockout mice on mixed C57BL/6J x 129/Sv strain background did not find a tumor suppressor role of p27 in the liver. An important feature of mouse liver tumorigenesis is strain-dependent tumor susceptibility. Here, we determined the role of p27 in liver tumorigenesis in C57BL/6J mice, a liver tumor resistant strain, in response to a diethylnitrosamine (DEN) and phenolbarbital (PB) two-stage carcinogenesis protocol. At 6 mo of age, while livers of DEN-PB treated p27+/+ and p27-/- C57BL/6J mice appeared morphologically normal, p27-/- livers, but not p27+/+ livers, contained readily detectable glucose-6-phosphatase (G6Pase)-deficient foci. At the 9-mo time point, p27-/- mice developed significantly enhanced liver tumor phenotypes than p27+/+ mice as demonstrated by increased numbers and sizes of liver surface nodules, increased liver-to-body weight ratios, and increased numbers of G6Pase-deficient nodules and histologically diagnosed foci and adenomas in liver sections. Hepatic lesions in p27-/- livers contained more proliferating hepatocytes than lesions in p27+/+ livers, while the numbers of apoptotic cells appeared similar in lesions of both genotypes. Unexpectedly, tumors in p27-/- livers contained only slightly elevated Cdk2 kinase activity compared with normal livers. These results reveal a liver tumor suppressor role of p27 in this resistant mouse strain, and the need to further study the role of Cdk2 kinase in liver tumor promotion by p27 inactivation.