HIPK2 controls cytokinesis and prevents tetraploidization by phosphorylating histone H2B at the midbody.

Failure in cytokinesis, the final step in cell division, by generating tetra- and polyploidization promotes chromosomal instability, a hallmark of cancer. Here we show that HIPK2, a kinase involved in cell fate decisions in development and response to stress, controls cytokinesis and prevents tetraploidization through its effects on histone H2B. HIPK2 binds and phosphorylates histone H2B at S14 (H2B-S14(P)), and the two proteins colocalize at the midbody. HIPK2 depletion by targeted gene disruption or RNA interference results in loss of H2B-S14(P) at the midbody, prevention of cell cleavage, and tetra- and polyploidization. In HIPK2 null cells, restoration of wild-type HIPK2 activity or expression of a phosphomimetic H2B-S14D derivative abolishes cytokinesis defects and rescues cell proliferation, showing that H2B-S14(P) is required for a faithful cytokinesis. Overall, our data uncover mechanisms of a critical HIPK2 function in cytokinesis and in the prevention of tetraploidization.

Impairment of the p27kip1 function enhances thyroid carcinogenesis in TRK-T1 transgenic mice.

Impairment of the p27(kip1) function, caused by a drastic reduction of its expression or cytoplasmic mislocalization, has been frequently observed in thyroid carcinomas. To understand the role of p27(kip1) impairment in thyroid carcinogenesis, we investigated the consequences of the loss of p27(kip1) expression in the context of a mouse modeling of papillary thyroid cancer, expressing the TRK-T1 oncogene under the transcriptional control of thyroglobulin promoter. We found that double mutant mice homozygous for a p27(kip1) null allele (TRK-T1/p27(-/-)) display a higher incidence of papillary thyroid carcinomas, with a shorter latency period and increased proliferation index, compared with p27(kip1) wild-type compounds (TRK-T1/p27(+/+)). Consistently, double mutant mice heterozygous for a p27(kip1) null allele (TRK-T1/p27(+/-)) show an incidence of thyroid carcinomas that is intermediate between TRK-T1/p27(-/-) and TRK-T1/p27(+/+) mice. Therefore, our findings suggest a dose-dependent role of p27(kip1) function in papillary thyroid cancer development.

SOM230, a new somatostatin analogue, is highly effective in the therapy of growth hormone/prolactin-secreting pituitary adenomas.

PURPOSE: We have previously shown that transgenic mice ubiquitously overexpressing the HMGA2 gene develop growth hormone/prolactin-secreting pituitary adenomas. This animal model has been used to evaluate the therapeutic efficacy of SOM230, a somatostatin analogue with high affinity for the somatostatin receptor subtypes 1, 2, 3, and 5, on the growth of the pituitary adenomas. EXPERIMENTAL DESIGN: Four groups of 3- and 9-month-old HMGA2 transgenic mice were treated for 3 months with a continuous s.c. injection of two different dosages of SOM230 (5 or 50 microg/kg/h), one dose of octreotide, corresponding to that used in human therapy, and a placebo, respectively. The development of the tumor before and after therapy was monitored by magnetic resonance imaging of the pituitary region and evaluation of the serum prolactin levels. RESULTS: The highest dose of SOM230 induced a drastic regression of the tumor, whereas octreotide was not able to induce any significant tumor regression, although tumor progression was significantly slowed down. No significant differences were observed between the animals treated with the lowest dose of SOM230 and those receiving placebo. CONCLUSIONS: These results clearly support the efficacy of the SOM230 treatment in human pituitary adenomas secreting prolactin based on the dramatic tumor shrinkage and fall in prolactin levels. This beneficial effect could be of crucial clinical usefulness in patients bearing tumors resistant to dopaminergic drugs.

Thyroid cell transformation requires the expression of the HMGA1 proteins.

Elevated expression of HMGA1 and HMGA2 proteins is correlated with a highly malignant phenotype in several human tumors. We previously demonstrated that the block of HMGA2 protein synthesis prevented rat thyroid cell transformation by murine retroviruses. Suppression of HMGA2 synthesis was associated with lack of induction of HMGA1 proteins suggesting that both HMGA1 and HMGA2 play a role in the process of neoplastic transformation. To determine the role of the HMGA1 gene in thyroid cell transformation, we blocked HMGA1 protein synthesis by an antisense methodology. Here we report that transfection of an HMGA1 cDNA antisense construct into a normal rat thyroid cell line (FRTL-5 Cl2), followed by infection with Kirsten murine sarcoma virus (KiMSV), generated a transformed cell line that expresses high levels of the v-ras-Ki oncogene and that does not require thyroid-stimulating hormones for growth. However, this cell line does not show the malignant phenotype, i.e., it neither grows in soft agar nor induces tumors after injection in athymic mice. Moreover, the lack of the neoplastic phenotype in the virus-infected thyroid cells carrying the HMGA1 antisense construct correlates with the absence of induction of AP-1 transcriptional activity.

Overexpression of the HMGA2 gene in transgenic mice leads to the onset of pituitary adenomas.

Overexpression of the HMGA2 gene is a common feature of neoplastic cells both in experimental and human models. Intragenic and extragenic HMGA2 rearrangements responsible for HMGA2 gene overexpression have been frequently detected in human benign tumours of mesenchymal origin. To better understand the role of HMGA2 overexpression in human tumorigenesis, we have generated transgenic mice carrying the HMGA2 gene under the transcriptional control of the cytomegalovirus promoter. High expression of the transgene was demonstrated in all the mouse tissues analysed, whereas no expression of the endogenous HMGA2 gene was detected in the same tissues from wild-type mice. In this study, two independent lines of transgenic mice have been generated. By 6 months of age, 85% of female animals of both transgenic lines developed pituitary adenomas secreting prolactin and growth hormone. The transgenic males developed the same phenotype with a lower penetrance (40%) and a longer latency period (about 18 months). Therefore, these data demonstrate that the overexpression of HMGA2 leads to the onset of mixed growth hormone/prolactin cell pituitary adenomas. These transgenic mice may represent an important tool for the study of this kind of neoplasia.