Maria Teresa Berlingieri

PTC is a novel rearranged form of the ret proto-oncogene and is frequently detected in vivo in human thyroid papillary carcinomas

We recently detected a novel activated oncogene by transfection analysis on NIH 3T3 cells in five out of 20 primary human thyroid papillary carcinomas and in the available lymph node metastases. We designated this transforming gene PTC (for papillary thyroid carcinoma). Here we describe the molecular cloning and sequencing of the gene. The new oncogene resulted from the rearrangement of an unknown amino-terminal sequence to the tyrosine kinase domain of the ret proto-oncogene. This gene rearrangement was detected in all of the transfectants and in all of the original tumor DNAs, but not in normal DNA of the same patients, thus indicating that this genetic lesion occurred in vivo and is specific to somatic tumors. Moreover, the transcript coded for by the fused gene was detected in an additional PTC-positive human papillary carcinoma for which mRNA was available.

One- and two-step transformations of rat thyroid epithelial cells by retroviral oncogenes.

A system of epithelial cells is described in which it is possible to study the number and the nature of genes capable of conferring the malignant phenotype. Two fully differentiated, hormone-responsive cell lines from rat thyroid glands are presented which are susceptible to one-step or two-step transformation upon infection with several murine acute retroviruses. After infection, both cell lines became independent from their thyrotropic hormone requirement for growth. However, complete transformation was achieved with one of the cell lines (FRTL-5 Cl 2), whereas the other cell line (PC Cl 3) failed to grow in agar and to give rise to tumors in vivo. The latter cell line was susceptible to complete transformation upon cooperation of the v-ras-Ha and the human c-myc oncogenes.

Inhibition of HMGI-C protein synthesis suppresses retrovirally induced neoplastic transformation of rat thyroid cells.

Elevated expression of the three high-mobility group I (HMGI) proteins (HMGI, HMGY, and HMGI-C) has previously been correlated with the presence of a highly malignant phenotype in epithelial and fibroblastic rat thyroid cells and in experimental thyroid, lung, mammary, and skin carcinomas. Northern (RNA) blot and run-on analyses demonstrated that the induction of HMGI genes in transformed thyroid cells occurs at the transcriptional level. An antisense methodology to block HMGI-C protein synthesis was then used to analyze the role of this protein in the process of thyroid cell transformation. Transfection of an antisense construct for the HMGI-C cDNA into normal thyroid cells, followed by infection with transforming myeloproliferative sarcoma virus or Kirsten murine sarcoma virus, generated cell lines that expressed significant levels of the retroviral transforming oncogenes v-mos or v-ras-Ki and removed the dependency on thyroid-stimulating hormones. However, in contrast with untransfected cells or cells transfected with the sense construct, those containing the antisense construct did not demonstrate the appearance of any malignant phenotypic markers (growth in soft agar and tumorigenicity in athymic mice). A great reduction of the HMGI-C protein levels and the absence of the HMGI(Y) proteins was observed in the HMGI-C antisense-transfected, virally infected cells. Therefore, the HMGI-C protein seems to play a key role in the transformation of these thyroid cells.

Elevated levels of a specific class of nuclear phosphoproteins in cells transformed with v-ras and v-mos oncogenes and by cotransfection with c-myc and polyoma middle T genes.

Transformation of a rat thyroid epithelial cell line (FRTL5‐C12) with Kirsten and Harvey murine sarcoma viruses (carrying the ras oncogenes) results in elevated levels of three perchloric acid‐soluble nuclear phosphoproteins. These three proteins are also induced to high levels in the PC‐C13 thyroid epithelial cell line when transformed by the myeloproliferative sarcoma virus (carrying the v‐mos oncogene) and when transformed by transfection with the c‐myc proto‐oncogene followed by infection with the polyoma leukaemia virus (PyMuLV) carry the polyoma middle T antigen gene. Neither c‐myc or PyMuLV alone induced high levels of the three nuclear proteins. Untransformed thyroid fibroblasts have high levels of two of the three proteins and can be transformed by PyMuLV alone resulting in the appearance of the third protein. Transformation with Harvey sarcoma virus also results in the induction of the third protein. The three phosphoproteins have been purified by h.p.l.c. and shown to be related to the HeLa protein HMGI already described. The results of these studies indicate that elevated levels of these HMGI‐like proteins are associated with neoplastic transformation and/or with an undifferentiated phenotype.

Molecular heterogeneity of RET loss of function in Hirschsprung's disease.

The RET proto‐oncogene encodes a receptor with tyrosine kinase activity (RET) that is involved in several neoplastic and non‐neoplastic diseases. Oncogenic activation of RET, achieved by different mechanisms, is detected in a sizeable fraction of human thyroid tumors, as well as in multiple endocrine neoplasia types 2A and 2B (MEN2A and MEN2B) and familial medullary thyroid carcinoma tumoral syndromes. Germline mutations of RET have also been associated with a non‐neoplastic disease, the congenital colonic aganglionosis, i.e. Hirschsprungs disease (HSCR). To analyse the impact of HSCR mutations on RET function, we have introduced into wild‐type RET and activated RET(MEN2A) and RET(MEN2B) alleles three missense mutations associated with HSCR. Here we show that the three mutations caused a loss of function of RET when assayed in two model cell systems, NIH 3T3 and PC12 cells. The effect of different HSCR mutations was due to different molecular mechanisms. The HSCR972 (Arg972–>Gly) mutation, mapping in the intracytoplasmic region of RET, impaired its tyrosine kinase activity, while two extracellular mutations, HSCR32 (Ser32–>Leu) and HSCR393 (Phe393–>Leu), inhibited the biological activity of RET by impairing the correct maturation of the RET protein and its transport to the cell surface.

Truncated and chimeric HMGI-C genes induce neoplastic transformation of NIH3T3 murine fibroblasts

Overexpression of the high mobility group I (HMGI) proteins is often associated with the malignant phenotype. Moreover, many benign human tumors, mainly of mesenchymal origin, are characterized by rearrangements of the HMGI-C gene. In most cases, HMGI-C alterations involve breaks within the third intron of the gene resulting in aberrant transcripts carrying exons from 1–3, which encode the three DNA binding domains, fused to ectopic sequences. Here, we show that the expression of a truncated form of HMGI-C protein carrying only the three DNA-binding domains, or of a fusion protein carrying the three DNA-binding domains of HMGI-C and the LIM domains of the lipoma preferred partner gene (LPP) protein, causes malignant transformation of NIH3T3 cells. The unrearranged wild-type HMGI-C cDNA did not exert any transforming activity. These findings indicate that rearranged forms of HMGI-C play a role in cell transformation.

Loss of the CBX7 Gene Expression Correlates with a Highly Malignant Phenotype in Thyroid Cancer

Using gene expression profiling, we found that the CBX7 gene was drastically down-regulated in six thyroid carcinoma cell lines versus control cells. The aims of this study were to determine whether CBX7 is related to the thyroid cancer phenotype and to try to identify new tools for the diagnosis and prognosis of thyroid cancer. We thus evaluated CBX7 expression in various snap-frozen and paraffin-embedded thyroid carcinoma tissues of different degrees of malignancy by quantitative reverse transcription-PCR and immunohistochemistry, respectively. CBX7 expression progressively decreased with malignancy grade and neoplasia stage. Indeed, it decreased in an increasing percentage of cases going from benign adenomas to papillary (PTC), follicular, and anaplastic (ATC) thyroid carcinomas. This finding coincides with results obtained in rat and mouse models of thyroid carcinogenesis. CBX7 loss of heterozygosity occurred in 36.8% of PTC and in 68.7% of ATC. Restoration of CBX7 expression in thyroid cancer cells reduced growth rate, with a retention in the G(1) phase of the cell cycle, suggesting that CBX7 can contribute to the proliferation of the transformed thyroid cells. In conclusion, loss of CBX7 expression correlates with a highly malignant phenotype in thyroid cancer patients.

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.

Somatostatin Inhibits PC Cl3 Thyroid Cell Proliferation through the Modulation of Phosphotyrosine Phosphatase Activity IMPAIRMENT OF THE SOMATOSTATINERGIC EFFECTS BY STABLE EXPRESSION OF E1A VIRAL ONCOGENE

In this study, we report the effects of somatostatin on the proliferation of PC Cl3 thyroid cell line and the intracellular mechanisms involved. We also evaluated the possible alterations, induced by E1A oncogene transformation on the intracellular pathways mediating somatostatin inhibition of cell proliferation. We showed that somatostatin was able to powerfully inhibit insulin- and insulin + TSH-dependent cell proliferation by inducing a block in the G/S progression in the cell cycle. These cytostatic effects were completely reverted by vanadate, suggesting that somatostatin may induce antiproliferative effects through the modulation of phosphotyrosine phosphatases. In the E1A-transformed cell line, somatostatin was completely ineffective. The lack of somatostatin inhibitory effects on cell proliferation were not due to alterations in the expression of somatostatin receptors, which were regularly expressed and coupled to adenylyl cyclase activity, but were dependent on an alteration in their coupling with the phosphotyrosine phosphatase. In fact, although in PC Cl3 cells somatostatin increased by 100% phosphotyrosine phosphatase activity, it was completely ineffective in E1A-expressing cells. In conclusion we demonstrated that somatostatin activates phosphotyrosine phosphatases in PC Cl3 thyroid cells to inhibit cell proliferation and that the stable expression of E1A oncogene in these cells completely abolishes this antiproliferative effect.

UbcH10 expression may be a useful tool in the prognosis of ovarian carcinomas

The UbcH10 gene codes for a protein that belongs to the ubiquitin-conjugating enzyme family. Previous studies of our group suggest UbcH10 expression as a valid indicator of the proliferative and aggressive status of thyroid carcinomas. Therefore, to better understand the process of ovarian carcinogenesis, and to look for possible tools to be used as prognostic markers in these neoplasias, we decided to extend the analysis of the UbcH10 expression to the ovarian neoplastic disease. We found that the UbcH10 gene was upregulated in some ovarian carcinoma cell lines analysed. Then, immunohistochemical studies demonstrate that UbcH10 expression significantly correlates with the tumor grade and the undifferentiated histotype of the ovarian carcinomas. Furthermore, a significant relationship between UbcH10 expression and overall survival was observed. Finally, the block of UbcH10 protein synthesis by RNA interference inhibited the growth of ovarian carcinoma cell lines, suggesting a role of UbcH10 overexpression in ovarian carcinogenesis. Therefore, all these data taken together suggest the possibility to use UbcH10 detection as a marker for the diagnosis and prognosis of these neoplastic diseases and open the perspective of a therapy of some ovarian carcinomas based on the suppression of the UbcH10 synthesis and/or function.