Histone deacetylase inhibitors induce thyroid cancer-specific apoptosis through proteasome-dependent inhibition of TRAIL degradation.

Anaplastic thyroid carcinoma (ATC) is considered one of the most aggressive malignancies, having a poor prognosis and being refractory to conventional chemotherapy and radiotherapy. Alteration in histone deacetylase (HDAC) activity has been reported in cancer, thus encouraging the development of HDAC inhibitors, whose antitumor action has been shown in both solid and hematological malignancies. However, the molecular basis for their tumor selectivity is unknown. To find an innovative therapy for the treatment of ATCs, we studied the effects of deacetylase inhibitors on thyroid tumorigenesis models. We show that HDACs 1 and 2 are overexpressed in ATCs compared with normal cells or benign tumors and that HDAC inhibitors induce apoptosis selectively in the fully transformed thyroid cells. Our results indicate that these phenomena are mediated by a novel action of HDAC inhibitors that reduces tumor necrosis factor-related apoptosis-inducing ligand protein degradation by affecting the ubiquitin-dependent pathway. Indeed, the combined treatment with HDAC and proteasome inhibitors results in synergistic apoptosis. These results strongly encourage the preclinical application of the combination deacetylase-proteasome inhibitors for the treatment of ATC.

Analysis of UbcH10 expression represents a useful tool for the diagnosis and therapy of astrocytic tumors.

Previous studies suggest the expression of UbcH10 gene, that codes for a protein belonging to the ubiquitin-conjugating enzyme family, as a valid indicator of the proliferative and aggressive status of tumors of different origin. Therefore, to look for possible tools to be used as diagnostic markers in astrocytic neoplasias, we investigated UbcH10 expression in normal brain, gliosis and low-grade and high-grade astrocytic tumors by immunohistochemistry. UbcH10 expression was observed in low-grade astrocytoma and in glioblastoma. Our data indicate a clear correlation between UbcH10 expression and the histological grade of the astrocytic tumors. Moreover, the analysis of UbcH10 expression allows the differentiation between gliotic and malignant tissues. Finally, since proteasome inhibitors have recently been considered as possible drugs in the chemotherapy of various tumors, our results would suggest new perspectives for the treatment of brain malignancies based on the suppression of the UbcH10 function.

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.

MicroRNA deregulation in human thyroid papillary carcinomas.

MicroRNAs (miRNAs) are a class of small non-coding RNAs involved in a wide range of basic processes such as cell proliferation, development, apoptosis and stress response. It has recently been found that they are also abnormally expressed in many types of human cancer. We analyzed the genome-wide miRNA expression profile in human thyroid papillary carcinomas (PTCs) using a microarray (miRNACHIP microarray) containing hundreds of human precursor and mature miRNA oligonucleotide probes. Using this approach, we found an aberrant miRNA expression profile that clearly differentiates PTCs from normal thyroid tissues. In particular, a significant increase in miRNA (miR)-221, -222 and -181b was detected in PTCs in comparison with normal thyroid tissue. These results were further confirmed by northern blot and quantitative RT-PCR analyses. Moreover, RT-PCR revealed miR-221, -222 and -181b overexpression in fine needle aspiration biopsies corresponding to thyroid nodules, which were eventually diagnosed as papillary carcinomas after surgery. Finally, miR-221, -222 and -181b overexpression was also demonstrated in transformed rat thyroid cell lines and in mouse models of thyroid carcinogenesis. Functional studies, performed by blocking miR-221 function and by overexpressing miR-221 in human PTC-derived cell lines, suggest a critical role of miR-221 overexpression in thyroid carcinogenesis. In conclusion, these data, taken together, indicate an miRNA signature associated with PTCs, and suggest miRNA deregulation as an important event in thyroid cell transformation.

UbcH10 overexpression may represent a marker of anaplastic thyroid carcinomas.

The hybridisation of an Affymetrix HG_U95Av2 oligonucleotide array with RNAs extracted from six human thyroid carcinoma cell lines and a normal human thyroid primary cell culture led us to the identification of the UbcH10 gene that was upregulated by 150-fold in all of the carcinoma cell lines in comparison to the primary culture cells of human normal thyroid origin. Immunohistochemical studies performed on paraffin-embedded tissue sections showed abundant UbcH10 levels in thyroid anaplastic carcinoma samples, whereas no detectable UbcH10 expression was observed in normal thyroid tissues, in adenomas and goiters. Papillary and follicular carcinomas were only weakly positive. These results were further confirmed by RT-PCR and Western blot analyses. The block of UbcH10 protein synthesis induced by RNA interference significantly reduced the growth rate of thyroid carcinoma cell lines. Taken together, these results would indicate that UbcH10 overexpression is involved in thyroid cell proliferation, and may represent a marker of thyroid anaplastic carcinomas.

A differential proteomic approach to identify proteins associated with thyroid cell transformation.

Tumour suppressor p53 is a transcription factor essential for DNA damage checkpoints during cellular response to stress. Mutations in the p53 gene are the most common genetic alterations found in human tumours; most pathogenetic modifications are missense mutations that abolish the p53 DNA-binding function. In the same cell type, distinct p53 missense mutations may determine different phenotypes. The PC Cl3 cell line retains several markers of thyroid differentiation in vitro. Introduction of the V143A mutant p53 allele, which abolishes the p53 DNA-binding function, leads to loss of differentiation markers as well as TSH dependency for growth. Conversely, PC Cl3 cells transfected with the S392A mutant p53 allele, presenting the mutation located outside the DNA-binding domain, show only loss of TSH dependency for growth. To identify molecular differences existing between PC Cl3 cell lines transformed by the V143A and the S392A mutant alleles, a differential proteomic approach was used. Two-dimensional gel electrophoresis analyses indicated that expression of a significant portion of protein species was modified by both p53 mutants. In fact, compared with wild-type PC Cl3 cells, modification of expression in V143A mutant cells occurred in 23.6% of the entire protein species. Conversely, modification of S392A mutant cells affected 14.0% of total proteins. Among these components, 8.3% were common to both mutants. Several of these proteins were identified by mass spectrometry procedures; some proteins, such as HSP90 and T-complex proteins, are already known to be related to p53 function.

Overexpression of proteins HMGA1 induces cell cycle deregulation and apoptosis in normal rat thyroid cells.

The high mobility group (HMG) proteins (HMGA1a, HMGA1b, and HMGA2) bind to DNA and interact with various transcriptional factors. Therefore, they play an important role in chromatin organization. HMGA protein expression is low in normal adult tissues, but abundant during embryonic development and in several experimental and human tumors. Blockage of HMGA expression inhibits the transformation of rat thyroid PC Cl 3 cells treated with oncogene-carrying retroviruses, thus implicating HMGA in rat thyroid transformation. To better understand the role of HMGA and to establish whether its up-regulated expression is sufficient to induce the transformed phenotype, we generated PC Cl 3 cells that overexpress the protein. We demonstrate that HMGA1b protein overexpression does not transform normal rat thyroid PC Cl 3 cells, but it deregulates their cell cycle: cells enter S-phase earlier and the G(2)-M transition is delayed. HMGA1-overexpressing cells undergo apoptosis through a pathway involving caspase-3 activation, probably consequent to the conflict between mitogenic pressure and the inability to proceed through the cell cycle. Using various HMGA1b gene mutations, we found that the third AT-hook domain and the acetylation site K60 are the protein regions required for induction of apoptosis in PC Cl 3 cells. In conclusion, although HMGA1 protein overexpression is associated with the malignant phenotype of rat and human thyroid cells, it does not transform normal thyroid cells in culture but leads them to programmed cell death.

The RFG oligomerization domain mediates kinase activation and re-localization of the RET/PTC3 oncoprotein to the plasma membrane.

The RET/PTC3 oncogene arises from the fusion between the N-terminal encoding domain of the RFG gene and the tyrosine kinase encoding domain of RET receptor. RET/PTC3 is very frequent in papillary thyroid carcinomas, especially in children exposed to the Chernobyl accident. We have studied the functional consequences of the RFG-RET fusion. Here we show that the N-terminal coiled-coil domain of RGF mediates oligomerization and activation of the kinase and of the transforming capability of RET/PTC3. In addition, the RFG coiled-coil domain mediates a physical association between RET/PTC3 and RGF proteins, rendering RFG a bona fide substrate of RET/PTC3 kinase. Finally, we show that the coiled-coil domain of RGF is essential for the distribution of the RET/PTC3 protein at the membrane/particulate cell compartment level, where also most of the RFG protein is localized. We propose that fusion to the RFG coiled-coil domain provides RET kinase with a scaffold that mediates oligomerization and re-localization of the RET/PTC3 protein, a process that may be crucial for the signalling of this specific RET/PTC variant.

Akt/protein kinase B promotes survival and hormone-independent proliferation of thyroid cells in the absence of dedifferentiating and transforming effects.

The Akt/protein kinase B serine/threonine kinase is a downstream effector of phosphoinositide 3-kinase (PI3K). Akt is an important component of mitogenic and antiapoptotic signaling pathways and is implicated in neoplastic transformation. Thyroid cells in culture retain a differentiated phenotype consisting of epithelial cell morphology and the expression of several tissue-specific genes. The survival and proliferation of these cells depend on thyrotropin and a mixture of five additional hormones that includes insulin. The regulation of proliferation and the expression of the thyroid differentiation program are intimately connected processes. As a result, oncogenes that induce hormone-independent proliferation invariably impair the expression of the thyroid-specific differentiation markers. Given that thyrotropin and insulin stimulate Akt activation in thyroid cells, we set out to determine the effects of Akt on thyroid cell proliferation, survival, and differentiation. To this end, we expressed constitutively active myristylated Akt (myrAkt) in PC Cl 3 thyroid cells. The myrAkt-expressing cells continued to proliferate, even in the absence of hormones, and they were resistant to programmed cell death induced by starvation. These effects were paralleled by the induction of the G1 cyclins D3 and E and by the inhibition of induction of the proapoptotic Fas, Fas ligand, and BAD genes in starved cells. However, in marked contrast with several other oncogenes, myrAkt did not interfere with the expression of thyroid differentiation functions. These results unveil the existence of an Akt-triggered thyroid cell pathway that modulates proliferation and survival without affecting the expression of the thyroid cell differentiated phenotype.

Protein tyrosine phosphatase-eta expression is upregulated by the PKA-dependent and is downregulated by the PKC-dependent pathways in thyroid cells.

We have recently reported the isolation of a rat cDNA encoding a receptor-type tyrosine phosphatase, which appears to be a marker of thyroid differentiation. To elucidate the molecular mechanisms underlying r-PTPeta expression in normal thyroid cells both in vitro and in vivo, we investigated the regulation of r-PTPeta expression in cultured thyrocytes (the rat cell line PC Cl 3) and in an animal model of TSH-dependent thyroid goitrogenesis. In vitro studies showed that mRNA expression of r-PTPeta in thyroid cells is induced in a time- and dose-dependent manner by the activation of growth- and differentiation-linked PKA pathways (TSH and forskolin), whereas it is down-regulated by the activation of the proliferative dedifferentiating PKC-dependent transduction pathway (TPA). However, the regulation of r-PTPeta expression by TSH and TPA, respectively, is observed only in normal thyroid cells, but is lost in transformed thyroid cells. In vivo studies with thiouracil-fed rats demonstrated that increased serum levels of TSH up-regulated r-PTPeta mRNA expression in parallel with the stimulation of thyroid growth and function. The reduction of blood TSH levels due to iodide refeeding to goitrous rats determined a marked down-regulation of r-PTPeta expression, in parallel with involution of thyroid hyperplasia. Taken together these results demonstrate that the phosphatase r-PTPeta is regulated by the two main thyroid regulatory pathways and suggest that it may play an important role in the growth and differentiation of thyroid cells.

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.

Thymosin beta-10 gene overexpression correlated with the highly malignant neoplastic phenotype of transformed thyroid cells in vivo and in vitro.

A subtractive thyroid cDNA library was constructed from two human thyroid carcinoma cell lines originating from an anaplastic carcinoma and a papillary thyroid carcinoma. The library was used to identify genes correlated with the progression to a highly malignant phenotype. The thymosin beta-10 gene was isolated and found to be expressed at much higher levels in the anaplastic cell line than in the papillary cells. The thymosin beta-10 gene was overexpressed in five carcinoma cell lines compared with normal thyroid tissue and normal thyroid primary culture cells. The highest expression occurred in the most malignant cell lines. Thymosin beta-10 gene expression was also increased in surgically removed human thyroid carcinomas and was highest in the anaplastic carcinomas. Thymosin beta-10 gene expression was correlated with the degree of the malignant phenotype also in rat thyroid cells transfected with cellular and viral oncogenes of different tumorigenicity. These results show that thymosin beta-10 overexpression is a general event of thyroid cell neoplastic transformation and suggest that the gene is involved in the progression of thyroid carcinogenesis. Finally, the thymosin beta-10 gene was located on chromosome 2q37 by fluorescence in situ hybridization analysis.

Cytokine production by a new undifferentiated human thyroid carcinoma cell line, FB-1.

A human anaplastic thyroid cancer cell line FB-1, derived from a 68-yr-old woman who underwent surgery for anaplastic thyroid cancer, has been established. The spindlelike cells have been proliferating stably for more than 2 yr. Karyotype analysis shows many abnormalities and many marker chromosomes have been observed. Heterotransplant of FB-1 cells into severe combined immunodeficient mice has resulted in rapidly growing tumors classified as anaplastic carcinomas, although 50% have shown areas with a trabecular pattern. FB-1 cells failed to express messenger RNA for thyroglobulin; TSH-receptor; thyroperoxidase, and placental angiogenic growth factor. Conversely, PAX8 and thyroid transcription factor 1, whose expression is thyroid specific, was kept in an FB-1 cell line at a level comparable with that observed in normal thyroid tissue. In addition, the present cell line expressed high levels of messenger RNA for high-mobility group proteins (Y) and -C. The in vitro study revealed that FB-1 cells are able to produce high levels of interleukin (IL)-8 and medium amount of IL-6, whereas no release of IL-1-alpha, IL-1-beta, and IL-4 was observed. No modulation of cell proliferation and DNA synthesis in FB-1 cells has been observed after the addition of exogenous IL-6.

Oncogene transformation of PC Cl3 clonal thyroid cell line induces an autonomous pattern of proliferation that correlates with a loss of basal and stimulated phosphotyrosine phosphatase activity.

The effects of the stable expression of E1A and/or middle T oncogenes on the proliferative activity of PC Cl3 normal thyroid cells are reported. The proliferation of PC Cl3 cells is mainly regulated by insulin and TSH in a stimulatory way and by somatostatin in an inhibitory fashion. The transformed cell lines, named PC Py and PC E1A Py, show an autonomous pattern of proliferation. The blockade of phosphotyrosine phosphatase activity with vanadate increased the proliferation rate of PC Cl3 under basal and stimulated conditions and completely prevented the inhibitory activity of somatostatin, suggesting that in PC Cl3 cells, a tonic tyrosine phosphatase activity regulates basal and stimulated proliferation, and that a somatostatin-dependent increase in this activity may represent a cytostatic signal. Conversely, in both PC Py and PC E1A Py, vanadate did not modify basal and stimulated proliferation. We analyzed tyrosine phosphatase activity in the different cell lines basally and under conditions leading to the arrest of cell proliferation: confluence (contact inhibition), growth factor deprivation (starvation), and somatostatin treatment. Under basal conditions, tyrosine phosphatase activity was significantly lower in PC Py and PC E1APy cell lines than that in the normal cells. The inhibition of the proliferation induced by contact inhibition or somatostatin treatment was accompanied by an increase in tyrosine phosphatase activity only in PC Cl3 cells. The reduction in tyrosine phosphatase activity in PC E1APy cells correlated with a significant reduction in the expression of R-PTP eta, a tyrosine phosphatase cloned from PC Cl3 cells. Conversely, the expression of another receptor-like PTP, PTP mu, was unchanged. Thus, PTP eta may be a candidate to mediate inhibitory signals (i.e. activation of somatostatin receptors or cell to cell contact) on the proliferative activity of PC Cl3 cells, and the reduction of its expression in the transformed cell lines may lead to an alteration in the control of cell proliferation.

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. Hirschsprung's 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.

Somatostatin inhibits PC Cl3 thyroid cell proliferation through the modulation of phosphotyrosine 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 C13 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 G1/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 C13 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 C13 thyroid cells to inhibit cell proliferation and that the stable expression of E1A oncogene in these cells completely abolishes this antiproliferative effect.

Block of c-myc expression by antisense oligonucleotides inhibits proliferation of human thyroid carcinoma cell lines.

Although elevated c-myc expression seems to be related to an unfavorable prognosis of human thyroid neoplasias, the role of c-myc overexpression in the process of thyroid carcinogenesis is still unknown. We analyzed c-myc expression in 7 human thyroid carcinoma cell lines, originating from different histotypes, and in 50 fresh thyroid tumors and found a higher level of c-myc mRNA in all the thyroid carcinoma cell lines and in several fresh thyroid tumors compared with normal thyroid. The highest increases occurred in the most malignant cell lines and in undifferentiated human thyroid carcinomas. The block of c-MYC protein synthesis with myc-specific antisense oligonucleotides reduced the growth rate of the thyroid carcinoma cell lines significantly. Our results indicate that c-myc overexpression plays a critical role in the growth of thyroid cancer cells, which supports the hypothesis that the myc proto-oncogene might be involved in the neoplastic progression of thyroid carcinogenesis.

Expression of galectin-1 in normal human thyroid gland and in differentiated and poorly differentiated thyroid tumors.

We previously reported that galectin-1 gene expression increases up to 100-fold in oncogene-transformed rat thyroid cells compared with their normal counterparts and that the relative mRNA levels correlate with the degree of malignancy. In the present study we investigated whether galectin-1 is differentially expressed in human thyroid neoplasms, which range from well-differentiated tumors to undifferentiated anaplastic carcinomas. We analyzed 74 human thyroid specimens of neoplastic, hyperproliferative and normal tissues and several tumor cell lines. Galectin-1 mRNA and protein levels were higher in 6 thyroid carcinoma-derived cell lines than in normal thyroid primary cultures and adenoma cells. Galectin-1 mRNA levels increased in 28/40 papillary carcinomas and in 6/7 anaplastic carcinomas compared with normal or hyperplastic thyroid. Conversely, galectin-1 expression was unaffected in follicular carcinomas and benign adenomas. Immunohistochemical analysis of normal thyroid and papillary carcinoma sections revealed a higher content of galectin-1 protein in neoplastic follicular cells than in normal cells.

The expression of the high mobility group HMGI (Y) proteins correlates with the malignant phenotype of human thyroid neoplasias.

High Mobility Group I (HMGI) proteins are nuclear proteins involved in the regulation of chromatin structure and function. Elevated expression of the HMGI proteins (HMGI, HMGY and HMGI-C) has been correlated with the presence of a highly malignant phenotype in epithelial and fibroblastic rat thyroid cells, and in several experimental carcinomas. Here, we demonstrate that HMGI and HMGY proteins are expressed in human thyroid carcinomas and thyroid carcinoma cell lines, but not in adenomas, goiters, normal thyroid tissues and cells. These results indicate a correlation between HMGI and HMGY expression and the malignant phenotype of thyroid neoplasias, suggesting that these proteins may be used as markers in thyroid cancer.

Transformation of thyroid epithelium is associated with loss of c-kit receptor.

The receptor for the stem cell factor encoded by the c-kit proto-oncogene is expressed by a number of epithelial cells including thyrocytes. Since malignant transformation may be associated with loss of this receptor (melanoma and breast cancer), we have analyzed its expression in benign (38 cases) and malignant (31 cases) thyroid lesions. While low levels of c-kit are expressed in normal thyroids and in 60% of benign lesions, the receptor is undetectable in 60 and 90% of the follicular and papillary carcinomas, respectively. Northern blot analysis from surgical specimens of carcinomas and from carcinoma cell lines has demonstrated a lack of specific c-kit transcripts. These findings indicate that the c-kit receptor may be involved in the growth control of thyroid epithelium and that this function may be lost following malignant transformation.