Role of Epac and protein kinase A in thyrotropin-induced gene expression in primary thyrocytes.

cAMP pathway activation by thyrotropin (TSH) induces differentiation and gene expression in thyrocytes. We investigated which partners of the cAMP cascade regulate gene expression modulations: protein kinase A and/or the exchange proteins directly activated by cAMP (Epac). Human primary cultured thyrocytes were analysed by microarrays after treatment with the adenylate cyclase activator forskolin, the protein kinase A (PKA) activator 6-MB-cAMP and the Epac-selective cAMP analog 8-pCPT-2'-O-Me-cAMP (007) alone or combined with 6-MB-cAMP. Profiles were compared to those of TSH. Cultures treated with the adenylate cyclase- or the PKA activator alone or the latter combined with 007 had profiles similar to those induced by TSH. mRNA profiles of 007-treated cultures were highly distinct from TSH-treated cells, suggesting that TSH-modulated gene expressions are mainly modulated by cAMP and PKA and not through Epac in cultured human thyroid cells. To investigate whether the Epac-Rap-RapGAP pathway could play a potential role in thyroid tumorigenesis, the mRNA expressions of its constituent proteins were investigated in two malignant thyroid tumor types. Modulations of this pathway suggest an increased Rap pathway activity in these cancers independent from cAMP activation.

Human thyroid tumor cell lines derived from different tumor types present a common dedifferentiated phenotype.

Cell lines are crucial to elucidate mechanisms of tumorigenesis and serve as tools for cancer treatment screenings. Therefore, careful validation of whether these models have conserved properties of in vivo tumors is highly important. Thyrocyte-derived tumors are very interesting for cancer biology studies because from one cell type, at least five histologically characterized different benign and malignant tumor types can arise. To investigate whether thyroid tumor-derived cell lines are representative in vitro models, characteristics of eight of those cell lines were investigated with microarrays, differentiation markers, and karyotyping. Our results indicate that these cell lines derived from differentiated and undifferentiated tumor types have evolved in vitro into similar phenotypes with gene expression profiles the closest to in vivo undifferentiated tumors. Accordingly, the absence of expression of most thyrocyte-specific genes, the nonresponsiveness to thyrotropin, as well as their large number of chromosomal abnormalities, suggest that these cell lines have acquired characteristics of fully dedifferentiated cells. They represent the outcome of an adaptation and evolution in vitro, which questions the reliability of these cell lines as models for differentiated tumors. However, they may represent useful models for undifferentiated cancers, and by their comparison with differentiated cells, can help to define the genes involved in the differentiation/dedifferentiation process. The use of any cell line as a model for a cancer therefore requires prior careful and thorough validation for the investigated property.

Long-term EGF/serum-treated human thyrocytes mimic papillary thyroid carcinomas with regard to gene expression.

Constitutive activation of the RAS/RAF/MAPK pathway has been found in different tumor types including papillary thyroid carcinomas (PTCs). To get more insight into genes primarily regulated in the human tumor cells, an in vitro model was developed in which primary cultures of human thyrocytes were treated for different times with epidermal growth factor and serum (EGF/serum), which stimulate the MAPK cascade. Gene expression profiles were obtained by microarrays and compared to the expression profiles of PTCs. An evolution from short-term to long-term EGF/serum-treated cells was found, i.e., a program change showing a distinction between gene expression profiles of short-term and long-term EGF/serum-treated cells. The late pattern of EGF/serum stimulated cells converges to the pattern of PTCs. Comparison of these two types of cells with cAMP activated cells, from thyroid-stimulating hormone-treated thyrocytes and autonomous adenomas, showed distinct gene expression profiles for the two pathways. For the two models, an overlap was found in a number of genes which were early induced in vitro but down-regulated later in vitro and in the in vivo tumors. Thus, long-term stimulated human primary cultures demonstrate a clear relation with the tumor in vivo and could therefore be used as models for the disease.

Gene expression in human thyrocytes and autonomous adenomas reveals suppression of negative feedbacks in tumorigenesis.

The cAMP signaling pathway regulates growth of many cell types, including somatotrophs, thyrocytes, melanocytes, ovarian follicular granulosa cells, adrenocortical cells, and keratinocytes. Mutations of partners from the cAMP signaling cascade are involved in tumor formation. Thyroid-stimulating hormone (TSH) receptor and Gsalpha activating mutations have been detected in thyroid autonomous adenomas, Gsalpha mutations in growth hormone-secreting pituitary adenomas, and PKAR1A mutations in Carney complex, a multiple neoplasia syndrome. To gain more insight into the role of cAMP signaling in tumor formation, human primary cultures of thyrocytes were treated for different times (1.5, 3, 16, 24, and 48 h) with TSH to characterize modulations in gene expression using cDNA microarrays. This kinetic study showed a clear difference in expression, early (1.5 and 3 h) and late (16-48 h) after the onset of TSH stimulation. This result suggests a progressive sequential process leading to a change of cell program. The gene expression profile of the long-term stimulated cultures resembled the autonomous adenomas, but not papillary carcinomas. The molecular phenotype of the adenomas thus confirms the role of long-term stimulation of the TSH-cAMP cascade in the pathology. TSH induced a striking up-regulation of different negative feedback modulators of the cAMP cascade, presumably insuring the one-shot effect of the stimulus. Some were down- or nonregulated in adenomas, suggesting a loss of negative feedback control in the tumors. These results suggest that in tumorigenesis, activation of proliferation pathways may be complemented by suppression of multiple corresponding negative feedbacks, i.e., specific tumor suppressors.