Acrylamide, an in vivo thyroid carcinogenic agent, induces DNA damage in rat thyroid cell lines and primary cultures.

Chronic treatment of rats with acrylamide induces various tumors among which thyroid tumors are the most frequent. The aim of the present study was to develop an in vitro model of acrylamide action on thyroid cells to allow the investigation of the mechanism of this tumorigenic action. The first part of the study considered as targets, characteristics of thyroid metabolism, which could explain the thyroid specificity of acrylamide action: the cAMP mitogenic effect and the important H2O2 generation by thyroid cells. However, acrylamide did not modulate H2O2 or cAMP generation in the thyroid cell models studied. No effect on thyroid cell proliferation was observed in the rat thyroid cell line FRTL5. On the other hand, as shown by the comet assay, acrylamide induced DNA damage, as the positive control H2O2 in the PC Cl3 and FRTL5 rat thyroid cell lines, as well as in thyroid cell primary cultures. The absence of effect of acrylamide on H2AX histone phosphorylation suggests that this effect does not reflect the induction of DNA double strand breaks. DNA damage leads to the generation of mutations. It is proposed that such mutations could play a role in the carcinogenic effect of acrylamide. The mechanism of this effect can now be studied in this in vitro model.

Sphingolipid-cholesterol domains (lipid rafts) in normal human and dog thyroid follicular cells are not involved in thyrotropin receptor signaling.

Partition of signaling molecules in sphingolipid-cholesterol-enriched membrane domains, among which are the caveolae, may contribute to signal transduction efficiency. In normal thyroid, nothing is known about a putative TSH/cAMP cascade compartmentation in caveolae or other sphingolipid-cholesterol-enriched membrane domains. In this study we show for the first time that caveolae are present in the apical membrane of dog and human thyrocytes: caveolin-1 mRNA presence is demonstrated by Northern blotting in primary cultures and that of the caveolin-1 protein by immunohistochemistry performed on human thyroid tissue. The TSH receptor located in the basal membrane can therefore not be located in caveolae. We demonstrate for the first time by biochemical methods the existence of sphingolipid-cholesterol-enriched domains in human and dog thyroid follicular cells that contain caveolin, flotillin-2, and the insulin receptor. We assessed a possible sphingolipid-cholesterol-enriched domains compartmentation of the TSH receptor and the alpha- subunit of the heterotrimeric G(s) and G(q) proteins using two approaches: Western blotting on detergent-resistant membranes isolated from thyrocytes in primary cultures and the influence of 10 mm methyl-beta-cyclodextrin, a cholesterol chelator, on basal and stimulated cAMP accumulation in intact thyrocytes. The results from both types of experiments strongly suggest that the TSH/cAMP cascade in thyroid cells is not associated with sphingolipid-cholesterol-enriched membrane domains.

Oncogenic mutations in the thyrotropin receptor of autonomously functioning thyroid nodules in the Japanese population.

OBJECTIVE: Constitutively activating mutations of the thyrotropin receptor (TSHR) have been found in the majority of autonomously functioning thyroid nodules (AFTNs) in European patients. The reported frequency of these mutations varies among reports but amounts to 50-80%. To date, only one such mutation responsible for AFTNs has been identified in the Japanese population and the pathogenic role of such mutations in Japanese AFTNs has been questioned. In the present study, we evaluated the frequency of activating mutations in the TSHR and G(alpha)s in 10 Japanese AFTNs. DESIGN: Genomic DNA was extracted from fresh frozen tissue. The TSHR and the almost entire sequence of the gene coding for the alpha subunit of Gs have been amplified and sequenced. RESULTS: In sequence analysis, four mutations in the TSHR (T632A, I486M, M453T and L512R) were found. To complete our analysis, we searched mutations in the gene coding for the alpha subunit of Gs, in the samples negative for TSHR mutations. In one case a mutation (R201H) affecting GTPase activity was found. CONCLUSIONS: If we focus on the solitary nodules, we obtain the same mutation proportion as in European patients (70%). The absence of TSHR and G(alpha)s mutations in a significant proportion of autonomous adenomas in multinodular goiters suggests that other causes may also play a role in the genesis of these lesions.

Mutation analysis of the Epac--Rap1 signaling pathway in cold thyroid follicular adenomas.

OBJECTIVE: The cyclic AMP (cAMP) cascade is the main regulatory pathway in thyrocytes. Whilst activating mutations in the TSH receptor or in the Gs alpha-subunit, which increase cAMP levels, have been shown to be responsible for 80% of the autonomous adenomas, no such mutations have been observed in the other types of thyroid tumors, suggesting that other mechanisms exist. The discovery of Epac ('exchange nucleotide protein directly activated by cAMP'), a novel cAMP-binding protein, which is strongly expressed in the thyroid, raised the possibility of a role for this protein in the generation of the unexplained cold thyroid follicular adenomas. Thus, we investigated whether activating mutations in either Epac or Rap (the downstream target of Epac) could be responsible for the generation of these thyroid nodules. DESIGN: Epac and Rap1 (Rap1A and Rap1B) cDNAs were sequenced in 10 patients. The sequencing of the cDNAs was realized on both strands in the cold nodule and the juxtanodular tissue of each patient. RESULTS: No mutations in either Epac or Rap1 cDNAs were found. For five patients, a polymorphism in Epac at codon 332 (Gly--Ser) was observed. CONCLUSIONS: In this report, we show that the cAMP--Epac--Rap1 signaling pathway in the thyroid gland does not play a major role in the generation of cold thyroid follicular adenomas, since no mutations in either Epac or Rap1 could be observed in the 10 nodules studied.

Expression of multiple adenylyl cyclase isoforms in human and dog thyroid.

Although the TSH receptor and Galpha(s), which activate the cAMP cascade in the thyroid gland have been much studied, nothing is known about the adenylyl cyclase (AC) isoforms which are actually involved in this pathway. To characterize the cAMP generation in the dog and human thyroid gland, resulting from the presence of distinct adenylyl cyclase families, the responses to various agents (Ca2+, calmodulin (CaM), phorbol esters (TPA) and thapsigargin (Tg)) were studied. These experiments suggest a role of at least two families of cyclases: cyclases negatively modulated by Ca2+ (ACV or ACVI) and cyclases positively modulated by PKC (ACII, ACIII or ACVII). To further analyze by other experimental procedures the expression pattern of the cyclase isoforms in the thyroid gland, Northern blotting, Western blotting and RT-PCR experiments were performed. The results clearly suggest that in both species, three different adenylyl cyclases ACIII, ACVI and ACIX are mainly expressed in thyrocytes.