BRAF mutations in thyroid tumors are restricted to papillary carcinomas and anaplastic or poorly differentiated carcinomas arising from papillary carcinomas

Activating point mutations of the BRAF gene have been recently reported in papillary thyroid carcinomas. In this study, we analyzed 320 thyroid tumors and six anaplastic carcinoma cell lines and detected BRAF mutations in 45 (38%) papillary carcinomas, two (13%) poorly-differentiated carcinomas, three (10%) anaplastic carcinomas, and five (83%) thyroid anaplastic carcinoma cell lines but not in follicular, Hürthle cell, and medullary carcinomas, follicular and Hürthle cell adenomas, or benign hyperplastic nodules. All mutations involved a T-->A transversion at nucleotide 1796. In papillary carcinomas, BRAF mutations were associated with older age, classic papillary carcinoma or tall cell variant histology, extrathyroidal extension, and more frequent presentation at stages III and IV. All BRAF-positive poorly differentiated and anaplastic carcinomas contained areas of preexisting papillary carcinoma, and mutation was present in both the well-differentiated and dedifferentiated components. These data indicate that BRAF mutations are restricted to papillary carcinomas and poorly differentiated and anaplastic carcinomas arising from papillary carcinomas. They are associated with distinct phenotypical and biological properties of papillary carcinomas and may participate in progression to poorly differentiated and anaplastic carcinomas.     

BRAF mutations are not a major event in post-Chernobyl childhood thyroid carcinomas

The BRAF gene has been shown to be a major target for mutations in papillary thyroid carcinoma (PTC) (36-69%), which forms almost all of the over 2000 cases of thyroid carcinoma that have occurred in Chernobyl. BRAF is activated by point mutation, and were it to occur at a high frequency in Chernobyl-related tumors, it would challenge the dominant role of double-strand breaks in radiation-induced PTC. In a previous study, we detected the BRAF V600E mutation in 46% (23 of 50) of sporadic adult PTC. Using the same methodology, we have analyzed 34 post-Chernobyl PTC and detected RET/PTC rearrangements in 14 (41%) and BRAF mutations (V600E) in four (12%). These two alterations did not coexist in any PTCs. The mean age at exposure of patients with PTC showing BRAF mutation was higher than that of patients with tumors without BRAF mutation irrespective of their RET status. We have also analyzed 17 sporadic cases of childhood PTC and found that only one (6%) harbored the BRAF V600E mutation. We conclude that the frequency of BRAF mutations is significantly lower (P = 0.0008) in post-Chernobyl PTC than in adult sporadic PTC, whereas no significant difference was found between post-Chernobyl and sporadic childhood PTCs.     

BRAF mutations are uncommon in papillary thyroid cancer of young patients.

Mortality is low for young patients (younger than 21 years) with papillary thyroid cancer (PTC), and different mutations might contribute to this. Previous studies detected ret/PTC rearrangements more frequently in PTC from children than adults, and recent reports describe a high incidence of BRAF T1796A transversion in adult PTC. However, BRAF mutations have not been adequately studied in PTC from young patients. We amplified and sequenced segments of the BRAF gene spanning the T1796A transversion site in 14 PTC from patients 10-21 years of age (mean, 17.5 +/- 3.5 years). The PTC (7 = class 1; 5 = class 2; 1 = class 3) ranged from 0.7-2.9 cm in diameter (mean, 1.4 +/- 0.75 cm). None of them (0/14) contained BRAF T1796A and none recurred (mean follow-up, 66 +/- 40 months). This incidence of BRAF T1796A is significantly less than that reported for adult PTC (270/699, 38.6%, p = 0.0015) in several series. None of our PTC (0/10) contained ras mutations, but 7/12 (58%) contained ret/PTC rearrangements. We conclude that BRAF mutations are less common in PTC from young patients, and ret/PTC rearrangements were the most common mutation found in these childhood PTC.     

The correlation between BRAF mutations, RET/PTC rearrangements and platelet-derived growth factor B expression in papillary thyroid carcinomas

Objective To investigate the prevalence of BRAF T1799A mutation and RET/PTC rearrangement in Qingdao and detect the expression of platelet-derived growth factor B(PDGF-B) in order to investigate the correlation     

Thyroid hormone receptor beta mutations in the 'hot-spot region' are rare events in thyroid carcinomas

Thyroid cancer constitutes the most frequent endocrine neoplasia. Targeted expression of rearranged during transfection (RET)/papillary thyroid carcinoma (PTC) and V600E V-raf murine sarcoma viral oncogene homolog B1 (BRAF) to the thyroid glands of transgenic mice results in tumours similar to those of human PTC, providing evidence for the involvement of these oncogenes in PTC. Kato et al. developed a mouse model that mimics the full spectrum of the human follicular form of thyroid cancer (FTC). FTC rapidly develops in these mice through introduction of the thyroid hormone receptor beta (THRB)(PV) mutant on the background of the inactivated THRB wt locus. Our aim was to verify if, in the context of human follicular thyroid carcinogenesis, THRB acted as a tumour suppressor gene. We screened for mutations of the THRB gene in the hot-spot region, spanning exons 7-10, in 51 thyroid tumours and six thyroid cancer cell lines by PCR and direct sequencing. We did not find mutations in any of the tumours or cell lines analysed. Our findings suggest that, in contrast to the findings on the THRB-mutant transgenic mice, THRB gene mutations are not a relevant mechanism for human thyroid carcinogenesis.     

Approach to hepatic involvement by endocrine tumors of the gastrointestinal tract

Endocrine cells of the GI tract derive from stem cells of the neurocrest. They belong to the diffuse endocrine system as defined by Feyrter and share common features, such as the capacity for APUD cells. From these regulatory peptide-producing cells, endocrine tumors may develop with specific clinical symptoms. In some other endocrine GI tumors, no hormone secretion has yet been found, and for some regulatory peptides, no specific clinical entity has yet been identified. Diagnosis can be confirmed by hormone measurements and by specific immunohistochemistry or electron microscopy of the tumor tissue. Metastases synthesize and secrete peptide hormones like those of the primary tumors. The principal target organ for metastases is the liver. Several approaches to treatment of hepatic tumor deposits may reduce tumor mass with consequent reduction of effective plasma hormone levels. There are also systemic treatments for neuroendocrine tumors from the GEP system.     

BRAF mutations are not an alternative explanation for the molecular etiology of ras-mutation negative cold thyroid nodules.

Activation of the RAS/RAF/MEK/ERK/MAP kinase pathway is a known mediator of signaling that results in cellular proliferation. Moreover, this activation can lead to a growth advantage of tumor cells. Therefore, mitogenic mutations in the RAS family of oncogenes are detectable in a significant percentage in most tumors. Moreover, mutations in the BRAF gene have recently been suggested as an alternate predominant cause of colorectal and papillary thyroid cancers without ras mutations. Similar to neoplasms of other organs mutations of all three ras genes can be found in thyroid tumors. In our set of 40 cold thyroid adenoma and adenomatous nodules ras mutations were detected in only a single case. We therefore tested these hypofunctional tumors for BRAF mutations. Genomic DNA was extracted from nodular and surrounding tissue. Mutational hot spots in exons 11 and 15 of the BRAF gene were polymerase chain reaction (PCR) amplified and denaturing gradient gel electrophoresis was used to screen for mutations. No point mutation could be found in the two exons of the BRAF gene. Our study suggests that BRAF mutations are rather rare in solitary cold adenomas and adenomatous nodules and do not explain the molecular etiology of ras mutation-negative cold thyroid nodules.     

Detection of BRAF mutation in thyroid papillary carcinomas by mutant allele-specific PCR amplification (MASA)

OBJECTIVE: The somatic point mutation in the BRAF gene, which results in a valine-to-glutamate substitution at residue 600 (BRAF(V600E)), is an ideal hallmark of papillary thyroid carcinoma (PTC). However, its prevalence is varyingly reported in different studies, and its expression in the follicular variant PTC is controversial, reducing its potential usefulness as diagnostic marker. DESIGN AND METHODS: We developed an assay based on mutant allele-specific PCR amplification (MASA) to detect BRAF mutation. We compared the sensitivity of MASA, single-strand conformation polymorphism (SSCP) and direct DNA sequencing of PCR products. Then, we used MASA 78 to analyze 78 archival thyroid tissues, including normal samples, follicular adenomas, follicular carcinomas and PTC. RESULTS: The MASA assay proved to be a more sensitive method than SSCP and DNA sequencing of PCR products. BRAF mutation was found by MASA in 19/43 (44.2%) of PTC, including 14/31 (45.2%) classic forms and 5/12 (41.7%) follicular variants. No mutations of BRAF were detected in the normal thyroid tissues, nor in follicular adenomas or follicular carcinomas. No correlation was found between BRAF mutation and clinicopathologic features nor with recurrence during a postoperative follow-up period of 4-11 years. BRAF(V600E) significantly correlated with absence of node metastasis. CONCLUSIONS: BRAF(V600E) is present in PTC, both in the classic form and in follicular variant with similar prevalence. No correlation was found between BRAF mutation and aggressive clinical behavior. MASA-PCR proved to be a specific, sensitive and reliable method to detect BRAF T1799A in DNA extracted from different sources, including cytologic samples obtained either fresh or from archival glass slides. We propose this method as a useful tool to improve accuracy of preoperative diagnosis identifying PTC from biopsies with indeterminate cytologic findings.     

Ras mutations are rare in solitary cold and toxic thyroid nodules

OBJECTIVE: Activation of ras proto-oncogenes as a result of point mutations is detectable in a significant percentage of most types of tumour. Similar to neoplasms of other organs, mutations of all three ras genes can be found in thyroid tumours. H-, K- and N-ras mutations have been detected in up to 20% of follicular adenomas and adenomatous nodules which were not functionally characterized. This raises the question as to whether ras mutations are specific for hypofunctional nodules and TSH receptor mutations for hyperfunctioning nodules. DESIGN: To investigate ras and TSH receptor mutations with respect to functional differentiation we studied 41 scintigraphically cold nodules and 47 toxic thyroid nodules. To address the likelihood of a somatic mutation we also studied the clonal origin of these tumours. MEASUREMENTS: Genomic DNA was extracted from nodular and surrounding tissue. Mutational hot spots in exons 1 and 2 of the H- and K-ras gene were PCR amplified and sequenced using big dye terminator chemistry. Denaturing gradient gel electrophoresis (DGGE) was used to verify sequencing results for the H-ras gene and to analyse the N-ras gene because its greater sensitivity in detecting somatic mutations. Clonality of nodular thyroid tissue was evaluated using X-Chromosome inactivation based on PCR amplification of the human androgen receptor locus. RESULTS: Monoclonal origin was detectable in 14 of 23 informative samples from cold thyroid nodules. In toxic thyroid nodules the frequency of clonal tissue was 20 in 30 informative cases. Only one point mutation could be found in the N-ras gene codon 61 (Gly to Arg) in a cold adenomatous nodule which was monoclonal. In toxic thyroid nodules no ras mutation was detectable. CONCLUSION: Our study suggests that ras mutations are rare in solitary cold and toxic thyroid nodules and that the frequent monoclonal origin of these tumours implies somatic mutations in genes other than H-, K- and N-ras.     

BRAF(V599E) mutation is the leading genetic event in adult sporadic papillary thyroid carcinomas

Activating mutations of BRAF have been identified in a variety of human cancers, most notably melanomas and papillary thyroid carcinomas (PTCs). The aim of the present study was to disclose the role of BRAF mutations in thyroid carcinoma development. Seventy-two thyroid tumors, including 60 PTCs, six follicular adenomas, five follicular carcinomas, and one anaplastic carcinoma, were studied. BRAF mutation screening focused on exon 15 and exon 11 of the gene by single-stranded conformational polymorphism and sequence analysis. Search of RET/PTC expression was conducted with the RT-PCR technique. The molecular genetic study of the BRAF gene showed the presence of a missense thymine to adenine transversion at nucleotide 1796, resulting in the V599E substitution, in 24 of 60 PTCs (40%), none of six follicular adenomas, and none of five follicular carcinomas or one anaplastic carcinoma. Moreover, nine of 60 PTCs (15%) presented RET/PTC expression. A genetico-clinical association analysis showed a statistically significant correlation between BRAF mutation and development of PTCs of the classic papillary histotype (P = 0.038). On the contrary, no link could be detected between expression of BRAF(V599E) and age at diagnosis, gender, dimension, and local invasiveness of the primary cancer, presence of lymph node metastases, tumor stage, and multifocality of the disease. These data clearly confirm that BRAF(V599E) is the more common genetic alteration found to date in adult sporadic PTCs, that it is unique for this thyroid cancer histotype, and that it might drive the development of PTCs of the classic papillary subtype.