Immunohistochemical detection of epithelialmesenchymal transition associated with stemness phenotype in anaplastic thyroid carcinoma

Anaplastic thyroid carcinoma (ATC) is a highly aggressive neoplasm resistant to radiation and chemotherapy. Epithelial-mesenchymal transition (EMT) generating cells with stem cell characteristics have been reported to be associated with chemoradioresistance in cultured cells. However, EMT and stem cell properties in ATC have not been fully investigated. In this study, we retrieved 2 thyroidectomy specimens of ATC with coexisting well differentiated thyroid carcinomas (DTCs) including one papillary carcinoma (PTC) and one follicular carcinoma (FTC). We used im-munohistochemistry to examine the expression of stem cell markers (nestin, CD133 and CD44) and a marker for EMT (E-cadherin). Intense expressions of nestin, CD133 and CD44, and no expression of E-cadherin were observed in both ATCs. In contrast, the PTC and FTC, and non-neoplastic thyroid tissue in both cases were negative for nestin and positive for E-cadherin. The expressions of CD133 and CD44 were variable in the PTC, FTC, and non-neoplastic thyroid tissue and were at a lower level of expression of these markers in the overall pattern. The results confirmed EMT, demonstrated the stem cell phenotype in ATC, and revealed the difference in expression of these markers between ATC and DTCs/non-neoplastic thyroid tissue. Nestin may be the most specific marker for stemness in ATC by immuno-histochemial staining. The results warrant future studies on a large series of cases in order to gain the understanding of the tumor biology and to provide molecular basis for restoring the sensitivities to clinical therapies.     

Evaluation of Lipocalin-2 and Twist expression in thyroid cancers and its relationship with epithelial mesenchymal transition

ObjectiveTo evaluate the expressions of lipocalin-2 (LCN-2) and Twist in thyroid cancers and examine its relationship with epithelial-to-mesenchymal transition (EMT) and clinicopathological factors.Materials and methodsThe expression of LCN-2 and Twist was immunohistochemically evaluated in a total of 249 cases, including 120 patients with papillary thyroid carcinomas (PTC), 34 with follicular thyroid carcinoma (FTC), 15 with medullary thyroid carcinomas (MTC), 20 with non-invasive follicular thyroid neoplasm with papillary-like nuclear features (NIFTP), 47 with follicular adenomas (FA), and 13 with nodular hyperplasia (NH). In addition, the relationship between the expression of EMT markers E-cadherin and vimentin was investigated in malignant cases.ResultsA significant increase was observed in the LCN-2 and Twist expression from NH and FA to NIFTP, MTC, FTC, and PTC (p = 0.001). A high degree of LCN-2 expression was observed in the aggressive variants of PTC (p = 0.002). Twist^high positivity was significantly higher in cases with the EMT-positive mesenchymal phenotype (p = 0.036).ConclusionsLCN-2 and Twist can be helpful diagnostic markers in the differentiation of benign and malignant thyroid nodules. Twist^high expression supports the EMT process in thyroid cancer. LCN-2 and Twist expression may also serve as valuable predictive biomarkers in patients with thyroid cancer. In future, the determination of a LCN-2^high expression in the aggressive variants of PTC may be integrated into targeted treatment strategies.     

The role of cell cycle regulatory protein, cyclin D1, in the progression of thyroid cancer.

Cell cycle progression is facilitated by cyclin-dependent kinases that are activated by cyclins including cyclin D1 and inactivated by cyclin-dependent kinase inhibitors (CDKIs) such as p27. Our previous studies have demonstrated decreased p27 expression in both papillary and more aggressive carcinomas of the thyroid compared to thyroid adenoma and almost similar level of cyclin D1 expression between thyroid adenoma and papillary carcinoma. These results indicate that CDKIs may have an important role in the carcinogenesis of the thyroid and that they probably have a limited role in malignant progression of the thyroid cancer. The role of cyclin D1 in malignant progression of thyroid carcinoma has yet to be established. We studied the expression of cyclin D1 by immunohistochemistry in 34 cases of conventional papillary carcinoma (CPC), 10 cases of minimally invasive follicular carcinoma (MIFC), and 32 cases of more aggressive thyroid carcinoma (ATC), which included 11 tall cell variants, one columnar cell variant of papillary carcinoma, seven insular carcinomas, and 13 anaplastic carcinomas. Cyclin D1 staining was classified by staining score as 0, negative; 1+, less than 25%; 2+, 25 to 50%; and 3+, more than 50% tumor cells staining positive. Kruskal-Wallis one-way ANOVA and Wilcoxon Rank Sum/Mann-Whitney U Test was used to assess the difference in the expression of cyclin D1 between the study groups. Twenty-eight out of the 34 CPCs were cyclin D1 positive, 24 (70%) were 1+, 3 (9%) were 2+, and one (3%) were 3+ positive. Seven of 10 MIFCs were cyclin D1 positive, five (71%) were 1+, and the remaining two (29%) were 2+ positive. On the other hand, 28 of 32 ATCs showed cyclin D1 immunostaining. Of these, three (9%) were 1+, five (13%) were 2+, and 20 (63%) were 3+ positive. This study demonstrates a significant overexpression of cyclin D1 in ATC compared CPC (P < .001) and MIFC (P < .005), suggesting that the cyclin D1 expression may play a role in tumor progression and may have prognostic significance in thyroid cancer.     

Clinical Utility of KAP-1 Expression in Thyroid Lesions

Although there are evidences of the involvement of KAP-1 in other tumors, data on differentiated thyroid carcinomas (DTC) are still lacking. We aimed to evaluate KAP-1 clinical utility in the diagnosis and prognosis of DTC. We used both visual immunohistochemistry and a semiquantitative analysis to evaluate KAP-1 expression in 230 thyroid carcinomas and 131 noncancerous thyroid nodules. There were 43 follicular carcinomas (FC) and 187 papillary thyroid carcinomas (PTC), including 130 classic (CPTC), 4 tall cells (TCPTC), and 53 follicular variants (FVPTC). Patients were followed up for 53.8?±?41 months. They were classified as free-of-disease (142 cases) or poor outcome (25 cases—10 deaths), according to their serum Tg levels and image evidences. KAP-1 was identified in 78 % PTC, 75 % TCPTC, 74 % FC, 72 % FVPTC, 55 % FA, 44 % hyperplasia, and 11 % normal thyroid tissues. A ROC analysis identified malignant nodules with 69 % sensitivity and 75 % specificity, using a cutoff of 73.19. In addition to distinguishing benign from malignant thyroid tissues (p?<?0.0001), KAP-1 expression differentiated CPTC from nodular hyperplasia (p?<?0.0001), CPTC from FA (p?=?0.0028), FVPTC from hyperplasia (p?=?0.0039), and FC from hyperplasia (p?=?0.0025). Furthermore, KAP-1 was more expressed in larger tumors (>4 cm; p?=?0.0038) and in individuals who presented recurrences/metastases (p?=?0.0130). We suggest that KAP-1 may help diagnose thyroid nodules, characterize follicular-patterned thyroid lesions, and identify individuals with poor prognosis.     

Muc-1 Expression May Help Characterize Thyroid Nodules but Does Not Predict Patients’ Outcome

Our purpose was to evaluate MUC1 clinical utility in the diagnosis and prognosis of thyroid cancer patients. We studied the protein expression of MUC1 in 289 thyroid carcinomas and 121 noncancerous thyroid nodules. There were 41 follicular carcinomas (FC) and 248 papillary thyroid carcinomas (PTC) including 149 classic (CPTC), 20 tall cell (TCPTC) and 79 follicular variants (FVPTC). In addition, we used a quantitative real-time PCR (q-PCR) method to measure MUC1 mRNA expression levels in 108 carcinomas, 23 hyperplasias, and 19 FA. According to their serum Tg levels and other evidences of recurrence/metastasis, the patients were classified as free-of-disease (185 cases) or bad outcome (56 cases, 10 deaths). MUC1 protein was identified in 80.2% PTC; 48.8% FC; 68.3% FVPTC; 70% TCPTC; 21.8% FA; 30% hyperplasias and 6% normal thyroid tissues. MUC1 distinguished benign from malignant thyroid tissues (sensitivity?=?89%; specificity?=?53%). MUC1 also differentiated FC from FA (p?=?0.0083). q-PCR mRNA expression of MUC1 also distinguished malignant from benign nodules (Mann–Whitney test, p?MUC1 expression was associated with any clinical or pathological feature of aggressiveness or outcome. We suggest that MUC1 expression may help differentiate follicular patterned thyroid lesions.     

Atypical adenoma of the thyroid diagnosed as anaplastic cancer by cytopathology

Atypical adenoma of the thyroid is a rare form of tumor, and its accurate diagnosis prior to surgical resection is difficult as the histological and pathological morphologies are very similar to those of anaplastic thyroid carcinoma (ATC), and its anaplastic transformation remains to be elucidated. We reported a case of a 75‐year‐old female with a thyroid isthmus nodule diagnosed repeatedly by FNAC as anaplastic carcinoma. Both the first and second FNAC specimen slides showed a large number of scattered or aggregated atypical cells consisting of large, pleomorphic nuclei with irregular membranes, chromatin clumps and prominent nucleoli. The morphology of the surgical specimen was similar to that of an anaplastic carcinoma and although it showed signs of transition from a normal follicular epithelium, there was no invasive growth or mitosis. This lesion was diagnosed as an atypical adenoma, and a papillary carcinoma was also present in the right lobe of the thyroid. Here we evaluate the molecular features of atypical adenomas in comparison with 9 ATC samples, and discuss whether or not atypical adenomas represent a form of premalignant lesion. Ki‐67 expression was found to be very low in atypical adenomas whereas all ATC samples showed high levels of Ki‐67 expression. Epithelial–mesenchymal transition (EMT) marker expression suggested that atypical adenomas maintain their epithelial phenotype to a higher degree than do ATCs. Differential diagnosis between ATC and atypical adenoma is difficult by cytological and histological methods alone, and Ki‐67 and EMT marker expression may support the diagnosis.     

Diagnostic utility of CD56 immunohistochemistry in papillary carcinoma of the thyroid

Diagnosis of papillary thyroid carcinoma (PTC), in many but not all cases, is an easily achievable diagnosis with almost minimal interobservable variability between pathologists. However, some cases of PTC, particularly the follicular variant, are quite challenging and show wide interobservable variability even among expert thyroid pathologists. Since proper diagnosis of PTC is crucial as it affects patients’ clinical management and prognosis, indications of PTC must be clearly apparent to be an objective rather than a subjective diagnosis. Unfortunately, to date, immunohistochemistry and molecular studies have failed to fully solve this problem. In this study, we assessed the protein expression and loss using antibodies against CD56 in normal follicular thyroid epithelium, follicular thyroid lesions, and follicular thyroid neoplasms in an attempt to evaluate its diagnostic value. A total of 185 cases were studied with tissues from 75 carcinomas (72 papillary, 2 follicular, 1 Hürthle cell) and 35 adenomas (32 follicular and 3 Hürthle cell) evaluated by immunohistochemistry for the expression of this marker. Non-neoplastic thyroids included 65 cases: nodular hyperplasia (n=25), thyrotoxic hyperplasia (Grave's disease) (n=5), lymphocytic thyroiditis (n=19), and Hashimoto's thyroiditis (n=6). Ten cases of normal thyroids from radical laryngectomies for laryngeal squamous cell carcinomas were also studied.     

NDRG1 protein overexpression in malignant thyroid neoplasms

OBJECTIVES:

The aim of this study was to examine the expression of the N-myc downstream-regulated gene 1 protein in benign and malignant lesions of the thyroid gland by immunohistochemistry.

INTRODUCTION:

N-myc downstream-regulated gene 1 encodes a protein whose expression is induced by various stimuli, including cell differentiation, exposure to heavy metals, hypoxia, and DNA damage. Increased N-myc downstream-regulated gene 1 expression has been detected in various types of tumors, but the role of N-myc downstream-regulated gene 1 expression in thyroid lesions remains to be determined.

METHODS:

A tissue microarray paraffin block containing 265 tissue fragments corresponding to normal thyroid, nodular goiter, follicular adenoma, papillary thyroid carcinoma (classical pattern and follicular variant), follicular carcinoma, and metastases of papillary and follicular thyroid carcinomas were analyzed by immunohistochemistry using a polyclonal anti- N-myc downstream-regulated gene 1 antibody.

RESULTS:

The immunohistochemical expression of N-myc downstream-regulated gene 1 was higher in carcinomas compared to normal thyroid glands and nodular goiters, with higher expression in classical papillary thyroid carcinomas and metastases of thyroid carcinomas (P < 0.001). A combined analysis showed higher immunohistochemical expression of NDRG1 in malignant lesions (classical pattern and follicular variant of papillary thyroid carcinomas, follicular carcinomas, and metastases of thyroid carcinomas) compared to benign thyroid lesions (goiter and follicular adenomas) (P  =  0.043). In thyroid carcinomas, N-myc downstream-regulated gene 1 expression was significantly correlated with a more advanced TNM stage (P  =  0.007) and age, metastasis, tumor extent, and size (AMES) high-risk group (P  =  0.012).

CONCLUSIONS:

Thyroid carcinomas showed increased immunohistochemical N-myc downstream-regulated gene 1 expression compared to normal and benign thyroid lesions and is correlated with more advanced tumor stages.     

Genomic Landscape of poorly Differentiated and Anaplastic Thyroid Carcinoma

Poorly differentiated thyroid carcinoma (PDTC) and anaplastic thyroid carcinoma (ATC) are aggressive thyroid tumors associated with a high mortality rate of 38–57 % and almost 100 % respectively. Several recent studies utilizing next generation sequencing techniques have shed lights on the molecular pathogenesis of these tumors, providing evidence to support a stepwise tumoral progression from well-differentiated to poorly differentiated, and finally to anaplastic thyroid carcinomas. While BRAF ^V600E and RAS mutations remain the main drivers in aggressive thyroid carcinoma, PDTC and ATC gains additional mutations, e.g., TERT promoter mutation, TP53 mutation, as well as frequent alterations in PIK3CA-PTEN-AKT-mTOR pathway, SWI-SNF complex, histomethyltransferases, and mismatch repair genes. RAS-mutated PDTCs are commonly associated with a histologic phenotype defined by Turin proposal, high frequency of distant metastasis, high thyroid differentiation score, and a RAS-like gene expression profile, whereas BRAF-mutated PDTCs are usually defined solely by the Memorial Sloan Kettering Cancer Center (MSKCC) criteria with a propensity for nodal metastasis and are less differentiated with a BRAF-like expression signature. Such demarcation is largely lost in ATC which is characterized by genomic complexity, heavy mutation burden, and profound undifferentiation. Additionally, several molecular events, e.g., EIF1AX mutation, mutation burden, and chromosome 1q gain in PDTCs, as well as EIF1AX mutation, chromosome 13q loss, and 20q gains in ATCs, may serve as adverse prognostic markers predicting poor clinical outcome.     

Stage-Specific Embryonic Antigen-1 (SSEA-1) Expression in Thyroid Tissues

Stage-specific embryonic antigen-1 (SSEA-1), also known as CD15, is a member of a cluster of differentiation antigens that have been identified in various normal tissues and in different types of cancers including papillary and medullary thyroid carcinoma. SSEA-1 may be expressed in normal stem cells and cancer stem-like cells. To evaluate the potential diagnostic and prognostic utility of SSEA-1 in thyroid tumors, we analyzed the expression of SSEA-1 in normal and neoplastic thyroid tissues by immunohistochemistry (IHC) using a tissue microarray with 158 different tissue cores. To evaluate the potential utility of SSEA-1 as a surface marker, we also assessed the expression of SSEA-1 in thyroid cell lines by flow cytometric analysis. SSEA-1 immunoreactivity was identified in malignant thyroid follicular epithelial cancers but not in the benign thyroid tissues. Anaplastic thyroid (ATC) (80 %) and conventional papillary thyroid carcinoma (PTC) (60.7 %) showed significantly higher percentage of cases that were SSEA-1 immunoreactive than follicular variant of papillary thyroid carcinoma (FVPTC) (20.6 %) and follicular carcinoma (FCA) (32.1 %). Flow cytometric analysis of cultured thyroid cell lines showed that a small subpopulation of ATC and PTC thyroid tumor cells had SSEA-1 immunoreactivity which may represent thyroid cancer stem-like cells. The ATC cells expressed more SSEA-1 immunoreactive cells than the PTC cell lines. Our findings suggest that expression of SSEA-1 immunoreactivity in thyroid neoplasms was associated with more aggressive thyroid carcinomas. SSEA-1 is a marker that detects malignant thyroid neoplasms in formalin-fixed paraffin-embedded thyroid tissue sections and may be a useful marker for thyroid cancer stem-like cells.     

Real-time analysis of beta- and gamma-catenin mRNA expression in ret/PTC-1 activated and nonactivated thyroid tissues.

Our group has previously demonstrated an association between ret/PTC-1 activation and decreased E-cadherin mRNA levels in papillary thyroid carcinoma. We also observed similarities in the E-cadherin expression profiles of Hashimoto thyroiditis and ret/PTC-1-positive papillary thyroid carcinomas and have hypothesized that ret/PTC-1 activation might cause not only the structural and nuclear peculiarities of PTC but also an immune reaction to thyroid epithelium. The objective of this study was to examine the expression of E-cadherin's ligands, beta- and gamma-catenin, in various thyroid tissue types in the context of ret/PTC-1 positivity using laser capture microdissection and TaqMan (Applied Biosystems, Foster City, CA). One-Step RT-PCR. Beta-catenin mRNA levels were found to be consistently decreased in both papillary and anaplastic carcinomas when compared with a normal/follicular adenoma group. A significant difference in expression levels was observed between papillary and follicular thyroid carcinomas with the latter having elevated mRNA levels of beta-catenin. Gamma-catenin mRNA was decreased in anaplastic carcinomas compared with normal/follicular adenoma groups. A similar expression profile of gamma-catenin as beta-catenin was observed in papillary and follicular carcinomas with the latter once again having higher mRNA levels. These results therefore suggest that although beta- and gamma-catenin may play a role in the progression of thyroid cancer in general, they do not appear to be associated with ret/PTC-1-modulated pathways.     

miR-183 promotes radioresistance of lung adenocarcinoma H1299 cells via epithelial-mesenchymal transition

Lung adenocarcinomas are usually sensitive to radiation therapy, but some develop resistance. Radiation resistance can lead to poor patient prognosis. Studies have shown that lung adenocarcinoma cells (H1299 cells) can develop radioresistance through epithelial-mesenchymal transition (EMT), and this process is regulated by miRNAs. However, it is unclear which miRNAs are involved in the process of EMT. In our present study, we found that miR-183 expression was increased in a radioresistant lung adenocarcinoma cell line (H1299R cells). We then explored the regulatory mechanism of miR-183 and found that it may be involved in the regulation of zinc finger E-box-binding homeobox 1 (ZEB1) expression and mediate EMT in lung adenocarcinoma cells. qPCR results showed that miR-183, ZEB1, and vimentin were highly expressed in H1299R cells, whereas no difference was observed in E-cadherin expression. Western blot results showed that ZEB1 and vimentin were highly expressed in H1299R cells, while E-cadherin expression was decreased. When miR-183 expression was inhibited in H1299R cells, radiation resistance, proliferation, and cell migration were decreased. The expression of ZEB1 and vimentin in H1299R cells was decreased, while the expression of E-cadherin was increased. Moreover, miR-183 overexpression in H1299 cells enhanced radiation resistance, proliferative capacity, and cell migration ability. The expression of ZEB1 and vimentin in H1299 cells was increased, while that of E-cadherin was decreased. In conclusion, miR-183 may promote EMT and radioresistance in H1299 cells, and targeting the miR-183-ZEB1 signaling pathway may be a promising approach for lung cancer treatment.     

Beta- and gamma-catenin expression in thyroid carcinomas

Cadherins are calcium-dependent cell–cell adhesion molecules whose intracellular domain forms a complex with proteins required for their function, called catenins. Down-regulation of cadherins has frequently been detected in many types of human carcinomas, being associated with tumour progression. The present study investigates the immunohistochemical expression of E-cadherin and beta- and gamma-catenin in 27 human thyroid carcinomas. E-cadherin immunoreactivity was found to be decreased at cell–cell contacts in 8/15 (53 per cent) papillary, 5/7 (71 per cent) follicular, and 5/5 (100 per cent) anaplastic carcinomas. Beta-catenin membrane localization was found to be decreased in 6/15 (40 per cent) papillary, 2/7 (28 per cent) follicular, and 5/5 (100 per cent) anaplastic carcinomas. Gamma-catenin expression was partially or totally lost in 13/15 (86 per cent) papillary, 6/7 (85 per cent) follicular, and 5/5 (100 per cent) anaplastic carcinomas. A normal pattern of expression for these three molecules was observed in areas of normal tissue in each sample. These data indicate that in addition to E-cadherin, catenins are also down-regulated at cell–cell junctions in thyroid tumours and could represent potentially useful differentiation and/or transformation markers. The high frequency of alterations of gamma-catenin expression found in thyroid carcinomas suggests an important role for this gene product in thyroid carcinogenesis. © 1998 John Wiley & Sons, Ltd.     

Immunohistochemical expressions of fatty acid synthase and phosphorylated c-Met in thyroid carcinomas of follicular origin

Thyroid carcinoma is the most common endocrine malignancy and the first cause of death among endocrine cancers. Fatty acid synthase (FASN) and c-Met are overexpressed in many types of human cancers. Recent studies have suggested a functional interaction between FASN and c-Met. However, their roles in thyroid carcinomas have not been fully investigated. In this study, we evaluated the expressions of FASN and phosphorylated (p)-c-Met by using immunohistochemistry in thyroid carcinomas of follicular origin, from 32 patients. The adjacent non-neoplastic thyroid tissue was also evaluated for comparison. Immunoreactive intensity and extensiveness were semi-quantified. The overexpression of FASN was observed in a subset of papillary thyroid carcinomas (PTC) including the classical type and tall cell, follicular, trabecular/insular and diffuse sclerosing variants, a subset of follicular thyroid carcinomas (FTC), and the PTC and FTC components in anaplastic thyroid carcinomas (ATC). No overexpression was observed in the ATCs per se and the columnar cell, solid, and cribriform variants of PTCs. All Hürthle cell variant FTCs and non-neoplastic Hürthle cells demonstrated positive staining for FASN while the non-neoplastic follicular cells without Hürthle cell change were negative. An association in overexpression between FASN and p-c-Met was observed in the majority of carcinomas as well as in the non-neoplastic Hürthle cells. In conclusion, overexpressions of FASN and p-c-Met were observed in a subset of thyroid carcinomas of follicular origin, which may be of values for targeted therapy and predicting prognosis while the positive immunostaining for these immunomarkers may be nonspecific for Hürthle cell thyroid carcinomas.     

Well-Differentiated Thyroid Cancer Neovasculature Expresses Prostate-Specific Membrane Antigen—a Possible Novel Therapeutic Target

Prostate-specific membrane antigen (PSMA), a type II transmembrane glycoprotein receptor, is highly expressed in prostate cancer and in the tumor neovasculature of colon, breast, and adrenocortical tumors. Here, we analyzed PSMA expression in the neovasculature of various thyroid cancer subtypes and assessed whether PSMA expression is correlated with aggressive behavior. From a prospectively maintained database, we evaluated 91 samples from 68 patients, including 37 primary differentiated thyroid cancers (DTCs) [11 classic papillary (cPTC), 9 follicular-variant (FvPTC), 11 follicular (FTC), 6 radioactive iodine-refractory (RAIR)], 5 anaplastic (ATC) carcinomas, 9 distant and 12 lymph node metastases, 21 benign thyroid nodules, and 7 normal thyroid specimens. Formalin-fixed paraffin-embedded tissue blocks were immunostained for vascular endothelial marker CD31 and PSMA with proper controls. PSMA expression was not detected in normal thyroid tissue. DTC tumors demonstrated a significantly higher PSMA expression, in regard to both intensity and percentage of vessels stained, than benign tumors (p < 0.001). Among the histologic subtypes, cPTC, FTC, and RAIR carcinomas demonstrated the highest percent of moderate to strong PSMA staining. PSMA expression was seen more frequently in specimens from distant metastases (100%) compared with specimens from only lymph node metastases (67%). PSMA is significantly overexpressed in the neovasculature of DTCs compared with normal and benign thyroid nodules specifically with increased expression in RAIR carcinomas and distant metastases. PSMA should be further explored as a novel therapeutic target for metastatic and RAIR carcinomas.