Skip to main content

Main menu

  • Home
  • Current Issue
  • Archive
  • Info for
    • Authors
    • Editorial Policies
    • Subscribers
    • Advertisers
    • Editorial Board
  • Other Publications
    • In Vivo
    • Cancer Genomics & Proteomics
    • Cancer Diagnosis & Prognosis
  • More
    • IIAR
    • Conferences
    • 2008 Nobel Laureates
  • About Us
    • General Policy
    • Contact
  • Other Publications
    • Anticancer Research
    • In Vivo
    • Cancer Genomics & Proteomics

User menu

  • Register
  • Subscribe
  • My alerts
  • Log in
  • My Cart

Search

  • Advanced search
Anticancer Research
  • Other Publications
    • Anticancer Research
    • In Vivo
    • Cancer Genomics & Proteomics
  • Register
  • Subscribe
  • My alerts
  • Log in
  • My Cart
Anticancer Research

Advanced Search

  • Home
  • Current Issue
  • Archive
  • Info for
    • Authors
    • Editorial Policies
    • Subscribers
    • Advertisers
    • Editorial Board
  • Other Publications
    • In Vivo
    • Cancer Genomics & Proteomics
    • Cancer Diagnosis & Prognosis
  • More
    • IIAR
    • Conferences
    • 2008 Nobel Laureates
  • About Us
    • General Policy
    • Contact
  • Visit us on Facebook
  • Follow us on Linkedin
Research ArticleExperimental Studies

Anaplastic Thyroid Carcinoma Exhibits Intratumoral Molecular Homogeneity for a Therapeutic Target Panel

SHAUN DEEN, OBI L. GRIFFITH, HAMID MASOUDI, ALLEN GOWN, STEVEN J.M. JONES and SAM M. WISEMAN
Anticancer Research July 2009, 29 (7) 2437-2444;
SHAUN DEEN
  • Find this author on Google Scholar
  • Find this author on PubMed
  • Search for this author on this site
OBI L. GRIFFITH
  • Find this author on Google Scholar
  • Find this author on PubMed
  • Search for this author on this site
HAMID MASOUDI
  • Find this author on Google Scholar
  • Find this author on PubMed
  • Search for this author on this site
ALLEN GOWN
  • Find this author on Google Scholar
  • Find this author on PubMed
  • Search for this author on this site
STEVEN J.M. JONES
  • Find this author on Google Scholar
  • Find this author on PubMed
  • Search for this author on this site
SAM M. WISEMAN
  • Find this author on Google Scholar
  • Find this author on PubMed
  • Search for this author on this site
  • For correspondence: smwiseman@providencehealth.bc.ca
  • Article
  • Figures & Data
  • Info & Metrics
  • PDF
Loading

Abstract

Background: The objective of this work was to determine if molecular heterogeneity exists between different intratumoral histological subtype foci of anaplastic thyroid carcinoma (ATC). Materials and Methods: A tissue microarray composed of 12 ATC specimens from 6 patients (two discrete histological subtype foci from each tumor) were evaluated for expression of 51 different molecular markers. Significant associations between marker staining and tumor focus (primary versus secondary) or subtype (epithelioid, giant cell, or spindled) were determined using contingency table statistics and samples and markers were clustered using a hierarchical clustering algorithm. Correlation between marker staining for the two tumor foci was also evaluated for each patient using a Spearman correlation. Results: Significant correlations and clustering were observed for the overall staining patterns for paired anaplastic foci from the same patient. This suggests that the different intratumoral foci showed consistent or homogeneous staining. Conclusion: These results suggest that observed ATC phenotypic heterogeneity does not necessarily reflect heterogeneity for therapeutic target expression.

  • Anaplastic carcinoma
  • thyroid cancer
  • intratumoral molecular homogeneity

Anaplastic thyroid carcinoma (ATC) is an uncommon endocrine malignancy with a grim prognosis. ATC most commonly presents as an enlarging neck mass in an elderly patient and up to half of these patients have metastatic disease identified at their initial clinical presentation (1). According to the current literature the mean survival time for ATC ranges from 2 to 11 months, with few patients surviving longer than 1 year (2). Often, anaplastic thyroid tumors are not surgically resectable and treatment is palliative and based on multimodality therapy. Multimodal treatment often includes hyperfractionated radiotherapy and doxorubicin-based chemotherapy. However, while multimodal treatment protocols may control local disease, most patients eventually die from distant metastases (3, 4).Thus, there is a current need to develop new treatments for this fatal malignancy.

Previous studies have identified numerous molecular markers that characterize ATC (5). Some of these markers, including the epidermal growth factor receptor (EGFR or HER1), Cyclin D1 and p53, may represent important molecular targets for anticancer agents. Cetuximab and erlotinib are examples of drugs currently clinically utilized to treat cancer that act by targetting EGFR (6). Targeted therapeutic drugs are now being clinically utilized to treat numerous human malignancies including lung, breast, colorectal, and gastrointestinal stromal tumors (GISTs). These drugs have also been found to improve outcomes for individuals diagnosed with metastatic disease (7-10). However, despite impressive initial responses of some tumors to therapy, the development of drug resistance and disease progression eventually occurs in the majority of cases. We hypothesize that one of the molecular mechanisms that contributes to the resistance that develops to targeted treatments may be a consequence of intratumoral molecular heterogeneity.

The literature describes 3 principal histological subtypes of ATC: spindle cell, giant cell and squamoid/epithelioid (11-12). The principal objective of this study was to evaluate the different intratumoral histological subtype foci of primary anaplastic thyroid tumors, and to determine if differences in tumor phenotype reflect intratumoral molecular heterogeneity for a panel of potential targets for treatment. In a population-based ATC patient cohort of 6 cases, each with 2 discrete intratumoral subtype foci, the expression of a panel of potential molecular targets for disease therapy was evaluated. This was carried out utilizing tissue microarrays (TMAs); the 51 markers evaluated are listed in Table I.

Materials and Methods

Sequential archival cases of ATC, with available paraffin blocks that had been diagnosed and treated in British Columbia Canada over a 20 year period (January 1, 1984 through December 31, 2004) were identified through the provincial tumor registry for TMA construction. All patients had newly diagnosed ATC and their clinical data were retrospectively collected from hospital charts. Clinicopathological data collected included patient: age, sex, type of therapy, duration of clinical follow-up and survival. This study was approved by our Research Ethics board. Two endocrine pathologists confirmed the diagnosis for each case.

Hematoxylin and eosin (H&E) stained sections of each tumor were examined and the areas of ATC were marked on both the slide and the corresponding paraffin block for TMA construction. TMA construction was carried out in a manner that has been previously described (13). All of the archival blocks for each of the 32 ATC cases were evaluated. However, only 6 ATC cases had 2 discrete anaplastic subtype foci present on pathological case review and these comprised our study cohort.

All of the study cohort ATC samples were stained for a panel of 51 molecular markers as listed in Table I. The dilutions, antigen retrieval methods, and other details for 51 markers have been previously described (14). All antibodies were optimized for thyroid tissue according to the manufacturers' instructions and for each case appropriate positive and negative controls were utilized.

Two pathologists that were blinded to all clinical data examined the stained TMA sections in order to evaluate expression of the molecular markers. The 2 discrete subtype foci from each ATC were each scored using a pre-determined scoring system. The scoring systems utilized were based on previously published reports of immunohistochemical studies evaluating these markers and have been previously described (14). All scores were recorded in a standardized TMA case map that corresponded to each TMA section (Microsoft Excel; Microsoft, Redmond, WA, USA) and all data were processed utilizing TMA-Deconvoluter 1.06 software (15). The deconvoluted data were then transferred into a master database that also included all collected clinical and pathological data for statistical analysis.

Significant associations between marker staining and focus (primary versus secondary) were determined using a Fisher's exact test or Pearson's Chi-square test. The most prevalent ATC subtype, or the ATC subtype that accounted for the larger proportion of the entire tumor, after review of all sections available for the case, was considered the primary focus, while the less prevalent ATC subtype was considered the secondary focus. Significant associations between the different foci subtypes (epithelioid, giant cell, or spindled) were determined using a Pearson's Chi-square test. Marker scores were grouped as either ‘negative’ (score=0) or ‘positive’ (score≥1). Correlation between marker staining for the two foci (primary versus secondary) was also assessed for each patient using a Spearman correlation. A significant positive correlation indicates that the marker scores (considering all 51 markers) are consistent or similar between the two foci for that patient. All tests were two-tailed and considered significant at alpha=0.05. Statistical analysis was carried out utilizing SPSS software (SPSS Inc., Chicago, IL, USA, version 13). The samples and markers were also clustered utilizing a hierarchical clustering algorithm and heat maps were generated to visualize the data utilizing the ‘gplots’ library (version 2.3.0) for the R programming language (Vienna, Austria, version 2.3.1).

Results

Thirty-two out of 94 ATC cases diagnosed over a 20-year period in British Columbia had adequate archival tissue available for evaluation, and 6 of these cases were each composed of 2 discrete ATC subtype foci. The histological subtypes of the 6 anaplastic tumors in the study cohort are summarized in Table II. The most common primary ATC subtype was spindled (83%) and the most common secondary ATC subtype was epithelioid (50%). The mean study patient age was 71.5 years (range 66 to 81 years) and there were 2 women and 4 men in the study cohort. Two study patients (33%) had distant metastases identified at their initial disease presentation. None of the study patients had a history of head and neck irradiation or a personal or family history of thyroid cancer. Surgical treatment for the study cohort included either a thyroidectomy (lobectomy or total thyroidectomy; 4 patients) or excision of less than a thyroid lobe (2 patients). All study patients received external beam radiation treatment and none received chemotherapy. The mean survival of the study cohort from their date of ATC diagnosis was 42.7 weeks (range 4 to 60 weeks).

There were no significant differences found between the intratumoral ATC foci and their marker expression. Figure 1 shows examples of stained ATC TMA cores and Table I shows the consolidated Pearson's Chi-square and Fisher's exact test results comparing the primary versus secondary ATC foci for the 51 markers. Similarly, no significant differences were found between the different histological subtypes and their marker expression. The Pearson's Chi-square results comparing the different histological subtypes are summarized in Table III. However, significant correlations were observed between overall staining patterns for paired foci from the same patient. This suggests that the different intratumoural foci showed consistent or homogeneous staining for the molecular marker panel evaluated. The Spearman correlations ranged from 0.514 to 0.937 when comparing the 2 foci from each of the 6 patients (Table II). All p-values for correlations were less than 0.004 and considered significant. In the clustering analysis (Figure 2), the two intratumoral foci from the same patient consistently clustered together, suggesting intratumoral molecular homogeneity for marker expression. In contrast, no obvious clustering of histological subtypes was observed.

View this table:
  • View inline
  • View popup
  • Download powerpoint
Table I.

Statistical comparison of staining patterns between primary and secondary focus.

Figure 1.
  • Download figure
  • Open in new tab
  • Download powerpoint
Figure 1.

Examples of immunostaining of anaplastic thyroid cancer for several markers employed in this study. A, bcl-2, showing negative immunostaining; B, Ki-67, showing a score of 3 (50-75% of cells positive); C, p53, showing overexpression; D, thyroglobulin, showing absence of immunostaining; E, topoisomerase II, showing a score of 2 (25-50% of cells positive); F, VEGFR, showing positive immunostaining. Original magnification of all images ×200.

Discussion

Previous reports evaluating molecular marker expression by different histologic subtype foci of ATC have been limited and none have examined a large marker panel (11, 12, 16, 17).The identification of intratumoral differences in expression of a panel of molecular targets is important because tumors that are more heterogeneous may be predisposed to the development of drug resistance and treatment failure (18). Intratumoral heterogeneity has been investigated in several different human cancer types. Pramana et al. carried out a study to evaluate intratumoral heterogeneity in head and neck cancer (19). Twelve carcinomas originating from the oropharynx (6 oral cavity, 2 larynx, and 2 hypopharynx) were studied by this group. They found that biopsies from different areas of the same tumor had a more similar gene expression profile than did biopsies from different tumors. Intratumoral heterogeneity has also been evaluated in breast cancer with regards to HER2 status. Loring et al. compared breast cancer HER2 status determined utilizing chromogenic in situ hybridization (CISH) to HER2 status determined utilizing fluorescence in situ hybridization (FISH) (20). This study also investigated intratumoral heterogeneity in 2+ HercepTest scored whole tumor sections by assaying both strongly and weakly stained intratumoral cancer foci using FISH and CISH. The authors found that when comparing foci of weak and strong HercepTest scoring (HER2 staining) within a single tumor (areas of intratumoral heterogeneity), there was no difference in the overall HER2 gene amplification status as evaluated by either CISH or FISH. Therefore, they concluded that intratumoral heterogeneity did not influence the patient's overall HER2 status. Finally, Walker et al. used histologically heterogenous gliomas to examine the relationship between phenotype and genotype for potentially clinically relevant molecular markers (21). Using PCR amplification these investigators found that different glioma histological phenotypes/subtypes were homogenous in their genotype and could not be distinguished using the molecular marker panel they utilized. Thus, the findings for breast cancer, oropharyngeal cancer, and gliomas are similar to our observations for ATC, specifically, differences in tumor phenotype, or histological heterogeneity, does not necessarily predict molecular heterogeneity for clinically relevant markers.

Figure 2.
  • Download figure
  • Open in new tab
  • Download powerpoint
Figure 2.

Hierarchical cluster heat map of protein expression for matched undifferentiated foci of six anaplastic thyroid carcinoma patients. Data for all 51 markers and 12 patient samples were submitted to a hierarchical clustering algorithm and a heat map of marker expression was generated. The color key indicates marker score values of 0 to 4 according to the marker scoring systems. Along the bottom axis, all markers are listed. Along the left axis, focus subtypes are indicated by the side bar color (purple for epitheliod; green for spindled; orange for giant cell). On the right axis, samples are listed with their focus source (P for primary; S for secondary) and patient numbers (one through six). The clustering results showed that anaplastic tumor foci tend to cluster together with their patient-matched counterparts (i.e. paired primary and secondary foci cluster together) rather than into histological subtypes based on their marker expression patterns.

View this table:
  • View inline
  • View popup
  • Download powerpoint
Table II.

Correlations between ATC intratumoral subtype foci.

For thyroid cancer, multiple studies have reported that the different foci identified in multifocal papillary thyroid cancer (PTC) exhibit molecular heterogeneity (22-24). These studies concluded that noncontiguous PTC tumor foci originate as unrelated clones derived from independent precursors rather than spreading from intraglandular metastases. However, these studies differ from the current study in that multifocal tumors, not unifocal tumors, were evaluated and intertumoral, not intratumoral molecular heterogeneity was evaluated. A study reported by Vasko et al. demonstrated intratumoral heterogeneity in papillary thyroid carcinomas by comparing the invasive peripheral regions of tumor with the same tumor's central regions. They found overexpression of the transforming growth factor beta (TGFβ) and integrin pathway genes in the invasive regions, as well as other genes known to be involved in epithelial-to-mesenchymal transition (EMT) (25). With respect to ATC, Garcia-Rostan et al. have found that mutations in beta-catenin are common in ATC, promote the development of intratumoral molecular heterogeneity, and also activate transcription (26). Another study by Garcia-Rostan et al. demonstrated the presence of RAS mutations in 51.7% of undifferentiated thyroid carcinomas (27). While it is recognized that ATC can exhibit intratumoral molecular heterogeneity, our study demonstrates intratumoral molecular homogeneity for a specific panel of markers when comparing morphologically discrete intratumoral ATC foci.

A possible explanation for the lack of intratumoral molecular heterogeneity observed in the present study is that ATC may have a monoclonal origin. ATC has been previously shown to transform or arise from pre-existing differentiated thyroid carcinoma (DTC) (28). In a molecular phenotyping study we have previously reported some of the alterations in protein expression that occur during thyroid tumor progression. This was accomplished by comparing intratumoral coexisting DTC and ATC foci to each other for a panel of molecular markers (14). It is possible that the intratumoral evolution that occurs during transformation, or thyroid cancer progression, arises through a process of clonal expansion and selection. Thus, the ATC that arises as the endpoint of this thyroid tumor progression may, as we observed in the current study, be homogeneous when evaluated for molecular marker expression. However, ATC may still be heterogeneous for other markers or proteins that were not evaluated in the current study. It seems probable that the morphological differences present in the different ATC subtypes are likely a consequence of differences present at the molecular level. The marker panel we evaluated was specifically selected to include a broad range of potential targets for disease therapy. It also seems probable that the markers we evaluated are not important for the maintenance of the histological differences observed in the ATC subtypes. Conversely, the presence within ATC of intratumoral phenotypic heterogeneity, or differences in morphology of the ATC subtype foci, does not necessarily reflect or predict heterogeneity in the expression of markers that may serve as targets for therapy.

View this table:
  • View inline
  • View popup
  • Download powerpoint
Table III.

Statistical comparison of staining patterns between different histological subtypes.

Despite there being 1224 separate data points evaluated in the current study (6 tumors × 2 subtype foci × 2 cores per focus × 51 markers), it was difficult to interpret the Pearson's Chi-square and Fisher's exact tests in the setting of the small cohort size (n=12 for these tests). The Spearman correlation based on expression patterns across all markers (n=51) was more helpful in analyzing the study data set. These correlations demonstrated that different ATC subtype foci from the same tumor exhibited similar molecular marker expression patterns (with p<0.004 in all cases).

In a previous study, we identified HER4, uPA-R, aurora A, aurora C, β-catenin, and EGFR as promising targets for treatment of ATC (5). Anticancer agents that could be used to target these markers for treatment of ATC are now clinically utilized for treatment of human tumors. One of these drugs, cetuximab (ImClone Systems, New York, NY, USA) specifically targets the extracellular domain of the EGFR receptor. This drug has been found to show promise in an in vivo orthotopic ATC mouse xenograft study. Kim et al. reported that cetuximab resulted in a 77% ATC growth inhibition in their preclinical study (29). Gefitinib (AstraZeneca, London, UK) is another targeted therapeutic drug that has also been found to be effective in some in vivo ATC animal model studies. This drug is an adenosine triphosphate (ATP) competitive inhibitor that targets the intracellular EGFR tyrosine kinase. In a study reported by Nobuhara et al., it was shown that in an in vivo ATC xenograft mouse model, gefitinib prevented anaplastic cell proliferation (30). Although a recent study has raised the possibility of cross-contamination of the ATC cell line that was utilized in this preclinical study with another human cell line, there are many pre-clinical studies that suggest targeted therapeutics show promise as future treatments of ATC (5, 31). An important connection can be made between these emerging targeted therapy strategies for ATC and the current study. For example, we have found that EGFR exhibits consistent and homogenous expression in different coexisting intratumoral ATC histological subtypes. Therefore, intratumoral histological heterogeneity, or intratumoral variation in ATC subtype histology does not necessarily reflect heterogeneity of expression for molecular targets for therapy.

Few studies have evaluated the molecular marker expression patterns of different histological subtypes of ATC. Despite being phenotypically heterogeneous, our findings suggest that ATC exhibits intratumoral molecular homogeneity for the large marker panel we evaluated. This is suggested by the significant correlations observed between the overall staining patterns observed for paired foci from within the same tumor. If ATC molecular target expression is utilized as the criteria required for selection of a specific anticancer treatment, the current study supports the utilization of such agents, regardless of the histological heterogeneity for ATC subtypes observed in these tumors. A future study could further validate our findings in a larger ATC patient cohort. Given the rarity and rapidly fatal course of ATC, a multicenter study would be required. Never the less, ongoing study of the molecular characteristics of ATC may provide further insights into the underlying biology of this cancer and potentially lead to the development of new treatments or identify efficacious existing treatments, to improve outcomes for individuals diagnosed with this fatal thyroid malignancy.

Acknowledgements

S.M.W. is a Michael Smith Scholar and this work was supported by the Michael Smith Foundation for Health Research (MSFHR) and the University of British Columbia Department of Surgery. O.L.G. was supported by the Canadian Institutes of Health Research (CIHR) and MSFHR. S.J.M.J. was supported by MSFHR and the British Columbia Cancer Foundation.

Footnotes

  • Disclosure/Conflict of Interest

    There are no conflicts of interest to declare.

  • Received March 26, 2009.
  • Revision received June 2, 2009.
  • Accepted June 4, 2009.
  • Copyright© 2009 International Institute of Anticancer Research (Dr. John G. Delinassios), All rights reserved

References

  1. ↵
    1. Goutsouliak V,
    2. Hay JH
    : Anaplastic thyroid cancer in British Columbia 1985-1999: a population-based study. Clin Oncol 17: 75-78, 2005.
    OpenUrl
  2. ↵
    1. Are C,
    2. Shaha AR
    : Anaplastic thyroid carcinoma: biology, pathogenesis, prognostic factors, and treatment approaches. Ann Surg Oncol 13: 453-464, 2006.
    OpenUrlCrossRefPubMed
  3. ↵
    1. Tennvall J,
    2. Lundell G,
    3. Wahlberg P,
    4. Bergenfelz A,
    5. Grimelius L,
    6. Akerman M,
    7. Hjelm Skog AL,
    8. Wallin G
    : Anaplastic thyroid carcinoma: three protocols combining doxorubicin, hyperfractionated radiotherapy and surgery. Br J Cancer 86: 1848-1853, 2002.
    OpenUrlCrossRefPubMed
  4. ↵
    1. Crevoisier RD,
    2. Baudin E,
    3. Bachelot A,
    4. Leboulleux S,
    5. Travagli JP,
    6. Caillou B,
    7. Schlumberger M
    : Combined treatment of anaplastic thyroid carcinoma with surgery, chemotherapy and hyperfractionated accelerated external radiotherapy. Int J Radiation Oncol Biol Phys 60: 1137-1143, 2004.
    OpenUrlCrossRefPubMed
  5. ↵
    1. Wiseman SM,
    2. Masoudi H,
    3. Niblock P,
    4. Turbin D,
    5. Rajput A,
    6. Hay J,
    7. Bugis S,
    8. Filipenko D,
    9. Huntsman D,
    10. Gilks B
    : Anaplastic Thyroid Carcinoma: Expression Profile Of Targets For Therapy Offers New Insights For Disease Treatment. Ann Surg Oncol 14: 714-729, 2007.
    OpenUrl
  6. ↵
    1. Baselga J,
    2. Arteaga CL
    : Critical update and emerging trends in epidermal growth factor receptor targeting in cancer. J Clin Oncol 23: 2445-2459, 2005.
    OpenUrlAbstract/FREE Full Text
  7. ↵
    1. Artega CL,
    2. Moulder S,
    3. Yakes F
    : HER (erB) tyrosine kinase inhibitors in the treatment of breast cancer. Sem Oncol 29: 4-10, 2002.
    OpenUrlPubMed
    1. Chung KY,
    2. Saltz LB
    : Antibody-based therapies for colorectal cancer. Oncologist 10: 701-709, 2005.
    OpenUrlAbstract/FREE Full Text
    1. Comis RL
    : The current situation: erlotinib (Tarceva©) and gefitinib (Iressa©) in non-small cell lung cancer. Oncologist 10: 467-470, 2005.
    OpenUrlFREE Full Text
  8. ↵
    1. Siegel-Lakhai WS,
    2. Beijnen JH,
    3. Schellens JHM
    : Current knowledge and future directions of the selective epidermal growth factor receptor inhibits erlotinib (Tarceva©) and gefitinib (Iressa©). Oncologist 10: 579-589, 2005.
    OpenUrlAbstract/FREE Full Text
  9. ↵
    1. Lee DH,
    2. Lee GK,
    3. Kong SY,
    4. Kook MC,
    5. Yang SK,
    6. Park SY,
    7. Park SH,
    8. Keam B,
    9. Park do J,
    10. Cho BY,
    11. Kim SW,
    12. Chung KW,
    13. Lee ES,
    14. Kim SW
    : Epidermal growth factor receptor status in anaplastic thyroid carcinoma. J Clin Pathol 60: 881-884, 2007.
    OpenUrlAbstract/FREE Full Text
  10. ↵
    1. Khoo M,
    2. Freeman J
    : Undifferentiated thyroid carcinoma. Curr Opin Otolaryngol Head Neck Surg 8: 113-116, 2000.
    OpenUrlCrossRef
  11. ↵
    1. Parker RL,
    2. Huntsman DG,
    3. Lesack DW,
    4. Cupples JB,
    5. Grant DR,
    6. Akbari M,
    7. Gilks CB
    : Assessment of interlaboratory variation in the immunohistochemical determination of estrogen receptor status using a breast cancer tissue microarray. Am J Clin Pathol 117: 723-728, 2002.
    OpenUrlAbstract/FREE Full Text
  12. ↵
    1. Wiseman SM,
    2. Griffith OL,
    3. Deen S,
    4. Rajput A,
    5. Masoudi H,
    6. Gilks B,
    7. Goldstein L,
    8. Gown A,
    9. Jones SJ
    : Identification of molecular markers altered during transformation of differentiated into anaplastic thyroid carcinoma. Arch Surg 142: 717-729, 2007.
    OpenUrlCrossRefPubMed
  13. ↵
    1. Liu CL,
    2. Prapong W,
    3. Natkunam Y,
    4. Alizadeh A,
    5. Montgomery K,
    6. Gilks CB,
    7. van de Rijn M
    : Software tools for high-throughput analysis and archiving of immunohistochemistry staining data obtained with tissue mircroarrays. Am J Pathol 161: 1557-1565, 2002.
    OpenUrlPubMed
  14. ↵
    1. Hurlimann J,
    2. Gardiol D,
    3. Scazziga B
    : Immunohistology of anaplastic thyroid carcinoma. A study of 43 cases. Histopathology 11: 567-580, 1987.
    OpenUrlPubMed
  15. ↵
    1. Eckert F,
    2. Schmid U,
    3. Gloor F,
    4. Hedinger C
    : Evidence of vascular differentiation in anaplastic tumours of the thyroid - an immunohistological study. Virchows Arch A 410: 203-215, 1986.
    OpenUrl
  16. ↵
    1. Dexter D,
    2. Leith J
    : Tumor heterogeneity and drug resistance. J Clin Oncol 4: 244-257, 1986.
    OpenUrlAbstract
  17. ↵
    1. Pramana J,
    2. Pimentel N,
    3. Hofland I,
    4. Wessels LF,
    5. van Velthuysen ML,
    6. Atsma D,
    7. Rasch CR,
    8. van den Brekel MW,
    9. Begg AC
    : Heterogeneity of gene expression profiles in head and neck cancer. Head Neck 29: 1083-1089, 2007.
    OpenUrlPubMed
  18. ↵
    1. Loring P,
    2. Cummins R,
    3. O'Grady A,
    4. Kay EW
    : HER2 positivity in breast carcinoma: a comaprison of chromogenic in situ hybridization with fluorescence in situ hybridization in tissue microarrays, with targeted evaluation of intratumoral heterogeneity by in situ hybridization. Appl Immunohistochem Mol Morph 13: 194-200, 2005.
    OpenUrl
  19. ↵
    1. Walker C,
    2. du Plessis DG,
    3. Joyce KA,
    4. Machell Y,
    5. Thomson-Hehir J,
    6. Al Haddad SA,
    7. Broome JC,
    8. Warnke PC
    : Phenotype versus genotype in gliomas displaying inter- or intratumoral histological heterogeneity. Clin Cancer Res 9: 4841-4851, 2003.
    OpenUrlAbstract/FREE Full Text
  20. ↵
    1. Giannini R,
    2. Ugolini C,
    3. Lupi C,
    4. Proietti A,
    5. Elisei R,
    6. Salvatore G,
    7. Berti P,
    8. Materazzi G,
    9. Miccoli P,
    10. Santoro M,
    11. Basolo F
    : The heterogenous distribution of BRAF mutation supports the independent clonal origin of distinct tumor foci in multifocal papillary thyroid carcinoma. J Clin Endocrinol Metab 92: 3511-3516, 2007.
    OpenUrlCrossRefPubMed
    1. Shattuck TM,
    2. Westra WH,
    3. Ladenson PW,
    4. Arnold A
    : Independent clonal origins of distinct tumor foci in multifocal papillary thyroid carcinoma. N Engl J Med 352: 2406-2412, 2005.
    OpenUrlCrossRefPubMed
  21. ↵
    1. Sugg SL,
    2. Ezzat S,
    3. Rosen IB,
    4. Freeman JL,
    5. Asa SL
    : Distinct multiple RET/PTC gene rearrangements in multifocal papillary thyroid neoplasia. J Clin Endocrinol Metab 83: 4116-4122,1998.
    OpenUrlCrossRefPubMed
  22. ↵
    1. Vasko V,
    2. Esinosa AV,
    3. Scouten W,
    4. He H,
    5. Auer H,
    6. Liyanarachchi S,
    7. Larin A,
    8. Savchenko V,
    9. Francis GL,
    10. de la Chapelle A,
    11. Saji M,
    12. Ringel MD
    : Gene expression and functional evidence of epithelial-to-mesenchymal transition in papillary thyroid carcinoma invasion. PNAS 104: 2803-2808, 2007.
    OpenUrlAbstract/FREE Full Text
  23. ↵
    1. Garcia-Rostan G,
    2. Tallini G,
    3. Herrero A,
    4. D'Aquila TG,
    5. Carcangiu ML,
    6. Rimm DL
    : Frequent mutation and nuclear localization of beta-catenin in anaplastic thyroid carcinoma. Cancer Res 59: 1811-1815, 1999.
    OpenUrlAbstract/FREE Full Text
  24. ↵
    1. Garcia-Rostan G,
    2. Zhao H,
    3. Camp RL,
    4. Pollan M,
    5. Herrero A,
    6. Pardo J,
    7. Wu R,
    8. Carcangiu ML,
    9. Costa J,
    10. Tallini G
    : RAS mutations are associated with aggressive tumor phenotypes and poor prognosis in thyroid cancer. J Clin Oncol 21: 3226-3235, 2003.
    OpenUrlAbstract/FREE Full Text
  25. ↵
    1. Wiseman SM,
    2. Loree TR,
    3. Rigual NR,
    4. Hicks WL Jr.,
    5. Douglas WG,
    6. Anderson GR,
    7. Stoler DL
    : Anaplastic transformation of thyroid cancer: review of clinical, pathologic, and molecular evidence provides new insights into disease biology and future therapy. Head Neck 25: 662-670, 2003.
    OpenUrlCrossRefPubMed
  26. ↵
    1. Kim S,
    2. Prichard CN,
    3. Younes MN,
    4. Yazici YD,
    5. Jasser SA,
    6. Bekele BN,
    7. Myers JN
    : Cetuximab and irinotecan interact synergistically to inhibit the growth of orthotopic anaplastic thyroid carcinoma xenografts in nude mice. Clin Cancer Res 12: 600-607, 2006.
    OpenUrlAbstract/FREE Full Text
  27. ↵
    1. Nobuhara Y,
    2. Onoda N,
    3. Yamashita Y,
    4. Yamasaki M,
    5. Ogisawa K,
    6. Takashima T,
    7. Ishikawa T,
    8. Hirakawa K
    : Efficacy of epidermal growth factor receptor - targeted molecular therapy in anaplastic thyroid cancer cell lines. Br J Cancer 92: 110-116, 2005.
    OpenUrl
  28. ↵
    1. Schweppe RE,
    2. Klopper JP,
    3. Korch C,
    4. Pugazhenthi U,
    5. Benezra M,
    6. Knauf JA,
    7. Fagin JA,
    8. Marlow LA,
    9. Copland JA,
    10. Smallridge RC,
    11. Haugen BR
    : Deoxyribonucleic Acid profiling analysis of 40 human thyroid cancer cell lines reveals cross-contamination resulting in cell line redundancy and misidentification. J Clin Endocrinol Metab 93: 4331-4341, 2008.
    OpenUrlCrossRefPubMed
PreviousNext
Back to top

In this issue

Anticancer Research: 29 (7)
Anticancer Research
Vol. 29, Issue 7
July 2009
  • Table of Contents
  • Table of Contents (PDF)
  • Index by author
  • Back Matter (PDF)
  • Front Matter (PDF)
Print
Download PDF
Article Alerts
Sign In to Email Alerts with your Email Address
Email Article

Thank you for your interest in spreading the word on Anticancer Research.

NOTE: We only request your email address so that the person you are recommending the page to knows that you wanted them to see it, and that it is not junk mail. We do not capture any email address.

Enter multiple addresses on separate lines or separate them with commas.
Anaplastic Thyroid Carcinoma Exhibits Intratumoral Molecular Homogeneity for a Therapeutic Target Panel
(Your Name) has sent you a message from Anticancer Research
(Your Name) thought you would like to see the Anticancer Research web site.
CAPTCHA
This question is for testing whether or not you are a human visitor and to prevent automated spam submissions.
2 + 0 =
Solve this simple math problem and enter the result. E.g. for 1+3, enter 4.
Citation Tools
Anaplastic Thyroid Carcinoma Exhibits Intratumoral Molecular Homogeneity for a Therapeutic Target Panel
SHAUN DEEN, OBI L. GRIFFITH, HAMID MASOUDI, ALLEN GOWN, STEVEN J.M. JONES, SAM M. WISEMAN
Anticancer Research Jul 2009, 29 (7) 2437-2444;

Citation Manager Formats

  • BibTeX
  • Bookends
  • EasyBib
  • EndNote (tagged)
  • EndNote 8 (xml)
  • Medlars
  • Mendeley
  • Papers
  • RefWorks Tagged
  • Ref Manager
  • RIS
  • Zotero
Reprints and Permissions
Share
Anaplastic Thyroid Carcinoma Exhibits Intratumoral Molecular Homogeneity for a Therapeutic Target Panel
SHAUN DEEN, OBI L. GRIFFITH, HAMID MASOUDI, ALLEN GOWN, STEVEN J.M. JONES, SAM M. WISEMAN
Anticancer Research Jul 2009, 29 (7) 2437-2444;
Reddit logo Twitter logo Facebook logo Mendeley logo
  • Tweet Widget
  • Facebook Like
  • Google Plus One

Jump to section

  • Article
    • Abstract
    • Materials and Methods
    • Results
    • Discussion
    • Acknowledgements
    • Footnotes
    • References
  • Figures & Data
  • Info & Metrics
  • PDF

Related Articles

  • No related articles found.
  • PubMed
  • Google Scholar

Cited By...

  • No citing articles found.
  • Google Scholar

More in this TOC Section

  • TIG1 Inhibits the mTOR Signaling Pathway in Malignant Melanoma Through the VAC14 Protein
  • Novel α-Trifluoromethyl Chalcone Exerts Antitumor Effects Against Prostate Cancer Cells
  • Differential Effects of Anti-PD-1/PD-L1 Checkpoint Inhibitors on Adhesion Molecules and Cytokine Secretion by THP-1 Monocytes
Show more Experimental Studies

Similar Articles

Anticancer Research

© 2023 Anticancer Research

Powered by HighWire