Project description:The incidence of thyroid cancer (TC) has doubled in recent years but the molecular mechanisms responsible for various TC forms are largely unknown. We hypothesize that, in a thyroid tumor, cancer nodules and surrounding benign tissue are governed by different gene master regulators (GMRs). GMRs are defined as coding/non-coding RNAs whose strongly protected (by the homeostatic mechanisms) abundance modulates most functional pathways by coordinating the expression of their composing genes. GMRs are the most legitimate targets for TC gene therapy. However, because of strong expression control, GMRs are not selectable among TC biomarkers whose frequent regulation in large cancer patient populations indicates low protection as for minor players. We determined the GMRs of the standard papillary (BCPAP) and anaplastic (8505C) thyroid cancer cell lines. The hierarchy of the known biomarkers was established based on their gene commanding height (GCH), an original measure combining the expression control and coordination with expression of other genes. We found that the sets of the GMRs are largely different in the two thyroid cancer cell lines, indicatibg that each type of thyroid cancer needs a different gene-targeting therapy.

Project description:An ideal cancer gene therapy would selectively destroy the cancer cells without affecting much the healthy tissue. This would be possible if and only if the cancer and normal cells of the tumor are governed by distinct gene master regulators (GMRs). Logic dictates that, while being strongly protected by the homeostatic mechanisms, expression of a GMR governs the phenotype by modulating major functional pathways through controlling the expression of the involved genes. We determined the GMRs of the standard papillary (BCPAP) and anaplastic (8505C) thyroid cancer cell lines. The hierarchy of the known biomarkers was established based on their gene commanding height (GCH), an original measure combining the expression control and coordination with expression of other genes. We found that the sets of the GMRs are largely different in the two thyroid cancer cell lines, indicatibg that each type of thyroid cancer needs a different gene-targeting therapy. In this experiment, we determined the transcriptomic effects of the stable transfection of UBALD1 gene in the BCPAP and 8505C thyroid cancer cell lines. UBALD1 was selected because it has significantly different GCHs in the two cell lines: 10.31 in 8505C and 1.12 in BCPAP. The significantly more up- and down-regulated genes in the transfected 8505C cells than in the transfected BCPAP cells compared to their untransfected counterparts validated the theory and indicated the usefulness of our personalized gene therapy approach.

Project description:An ideal cancer gene therapy would selectively destroy the cancer cells without affecting much the healthy tissue. This would be possible if and only if the cancer and normal cells of the tumor are governed by distinct gene master regulators (GMRs). Logic dictates that, while being strongly protected by the homeostatic mechanisms, expression of a GMR governs the phenotype by modulating major functional pathways through controlling the expression of the involved genes. We determined the GMRs of the standard papillary (BCPAP) and anaplastic (8505C) thyroid cancer cell lines. The hierarchy of the known biomarkers was established based on their gene commanding height (GCH), an original measure combining the expression control and coordination with expression of other genes. We found that the sets of the GMRs are largely different in the two thyroid cancer cell lines, indicatibg that each type of thyroid cancer needs a different gene-targeting therapy. In this experiment, we determined the transcriptomic effects of the stable transfection of PANK2 gene In the papillary (BCPAP) and anaplastic (8505C) thyroid cancer cell lines. PANK2 was selected because it has significantly different GCHs in the two cell lines: 44.64 in BCPAP and 3.61 in 8505C. The significantly more up- and down-regulated genes in the transfected BCPAP than in the transfected 8505C cells compared to their untransfected counterparts validated the theory and indicated the usefulness of our personalized gene therapy approach.

Project description:An ideal cancer gene therapy would selectively destroy the cancer cells without affecting much the healthy tissue. This would be possible if and only if the cancer and normal cells of the tumor are governed by distinct gene master regulators (GMRs). Logic dictates that, while being strongly protected by the homeostatic mechanisms, expression of a GMR governs the phenotype by modulating major functional pathways through controlling the expression of the involved genes. We determined the GMRs of the standard papillary (BCPAP) and anaplastic (8505C) thyroid cancer cell lines. The hierarchy of the known biomarkers was established based on their gene commanding height (GCH), an original measure combining the expression control and coordination with expression of other genes. We found that the sets of the GMRs are largely different in the two thyroid cancer cell lines, indicatibg that each type of thyroid cancer needs a different gene-targeting therapy. In this experiment, we determined the transcriptomic effects of the stable transfection of DDX19B gene In the papillary (BCPAP) and anaplastic (8505C) thyroid cancer cell lines. DDX19B was selected because it has significantly different GCHs in the two cell lines: 1.64 in BCPAP and 6.03 in 8505C. The significantly more up- and down-regulated genes in the transfected 8505C than in the transfected BCPAP cells compared to their untransfected counterparts validated the theory and indicated the usefulness of our personalized gene therapy approach.

Project description:An ideal cancer gene therapy would selectively destroy the cancer cells without affecting much the healthy tissue. This would be possible if and only if the cancer and normal cells of the tumor are governed by distinct gene master regulators (GMRs). Logic dictates that, while being strongly protected by the homeostatic mechanisms, expression of a GMR governs the phenotype by modulating major functional pathways through controlling the expression of the involved genes. We determined the GMRs of the standard papillary (BCPAP) and anaplastic (8505C) thyroid cancer cell lines. The hierarchy of the known biomarkers was established based on their gene commanding height (GCH), an original measure combining the expression control and coordination with expression of other genes. We found that the sets of the GMRs are largely different in the two thyroid cancer cell lines, indicatibg that each type of thyroid cancer needs a different gene-targeting therapy. In this experiment, we determined the transcriptomic effects of the stable transfection of NEMP1 (TMEM194A) gene encoding a nuclear envelope protein in the papillary (BCPAP) and anaplastic (8505C) thyroid cancer cell lines. NEMP1 was selected because it has significantly different GCHs in the two cell lines: 5.95 in BCPAP and 0.40 in 8505C. The significantly more up- and down-regulated genes in the transfected BCPAP than in the transfected 8505C cells compared to their untransfected counterparts validated the theory and indicated the usefulness of our personalized gene therapy approach.

Project description:<p><strong>BACKGROUND:</strong> Novel biomarkers are urgently needed to distinguish between benign and malignant thyroid nodules and detect thyroid cancer in the early stage. The associations between serum IgG N-glycosylation and thyroid cancer risk have been revealed. We aimed to explore the potential of IgG N-glycan traits as biomarkers in the differential diagnosis of thyroid cancer.</p><p><strong>METHODS:</strong> Plasma IgG N-glycome analysis was applied to a discovery cohort followed by independent validation. IgG N-glycan profiles were obtained using a robust quantitative strategy based on matrix-assisted laser desorption/ionization time-of-flight mass spectrometry. IgG N-glycans were relatively quantified, and classification performance was evaluated based on directly detected and derived glycan traits.</p><p><strong>RESULTS: </strong>Four directly detected glycans were significantly changed in thyroid cancer patients compared to that in non-cancer controls. Derived glycan traits and a classification glycol-panel were generated based on the directly detected glycan traits. In the discovery cohort, derived trait BN (bisecting type neutral N-glycans) and the glyco-panel showed potential in distinguishing between thyroid cancer and non-cancer controls with AUCs of 0.920 and 0.917, respectively. The diagnostic potential was further validated. Derived trait BN and the glycol-panel displayed “accurate” performance (AUC&gt;0.8) in discriminating thyroid cancer from benign thyroid nodules and healthy controls in the validation cohort. Meanwhile, derived trait BN and the glycol-panel also showed diagnostic potential in detecting early-stage thyroid cancer.</p><p><strong>CONCLUSIONS:</strong> IgG N-glycome analysis revealed N-glycomic differences that allow classification of thyroid cancer from non-cancer controls. Our results suggested that derived trait BN and the classification glyco-panel rather than single N-glycans may serve as candidate biomarkers for further validation.</p>

Project description:There is a challenge of thyroid cancer versus benign follicular denoma differential diagnostics using fine-needle biopsy. RNA expression profiles can be used to identify biomarkers suitable for molecular diagnostics. Here we present raw RNA sequencing data obtained during Oncobox platform observational study for 96 human pathological thyroid biosamples. Data are compatible with Oncobox Atlas of Normal Tissue Expression (ANTE) database including profiles for healthy thyroid tissues. . The data provided are helpful to those implicated in thyroid cancer research and diagnostics, and in comparative analyses of human cancers.

Project description:Thyroid cancer is a common endocrine malignancy; however, its diagnosis is not straightforward. The current gold standard for diagnosing thyroid cancer is fine needle aspiration biopsy (FNAB), but when cytological analysis does not provide viable results or samples belong to less defined categories of diagnosis, patients are often referred to diagnostic surgery. Given that not all these nodules require removal, nor all of them are malignant, patients would not necessarily require surgery had the initial FNAB diagnosis been more conclusive. There is therefore a lack of reliable and specific biomarkers for thyroid cancer malignancy, that can complement and improve the current diagnosing methods. “Omics” approaches have gained much attention in the last decade in the field of biomarker discovery for diagnostic and prognostic characterization of various pathophysiological conditions. In this project, proteomics and metabolomics approaches were applied to the same thyroid nodules from patients with benign and malignant lesions. Tissue analysis provided several interesting biomarkers by both proteomics and metabolomics. The combination of these results demonstrated the high energetic and biomass demand of cancer cells, as well as a biomarker panel including 2 free peptides and 2 proteins with high sensitivity and specificity. Together, these results have contributed to increasing the knowledge of thyroid cancer phenotype and corresponding biochemical profiles, as well as providing potential biomarkers for malignancy, and improving diagnostic methodologies.

Project description:PURPOSE: Thyroid cancer is frequently difficult to diagnose due to an overlap of cytological features between malignant and benign nodules. This overlap leads to unnecessary removal of the thyroid in patients without cancer. While providing some improvement over cytopathologic diagnostics, molecular methods frequently fail to provide a correct diagnosis for thyroid nodules. These approaches are based on the difference between malignant nodules and normal adjacent thyroid tissue and assume that normal thyroid tissues are the same as benign nodules. However, in contrast to normal thyroid tissues, benign thyroid nodules can contain genetic alterations that can be found in cancerous nodules. PATIENTS AND METHODS: For the development of a new molecular diagnostic test for thyroid cancer, we evaluated DNA methylation in 109 thyroid tissues by using genome wide single base resolution DNA methylation analysis (Reduced Representation Bisulfite Sequencing). The test was validated in the retrospective cohort containing 64 thyroid nodules. RESULTS: By conducting Reduced Representation Bisulfite Sequencing in 109 thyroid specimens, we found significant differences between normal tissue, benign nodules, and cancer. Based on tissue-specific epigenetic signatures for benign and malignant nodules, we developed a new epigenetic approach for thyroid diagnostics. According to the validation cohort, our test has an estimated specificity of 97% (95% CI, 80 to 100), sensitivity of 100% (95% CI, 86 to 100), PPV of 97% (95% CI, 82-100), NPV of 100% (95%, 85 to 100). CONCLUSION: These data show that epigenetic testing can provide outstanding diagnostic accuracy for thyroid nodules by evaluating tissue specific DNA methylation.

Project description:About 20-30% of patients with metastatic non-medullary thyroid cancer (TC) have persistent or recurrent disease resulting from tumor dedifferentiation. Tumor redifferentiation to restore sensitivity to radioactive iodine therapy is considered a promising strategy to overcome RAI resistance. Autophagy has emerged as an important mechanism in cancer dedifferentiation. Here, we demonstrate the therapeutic potential of autophagy activation for redifferentiation in thyroid cancer cell lines. Five, all digitalis-like compounds, restored hNIS expression and iodine uptake in TC cell lines. Upregulation of hNIS was mediated by intracellular Ca2+ and cFOS activation. Cell proliferation was inhibited by downregulating Akt1 and by induction of autophagy and p21-dependent cell cycle arrest. All together, digitalis-like compounds could represent a promising treatment modality for patients with dedifferentiated TC.