High iodine effects on the proliferation, apoptosis, and migration of papillary thyroid carcinoma cells as a result of autophagy induced by BRAF kinase.

Papillary thyroid carcinoma (PTC) is a common endocrine tumor. This study found that different iodine concentrations affected the proliferation, apoptosis, and migration of PTC. For this study, we collected clinical information from PTC patients and monitored the levels of urinary iodine, LC3-II, and caspase-3 in cancer tissue, and BRAF kinase in peripheral blood from PTC patients. We also monitored the proliferation, apoptosis and migration ability of human papillary-thyroid carcinoma (BCPAP) cells at different iodine concentrations and their association with changes in autophagy and BRAF kinase activity of BCPAP cells at high iodine levels (10-3 mol/l). We found that the proportion of tumor diameters ≥ 1 cm in the iodine excess group were lower than that in the iodine non-excess group. The proportion of PTC patients with infiltration in the iodine excess group was higher than that in the iodine non-excess group. Levels of the autophagy-related protein LC3-II and the apoptosis-related protein caspase-3 in cancer tissues, and activity of BRAF kinase in peripheral blood, were positively correlated with urinary iodine concentrations from PTC patients. At high iodine levels, the proliferation rate decreased, and apoptosis percentage and migration rates increased compared with the no-iodine group. At high iodine levels, the frequencies of autophagosomes (Aph) and autophagosome-lysosomes (Apl) in BCPAP cells increased significantly, and activities of LC3-II and BRAF kinase increased, respectively. The activity of LC3-II decreased when BRAF kinase was inhibited. The activity of LC3-II and the proliferation and migration rates of BCPAP cells decreased, and the apoptosis percentage increased when autophagy was inhibited at high iodine concentrations. Our results demonstrated that, in the presence of excessive iodine, the mean tumor size of PTC patients was smaller and easier to invade than tumors in patients not supplied with excessive iodine. The levels of autophagy and apoptosis in PTC cancer tissues, and activities of BRAF kinase in peripheral blood increased with increasing urinary iodine concentrations. High iodine levels inhibited cell proliferation and promoted apoptosis and migration of PTC cells. Autophagy induced by BRAF kinase in PTC cells was involved in anti-apoptosis, and promoted proliferation and migration at high iodine concentrations. This study provides a rationale for iodine supplementation in PTC patients.

The Gene Master Regulators (GMR) Approach Provides Legitimate Targets for Personalized, Time-Sensitive Cancer Gene Therapy.

The dynamic and never exactly repeatable tumor transcriptomic profile of people affected by the same form of cancer requires a personalized and time-sensitive approach of the gene therapy. The Gene Master Regulators (GMRs) were defined as genes whose highly controlled expression by the homeostatic mechanisms commands the cell phenotype by modulating major functional pathways through expression correlation with their genes. The Gene Commanding Height (GCH), a measure that combines the expression control and expression correlation with all other genes, is used to establish the gene hierarchy in each cell phenotype. We developed the experimental protocol, the mathematical algorithm and the computer software to identify the GMRs from transcriptomic data in surgically removed tumors, biopsies or blood from cancer patients. The GMR approach is illustrated with applications to our microarray data on human kidney, thyroid and prostate cancer samples, and on thyroid, prostate and blood cancer cell lines. We proved experimentally that each patient has his/her own GMRs, that cancer nuclei and surrounding normal tissue are governed by different GMRs, and that manipulating the expression has larger consequences for genes with higher GCH. Therefore, we launch the hypothesis that silencing the GMR may selectively kill the cancer cells from a tissue.

Differential proteomic and phenotypic behaviour of papillary and anaplastic thyroid cell lines.

Thyroid carcinomas account for a minority of all malignant tumours but, after those of the gonads, they represent the most common forms of endocrine cancers. They include several types, among which the papillary thyroid cancer (PTC) and the anaplastic thyroid cancer (ATC) are the best known. The two hystotypes display significant biological and clinical differences: PTC is a well differentiated form of tumour with a high incidence and a good prognosis, while the ATC is less frequent but represents one of the most aggressive endocrine tumours with morphological features of an undifferentiated type. To date, as far as we know, no conclusive studies, useful to design arrays of molecular markers, have been published illustrating the phenotypic and proteomic differences between these two tumours. The aim of this work was to perform a comparative analysis of two thyroid cancer cell lines, derived respectively from papillary (BCPAP) and anaplastic (8505C) thyroid carcinomas. The comparative analysis included cell behaviour assays and proteomic analysis by 2D-PAGE and mass spectrometry. The results have highlighted a new proteomic signature for the anaplastic carcinoma-derived cells, consistent with their high proliferation rate, motility propensity and metabolic shift, in relation to the well-differentiated PTC cells.