Valproic acid radiosensitizes anaplastic thyroid cells through a decrease of the DNA damage repair capacity.

BACKGROUND: Anaplastic thyroid cancer (ATC) represents a rare lethal human malignancy with poor prognosis. Multimodality treatment, including radiotherapy, is recommended to improve local control and survival. Valproic acid (VA) is a clinically available histone deacetylase inhibitor with a well-documented side effect profile. In this study, we aim to investigate the combined effect of VA with photon irradiation in vitro. METHODS: Anaplastic thyroid cancer cells (8505c) were used to investigate the radiosensitizing effect of VA. RESULTS: VA sensitized cells to photon irradiation. VA increased radiation-induced apoptosis and radiation-induced DNA damage measured by γH2AX foci induction. Furthermore, VA prolonged γH2AX foci disappearance over time in irradiated cells and decreased the radiation-induced levels of mRNA of key DNA damage repair proteins of the homologous recombination (HR) and the nonhomologous end joining (NHEJ) pathways. CONCLUSIONS: VA at a clinically safe dose enhance the radiosensitivity of 8505c cells through an increase in radiation-induced apoptosis and a disruption in the molecular mechanism of HR and NHEJ DNA damage repair pathways.

Inhibition of goiter growth and of cyclic AMP formation in rat thyroid by 2-iodohexadecanal.

INTRODUCTION: Thyroid autoregulation has been related to intraglandular content of an unknown putative iodocompound. The thyroid is capable of producing different iodolipids such as 6-iodo-deltalactone (ILdelta) and 2-iodohexadecanal (2-IHDA). Data from different laboratories have shown that these iodolipids inhibit several thyroid parameters. ILdelta has an antigoitrogenic action but no data about the action of 2-IHDA on this parameter has been published. OBJECTIVES: to study the action of 2-IHDA on methimazole (MMI)-induced goiter and analyze if this compound can cause the involution of preformed goiter. RESULTS: Administration of MMI to rats during 10 days increased thyroid weight by 112%. This effect was significantly inhibited by the simultaneous injection of 20mug/day of 2-IHDA (51% vs. MMI) while iodine or non iodinated hexadecanal were without action. Thyroidal proliferating cell nuclear antigen (PCNA) content was increased by MMI while 2-IHDA decreased this value (control: 100%; MMI: 190+/-11; MMI+2-IHDA: 134+/-10). Serum TSH was increased after MMI administration and 2-IHDA did not modify this parameter (control: 1.89+/-0.10; MMI: 8.19+/-0.93ng/ml; MMI+2-IHDA: 7.38+/-0.72). Treatment with MMI increased thyroidal cAMP content (control: 16.1+/-0.82, MMI: 42.4+/-4.6 fmol/mg protein) while injection of 2-IHDA significantly decreased this value (22.3+/-2.0). Goiter prevention by 2-IHDA was also observed at 30 days of treatment reducing total number of cells (51% inhibition) and epithelial height (81% inhibition). Goiter involution was induced after withdrawal of MMI and injection with 2-IHDA, KI or saline. 2-IHDA led to a reduction of 74.5% in thyroid weight after 3 days while spontaneous involution (saline) was only of 32%. KI failed to alter this value. This significant involution was accompanied by a reduction in the number of cells (66%). Administration of the iodolipids did not produce significant changes in several serum parameters such as total T(3) and T(4), cholesterol, transaminases, urea and creatinine. CONCLUSION: 2-Iodohexadecanal, as 6-iodo-deltalactone, prevents goiter growth in rats and opens a potential therapeutic application of iodolipids.