Cell Population Kinetics and Dna Content During Thyroid Carcinogenesis

The proliferation kinetics and DNA content of thyroid follicular cells in rats were studied by autoradiography and cytophotometry. Continuous treatment of animals with methylthiouracil (MTU) results in hyperplasia followed by tumour growth in the thyroid gland. the mitotic index (MI) increases from 0.006 ± 0.002% in controls to 0.13 ± 0.06% in hyperplasia and to 0.09 ± 0.03% in malignant cells. the same is true for the labelling index (LI) which rises from 0.08 ± 0.003% in controls to 1.4 ± 1.1% in hyperplasia and to 1.0 ± 0.6% in follicular adenomas. the S-phase duration (T_s) is shortened from 8.0 ± 1.2 hr in controls to 6.0 ± 1.4 hr in animals treated for 9 months with MTU and prolonged to 15.4 ± 2.1 hr in papillary carcinomas. In all MTU-treated animals a decrease in the value of the potential population doubling time (T_PD) and thyroid weight doubling time (T_D) was observed. the cell loss factor (ø) decreases in animals treated for 3 months with MTU and increases during the stage of tumour growth in the gland (animals treated 12–15 months with MTU). DNA measurements in the nuclei of hyperplastic and neoplastic thyroid tissues reveal cells with values exceeding that in control animals. However, no difference was found in the DNA content between thyroid adenomas and carcinomas, nor between thyroid hyperplasia and neoplasia. During the last decade numerous autoradiographic studies have been performed on the cell population kinetics of benign and malignant tumours in animals and man (Steel, 1977; Tubiana & Malaise, 1977). It has been established that cell proliferation is an important parameter in both the initiation and promotion phases of carcinogenesis (Oehlert, 1973; Berenblum, 1979). Cell kinetic studies during carcinogenesis have predominantly dealt with the liver (Rajewsky, 1967; Chernozemski & Warwick, 1970), skin (Raick, 1974), the mammary gland (Bresciani, 1965; Nagasawa, Yanai & Nagigushi, 1976b), the uterine cervix (Nagasawa, Matsuura & Tojo, 1976a) and intestinal cells (Tutton & Barka, 1966; Pozharisski, Klimashewski & Gushin, 1977). Information on the changes in cell population kinetics during thyroid carcinogenesis is still incomplete. Data reported in the literature are mainly devoted to the short-term effects of goitrogens and radiation factors (Santler, 1957; Sheline, 1969; Philip, Crooks & MacGregor, 1969; Wynford-Stringer & Williams, 1982; Redmond & Tuffery, 1981). The present study was carried out to investigate if changes in the cell population kinetics and DNA content occur during thyroid carcinogenesis, as well as if thyroid adenomas and carcinomas differ in their proliferative potential and DNA content.