Thyroglobulin (TG) is secreted by the thyrocytes into the follicular lumen of the thyroid. After maturation and hormone formation, TG is endocytosed and delivered to lysosomes. Quality control mechanisms may occur during this bidirectional traffic since 1) several molecular chaperones are cosecreted with TG in vivo, and 2) lysosomal targeting of immature TG is thought to be prevented via the interaction, in acidic conditions, between the Ser789–Met1172 TG hormonogenic domain (BD) and an unidentified membrane receptor. We investigated the secretion and cell surface expression of PDI and other chaperones in the FRTL5 thyroid cell line, and then studied the characteristics of the interaction between TG and PDI. We demonstrated that PDI, but also other chaperones such as calnexin and KDEL-containing proteins are exposed at the cell surface. We observed on living cells or membrane preparations that PDI specifically binds TG in acidic conditions, and that only BD is involved in binding. Surface plasmon resonance analysis of TG/PDI interactions indicated: 1) that PDI bound TG but only in acidic conditions, and that it preferentially recognized immature molecules, and 2) BD is involved in binding even if cysteine-rich modules are deleted. The notion that PDI acts as an "escort" for immature TG in acidic post-endoplasmic reticulum compartments is discussed.
In the present study, changes in thyroid follicular cell volume and its regulation have been investigated during the early involution of a hyperplastic goitre. Male Wistar rats were administered an iodine deficient diet for 6 months with propylthiouracil (PTU, 0.15%) during the last two months. At the end of iodine deficiency (day 0), some rats were killed and the others received a normal iodine diet. These rats were killed after different periods of iodine refeeding. Thyroid follicular cell volume was very high in hyperplastic gland whereas thyroid protein concentration was low. Thyroid follicular cell volume quickly decreased when rats were normally iodine refed, whereas thyroid protein concentration increased. Electron microscopal observations showed that thyroid follicular cells retained their endocrine aspect in hyperplastic state and throughout the iodine refeeding period. Using concomitant stereological and biochemical techniques, it is shown that the amount of cellular iodide and an unknown iodinated compound strongly increased during the early iodine refeeding. Plasma TSH was high on day 0 and remained at this level until day 8 whereas plasma T3 and T4 were low on day 0 and remained at this low level until day 4. The present data show that the involution of thyroid follicular cell volume is induced by iodide and mediated by an iodinated compound at least in the initial phase, and is independent of plasma TSH, T3, T4, so indicating the involvement of a thyroid autoregulatory mechanism. These changes in cell volume may be of importance in ion transport, i.e. in the metabolism of thyroid follicular cell during the early involution of the hyperplastic goitre.
To avoid premature lysosomal degradation, thyrocytes have a system able to recycle internalized immature thyroglobulin molecules (Tg) to the follicular lumen via the Golgi apparatus. It has been shown that this quality control system depends on recognition of exposed N-acetylglucosamine (GlcNAc) determinants (Miquelis et al., J Cell Biol, 1993, 123, 1695) present on immature Tg (Bastiani et al., 1995, Endocrinology, 1995, 136, 4204). However, the same in vitro kinetics studies also showed that GlcNAc residues alone induce only weak recycling. The latter finding led us to investigate the possibility that protein determinants might also be involved in binding. For this purpose, we studied binding of Tg to FRTL 5 cells, a widely available TSH-dependent cell line and found that binding to plasma membranes occurred at acidic pH in the presence of calcium, i.e. under conditions previously reported for binding of GlcNAc-BSA to porcine thyroid cell membranes. As expected, binding was GlcNAc- and oligosaccharide-dependent because Bandeiraea Simplificiola II affinity column analysis indicated that GlcNAc-bearing Tg were preferentially bound and N-glycanase treatment of Tg inhibited interaction. Ovomucoid, GlcNAc-BSA, and porcine Tg oligosaccharides did not inhibit binding, indicating that carbohydrates were not the sole determinants for binding. The fact that pronase digestion of Tg totally abolished binding implied that peptide determinants were involved in the interaction. This involvement is supported by the observation that porcine, rat, bovine, and human Tg bound FRTL 5 cell membranes and that monoclonal antibodies raised against human Tg interfered with the binding of both human and porcine Tg. Based on these findings we conclude that, besides the involvement of GlcNAc-bearing oligosaccharides, Tg receptors form a stable bond with peptide determinants.
Global response of the thyroid to a 10-fold increase in plasma iodide concentration results only in modifications of basolateral transfer for iodide where, by a balance phenomenon between influx and efflux, a net thyroid intake of 1.2 micrograms I/day is constantly maintained. The other main steps of thyroid iodine metabolism, thyroglobulin (Tg) iodination, endocytosis, and hydrolysis, remain constant. A stationary hormone secretion delivery results. This constant state is not found at a cellular level, where structural changes are observed in correlation with functional regulation of the cell dynamic state. Thus, an increase in plasma iodide concentration results in an increase of the apical membrane area (40%), whereas the basolateral membrane area decreases (18%). The volume of the follicle lumen increases (76%). Nevertheless, neither epithelial cell volume nor the structure of microvilli are modified. Comparison of iodine fluxes through the apical and basolateral membrane of the epithelial cell shows that an increase in plasma iodide concentration is correlated to a decrease of the Tg iodination and endocytotic fluxes (45%). A regulation also appears for basolateral transfer of iodide, whereas the lysosome system does not modulate the hormone secretion mechanism.
The long-term iodine turnover (140 days) of thyroid gland and plasma has been studied in rats in a steady state and receiving either 5 (group 5) or 50 (group 50) mug of iodine daily. At 60 days, the turnover of Thyroglobin is total (group 50) or 80% (group 5) but is total for PBI in the two groups. An iodine pool with a very slow turnover participates neither in the PBI secretion nor in the iodide recycling within the gland.
The morphological and functional changes during involution of hyperplastic goitre have been investigated in the adult male rat. Male wistar rats received an iodine-deficient diet for 6 months and during the last 2 months received propylthiouracil (PTU, 0.15%). By the end of this treatment (day 0), a hyperplastic goitre was obtained. A normal iodine supply was then given and PTU withdrawn. During the first 8 days of iodine refeeding, the plasma thyrotropin (TSH) remained at a high level (ten times the control value), whereas the thyroid iodide content was low on day 0, markedly increased on day 1 and decreased on day 4. Plasma T3 and T4 levels remained unchanged for 4 days and only increased on day 8. The total thyroid protein concentration was low on day 0 and then increased rapidly on day 8 (by 34%). The volume density of colloid remained low and unchanged until day 8, when it started to increase. However, the thyroid epithelial cell volume and the volume density of capillaries were raised on day 0, decreased rapidly in the next 8 days and more slowly later on. The total number of thyroid epithelial cells was considerably raised in the hyperplastic gland. It did not vary until day 16, when it decreased slowly, reaching a plateau on day 45 above the control value. The present data show that involution of hyperplastic goitre in the rat is due essentially to a decrease in thyroid epithelial cell volume and to a reduction of the increased number of capillary blood vessels present. The decrease in the number of epithelial cells is only 16.5%, suggesting that the death of thyroid epithelial cells contributes little. Half the process of involution, which occurs from days 0 to 8, is controlled by the thyroid iodide concentration rather than TSH, indicating the involvement of a thyroid autoregulatory mechanism. It must be emphasized, however, that the discontinuous pattern of epithelial cell number during involution may indicate that some cells with larger nuclei and more rapid turnover disappear more quickly after iodine refeeding.
Incubation at 37 degrees C or treatment of granule membranes of chromaffin cells with Staphylococcus aureus phosphatidylinositol-specific phospholipase C converted from an amphiphilic to a hydrophilic form two proteins with molecular masses of 82 and 68 kDa respectively. Their release is time- and enzyme-concentration-dependent. We showed that they were immunoreactive with an anti-(cross-reacting determinant) antibody known to be revealed only after removal of a diacylglycerol anchor. Furthermore, the action of HNO2 suggests the presence of a non-acetylated glucosamine residue in the determinant. This is one of the first reports suggesting that a glycosylphosphatidylinositol anchor might exist in membranes other than the plasma membrane. We showed that the 68 kDa protein is probably not the subunit of dopamine (3,4-dihydroxyphenethylamine) beta-hydroxylase, an enzyme present in granules in both soluble and membrane-associated forms.
To estimate the relative participation of transported and intrathyroidally generated iodide (internal iodide) in the iodination of newly synthesized and preexisting thyroglobulin (Tg) in the rat thyroid, the specific radioactivities (SRAs) of thyroid iodide, Tg, lysosomal iodine, and plasma hormones were followed for 92 h after radioactive iodide injection in intact or hypophysectomized rats. In control rats, the SRA of Tg and lysosomal iodine reached a maximum at 12 h. However, the SRA of lysosomal iodine was always smaller than that of Tg. In contrast, the SRA of hormonal iodine attained a maximum at 48 h. Thus, newly labeled iodine is endocytosed and mixed inside the lysosomes with older previously iodinated molecules; hormone secretion is mainly due to old labeled iodine (i.e. iodine with a high SRA from 48–96 h). These results are consistent with the presence of at least two Tg compartments, with different turnover rates and hormone contents. On the other hand, in hypophysectomized rats, the SRA of Tg, lysosomes, and hormones showed only one maximum, at 24 h. Furthermore, the SRAs of Tg and lysosomes were similar at each time interval. It is inferred that in such rats, the old labeled iodine compartment is strongly reduced, and that inside the lysosomes, newly labeled iodine is predominant. Since in hypophysectomized rats, the recycling of iodide is abolished, it is concluded that in normal rats: 1) transported iodide is organified mainly by direct iodination of newly synthesized Tg, independently of TSH, and 2) internal iodide is organified mainly by delayed iodination of preexisting Tg, this process being TSH dependent.
