Torsten Öfverholm

Electron-microscopic studies of iodine-binding and peroxidase activity in the endostyle of the larval amphioxus (Branchiostoma lanceolatum)

SummaryThe asymmetric endostyle in the larval amphioxus (Branchiostoma lanceolatum) was examined by light-and electron-microscopic cytochemistry (peroxidase; incubation in diaminobenzidine) and autoradiography (incubation in 125I-). Compared to the adult the same cellular zones were also found in the larval endostyle, with the exception of zone 1, which was absent. The corresponding adult and larval zones had a similar morphology. All cells in zones 5a, 5b, and 6 were reactive for peroxidase. A reaction product was also present in the lateral 2 to 3 cell rows of zone 3. The dense reaction product was located on the inner surface of membranes of the rough endoplasmatic reticulum, Golgi apparatus and vesicles, and multivesicular bodies as well as on the outer surface of the luminal plasma membrane. An incomplete row of granule-containing, peroxidase-negative cells was located between zones 5b and 6. After incubation of larvae in sea water containing 125I-, autoradiographic grains were selectively concentrated over the lumen at the apical surface of all peroxidase-positive zones. The highest grain density occurred in relation to zone 5a, which in the adult has been recognized as the iodination center. Few grains were located over the cytoplasm. Methimazole, an inhibitor of peroxidase, abolished the cytochemical reaction and the appearance of autoradiographic grains. The observations indicate that iodination in the larval endostyle takes place extracellularly and is catalyzed by peroxidase bound in the plasma membrane.

Ultrastructural demonstration of iodine binding and peroxidase activity in the endostyle of Oikopleura dioica (appendicularia)

The endostyles of cephalochordates, ascidians, and larval petromyzontids have the capacity to organify iodine. A similar mechanism in the appendicularian endostyle has hitherto been unknown. Observations in this study of Oikopleura dioica with electron microscopic autoradiography and cytochemistry show that also the appendicularian endostyle has iodinating capacity and that the iodinating cells contain peroxidase, an enzyme responsible for iodination. After incubation in seawater containing 125I-, autoradiography revealed a selective labeling in the dorsal portion of the endostyle. The endostyle of O. dioica is on each side lined by four rows of corridor cells. The autoradiographic grains were mainly located over the endostylar lumen or associated with the luminal surface of the two central rows of corridor cells. These cells, but no other endostylar cells, also showed a positive reaction for peroxidase. The reaction product was distributed along the luminal plasma membrane and was also present in the cytoplasm within rough endoplasmatic reticulum, Golgi apparatus, and vesicles. The selective labeling as well as the cytochemical reaction were abolished by incubation in methimazole, an inhibitor of peroxidase. It is suggested that the two central rows of the corridor cells can be considered as homologs to iodine-binding zones in other endostyles and also as a primitive forerunner to the vertebrate thyroid gland.

Ultrastructural localization of the iodination centre in the endostyle of the adult amphioxus (Branchiostoma lanceolatum)

SummaryThe site of iodination in the endostyle of the adult amphioxus was examined by light-and electron-microscopic autoradiography. In accordance with previous studies, light-microscopic autoradiography showed a distinct accumulation of autoradiographic grains at the apical end of epithelial cells in the lateral part of the endostyle. In the electron microscope two distinct cellular zones were identified in an approximate position of the light-microscopic zone 5. Zone 5a, not previously recognized, was adjacent to zone 4 and consisted of six to nine rows of cells free of characteristic granules. Cells in zone 5b contained large “mucous” granules and had, in previous ultrastructural studies, been identified as belonging to the typical zone 5. Four or less incomplete rows of granule-containing cells, not observed in previous studies, marked the border between zones 5b and 6. After incubation in 125I for 5 min, electron-microscopic autoradiography showed a selective concentration of label to zone 5a, which, thus, corresponds to the iodination centre seen in the light microscope. The grains were associated with cilia and microvilli in the lumen. After longer incubation times (30, 60, 90 min) grains were still concentrated at the surface of zone 5a but were also associated with the surface of zones 5b and 6. Grains were also located over the cytoplasm of all three zones. They were associated with vesicles and lysosome-like structures, suggesting secondary uptake of labelled products by endocytosis. Methimazole, an inhibitor of peroxidase, abolished the autoradiographic reaction. In conclusion, the site of iodination in the endostyle of amphioxus is located in zone 5a, which has not previously been ultrastructurally defined. Iodination in the endostyle is an extracellular process, but secondary uptake by endocytosis appears to occur.

Electron-microscopic immunocytochemistry of 5-hydroxytryptamine in the ascidian endostyle

SummaryThe cellular and subcellular distribution of serotonin (5-hydroxytryptamine, 5-HT) in the endostyle of three species of ascidians, Ciona intestinalis, Corella parallelogramma, Ascidia mentula, was studied by light-(immunoperoxidase) and electron-microscopic (immunogold) immunocytochemistry. At the light-microscopic level 5-HT-like immunoreactivity (5-HT-LI) was exclusively found in cells located in the lateral portion of the endostyle, between zone 7, known to have iodinating capacity, and zone 8, which consists of ciliated cells. At the electron-microscopic level, the 5-HT-immunoreactive cells were found to correspond to cells containing polymorphous, dense granules, 100–300 nm in diameter. The granules were located in the supranuclear cytoplasm facing the endostyle lumen as well as in the infranuclear cytoplasm facing the extracellular space. Quantification showed that the 5-HT-LI was considerably higher (13–67 times) in cytoplasmic areas containing granules as compared to areas devoid of granules. Most, but not all, of the 5-HT-LI was associated with the dense core of the granules. In conclusion, serotonin-containing cells are located in the peripheral portion of the endostyle, between zones 7 and 8. Serotonin is stored in cytoplasmic granules that are present both in the apical and basal cytoplasm. This suggests the possibility that the cells are bipolar and secrete serotonin both in a basal direction to the extracellular space, and in an apical direction to the pharyngeal lumen.

Iodine binding and peroxidase activity in the endostyle of Salpa fusiformis, Thalia democratica, Dolioletta gegenbauri and Doliolum nationalis (Tunicata, Thaliacea)

SummaryThe protothyroid region in the endostyles of four species of tunicates was examined by means of autoradiography and cytochemistry, at both the light and electronmicroscopic levels. To reveal the primary binding site for iodine, autoradiography was carried out on endostylar tissue from animals that had been incubated with high activity 125I- over a short period of time. The specific iodine binding enzyme, a peroxidase, was traced by its reaction with DAB. In accordance with previous findings, the iodinebinding cells proved to be the same as those containing the peroxidase. There were also strong indications of a secondary uptake of iodinated compounds and subsequent release into the body fluid. Together with the ultrastructural features, the data provided strong evidence indicating that these cells constitute a protothyroid region, which partly functions as an endocrine organ, possibly homologous with the vertebrate thyroid gland. Since the number of zones varied between the species, the numeration of the protothyroid region also varied. However, in all the examined endostyles, the protothyroid region was seen to be situated dorsolaterally to the glandular regions of the endostyle concerned with food capture.

In vivo shedding of apical plasma membrane in the thyroid follicle cells of the mouse

SummaryClusters of luminal dense bodies, limited by a triple-layered membrane, were found in all follicle lumina in thyroid glands of mice. After thyroxine treatment the number of luminal dense bodies increased, especially in the periphery of the lumen, where the intraluminal bodies often displayed a striking resemblance to microvilli. In hyperplastic goiters, obtained by feeding mice with propylthiouracil, luminal dense bodies were replaced by intraluminal vesicles. During goiter involution the vesicles were gradually replaced by luminal dense bodies; the presence of intermediate forms suggests that vesicles and dense bodies are basically the same formations. Luminal dense bodies were observed in colloid droplets indicating their removal by endocytosis. As demonstrated by electron-microscopic cytochemistry, luminal dense bodies contain a membranebound peroxidase, and electron-microscopic autoradiography after administration of 125I indicate that they possess an iodinating capacity.Our observations on mouse thyroid glands suggest that the luminal dense bodies, which appear as vesicles in hyperplastic glands, are formed by shedding of the apical plasma membrane of the follicle cell. The shedding process might be of importance for the turnover of plasma-membrane material.

Forskolin-induced elevation of cyclic AMP does not cause exocytosis and endocytosis in rat thyroid follicle cells in vivo.

Using a newly developed infusion technique, the in vivo effects of forskolin and dibuturyl cyclic AMP (dbcAMP) on exocytosis and endocytosis in thyroid follicle cells were studied in thyroxine-treated rats and mice. Reactants were selectively infused via the superior thyroid artery to one thyroid lobe. The contralateral lobe served as a control. In the rat, a supramaximal i.v. dose of thyrotropin (TSH, 500 mU) induced a slight increase in thyroidal tissue levels of cyclic adenosine monophosphate (cAMP) while TSH 50 mU i.v. had no effect on cAMP levels. On the other hand both doses of TSH stimulated exocytosis, signified by a decrease in the number of exocytotic vesicles and endocytosis, signified by the appearance of pseudopods and colloid droplets. Selective thyroid infusion of dbcAMP (5 mM) or forskolin (25 microM), which induced a 10-fold increase in thyroid cAMP levels, did not induce any morphological sign of exocytosis or endocytosis in the follicle cells. The morphological response to TSH given i.v. was quantitatively unaltered by simultaneous infusion of forskolin. In contrast to the findings in rats, infusion of forskolin and dbcAMP in mice induced endocytosis. In conclusion, our findings in the mouse are in agreement with earlier studies in this and other species, indicating that cAMP mediates the effects of TSH on endocytosis and probably also on exocytosis. In contrast, our observations in the rat thyroid in vivo lead to the conclusion that cAMP is not the main intracellular mediator of exocytosis and endocytosis in this species. This conclusion is at variance with previous reports, mostly from in vitro studies.(ABSTRACT TRUNCATED AT 250 WORDS)

Endocytosis of Organified Iodine in the Endostyle of the Amphioxus

Parts of the protochordate endostyle are considered homologous to the vertebrate thyroid (1–3). In the adult amphioxus, the endostyle forms a groove in the floor of the pharynx lined by paired, longitudinal zones of epithelial cells. In the larval amphioxus, the endostyle is an unpaired structure in the right buccal wall (4). In the adult (5–7), as well as larval endostyle (8,9), iodination takes place in the lumen at the apical surface of a well-defined cell zone in the lateral portion of the endostyle. Iodination is catalyzed by a peroxidase, present in the apical plasma membrane (9). A thyroglobulin-like protein and iodothyronines have been found in the amphioxus (10,11). Thus, the mechanism of iodination shares many features with that in thyroid follicle cells (12).