To elucidate the mechanism of decreased 131I uptake by the thyroid gland in patients with subacute thyroiditis and painless thyroiditis, human thyroid follicles were cultured with interleukin-1 (IL-1), tumor necrosis factor-alpha (TNF alpha), and/or interferon-gamma (IFN gamma), and the effects of these cytokines on thyroid function were studied in vitro. When human thyrocytes were cultured in RPMI-1640 medium containing 0.5% fetal calf serum and TSH for 5-8 days, the cells incorporated 125I, synthesized de novo [125I]iodotyrosines and [125I]iodothyronines, and secreted [125I]T4 and [125I]T3 into the medium. IL-1 alpha and IL-1 beta inhibited 125I incorporation and [125I]iodothyronine release in a concentration-dependent manner. The minimal inhibitory effect was detected at 10 pg/ml. Electron microscopic examination revealed a marked decrease in lysosome formation in IL-1-treated thyrocytes. TNF alpha and IFN gamma also inhibited thyroid function in a concentration-dependent manner. Furthermore, when thyrocytes were cultured with IL-1, TNF alpha and IFN gamma, these cytokines more than additively inhibited thyroid function. Although the main mechanism of 131I uptake suppression in the thyroid gland in subacute thyroiditis is due to cellular damage and suppression of TSH release, our present findings suggest that IL-1, TNF alpha, and IFN gamma produced in the inflammatory process within the thyroid gland further inhibit iodine incorporation and at least partly account for the decreased 131I uptake by the thyroid gland in destruction-induced hyperthyroidism.
Hematin polymerization is a parasite-specific process that enables the detoxification of heme following its release in the lysosomal digestive vacuole during hemoglobin degradation, and represents both an essential and a unique pharmacological drug target. We have developed a high-throughput in vitro microassay of hematin polymerization based on the detection of 14 C-labeled hematin incorporated into polymeric hemozoin (malaria pigment). The assay uses 96-well filtration microplates and requires 12 h and a Wallac 1450 MicroBeta liquid scintillation counter. The robustness of the assay allowed the rapid screening and evaluation of more than 100,000 compounds. Random screening was complemented by the development of a pharmacophore hypothesis using the "Catalyst" program and a large amount of data available on the inhibitory activity of a large library of 4-aminoquinolines. Using these methods, we identified "hit" compounds belonging to several chemical structural classes that had potential antimalarial activity. Follow-up evaluation of the antimalarial activity of these compounds in culture and in the Plasmodium berghei murine model further identified compounds with actual antimalarial activity. Of particular interest was a triarylcarbinol (Ro 06-9075) and a related benzophenone (Ro 22-8014) that showed oral activity in the murine model. These compounds are chemically accessible and could form the basis of a new antimalarial medicinal chemistry program.
Hemopexin (Hx), the major heme-binding plasma glycoprotein, scavenges circulating heme and performs an antioxidant function. In the present study, human Hx was expressed in a baculovirus system and its presumed essential His residues were mutated to Thr as a means of investigating their participation in heme binding. The recombinant Hx proteins were purified by sequential chromatography on Con A-agarose and SP-Sepharose. The purified recombinant wild-type Hx retained its heme binding. The binding constant for heme was considerably reduced, however, suggesting that glycosylation contributes critically to the heme binding property of Hx. Mutation either at His-127 or at His-56 plus His-127, but not at His-56 per se, reduced the affinity for heme by an order of magnitude relative to wild-type Hx. It is concluded that His-127 contributes to the high affinity for heme. We recorded proton NMR spectra to investigate the possibility that the degree of high-spin content is increased by deletion of an axial His-iron coordination. 1H NMR data indicate that each of the single-mutant heme-Hx complexes is predominantly low-spin, perhaps owing to coordination of the heme iron by the Thr side-chain oxygen or water oxygen coordinating to the iron.
The haemolytic action of Vibrio vulnificus haemolysin (VVH) was compared to that of streptolysin O (SLO). Both were cholesterol-binding haemolysins, but differed in the release of haemoglobin (Hb). In the first step of haemolysis, the haemolysins were temperature-independently bound to the cholesterol site on the target erythrocyte membrane. This was followed by the rapid release of K+, which is an intra-erythrocyte marker. Hb was then released, in different ways. In the case of VVH, Hb was released slowly after a relatively long lag, whereas with SLO, Hb was released as rapidly as K+. Haemolysis by VVH was inhibited by the addition of 30 mM-dextran 4 (mean Mr 4000), which is considered to be an effective colloid-osmotic protectant. The results therefore indicated that haemolysis by VVH (like that by Escherichia coli alpha-haemolysin and Staphylococcus aureus alpha-toxin) was caused by a colloid-osmotic mechanism. Both K+ and Hb release caused by VVH proceeded temperature-dependently, and the membrane fluidity of liposomes prepared with lipids extracted from sheep red blood cell membranes increased above 20 degrees C. These results suggest that the temperature-dependence of the haemolysis by VVH is due to the requirement for an increase in the membrane fluidity during the formation of a transmembrane pore.
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