Fractionation of iodinated particles and mitochondria from thyroid by zonal centrifugation and a study of their heterogeneity.
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1. The subcellular particles of horse and rat thyroids were fractionated in a B XIV zonal rotor on a non-linear gradient of Ficoll after labelling with radioactive iodine in vitro (horse) or in vivo (rat). In the horse, the resulting fractions were analysed for radioactive iodine, protein and enzymes representative of certain subcellular particles. In the rat, iodine turnover and thyrotrophin stimulation were studied. 2. The population of iodinated particles could be subdivided into three main classes, characterized by differences in beta-galactosidase and acid phosphatase content and position in the gradient. The presence of a fourth class of particles is suggested. 3. It is concluded that iodinated particles isolated from the thyroid are essentially secondary lysosomes. Their heterogeneity is established with respect to their position in the gradient, their content of acid hydrolases and their iodine turnover. 4. The iodine pools of these secondary lysosomes are increased by thyrotrophin without any change in their number. 5. Their functional significance is discussed. 6. The distribution of mitochondria as judged by succinate dehydrogenase was also studied. The succinate dehydrogenase was spread throughout the gradient with a maximum of activity (40%) in the upper layer of the gradient. Separation of mitochondria from lysosomes by this method was not successful. (+info)
Studies on the congenitally goitrous sheep. Iodoproteins of the goitre.
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1. Congenitally goitrous thyroid tissue was obtained from South Australian Merino sheep. Ultrastructural studies of the secretory cells in this tissue showed active cells of normal appearance, containing apical protein droplets. 2. (125)I-labelling in vivo of goitre tissue was used to investigate the iodoproteins, in which the major proportion of (125)I appeared in the cell protein fraction soluble in 0.9% sodium chloride (average 62% in goitres from untreated sheep). 3. Ammonium sulphate fractionation showed two clear peaks of iodoprotein precipitation, one at 35-40% saturation and the other at 50-55% saturation. Both iodoprotein fractions contained iodotyrosines and iodothyronines, which were identified chromatographically after enzymic hydrolysis of the protein. 4. Polyacrylamide-gel electrophoresis at pH9.4, at either 7.5 or 5.0% acrylamide concentration, was used to characterize the iodoproteins. Two major fractions were observed, the fastest-migrating fraction coincident with serum albumin, and a slower-migrating, less-well-defined zone. This fraction migrated in 7.5% acrylamide gel, which excluded normal thyroglobulin. 5. Density-gradient (10-40% sucrose) centrifugation was used to determine the approximate sedimentation coefficients of the iodoproteins, which showed major components at s(20,w) 8-9S and s(20,w)<5S. 6. Immunoprecipitation with rabbit anti-(sheep thyroglobulin) failed to sediment (125)I-labelled proteins from goitre extracts. 7. Ouchterlony-type double diffusion in agar plates demonstrated immunoprecipitation lines between rabbit anti-(sheep thyroglobulin) and both the concentrated goitre extract and its Sephadex G-200-excluded fraction, which were confluent with that obtained on reaction with purified normal thyroglobulin. 8. It was concluded that both major iodoprotein fractions were capable of supplying thyroid hormones to the animal, and that the fraction of s(20,w)<5S was iodinated serum albumin. As (125)I-labelled thyroglobulin was not detected in goitre tissue from untreated or thyroxine-treated animals, it was possible that the genetic defect causing goitre resulted in an abnormal thyroglobulin, incapable of being iodinated but immunologically reactive. (+info)
Site-site interactions among insulin receptors. Characterization of the negative cooperativity.
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By studying the dissociation of 125I-instulin from its receptors in the absence and phe negatively cooperative type for the insulin receptors. In the present study we extend oy purified mouse and rat liver membranes as well as in human circulating monocytes and human cultured lymphocytes demonstrated negative cooperativity that was extraordinarily simn membranes more slowly than it does from its receptors on whole cells. The dissociaty a small percentage of the receptor sites (1 to 5%), are sufficient to accelerate dissociation of hormone from receptor. At these insulin concentrations insulin is entirely monomeric, and in fact at higher concentrations of insulin (greater than 10(-7) M) where insulin dimers predominate, the cooperativity effect is progressively lost. The dissociation rate of 125I-insulin alone (that is at very low fractional saturation of receptors) was markedly accelerated by dripping the pH from 8.0 to 5.0, whereas the dissociation of 125I-insulin at high receptor occupancy was only slightly accelerated by the fall in pH. The dissociation rate was directly related to temperature, but the dissociation rate of 125I-insulin at low receptor occupancy was much more affected by reduction in temperature and showed a sharp transition at 21 degrees. Urea at concentrations as low as 1 M produced a marked acceleration of 125I-insulin dissociation. Divalent cations (calcium and magnesium) appear to stabilize the insulin-receptor interaction, since higher degrees of receptor occupancy were required to achieve a given rate of dissociation of 125I-insulin. These data make it likely that the insulin receptors exist as oligomeric structures or clusters in the plasma membrane. Insulin receptor sites appear to switch from a "slow dissociating" state to a "fast dissociating" state when their occupancy increases; the proportion of sites in each state is a function of occupancy of the receptor sites by the insulin monomer as well as of the physiochemical environment. Other models which could explain apparent negative cooperativity besides site-site interactions, i.e. polymerization of the hormone, steric or electrostatic hindrance due to ligand-ligand interactions, or unstirred (Noyes-Whitney) layers are considered unlikely in the case of insulin receptors on both experimental and theoretical grounds. (+info)
Immunological and biological properties of iodoinsulin labeled with one or less atoms of iodine per molecule.
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Experiments were designed to compare the distribution of free and antibody-bound unlabeled insulin to the distribution of free and antibody-bound insulin-(125)I. The insulin antibody was incorporated in a specific immune precipitate similar to the one used by Hales and Randle for the radioimmune assay of insulin. Insulin which was not bound by the specific immune precipitate was measured by the immune hemolysis inhibition assay. This report contains evidence that the addition of the unlabeled insulin in the radioimmune assay results in relatively more insulin-(125)I which remains free and less bound by antibodies than is the case with the unlabeled insulin. Methods are described for the separation of an electrophoretically homogeneous iodoinsulin from samples of crude iodoinsulin with average incorporations of less than 0.2 atoms iodine per molecule. These purified iodoinsulin fractions have a markedly attenuated biological activity. Evidence is presented which supports the postulate that only a portion of the antibodies in guinea pig insulin antiserum are capable of effectively binding with purified iodoinsulin. (+info)
Iodinated phospholipids and the in vitro iodination of proteins of dog thyroid gland.
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Slices of dog thyroid gland were incubated with liposomes consisting of (125)I-labelled phosphatidylcholine (the iodine was covalently linked to unsaturated fatty acyl chains). The (125)I label of (125)I-labelled liposomes was incorporated into thyroid protein and/or thyroglobulin at a higher rate than was the (131)I label of either Na(131)I or (131)I(2). The iodine was shown to be protein-bound by the co-migration of the labelled iodine with protein under conditions where free iodine, iodide and lipid-bound iodine were removed from protein. The uptake of iodine from the iodinated phospholipid was probably due to phospholipid exchange between the iodinated liposomes and the thyroid cell membrane, since (a) (14)C-labelled phospholipid was metabolized to (14)CO(2) and (b) many lipids in the tissue slice became (14)C-labelled. A very strong inhibition of iodide ;uptake' from Na(131)I, caused by thiosulphate, produced only a minor inhibition of the incorporation of (125)I from (125)I-labelled liposomes into thyroid protein and/or thyroglobulin. This implies that free iodide may not necessarily be formed from the iodinated phospholipids before their entrance or utilization in the cell. Synthetic polytyrosine polypeptide suspensions showed some iodination by (131)I-labelled liposomes. In tissues with low tyrosine contents, such as liver and kidney, only a trace uptake was observed. Salivary gland showed some uptake. Endoplasmic reticulum of thyroid gland showed a higher iodine uptake than that of the corresponding plasma membranes. These experiments, together with the demonstration of the diet-dependent presence of iodinated phospholipids in dog thyroid, leads us to suggest that iodination of the membrane phospholipids of thyroid cells may be directly or indirectly involved at some stage in the synthesis of thyroglobulin, or exists as a scavenger mechanism, to re-utilize and/or recover released iodine from unstable compounds inside the thyroid cell. (+info)
Binding of sea anemone toxin to receptor sites associated with gating system of sodium channel in synaptic nerve endings in vitro.
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Iodination of toxin II from the sea anemone Anemonia sulcata gives a labeled monoiododerivative that retains 80% of the original neurotoxicity. This derivative binds specifically to rat brain synaptosomes at 20 degrees C and pH 7.4 with a second-order rate constant of association ka = 4.6 x 10(4) M-1 sec-1 and a first-order rate constant of dissociation kd = 1.1 x 10(-2) sec-1. The binding occurs on the Na+ channel at a binding site distinct from that of other gating system toxins like batrachotoxin, veratridine, grayanotoxin, aconitine, and pyrethroids. The maximal binding capacity Bmax is 3.2 pmol/mg of protein (i.e., about two sea anemone toxin binding sites per tetrodotoxin binding site) and the Kd is 240 nM for the monoiododerivative and 150 nM for the native toxin. Corresponding binding parameters for the association of a 125I-labeled derivative of toxin II from the scorpion Androctonus australis Hector are Bmax = 0.3 pmol/mg of protein and Kd = 1 nM, whereas the Kd of the unmodified scorpion toxin is 0.6 nM. Competition experiments involving scorpion toxins, sea anemone toxins, and synaptosomes demonstrate that, although the sea anemone toxin is able to displace the scorpion toxin bound to synaptosomes, the scorpion toxin does not displace the sea anemone toxin. The sea anemone toxin but not the scorpion toxin binds to depolarized synaptosomes. Differences between binding properties of the two polypeptide toxins are analyzed in the discussion. (+info)
Sequence of picornavirus RNAs containing a radioiodinated 5'-linked peptide reveals a conserved 5' sequence.
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Virion RNA (vRNA) from poliovirus type 1 (PV1), poliovirus type 2 (PV2), and coxsackie virus B1 (Cox B1) were treated with proteinase K to remove all but a small peptide of the covalently attached 5' genome-linked virion protein (VPg). The peptide on these RNA molecules was then treated with Bolton-Hunter 125I reagent, which iodinates primary amine groups, in order to obtain specific 5'-terminal radioactive labeling. Sequences of 125I-labeled vRNAs were determined by using a set of base-specific RNases and a partial alkaline hydrolysis "ladder." The first 20 positions of these RNAs show a remarkable conservation of sequence. The initial 10 nucleotides are identical in PV1, PV2, and Cox B1, with the sequence VPg-pU-U-A-A-A-A-C-A-G-C. The next 10 nucleotides show a one-base difference between PV1 and PV2 and 50% homology between PV1 and Cox B1. This conserved 5' region may provide a recognition site for interaction between the viral mRNA and the host translation system. (+info)
The role of calcium and guanosine 3':5'-monophosphate in the action of acetylcholine on thyroid metabolism.
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The role of calcium and guanosine 3':5'-monophosphate (cyclic GMP) in the regulation of thyroid metabolism has been investigated in dog thyroid slices. Carbamoylcholine enhanced glucose carbon-1 oxidation, protein iodination, cyclic GMP accumulation and decreased thyrotropin-induced adenosine 3':5'-monophosphate (cyclic AMP) accumulation and iodine secretion; it did not affect protein synthesis. The effects of carbamoylcholine were reproduced under various experimental conditions by supplementary calcium in the medium, ouabain, and in media in which Na+ had been replaced by choline chloride. They were inhibited by lanthanum. These results further support the hypothesis that free intracellular Ca2+ is the intracellular signal for carbamoylcholine effects and suggest that a Na+ -gradient-driven Ca2+ extrusion mechanism operates in the thyroid cell. Mn2+ reproduced the effect of Ca2+ on glucose oxidation, protein iodination and cyclic GMP accumulation in Ca2+ -depleted slices and medium, and thus mimicked some intracellular effects of Ca2+. On the other hand Mn2+ inhibited the carbamoylcholine effect on thyrotropin-induced thyroid secretion and cyclic AMP accumulation, and Ca2+ inhibited the Mn2+-induced cyclic GMP accumulation. This suggests that the two ions compete for the same channel. Similarly Mn2+ inhibited calcium effects in the presence of ionophore A23187. Procaine inhibited protein iodination under all conditions suggesting a primary effect; it also inhibited all carbamoylcholine and ouabain actions. However the drug did not inhibit the effects of choline chloride and its action was reversed by raising carbamoylcholine but not Ca2+ concentration; it is therefore doubtful that procaine acts by blocking Ca2+ channels. In media without added Ca2+, Mn2+ increased cyclic GMP accumulation but did not decrease thyrotropin-induced cyclic AMP accumulation or iodine secretion, which suggests that cyclic GMP cannot be the sole mediator of the latter two effects of carbamoylcholine. (+info)