High bromide intake affects the accumulation of iodide in the rat thyroid and skin

The effect of a high bromide intake on the kinetics of iodide uptake and elimination in the thyroid and skin of adult male rats was studied. In rats fed a diet with sufficient iodine supply (>25 μg I/d), the iodide accumulation in the skin predominated during the first hours after ¹³¹I -iodide application. From this organ, radioiodide was gradually transferred into the thyroid. A high bromide intake (>150 mg Br⁻/d) in these animals led to a marked decrease in iodide accumulation, especially by the thyroid, because of an increase in iodide elimination both from the thyroid and from the skin. In rats kept under the conditions of iodine deficiency (<1 μ I/d), the iodide accumulation in the thyroid, but not in the skin, was markedly increased as a result of a thyrotropic stimulation. The effect of a high bromide intake (>100 mg Br⁻/d) in these animals was particularly pronounced because the rates of iodide elimination were most accelerated both from their thyroid and from their skin. Presented in part at the 20th Workshop on Macro and Trace Elements held in Jena (Germany) on December 1–2, 2000.     

Effect of increased bromide intake on iodine excretion in rats

The time course of iodine excretion in adult male rats substantially differs from bromine excretion. Bromine is excreted at a single rate, whereas iodine evinces two excretion rates. Even a strong increase in bromide intake in experimental animals failed to affect the rate of iodine excretion but it lowered the fraction of iodine accumulated increase in bromide intake in experimental animals failed to affect the rate of iodine excretion but it lowered the fraction of iodine accumulated in the thyroid gland by 20% probably by affecting the transport of iodide into the thyroid gland.     

Interaction of bromine with iodine in the rat thyroid gland at enhanced bromide intake

In experiments with rats, we have found that at enhanced intake of bromide, bromine does not replace chlorine in the thyroid; it replaces iodine. Under our experimental conditions, more than onethird of the iodine content in the thyroid was replaced by bromine. In the thyroid, bromine probably remained in the form of bromide and, in proportional to its increased concentration, the production of iodinated thyronines decreased, with the sum of the iodine and bromine concentrations being constant at the value of 20.51±1.16 μmol/g dry wt of the thyroid. In contrast to other organs, the biological behavior of bromine in the thyroid is not similar to the biological behavior of chlorine but resembles more that of iodine.     

Biological half-lives of bromide and sodium in the rat are connected and dependent on the physiological state

The parallel course of the excretion rates of sodium and bromide ions was demonstrated in adult male rats administered simultaneously with ²⁴Na-sodium chloride and ⁸²Br-bromide. These excretion rates were inversely proportional to the magnitude of sodium intake in the animals. The biological half-life of bromide, as a substitute for sodium or chloride, was investigated with the aid of the radionuclide ⁸²Br in animals situated in very different physiological states (i.e., in lactating and nonlactating female rats as well as in young rats of varying ages [2,4,6, and 10 wk of age]). The ⁸²Br radioactivity retained in mothers and in whole litters was measured in vivo at appropriate time intervals (up to 240 h) after the application of ⁸²Br-bromide to the mothers. The time-course of the changes in the ⁸²Br radioactivity of the young was calculated as the difference between the rate of ⁸²Br intake in the mother's milk and the ⁸²Br excretion through the kidneys into the urine. The rate of ⁸²Br excretion through the kidneys of the dam could be calculated also. Nonweaned young rats (12 d) had the highest half-life (269 h) and lactating dams had the lowest (44 h). The determined values demonstrated that nonweaned young apparently conserve sodium, because of its relatively low concentration in mother's milk, whereas lactating dams, because of their large food intake, waste sodium. Presented in part at the 4th International Symposium on Trace Elements in Human: New Perspectives held in Athens (Greece) on 9–11 October 2003     

Bromide transfer through mother's milk and its impact on the suckling rat

Effects of a high bromide intake in lactating rats on the performance of the dams and on the prosperity of their young were studied. In the dams, two marked consequences undoubtedly caused by high bromide intake were observed: stagnation in the extent of diet and water consumption in the course of the lactation period, and a conspicuous drop in the production rate of mother's milk. A very high intake of bromide in the mothers in the course of the nursing period (about 220 mg Br⁻/d per dam) also caused a marked decrease in the body weight increments in their suckling young. Only about one-half of these young survived and their general condition was very poor. It is suggested that one of the possible reasons for the observed marked decrease in the production of mother's milk in dams with high bromide intake could be a decreased stimulation of the mammary glands as a consequence of reduced consumption of mother's milk by the suckling. Bromide ions ingested by the dams easily moved into the rat milk. Via mother's milk, bromide was transferred in a large extent to the suckling. The amount of bromide in mother's milk depended on the bromide concentration in the drinking water taken by the dams. With the addition of 5 g bromide per liter (providing the mean daily bromide dose of 220 mg), bromide ions replaced about 54% of the chloride in the milk. A rise in the concentration of both halogens caused also an increase in the concentration of sodium in mother's milk. The exact mechanism(s) of bromide interference with postnatal developmental processes in the young remain(s) unclear. Presented in part at the, 4th International Symposium on Trace Elements in Human: New Perspectives held in Athens (Greece) on 9–11 October 2003.     

Biological half-life of cadmium in the urine of inhabitants after cessation of cadmium exposure

We investigated the biological half-life of the urinary cadmium concentration (U-Cd) based on a 24-year follow-up study after cessation of cadmium exposure in a cadmium-polluted area. Spot urine samples were obtained from all inhabitants in this area in 1979, 1986, 1991, 1999 and 2003. Biological half-life was calculated in the inhabitants whose U-Cd was more than 5 μg?l^?1 (9 men and 12 women) or 5 μg?g^?1 creatinine (9 men and 19 women) using a one-compartment model. The estimated half-life and 95% confidence intervals were 13.6 years (9.0–28.2 years) and 13.9 years (9.6–25.6 years) for unadjusted U-Cd in men and women, respectively. For creatinine-adjusted U-Cd, they were 14.2 years (11.2–19.4 years) and 23.5 years (17.7–35.0 years) in men and women, respectively. The biological half-lives of U-Cd obtained in this study were identical with the values of total body burden determined by a different method.     

Biological half-life of bromide in the rat depends primarily on the magnitude of sodium intake

The parallel course of the excretion rates of bromide and sodium ions was demonstrated in adult male and female rats administered simultaneously with potassium 82Br-bromide and 24Na-sodium chloride. The animals were exposed to various intakes of sodium ions accompanied with five different anions: Br-, Cl-, HCO3-, ClO4-, and SCN-. Regardless of the anion accompanying the sodium ion, the excretion rates of 82Br- and 24Na+ ions were proportional to the magnitude of sodium intake in the animals. Hence, we have proved our hypothesis that the biological half-life of bromide depends on the magnitude of sodium intake rather than on the intake of chloride.     

Reaction of 2'-deoxycytidine with peroxynitrite in the presence of ammonium bromide

Peroxynitrite, a reactive nitrogen species generated from nitric oxide and superoxide anion radical, is an endogenous potential risk factor for human cancer. When 2′-deoxycytidine was incubated with peroxynitrite at neutral pH and 37 °C, the reaction was greatly enhanced by the addition of ammonium bromide. Both ammonium ion and bromide ion were required to exert the enhancing effect. In addition to ammonium ion, methylamine and dimethylamine exerted the enhancing effect in the presence of bromide ion. Two major products were identified as 5-hydroxy-2′-deoxycytidine and 5-bromo-2′-deoxycytidine. Hypochlorite solution and bromine water reacted with 2′-deoxycytidine generating 5-hydroxy-2′-deoxycytidine and 5-bromo-2′-deoxycytidine in the presence of ammonium bromide with the yields similar to those of the reaction of peroxynitrite with ammonium bromide. Fenton reaction of 2′-deoxycytidine was suppressed by the addition of ammonium bromide. Nitrogen dioxide gas did not react with 2′-deoxycytidine in the presence or the absence of ammonium bromide. These results suggest that in the presence of ammonium ion or amines, bromide ion interacts with peroxynitrous acid, which is a protonated form of peroxynitrite, but not with hydroxyl radical or nitrogen dioxide generated by homolysis of peroxynitrous acid, to form hypobromous acid. In the presence of ammonium ion or amines, bromide ion may play a role in enhancing the genotoxic effects of peroxynitrite in humans.     

Changes in iodine mapping in rat thyroid during the course of iodine deficiency: imaging and relative quantitation by analytical ion microscope

The analytical ion microscope (AIM) makes possible imaging and relative quantitation of multiple stable or labeled elements on an even tissue section, according to their mass. The purpose of this work was to follow at the rat thyroid follicle level the changes in 127I mapping during low iodine diet (LID) in relation to the ability of thyroid to pick up radioiodine (129I) and to synthesize Tg from its precursor, 2H-labeled leucine. The overall picture of images and countings of 127I shows a progressive decrease of the luminal iodine concentration which on day 80 was 10-fold lower than that of control value. In control rat thyroid cell, concentration was 10-fold lower than that of follicular lumina and was unchanged until 35 days, but the size of the cytoplasmic compartment increased, suggesting a redistribution of iodine stores between thyroid cells and follicular lumina. 129I was always found in colloid as well as in cells at all stages. After 35 days of LID, cytoplasmic and luminal radioiodine concentrations decreased. In control rats, [2H]leucine was found mainly in the cells. During LID its localization was evidenced progressively in most of the lumina. The most striking fact was the presence up to 35 days of some large residual follicles with high 127I concentration and low 129I and 2H incorporation. These data demonstrate the follicular heterogeneity of thyroid response to progressive chronic TSH stimulation induced by LID.     

Plant‐produced human growth hormone shows biological activity in a rat model

Plants have been shown to be efficient systems for expressing a wide range of recombinant proteins from various origins. Here, using a plant virus‐based expression vector to produce human growth hormone (hGH) in Nicotiana benthamiana plants, we demonstrate, for the first time, that the plant‐produced hGH (pphGH) is biologically active in a hypophysectomized rat model. We observed an average weight gain of ～17 g per animal in a group of 10 animals that were injected subcutaneously with pphGH with 60 μg/dose for 10 days. With the increasing demand for hGH, accompanied with the need to make this recombinant protein available to a wider population at a more reasonable cost, plants provide a feasible alternative to current production platforms. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009     

The functional half-life of an mRNA depends on the ribosome spacing in an early coding region

Bacterial mRNAs are translated by closely spaced ribosomes and degraded from the 5′-end, with half-lives of around 2 min at 37 °C in most cases. Ribosome-free or “naked” mRNA is known to be readily degraded, but the initial event that inactivates the mRNA functionally has not been fully described. Here, we characterize a determinant of the functional stability of an mRNA, which is located in the early coding region. Using literature values for the mRNA half-lives of variant lacZ mRNAs in Escherichia coli, we modeled how the ribosome spacing is affected by the translation rate of the individual codons. When comparing the ribosome spacing at various segments of the mRNA to its functional half-life, we found a clear correlation between the functional mRNA half-life and the ribosome spacing in the mRNA region approximately between codon 20 and codon 45. From this finding, we predicted that inserts of slowly translated codons before codon 20 or after codon 45 should shorten or prolong, respectively, the functional mRNA half-life by altering the ribosome density in the important region. These predictions were tested on eight new lacZ variants, and their experimentally determined mRNA half-lives all supported the model. We thus suggest that translation-rate-mediated differences in the spacing between ribosomes in this early coding region is a parameter that determines the mRNAs functional half-life. We present a model that is in accordance with many earlier observations and that allows a prediction of the functional half-life of a given mRNA sequence.     

Determination of the halothane metabolites trifluoroacetic acid and bromide in plasma and urine by ion chromatography

Halothane (CF₃CHClBr), a widely used volatile anesthetic, undergoes extensive biotransformation in humans. Oxidative halothane metabolism yields the stable metabolites trifluoroacetic acid and bromide which can be detected in plasma and urine. To date, analytical methodologies have either required extensive sample preparation, or two separate analytical procedures to determine plasma and urine concentrations of these analytes. A rapid and sensitive method utilizing high-performance liquid chromatography-ion chromatography (HPLC-IC) with suppressed conductivity detection was developed for the simultaneous detection of both trifluoroacetic acid and bromide in plasma and urine. Sample preparation required only ultrafiltration. Standard curves were linear (r²≥0.99) from 10 to 250 μM trifluoroacetic acid and 2 to 5000 μM bromide in plasma and 10 to 250 μM trifluoroacetic acid and 2 to 50 μM bromide in urine. The assay was applied to quantification of trifluoroacetic acid and bromide in plasma and urine of a patient undergoing halothane anesthesia.     

碘的安全摄入量范围研究进展

动物实验表明,短期或长期高碘摄入会对机体产生一定的毒性,包括发育毒性、遗传毒性和致畸性等。目前世界各国家及组织对于碘的推荐摄入量（reference nutrition intake,RNI）和可耐受最高摄入量（tolerable upper intake level,UL）的制定一般是基于一些的人体实验研究和人群调查,但由于地理环境及人种差异等原因,所得数据并不统一。由于参照的研究数据不同,各国对不同人群设定的碘安全摄入量参照标准也不尽相同。鉴于此,分析了国际上主要的国家及国际组织制订标准的过程与依据,概述了我国相关标准的制订过程与依据以及El前的研究进展,明确了进一步探讨和研究更适合我国人群的碘的安全摄入量是当前和今后的工作重点之一,也是食盐加碘计划（universal salt iodization,USI）科学实施的重要保障。     

Effect of chronic administration of phenytoin on regional monoamine levels in rat brain

Phenytoin (DPH) is a widely used anticonvulsant drug but a conclusive mode of action is not yet clear. This study was undertaken to assess the effects of chronic administration of DPH on monoamine levels. DPH (50 mg/kg body weight) was administered to adult male Wistar rats by intraperitoneal injections for 45 days and the regional brain levels of norepinephrine (NE), dopamine (DA) and serotonin (5-HT) were assayed using high performance liquid chromatographic (HPLC) method. The experimental rats revealed no behavioral deficits of any kind nor body and brain weight deficits were observed. Increased NE levels were observed after DPH administration in motor cortex (P<0.05), striatum-accumbens (P<0.01) and hippocampus (P<0.01), whereas, NE level was decreased in brain stem (P<0.05). DA levels were increased in striatum-accumbens (P<0.05), hypothalamus (P<0.001) and cerebellum (P<0.001) but decreased in brainstem (P<0.01). In DPH treated rats, 5-HT levels were increased in motor cortex (P<0.001) but decreased in cerebellum (P<0.001) when compared to control group of rats. The present study suggest that chronic administration of DPH induces alterations in monoamine levels in specific brain regions. DPH seems to mediate, its anticonvulsant action by selectively altering the monoamine levels in different brain regions.     

Effect of dietary iodine on thyroid hormones and energy blood metabolites in lactating goats

Aim of this work was to evaluate if long-term dietary supplementation of potassium iodide (KI) to dairy goats can influence metabolic and hormonal parameters. Thirty Sarda crossbred dairy goats were divided into three groups, which were orally administered 0 (control group; CON), 0.45 (low iodine group; LI) or 0.90 (high iodine group; HI) mg of KI/day, respectively. The daily dose of KI (76.5% of iodine) was administered as salt dissolved in water for 8 weeks. Plasma contents of nonesterified fatty acids (NEFA), urea, glucose, insulin, free triiodothyronine (FT₃) and thyroxine (FT₄) were determined weekly. Iodine supplementation increased significantly the FT₃ hormone (P = 0.007) and FT₃/FT₄ ratio (P = 0.001) and tended to influence the FT₄ hormone (P = 0.059). An iodine level × week of sampling interaction for NEFA (P = 0.013) evidenced a temporary concentration increase in supplemented groups. The ‘Revised Quantitative Insulin Sensitivity Check Index’ increased with KI supplementation (P ⩽ 0.01). Blood urea nitrogen (BUN) and insulin were lowered (P ⩽ 0.01) by iodine supplementation (groups LI and HI; P ⩽ 0.01). The glucose concentration evidenced an iodine level × week of sampling interaction (P = 0.025) due to an unexpected and temporary increase of its concentration in the CON group. Glucose concentration was decreased by KI supplementation only in LI group (P < 0.05). In conclusion, the daily supplementation of low doses of KI can improve insulin sensitivity and decrease BUN in dairy goats.     

Effect of long-term injection of high doses of potassium iodide on iodine metabolism in rat thyroid gland

Concentration of thyroid hormones in the serum of the rats after 14-day injections of potassium iodide (1, 3, 10, 100, and 500 physiological daily doses) did not differ from the control values. Excessive administration of potassium iodide increased the total iodide content in the rat thyroid tissue by 60–121% (35–108% and 94–128% for the protein-bound and free iodide, respectively), indicating the activation of the uptake and organification of iodide. The long-term injection of both low and high doses of potassium iodide increased the activity of catalase by 8–18% and SOD by 33–50% and enhanced the level of toxic LPO products reacting with thiobarbituric acid by 15–38%. It is suggested that reactive oxygen species and the excessive iodination of proteins (particularly thyroglobulin) induced by the long-term administration of high doses of potassium iodide can play an important role in the development of thyroid dysfunctions and autoimmune diseases.