亚硒酸钠诱导SW480细胞凋亡过程中活性氧的作用

为探讨亚硒酸钠诱导人结肠癌SW480细胞凋亡的机理,将荧光探针2′,7′－二氯荧光黄乙二脂（2′,7′－DCFH－DA）、罗丹明123（rhodamine123）负载人结肠癌细胞,利用多光子成像系统测定胞内活性氧（ROS）、线粒体跨膜电位（△Ψm）的变化。结果发现（1）Na2SeO3作用SW480细胞,可导致细胞凋亡和胞内的ROS增加。SOD、过氧化氢酶可降低凋亡率并抑制ROS的增加。（2）线粒体电子传递链抑制剂鲁藤酮及氰化钠可抑制OS增加。（3）Na2SeO3可导致线粒体的跨膜电位的下降。表明Na2SeO3作用细胞可导致来源于线粒体的ROS增加,ROS介导亚硒酸钠诱导细胞凋亡。     

硒对AOM所致结肠癌模型大鼠肾上腺皮质束状带细胞组织化学的影响

目的观察硒对致癌剂氧化偶氮甲烷(azoxymethane,AOM)所致结肠癌模型大鼠肾上腺皮质束状带细胞组织化学的变化。方法随机将20只3周龄SPF级断乳雄性Sprague Dawley(SD)大鼠随机分4组:正常对照组、实验对照组、致癌剂前补硒组和致癌剂后补硒组。用AOM(15mg/kg)每周腹腔注射,连续2周,诱导大鼠结肠癌的形成。亚硒酸钠(Na2SeO3)水溶液(4mg/L)分别在AOM前、后干预,并持续至实验结束。各组均于34周取大鼠肾上腺,用组织化学的方法,观察大鼠肾上腺皮质束状带细胞组织化学的变化,对脂类、琥珀酸脱氢酶(SDH)和3β-羟类固醇脱氢酶(3β-HSD)进行染色,并图像分析。结果亚甲基蓝染色光镜下观察,可见AOM腹腔注射的大鼠结肠黏膜出现异常隐窝(aberrant crypt,AC)和异常隐窝灶(aberrant crypt foci,ACF)。组织化学显示,与正常对照组相比,实验对照组大鼠肾上腺皮质束状带细胞的SDH和3β-HSD的MOD值明显增加(P<0.05),脂类的MOD值明显减少(P<0.05);硒干预的各组与实验对照组相比,大鼠肾上腺皮质束状带细胞的SDH和3β-HSD的M...     

亚硒酸钠对糖尿病肾病大鼠肾脏Nephrin表达的影响与意义

探讨亚硒酸钠对糖尿病肾病大鼠肾脏Nephrin表达的影响及二者间的关系,从而研究亚硒酸钠和Nephrin在糖尿病肾病中的作用机制.通过链脲佐菌素法及给予高脂饮食诱导模拟大鼠糖尿病肾病模型,实验设空白对照组、糖尿病肾病对照组、亚硒酸钠干预组,亚硒酸钠干预组每日给予亚硒酸钠溶液灌胃,其它组给予等量生理盐水灌胃.灌胃10周后处死大鼠,取血、尿标本测相关生化指标.取肾脏组织戊二醛固定制作切片电镜下观察超微结构改变,取肾脏组织多聚甲醛固定制石蜡切片光镜下观察病理改变和免疫组化定位蛋白表达.取肾脏组织RT-PCR检测Nephrin的mRNA表达、Western Blotting检测nephrin的蛋白表达,分析各组数据的统计差异.结果发现亚硒酸钠干预组大鼠基本状况和生化指标较糖尿病肾病对照组明显改善,光镜和电镜下观察病理改变和超微结构病变较糖尿病肾病对照组明显减轻.免疫组化nephrin蛋白表达着色糖尿病肾病对照组较空白对照组减少,亚硒酸钠干预组较糖尿病肾病对照组着色明显增多.Nephrin mRNA和蛋白表达糖尿病肾病对照组较空白对照组明显降低,而亚硒酸钠干预组较糖尿病肾病对照组升高,但低于空白对照组,差异均有统计学意义（P〈0．05）．亚硒酸钠明显促进肾脏Nephrin表达,改善了糖尿病肾病,表明亚硒酸钠和Nephrin在防治和延缓糖尿病肾病的发生发展中可能起重要作用．     

硒性白内障大鼠模型晶状体中GR和GSH-Px的表达

 为探讨硒性白内障大鼠晶状体中谷胱甘肽过氧化物酶 (GSH Px)和谷胱甘肽还原酶 (GR)的活性调节在硒性白内障形成中的作用及调节方式 ,采用半定量RT PCR方法 ,比较正常晶状体、核中心混浊晶状体 (核白 )和完全混浊晶状体 (全白 )中GSH Px和GR的mRNA水平及酶活性的变化 .研究发现 ,核白晶状体中 2种酶的活性和mRNA水平均升高 ,其中酶活性的升高幅度小于mRNA水平 .随着白内障的发展 ,2种酶的活性和mRNA水平均逐渐下降 .至晶状体全白时 ,2种酶的活性均显著低于正常 ;全白时GR的mRNA水平降至正常 ,GSH Px的mRNA水平则仍高于正常 .结果表明 ,硒性白内障形成与细胞内GSH Px和GR的活性调节密切相关 ,GSH Px和GR的活性调节可能主要发生在转录水平     

Transport measurements across Caco-2 monolayers of different organic and inorganic selenium

The transport and uptake of the most common Se compounds, selenate (SeO ₄ ²⁻ ), selenite (SeO ₃ ²⁻ ), selenomethionine, and selenocystine, were investigated using confluent monolayers of Caco-2 cells, a human carcinoma cell line. Comparative measurements were performed in the absorptive (apical to basolateral side) and exsorptive (basolateral to apical side) directions. Apparent permeability coefficients (P _app), calculated from transport experiments in the absorptive direction, showed increasing values in the following rank order: about 1×10⁻⁶ cm/s ≤ mannitol ≤ SeO ₃ ²⁻ ≤ selenocystine < selenomethionine < SeO ₄ ²⁻ ≤ about 16×10⁻⁶ cm/s. The ratios of the P _app measured in the absorptive versus exsorptive directions indicated that only the organic forms presented a net polarized transport (P _app ratio ≫1), suggesting the presence of a transcellular pathway. No significant excretion was observed. The transport of selenomethionine was inhibited by its sulfur analog, methionine, suggesting a common transport mechanism. In contrast, an inhibition of the transport of selenocystine by cysteine was not observed. From the two substrates tested, sulfate and thiosulfate, only thiosulfate inhibited the transport of SeO ₄ ²⁻ . This effect was also observed for SeO ₃ ²⁻ (i.e., was unspecific), which questioned the assertion of a common transport for sulfate and SeO ₄ ²⁻ and may confirm the paracellular pathway of SeO ₄ ²⁻ suggested by the P _app ratio of about 1. The addition of glutathione (GSH) in large excess had no consequence on the passage of SeO ₃ ²⁻ but strongly increased the uptake (about fourfold). The liquid chromatography — mass spectrometry (LC-MS) data showed that, in the ionic condition of incubation medium, GSH promptly reduced SeO ₃ ²⁻ (≤2 min) in its elemental form Se⁰, which cannot ascribe to selenodiglutathione a direct role in the effect of GSH.     

Selenite or selenomethionine interaction with methylmercury on uptake and toxicity showing a weak selenite protection: studies on cultured K-562 cells

Selenium and methylmercuric chloride (MMC) interactions regarding cellular uptake and selenium protection on MMC toxicity have been studied. Human K-562 cells were pretreated or simultaneously treated with either selenite (5 or 50 μM) or selenomethionine (10 or 50 μM) together with (3.5 or 5 μM) MMC. Cells simultaneously treated with selenite or selenomethionine and 3.5 μM MMC showed a decreased mercury concentration with increased selenium dose especially seen in the selenite combinations. The simultaneous selenite and MMC 3.5 μM combinations showed growth curves with an increasing number of viable cells with increased selenite dose. All combinations with 5 μM MMC were toxic to the cells. Interactions between selenite or selenomethionine and MMC regarding cellular uptake of mercury and selenium were observed and indications of selenite protection against MMC toxicity in human K-562 cells were noticed.     

Uptake and transport of selenite and selenate by soybean seedlings of two genotypes

In an attempt to address the role of biological behavior on Se uptake by soybean crop and the genotype effects, experiments with time and concentration sequences of Se uptake by seedlings in Hoagland solution are conducted using selenite and selenate respectively. Two soybean cultivars Tong-ai 405 (TA) and Qidong Green-skin (QG) are used as different genotypes. In presence of selenite, Se uptake by both roots and shoots exhibited a linear increase with the growing time at 5 M and with the solution Se concentrations. However, in presence of selenate, the linear response to growing time is only valid before 24 h of growing. While root Se uptake is much slower under selenate than under selenite in the time sequence experiment, shoot Se levels are similar between the two different Se form treatments. Nevertheless, in the experiment of concentration sequence, either root Se or shoot Se responses linearly to solution Se concentration regardless of the Se forms supplied. A big discrepancy of root Se level with a similarity of shoot Se between the two cultivars is observed in the concentration sequence experiment. This supports a much faster passive uptake of selenite but more or less an active uptake of selenate by soybean seedlings. Comparatively, cultivars TA have a consistently higher Se concentration than QG both in roots and shoots under selenate, while no difference of concentration ratio of shoot to root is recognized between them. The higher Se level in seed grains, therefore, may be accounted for not by Se transport form root to shoot but by greater ability of Se uptake and retention under selenate by the former cultivar. Therefore, not only forms of Se supply but also genotype difference affects the Se bioavailability by different soybean cultivars. This should be taken into account for screening the high Se-efficiency plants or cultivars to improve the Se supply of the food chain.     

Sulphydryl groups involved in Na+-Li+ exchange in human erythrocytes

Oxidative stress causes cellular injury that is thought to be due to increased cytosolic cation levels. Disturbances of a variety of mechanisms which normally maintain intracellular anion/cation homeostasis, occur during oxidative stress. Reactivity of the SH- groups essential for oubain-resistant Na(+)-Li(+) exchange by N-ethylmaleimide (NEM) and selenite was studied in human erythrocytes. In addition, the reactivity of the substances on SH- groups and Li(+) influx have been studied as a function of pH of the medium. The results show that NEM induces an irreversible inhibition of Li(+) influx. It diminishes progressively with the increasing pH of the medium. Whereas we obtain increasing intracellular Li(+) concentration with the rising selenite concentration in the medium. The maximum effect with this substance is reached at about pH 8.0. We can state that the -SH reagents (NEM and selenite) studied behave differently: NEM inhibits Li(+) influx by modifying the essential SH-groups of the membrane proteins in such a way that the exchange is reduced, whereas it maintains the Na(+) permeability almost unaltered. The slight increase in intracellular Na(+) induced by selenite suggests that the oxidative changes in the intracellular sulphydryl groups may constitute an important mechanism for the regulation of the intracellular cations.     

Reduction of chromate,selenite, tellurite,and iron (III) by the moderately thermophilic bacterium <Emphasis Type="Italic">Bacillus thermoamylovorans</Emphasis> SKC1

A moderately thermophilic, facultatively anaerobic bacterium capable of reducing Cr(VI) (strain SKC1) was isolated from municipal sewage. Based on the analysis of the 16S rRNA gene nucleotide sequence and DNA-DNA hybridization data, strain SKC1 was identified as a representative of the species Bacillus thermoamylovorans. B. thermoamylovorans SKC1 is capable of reducing chromate with L-arabinose as an electron donor with an optimum at 50°C and neutral pH. The culture is able to reduce Cr(VI) at its initial concentration in the medium of up to 150 mg/l. In addition to chromate, strain SKC1 is capable of reducing selenite and tellurite, as well as soluble forms of Fe(III). It was shown that Cr(VI), Te(IV), and Se(IV) exert a bacteriostatic effect on strain SKC1, and the reduction of these anions performs the detoxification function. This is the first communication on the reduction of chromate, selenite, tellurite, and soluble Fe(III) species by a culture of thermophilic bacilli.     

Inhibition of Anaplerotic Glutaminolysis Underlies Selenite Toxicity in Human Lung Cancer

Large clinical trials and model systems studies suggest that the chemical form of selenium dictates chemopreventive and chemotherapeutic efficacy. Selenite induces excess ROS production, which mediates autophagy and eventual cell death in non‐small cell lung cancer adenocarcinoma A549 cells. As the mechanisms underlying these phenotypic effects are unclear, the clinical relevance of selenite for cancer therapy remains to be determined. The authors' previous stable isotope‐resolved metabolomics and gene expression analysis showed that selenite disrupts glycolysis, the Krebs cycle, and polyamine metabolism in A549 cells, potentially through perturbed glutaminolysis, a vital anaplerotic process for proliferation of many cancer cells. Herein, the role of the glutaminolytic enzyme glutaminase 1 (GLS1) in selenite's toxicity in A549 cells and in patient‐derived lung cancer tissues is investigated. Using [¹³C₆]‐glucose and [¹³C₅,¹⁵N₂]‐glutamine tracers, selenite's action on metabolic networks is determined. Selenite inhibits glutaminolysis and glutathione synthesis by suppressing GLS1 expression, and blocks the Krebs cycle, but transiently activates pyruvate carboxylase activity. Glutamate supplementation partially rescues these anti‐proliferative and oxidative stress activities. Similar metabolic perturbations and necrosis are observed in selenite‐treated human patients' cancerous lung tissues ex vivo. The results support the hypothesis that GLS1 suppression mediates part of the anti‐cancer activity of selenite both in vitro and ex vivo.