低硒心肌损伤与钾离子通道蛋白的关系研究

目的:心肌上的离子通道蛋白与心肌损伤有很大的关系,本研究通过低硒喂养对C57BL/6小鼠心肌组织损伤的影响及其对钾通道蛋白的改变。方法:将实验小鼠分为4组:对照组,低硒30天组,低硒90天组和低硒180天组。采用低硒饲料(硒含量0.0045μg/g)喂养的方法建立低硒小鼠模型,对照组给予正常饲料(硒含量0.256μg/g),与低硒组同时喂养;硒含量的测定和HE染色方法观察心肌损伤情况,Western Blotting方法检测其钾通道蛋白的表达。结果:低硒饲料喂养小鼠的心脏硒含量与正常饲料喂养的硒含量相比明显降低(P0.01);并出现轻微的心肌损伤,钾通道蛋白的表达量在低硒30天组,低硒90天组和低硒180天组下调(P0.01)。结论:成功建立低硒小鼠模型,低硒能引起小鼠心肌损伤,这种改变可能有心脏的钾通道蛋白的表达水平有关。     

低硒心肌损伤与钾离子通道蛋白的关系研究

目的：心肌上的离子通道蛋白与心肌损伤有很大的关系,本研究通过低硒喂养对C57BL／6小鼠心肌组织损伤的影响及其对钾通道蛋白的改变。方法：将实验小鼠分为4组：对照组,低硒30天组,低硒90天组和低硒180天组。采用低硒饲料（硒含量0．0045μg／g）喂养的方法建立低硒小鼠模型,对照组给予正常饲料（硒含量0．256μg/g）,与低硒组同时喂养;硒含量的测定和HE染色方法观察心肌损伤情况,WesternBlotting方法检测其钾通道蛋白的表达。结果：低硒饲料喂养小鼠的心脏硒含量与正常饲料喂养的硒含量相比明显降低（P〈0．01）;并出现轻微的心肌损伤,钾通道蛋白的表达量在低硒30天组,低硒90天组和低硒180天组下调（P〈0．01）。结论：成功建立低硒小鼠模型,低硒能引起小鼠心肌损伤,这种改变可能有心脏的钾通道蛋白的表达水平有关。     

硒的抗自由基损伤作用

用黄嘌呤-黄嘌呤氧化酶体系或低硒饲料诱发自由基损伤。在培养的鼠心肌细胞上,硒能使受损心肌细胞的自由基含量、超微结构、动作电位、膜输入阻抗恢复正常;在离体灌流的鼠心上,硒能改善受损心脏的心肌收缩性能;硒能使受损鼠的心硒含量与肝谷胱甘肽过氧化物酶(GSH_(ps))活力回升、肝过氧化脂质(LPO)含量下降。上述结果提示硒保护作用的基本机制可能与增强GSH_(px)活力、促进自由基清除有关。     

大黄鱼幼鱼对饲料硒的需求量

为确定大黄鱼(Larimichthys croceus)对饲料硒的需求量, 以Na2SeO3为饲料硒源, 配制6种饲料, 硒的添加水平分别为0(对照组)、0.05、0.2、0.4、0.6和0.9 mg/kg, 实测值分别为0.08、0.16、0.27、0.44、0.66和0.96 mg/kg。在海水浮式网箱中养殖初始体重为(9.140.09) g的大黄鱼幼鱼10周, 结果表明增重率(WG)、全鱼和骨骼中的硒含量随着饲料硒含量的升高而显著升高(P0.05)。当饲料硒含量分别超过0.27、0.66、0.66 mg/kg时, 这些指标的变化趋于平稳。饲料硒含量对存活率(SR)、饲料效率(FE)、体组成、肝体比(HSI)、脏体比(VSI)和肥满度(CF)都没有显著影响(P0.05)。在血清中谷胱甘肽过氧化物酶(GPX)活性、超氧化物歧化酶(SOD)活性和总抗氧化力(T-AOC)随着饲料硒含量的升高呈现先升高后稳定的趋势(P0.05), 并分别在饲料硒含量为0.44、0.44、0.16 mg/kg时达到最大值。肝脏中GPX活性、SOD活性、T-AOC、过氧化氢酶(CAT)活性和谷胱甘肽还原酶(GR)活性与血清中相应酶的活性有相同的趋势。在肝脏中谷胱甘肽硫转移酶(GST)活性随着饲料硒含量的升高呈现先降低后升高的趋势(P0.05), 并在饲料硒含量最高(0.96 mg/kg)时其活力取得最大值。以WG为评价指标, 得出大黄鱼幼鱼对饲料中硒的需求量为0.178 mg/kg。以全鱼和骨骼中硒含量、肝脏GPX活性为评价指标, 得出大黄鱼幼鱼对饲料中硒的最小需求量分别为0.575、0.387和0.440 mg/kg。       

黄粉虫幼虫对硒的生物积累

在饲料中添加含硒化合物喂养黄粉虫Tenebrio molitor L.幼虫,测定幼虫硒含量、粪便硒含量和体重的变化,计算黄粉虫幼虫特定生长率及幼虫对硒生物积累系数,分析黄粉虫有效积累硒的条件。结果表明,饲料硒含量在15~20mg/kg时,幼虫硒含量明显提高,对硒的生物积累系数高于其它试验组水平,饲料硒含量过高,幼虫硒含量降低,正常生长受到抑制。黄粉虫幼虫特定生长率、取食量、排粪量、干物质含量随着饲料硒含量的增加而降低,死亡率、粪便硒含量随着饲料硒含量的增加而增大。饲料硒含量为15～20mg/kg时黄粉虫幼虫对硒的生物积累效果最好。     

硒对小鼠柯萨奇性病毒性心肌炎脂质过氧化反应的影响

目的：探讨硒对小鼠病毒性心肌炎发生中脂质过氧化反应的影响。方法：昆明种小鼠分为常规饲料喂养和适量补硒喂养4周后,腹腔接种柯萨奇B3病毒建立小鼠心肌炎模型,测定小鼠谷胱甘肽过氧化物酶（GSH-Px）、超氧化物歧化酶（SOD）、丙二醛（MDA）含量及心肌病变情况。结果：光镜下补硒组小鼠的心肌病理变化轻,其病理积分明显低于常规喂养组（P〈0.05）。补硒组小鼠GSH-Px、SOD明显高于正常喂养组;MDA明显低于常规喂养组（P〈0.05）。结论：补硒能提高脂质过氧化酶的活性、减少脂质过氧化产物的产生,减轻病毒感染引起的心肌细胞损伤。     

亚硒酸钠、酵母硒和富硒螺旋藻对杂交鲟幼鱼生长、抗氧化能力及组织硒含量的影响

实验旨在研究饲料中不同类型和水平的硒源对杂交鲟(Acipenser baerii♂×Acipenser schrenckii♀)幼鱼生长、抗氧化能力及组织硒含量的影响。不同类型的硒源为亚硒酸钠、酵母硒和富硒螺旋藻,添加水平为0、0.4和1.2 mg/kg,制作对照饲料(C)、亚硒酸钠添加饲料(S1和S2)、酵母硒添加饲料(Y1和Y2)和富硒螺旋藻添加饲料(P1和P2)。使用实验饲料饲喂初始体重为(7.82±0.12) g的杂交鲟幼鱼,养殖62d。结果表明,不同硒源和硒水平对杂交鲟幼鱼的特定生长率和饲料效率无显著影响(P>0.05)。高水平亚硒酸钠显著提高了全鱼和肝脏硒含量(P<0.05),但对肌肉和脊椎骨硒含量无显著影响(P>0.05)。高水平酵母硒和富硒藻螺旋添加组杂交鲟幼鱼的全鱼、肝脏、肌肉及脊椎骨硒含量均显著高于对照组(P<0.05)。酵母硒添加组的血浆总蛋白(TP)和总胆固醇(TC)含量均显著高于对照组(P<0.05)。同时,高水平硒添加组杂交鲟幼鱼的血浆谷胱甘肽过氧化物酶(GSH-Px)活性显著高于对照组和低水平硒添加组(P<0.05)。亚...     

低硒对大鼠心电图的影响及补硒后的变化

目的:探讨低硒对大鼠心电图的影响及补硒后心电图的变化。方法:将30只SD大鼠随机分为对照组、低硒组及补硒组,每组各10只,对照组喂养标准饲料,低硒组喂养低硒饲料,补硒组喂养低硒饲料14周后再给予亚硒酸钠补硒3周,各组喂养17周后,检测大鼠的血硒、血清谷胱甘肽过氧化物酶及心电图的变化。结果:低硒组大鼠血硒水平和血清谷胱甘肽过氧化物酶水平与对照组相比明显降低(P0.05),补硒后两者又明显增加(P0.05)。正常对照组大鼠心电图大部分正常,低硒组大鼠心电图多数为异常心电图,主要表现为室性早搏、室性心动过速、交界性房性早搏、T波低平等,补硒组大鼠心电图大部分恢复正常心电图,仅有少部分表现为异常心电图。结论:低硒可导致大鼠谷胱甘肽过氧化物酶活性减低,低硒饮食后,大鼠心电图明显发生异常,多表现为室性心律失常,补硒可使低硒所致的心电图变化多数恢复正常。     

硒对甲型H1N1流感病毒感染小鼠的保护作用

目的:通过研究硒对流感病毒悬液滴鼻处理的小鼠的体重变化、死亡率、血清硒水平和细胞因子的影响,探讨硒对感染流感病毒小鼠的保护作用。方法:将60只昆明小鼠分为5组,每组12只,分别为缺硒组(0 mg/kg)、正常给硒组(0.2 mg/kg)、补充硒组(0.3 mg/kg)、补充硒组(0.4 mg/kg)、补充硒组(0.5 mg/kg)。给5周龄的小鼠滴鼻接种50μL的A/NWS/33(H1N1)病毒悬液并观察21天,监测每组小鼠的体重变化和死亡率;并在接种病毒后的第3天、第5天,检测小鼠的血清硒、TNF-α和IFN-γ水平。结果:缺硒组小鼠的死亡率高于正常给硒组和补充硒组(P0.05);缺硒组小鼠的血清硒水平明显低于正常给硒组和补充硒组(P0.05);在病毒感染第5天,缺硒组小鼠的TNF-α和IFN-γ含量低于正常给硒组和补充硒组(P0.05),差异均有统计学意义。结论:硒可以提高机体对抗流感病毒的免疫反应。     

富硒壶瓶碎米荠对青鱼幼鱼生长、生理生化、硒代谢、抗氧化及先天免疫的影响

为探究富硒壶瓶碎米荠(Cardamine hupingshanensis)对青鱼(Mylopharyngodon piceus)幼鱼生长、血清生理生化、肝脏硒代谢、抗氧化能力和先天免疫指标的影响,选取360尾初始体重为(5.51±0.02) g的青鱼幼鱼随机分配至4个实验组中,每组3个重复。在基础饲料中添加富硒壶瓶碎米荠的量为0、0.5、1.0和2.0 g/kg(硒的实际含量分别为0.04、0.43、0.75和1.57 mg/kg),同时添加矿物质混合物(无硒添加)和维生素混合物,配置成4种等氮等能的青鱼幼鱼试验饲料,养殖周期为60d。结果显示:饲料中添加0.5和1.0 g/kg富硒壶瓶碎米荠时,鱼体增重率(WG),特定生长率(SGR)较对照组和过量组(2.0 g/kg)显著升高,饲料系数(FCR)显著降低(P<0.05)。当饲料中富硒壶瓶碎米荠添加量为0.5—1.0 g/kg时,血清中的甘油三酯(TG)、总胆固醇(TCH)和白蛋白(ALB)含量呈上升趋势,而葡萄糖(GLU)含量显著下降(P<0.05)。饲料中添加0.5—1.0 g/kg富硒壶瓶碎米荠时可显著提高肝脏核因子...     

Long-term Selenium Deficiency Increases the Pathogenicity of a Citrobacter rodentium Infection in Mice

Citrobacter rodentium is a mouse pathogen that causes infectious colitis and shares characteristics with human enteropathogenic (EPEC) and enterohemorrhagic (EHEC) Escherichia coli, including the ability to cause attaching and effacing lesions in the colon and serves as a useful model to study the pathogenicity of these bacteria. In this study, mice were fed a selenium-deficient diet for 5 or 20?weeks and then infected with C. rodentium. Colonization of the colon by C. rodentium was similar in mice fed adequate or selenium-deficient diets, but total bacterial colonization of the spleen was elevated in mice fed selenium-deficient diet for 20?weeks. Infection-induced changes to the colon included inflammatory cell infiltration, gross changes in crypt architecture, and ulceration and denuding of the epithelial layer that were greatest in mice fed a selenium-deficient diet for 20?weeks. Expression of pro-inflammatory genes was significantly higher 12-days post-infection in mice fed the selenium-deficient diet for 20?weeks compared to mice fed a selenium-adequate diet or selenium-deficient diet for 5?weeks. Diarrhea was prevalent in mice fed the selenium-deficient diet for 20?weeks but not 5?weeks, and this was associated with decreased expression of solute carrier family 26a3 and carbonic anhydrase IV, genes involved in ion transport. These results indicated that selenium played an important role in resistance to the pathological effects of a C. rodentium infection, and therefore, selenium status may be important in the expression of human disease caused by common food-borne bacteria.     

Deletion of selenoprotein P alters distribution of selenium in the mouse

Selenoprotein P (Se-P) contains most of the selenium in plasma. Its function is not known. Mice with the Se-P gene deleted (Sepp(-/-)) were generated. Two phenotypes were observed: 1) Sepp(-/-) mice lost weight and developed poor motor coordination when fed diets with selenium below 0.1 mg/kg, and 2) male Sepp(-/-) mice had sharply reduced fertility. Weanling male Sepp(+/+), Sepp(+/-), and Sepp(-/-) mice were fed diets for 8 weeks containing <0.02-2 mg selenium/kg. Sepp(+/+) and Sepp(+/-) mice had similar selenium concentrations in all tissues except plasma where a gene-dose effect on Se-P was observed. Liver selenium was unaffected by Se-P deletion except that it increased when dietary selenium was below 0.1 mg/kg. Selenium in other tissues exhibited a continuum of responses to Se-P deletion. Testis selenium was depressed to 19% in mice fed an 0.1 mg selenium/kg diet and did not rise to Sepp(+/+) levels even with a dietary selenium of 2 mg/kg. Brain selenium was depressed to 43%, but feeding 2 mg selenium/kg diet raised it to Sepp(+/+) levels. Kidney was depressed to 76% and reached Sepp(+/+) levels on an 0.25 mg selenium/kg diet. Heart selenium was not affected. These results suggest that the Sepp(-/-) phenotypes were caused by low selenium in testis and brain. They strongly suggest that Se-P from liver provides selenium to several tissues, especially testis and brain. Further, they indicate that transport forms of selenium other than Se-P exist because selenium levels of all tissues except testis responded to increases of dietary selenium in Sepp(-/-) mice.     

Nutritional and supranutritional levels of selenate differentially suppress prostate tumor growth in adult but not young nude mice

The inhibitory effect of oral methylseleninic acid or methylselenocysteine administration on cancer cell xenograft development in nude mice is well characterized; however, less is known about the efficacy of selenate and age on selenium chemoprevention. In this study, we tested whether selenate and duration on diets would regulate prostate cancer xenograft in nude mice. Thirty-nine homozygous NU/J nude mice were fed a selenium-deficient, Torula yeast basal diet alone (Se-) or supplemented with 0.15 (Se) or 1.0 (Se+) mg selenium/kg (as Na(2)SeO(4)) for 6 months in Experiment 1 and for 4 weeks in Experiment 2, followed by a 47-day PC-3 prostate cancer cell xenograft on the designated diet. In Experiment 1, the Se- diet enhanced the initial tumor development on days 11-17, whereas the Se+ diet suppressed tumor growth on days 35-47 in adult nude mice. Tumors grown in Se- mice were loosely packed and showed increased necrosis and inflammation as compared to those in Se and Se+ mice. In Experiment 2, dietary selenium did not affect tumor development or histopathology throughout the time course. In both experiments, postmortem plasma selenium concentrations in Se and Se+ mice were comparable and were twofold greater than those in Se- mice. Taken together, dietary selenate at nutritional and supranutritional levels differentially inhibit tumor development in adult, but not young, nude mice engrafted with PC-3 prostate cancer cells.     

Modulation of β-amyloid precursor protein trafficking and processing by the low density lipoprotein receptor family

Selenium is an essential micronutrient that function through selenoproteins. Selenium deficiency results in lower concentrations of selenium and selenoproteins. The brain maintains it's selenium better than other tissues under low-selenium conditions. Recently, the selenium-containing protein selenoprotein P (Sepp) has been identified as a possible transporter of selenium. The targeted disruption of the selenoprotein P gene (Sepp1) results in decreased brain selenium concentration and neurological dysfunction, unless selenium intake is excessive However, the effect of selenoprotein P deficiency on the processes of memory formation and synaptic plasticity is unknown. In the present studies Sepp1(-/-) mice and wild type littermate controls (Sepp1(+/+)) fed a high-selenium diet (1 mg Se/kg) were used to characterize activity, motor coordination, and anxiety as well as hippocampus-dependent learning and memory. Normal associative learning, but disrupted spatial learning was observed in Sepp1(-/-) mice. In addition, severe alterations were observed in synaptic transmission, short-term plasticity and long-term potentiation in hippocampus area CA1 synapses of Sepp1(-/-) mice on a 1 mg Se/kg diet and Sepp1(+/+) mice fed a selenium-deficient (0 mg Se/kg) diet. Taken together, these data suggest that selenoprotein P is required for normal synaptic function, either through presence of the protein or delivery of required selenium to the CNS.     

The effects of selenium depletion and repletion on the metabolism of thyroid hormones in the rat

Rats were fed selenium-deficient (less than 0.005 mg selenium/kg) or selenium-supplemented diets (0.1 mg selenium/kg, as Na2SeO2) for up to five wks from weaning to assess the effects of developing selenium deficiency on the metabolism of thyroid hormones. Within two wks 3:5,3'-triiodothyronine (T3) production from thyroxine (T4) in liver homogenates from selenium-deficient rats was significantly lower compared with the activity in liver homogenates from selenium-supplemented rats. This decreased activity was probably responsible, in part, for the higher T4 and lower T3 concentrations in plasma from the selenium-deficient rats after 3, 4, and 5 weeks of experiment. Repletion of selenium-deficient rats with single intra-peritoneal injections of 200 micrograms selenium/kg body wt. (as Na2SeO3) 5 days before sampling reversed the effects of the deficiency on thyroid hormone metabolism and significantly increased liver and plasma glutathione peroxidase activities. However a dose of 10 micrograms selenium/kg body wt given to rats of similar low selenium status had no effect on thyroid hormone metabolism or glutathione peroxidase activity but did reverse the increase in hepatic glutathione S-transferase activity characteristic of severe selenium deficiency. Imbalances in thyroid hormone metabolism are an early consequence of selenium deficiency and are probably not related to changes in hepatic xenobiotic metabolizing enzymes associated with severe deficiency.     

Selenoprotein P Is the Major Selenium Transport Protein in Mouse Milk

Selenium is transferred from the mouse dam to its neonate via milk. Milk contains selenium in selenoprotein form as selenoprotein P (Sepp1) and glutathione peroxidase-3 (Gpx3) as well as in non-specific protein form as selenomethionine. Selenium is also present in milk in uncharacterized small-molecule form. We eliminated selenomethionine from the mice in these experiments by feeding a diet that contained sodium selenite as the source of selenium. Selenium-replete dams with deletion of Sepp1 or Gpx3 were studied to assess the effects of these genes on selenium transfer to the neonate. Sepp1 knockout caused a drop in milk selenium to 27% of the value in wild-type milk and a drop in selenium acquisition by the neonates to 35%. In addition to decreasing milk selenium by eliminating Sepp1, deletion of Sepp1 causes a decline in whole-body selenium, which likely also contributes to the decreased transfer of selenium to the neonate. Deletion of Gpx3 did not decrease milk selenium content or neonate selenium acquisition by measurable amounts. Thus, when the dam is fed selenium-adequate diet (0.25 mg selenium/kg diet), milk Sepp1 transfers a large amount of selenium to neonates but the transfer of selenium by Gpx3 is below detection by our methods.     

Gene expression profiling reveals differential effects of sodium selenite, selenomethionine, and yeast-derived selenium in the mouse

The essential trace mineral selenium is an important determinant of oxidative stress susceptibility, with several studies showing an inverse relationship between selenium intake and cancer. Because different chemical forms of selenium have been reported to have varying bioactivity, there is a need for nutrigenomic studies that can comprehensively assess whether there are divergent effects at the molecular level. We examined the gene expression profiles associated with selenomethionine (SM), sodium selenite (SS), and yeast-derived selenium (YS) in the intestine, gastrocnemius, cerebral cortex, and liver of mice. Weanling mice were fed either a selenium-deficient (SD) diet (<0.01 mg/kg diet) or a diet supplemented with one of three selenium sources (1 mg/kg diet, as either SM, SS or YS) for 100 days. All forms of selenium were equally effective in activating standard measures of selenium status, including tissue selenium levels, expression of genes encoding selenoproteins (Gpx1 and Txnrd2), and increasing GPX1 enzyme activity. However, gene expression profiling revealed that SS and YS were similar (and distinct from SM) in both the expression pattern of individual genes and gene functional categories. Furthermore, only YS significantly reduced the expression of Gadd45b in all four tissues and also reduced GADD45B protein levels in liver. Taken together, these results show that gene expression profiling is a powerful technique capable of elucidating differences in the bioactivity of different forms of selenium.

Electronic supplementary material

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