对-二甲氨基苯酚通透红细胞膜的研究

根据抗氰药对-二甲氨基苯酚(DMAP)穿透红细胞膜使Hb变成MetHb的反应特性及DMAP的磷光性质,分别采用光密度法和燐光法对MetHb生成速度与血球外的DMAP浓度变化进行定量分析,建立红细胞膜对DMAP的通透性研究方法,计算出DMAP穿透速率常数为0.153min^-1,t_1／2等于4.53min,推测DMAP的透过方式为易化扩散。     

菠萝叶片绿色组织与贮水组织中代谢物水平的昼夜变化

研究了景天酸代谢(CAM)植物菠萝叶片绿色组织与贮水组织(WSP)的苹果酸、柠檬酸、异柠檬酸、淀粉、果糖、葡萄糖、蔗糖、葡糖-1-磷酸(G-1-P)、葡糖-6-磷酸(G-6-P)、果糖-6-磷酸(F-6-P)、草酰乙酸(OAA)及磷酸烯醇式丙酮酸(PEP)水平的昼夜变化。夜间苹果酸的积累仅发生在绿色组织中,表明只有绿色组织才能进行CAM。可溶性已糖(葡萄糖和果糖)是绿色组织中夜间苹果酸累积的主要碳源。绿色组织G-1-P、G-6-P和F-6-P水平在夜间的初期上升,后期下降,昼间的头3h仍下降,3h后变化不明显。绿色组织中OAA和PEP水平也发生昼夜变化。在贮水组织中没有测到淀粉、蔗糖、OAA和PEP。除葡萄糖和果糖外,WSP中其它代谢物的含量都远低于绿色组织,而且WSP中所有代谢物都无明显的昼夜变化。     

蜂毒肽的溶血作用与红细胞膜上两种酶活性变化的关系

从蜂毒肽作用于红细胞膜上的Na^＋-K^＋-ATPase和葡萄糖-6-磷酸脱氢酶(G-6-PD)活性变化的角度,利用分光光度法测定酶活性,研究蜂毒肽与红细胞及膜作用过程中可能的靶点,讨论了蜂毒肽溶血过程与RBC膜上2种酶活性的变化．结果发现,蜂毒肽抑制RBC膜上酶活性的主要模式为附着/插入质膜与游离态并存模式,附着/插入质膜中的作用大于游离态的作用．Na^＋-K^＋-ATPase的K⁺结合位点是蜂毒肽的1个作用靶点．蜂毒肽插膜过程与其对此酶的作用随时间延长同步发生．蜂毒肽通过作用于葡萄糖-6-磷酸和NADP使G-6-PD的催化受到缓慢抑制,蜂毒肽形成四聚体的程度与酶活性密切相关．EDTA抑制蜂毒肽聚集,干扰蜂毒肽作用于G-6-P,蜂毒肽作用于底物G-6-P及辅酶NADP的生化机理相似,蜂毒肽抑制作用与G-6-PD的结构无关.     

甘氨酸受体在肾细胞缺氧保护中的作用研究

目的明确甘氨酸受体(glycine receptor,GlyR)是否介导甘氨酸对ATP耗竭细胞的保护作用。方法构建甘氨酸受体α1亚单位(GlyRα1)的真核表达载体pcDNA3.1(b),转染入缺乏天然GlyR的人胚胎肾细胞HEK293。化学性缺氧使细胞处于ATP耗竭状态,光学显微镜及电镜观察细胞形态及超微结构改变,LDH释放率、细胞膜对荧光标记复合物通透性反映细胞膜完整性,台盼蓝染色观察细胞活性。结果细胞ATP耗竭3h后,细胞膜通透性明显增加,细胞器结构损伤,大量细胞死亡。甘氨酸明显降低表达GlyR的转染HEK293细胞膜通透性,阻止荧光标记复合物进入细胞内,细胞LDH释放率由59.18±8.10%下降为35.15±2.61%。从而维持细胞形态结构,降低细胞死亡率。对不表达GlyR细胞无保护作用。结论GlyR介导甘氨酸对ATP耗竭细胞的保护作用,增强细胞对ATP耗竭的耐受能力,增加细胞的存活几率。     

硒与巯基作用稳定红细胞膜骨架

Na_2SeO_3可以减少人红细胞膜血影收缩蛋白(Spectrin)从膜骨架上解离下来.当含有巯基的二硫苏糖醇(DTT)存在下或红细胞膜用碘代乙酰胺(IAA)封闭巯基后.Na_2SeO_3的效应就不再呈现.用与巯基结合的荧光探针:N-[3-芘]-马来酰胺(N-[3-P]-M)来测试不同浓度Na_2SeO_3存在下红细胞膜的荧光强度.结果表明,随着Na_2SeO_3浓度增加,荧光强度就相应降低,这都说明硒是通过与红细胞膜巯基相作用来发挥效应的.~(31)P-NMR测试表明,人红细胞膜在加硒条件下透析,化学位移各向异性(Δσ)值低于不加硒的样品,这提示硒与红细胞膜蛋白巯基作用后红细胞膜脂-蛋白质的相互作用发生了变化.根据实验结果对硒作用后可能引起膜蛋白构象的变化也进行了讨论.     

非生物胁迫对烟草悬浮细胞胞内和胞外ATP水平的影响

以烟草悬浮细胞BY-2(Nicotiana tabacum ‘Bright Yellow-2’)为材料,研究了NaCl、PEG(6000)、低温3种非生物胁迫对细胞内ATP(intracellular ATP,iATP)和细胞外ATP(extracellular ATP,eATP)水平的影响。结果显示：50～200 mmol·L^-1 NaCl处理导致烟草悬浮细胞膜通透性显著增加(P<0.05),100和200 mmol·L^-1 NaCl处理时iATP和eATP水平显著降低(P<0.05)。随着PEG质量浓度的增加(50、100、200 g·L^-1),烟草悬浮细胞膜通透性和eATP水平逐渐增加,其中在200 g·L^-1 PEG处理时eATP水平显著增加至对照的3.4倍(P<0.05),而iATP水平则在200 g·L^-1 PEG处理时显著降低至对照的0.5倍(P<0.05)。0～10℃低温处理后,烟草悬浮细胞膜通透性和iATP水平呈不同程度增加,其中0℃处...     

小鼠腹水型肝癌H22a细胞浆内磷蛋白磷酸酶活力调节的研究

小鼠腹水型肝癌细胞胞浆内磷蛋白磷酸酶对磷酸化的组蛋白、酪蛋白、鱼精蛋白具有脱磷酸化活力,而对小分子底物P-Ser、P-Thr、P-Tyr、PNPP等无活力。二价金属离子Mn~(2+)、Co~(2+)、Mg~(2+)对酶有明显激活作用,而Zn~(2+)、F~-、Pi对酶有明显抑制作用。代谢中间物G-6-P、G-1-P、F-6-P、F-1.6-2P、ATP、ADP、GTP对酶有抑制作用,而磷酸化氨基酸和环核苷酸对酶活影响很小。还试验了碱性蛋白质和酸性蛋白质对酶活力的影响,肝素和组蛋白均对酶活力有抑制作用,当两者混和后,其抑制作用会相互抵消。     

亚硒酸钠抗红细胞膜蛋白交联作用的机理探讨

邻苯二酚氧化处理人红细胞膜会导致膜蛋白交联,产生高分子聚合物(HMP)。用N—乙基马来酰胺(NEM)封闭膜蛋白硫基,则不产生HMP。预先用Na SeO_3(0.05mol/L)处理红细胞膜,也同样不产生HMP。用N—(3-芘)马来酰胺(N-〔3-P〕NEM)标记红细胞膜来测试不同浓度Na_2SeO_3对荧光强度的影响。结果表明,随着Na SeO_3浓度增高荧光强度相应降低。Na_2SeO_3对红细胞膜的预处理时间和荧光强度的变化有关。经Na SeO_3处理的红细胞膜ESR谱提示了Na_2SeO_3与材相互作用有关。用荧光法测定膜结合硒含量表明,Na_2SeO_3处理红细胞膜可导致膜结合硒含量增高。推测,Na SeO_3很可能与膜蛋白疏基作用形成结合硒,从而起到抗膜蛋白交联作用。     

转铁蛋白在低钾刺激Madin Darby狗肾细胞钠-钾ATP酶中的作用

体外低钾培养肾细胞能刺激细胞膜钠-钾ATP酶。本研究利用Madin Darby狗肾细胞能在无血清培养液中健康生存48h这一特征,研究体外低钾刺激细胞膜钠-钾ATP酶所依赖的血清中的活性因子,观察了表皮生长因子(EGF)、胰岛素样生长因子(IGF1)、前列腺素1(PGE1)和转铁蛋白(tranderrin)在这一过程中的作用。结果表明,在无血清培养液中低钾并不能刺激细胞膜钠—钾ATP酶,而添加转铁蛋白可模拟血清的作用。转铁蛋白能剂量依赖性地增加ouabain结合位点,对细胞膜钠-钾ATP酶作用呈良好的时间效应关系。在低钾无血清培养液中,细胞膜钠-钾ATP酶α1亚基启动子活性增强,α1与β1亚基蛋白质表达的增加依赖于转铁蛋白的存在。进一步研究结果表明,低钾在转铁蛋白的无血清培养液环境中能增加细胞对铁的摄取(^59Fe),该作用可被铁螯合剂(deferoxamine,DFO;35 μmol/L)所阻断。DFO也可阻断转铁蛋白依赖性低钾刺激细胞膜钠-钾ATP酶数目的增多,α1亚基启动子活性增强,α1与β1亚基蛋白质表达增加。以上结果表明,低钾对细胞膜钠-钾ATP酶活性的刺激作用依赖于转铁蛋白所调节的铁的摄取。     

十二指肠-空肠转流手术对2型糖尿病大鼠胰岛素抵抗的改善作用

目的建立十二指肠-空肠转流手术(duodenal-jejunal bypass surgery,DJB)动物模型,观察术后GK大鼠胰岛素抵抗情况的变化,研究DJB手术治疗2型糖尿病的机理。方法雄性Wistar大鼠为空白对照组;雄性GK大鼠分为模型对照组和DJB手术组。分别于手术后3、6和9周每组随机抽取6只动物进行高胰岛素-正葡萄糖钳夹实验;钳夹实验结束后1周,检测肝脏Gc K、G6P以及PEPCK mRNA表达情况以及骨骼肌细胞膜GLUT4含量变化。结果术后3周和6周,DJB手术组动物的葡萄糖输注率(GIR)较模型对照组差异无显著性(P0.05),肝脏Gc K、G6P以及PEPCK mRNA表达量较模型对照组差异无显著性(P0.05);术后9周,DJB手术组动物的葡萄糖输注率(GIR)显著高于模型对照组(P0.05),肝脏Gc K表达量DJB手术组显著高于模型对照组(P0.05),而G6P以及PEPCK mRNA表达量显著低于模型对照组(P0.05);DJB手术后3、6和9周,DJB手术组骨骼肌细胞膜GLUT4的含量较模型对照组差异无显著性(P0.05)。结论 DJB手术改善血糖的水平是通过改善体内肝脏组织的胰岛素抵抗,通过调节糖代谢酶的表达,进而提高肝脏葡萄糖摄取并抑制肝脏糖异生作用。在实验周期内,DJB手术对于骨骼肌组织的胰岛素抵抗未发现有明显改善,提示DJB手术治疗2型糖尿病的效果与时间有一定关系。     

Effect of sodium nitrite poisoning on the activity of enzymes of anti-oxidant protection and peroxidation processes in mouse erythrocytes]

The intoxication of white mice with sodium nitrite results in the decrease of red cell superoxide dismutase (SOD) and catalase activity. The glutathione peroxidase activity is the same as in the control group. The level of red cell lipid peroxidation in the group of mice that receive sodium nitrite is higher as compared to the control group. After the intoxication the total activity of glucose-6-phosphate dehydrogenase and dehydrogenase of 6-phosphogluconate as well as the activity of glutathione reductase are higher than in the control group. The level of SH-groups and reduced glutathione is higher in the group of mice that receive sodium nitrite in comparison with the control group.     

The effect of 1-cyclohexyl-3-(2-morpholinoethyl)carbodiimide on the rat liver microsomal glucose-6-phosphatase system

The effect of 1-cyclohexyl-3-(2-morpholinoethyl)carbodiimide (CMC) on the reactions catalyzed by the glucose-6-phosphatase system of rat liver microsomes was studied. Modification of the intact microsomes by CMC leads to the inhibition of the glucose-6-phosphatase, pyrophosphate:glucose and carbamoyl-phosphate : glucose phosphotransferase activities of the system. The activities are restored by the disruption of the microsomal permeability barrier. The mannose-6-phosphate, pyrophosphate, and carbamoyl-phosphate phosphohydrolase activities of the intact as well as the disrupted microsomes were not affected by CMC. It follows from the results obtained that CMC inactivates the microsomal glucose-6-phosphate translocase, the inactivation is a result of the modification of a single sulfhydryl or amino group of the translocase; pyrophosphate, carbamoyl phosphate and inorganic phosphate are transported across the microsomal membrane without participation of the glucose-6-phosphate translocase; pyrophosphate and carbamoyl phosphate may act as the phosphate donors in the glucose phosphorylation reactions in vivo.     

Reversal of oxidative phosphorylation in submitochondrial particles using glucose 6-phosphate and hexokinase as an ATP regenerating system.

During steady-state, the Pi released in the medium is derived from glucose-6-phosphate which continuously regenerates the ATP hydrolyzed. A membrane potential (delta psi) can be built up in submitochondrial particles using glucose-6-phosphate and hexokinase as an ATP-regenerating system. The energy derived from the membrane potential thus formed, can be used to promote the energy-dependent transhydrogenation from NADH to NADP+ and the uphill electron transfer from succinate to NAD+. In spite of the large differences in the energies of hydrolysis of ATP (delta G degrees = -7.0 to -9.0 kcal/mol) and of glucose-6-phosphate (delta G degrees = -2.5 kcal/mol), the same ratio between Pi production and either NADPH or NADH formation were measured regardless of whether millimolar concentrations of ATP or a mixture of ADP, glucose-6-phosphate and hexokinase were used. Rat liver mitochondria were able to accumulate Ca2+ when incubated in a medium containing hexokinase, ADP and glucose-6-phosphate. The different reaction measured with the use of glucose-6-phosphate and hexokinase were inhibited by glucose concentrations varying from 0.2 to 2 mM. Glucose shifts the equilibrium of the reaction towards glucose-6-phosphate formation thus leading to a decrease of the ATP concentration in the medium.     

Methemoglobinemia and acidosis during the first week of life

Recently attention has been called on the possible role of acidosis in the increased methemoglobin formation in the erythrocyte of newborn infant. In the present paper the relations between acidosis and methemoglobin content in the red cells of newborns has been investigated. No significant differences between the percent of methemoglobin in the normal newborns and percent of methemoglobin in the newborns with acidosis has been found. In addition, no correlations between the base excess and percent of methemoglobin has been observed. On the contrary, two newborns with low glucose-6-phosphate dehydrogenase activity demonstrated a significantly increased methemoglobin content in their red cells. The results of our study do not confirm a key role of acidosis in the mechanism of methemoglobin formation in the neonate. It is likely than impairment of red cell metabolism should be the main factor in the formation of methemoglobin in the first days of life.     

Hexose monophosphate shunt-stimulated reduction of methemoglobin by divicine

Reduced divicine (2,6-diamino-4,5-dihydroxypyrimidine), an aglycone implicated in the pathogenesis of favism, reduces methemoglobin efficiently in intact erythrocytes and in hemolysates. Oxidized divicine produces the same effect when glucose or an NADPH-generating system is added to intact erythrocytes or to hemolysates. Although NADPH, NADH, and GSH have no direct methemoglobin-reducing activity in vitro, they convert oxidized divicine to the reduced hydroquinone species, which is responsible for the electron transfer to methemoglobin. Reduction of methemoglobin is optimally observed under nitrogen since, in the presence of oxygen, reduced divicine undergoes autoxidation. Several lines of evidence rule out the reduction of methemoglobin by divicine through an enzyme-catalyzed process, although it is certainly sustained by the hexose monophosphate shunt activity of erythrocytes through the generation of both NADPH and GSH. Thus, the strong enhancing effect that glucose produces on the divicine-dependent methemoglobin reduction within intact normal erythrocytes is completely absent in erythrocytes from glucose-6-phosphate dehydrogenase-deficient subjects. This distinctive behavior might account for the enhanced methemoglobin levels that are found both in vitro in glucose-6-phosphate dehydrogenase-deficient erythrocytes exposed to divicine and in vivo as a typical feature of the acute hemolytic crisis of favic patients.     

Inhibition of protein phosphorylation by chloroquine

The rapid phase of fructose-1,6-bisphosphatase (FBPase) inactivation following glucose addition to starved yeast cells [reported previously] is inhibited on addition of 10 mM chloroquine (CQ) at about pH 8. This inhibition of inactivation was shown to be due to the prevention of phosphorylation of the enzyme. CQ was also found to inhibit general protein phosphorylation in the yeast cells. Glycolysis, as observed by changes in intracellular glucose-6-phosphate and extracellular glucose and ethanol concentrations, was shown to be significantly inhibited in cells treated with CQ. Similarly, a decrease in ATP concentrations was observed. However, during the early stages of phosphorylation of FBPase, levels of ATP were similar in cells containing CQ as in those without CQ. Thus, decrease in ATP levels is not thought to be significantly responsible for the inhibition of protein phosphorylation. However, the phosphorylating activity of cyclic AMP-dependent protein kinases is inhibited in vitro by relatively low concentrations of CQ. Thus, prevention of protein phosphorylation by CQ is believed to be due to inhibition of protein kinases in yeast cells.Abbreviations FBPase fructose-1,6-bisphosphatase - CQ chloroquine - SDS sodium dodecyl sulfate - G6P glucose-6-phosphate - TCA trichloroacetic acid     

Role of ATP in nitrite reduction in roots of wheat and pea

Excised wheat (Triticum aestivum L.) and field pea (Pisum arvense L.) roots, incubated under anaerobic conditions or in the presence of uncouplers of oxidative phosphorylation [2,4-dinitrophenol (DNP), carbonylcyanide-m-chlorophenylhydrazone, pentachlorophenol] accumulated nitrite as a result of an inhibition of nitrite reduction. In isolated root plastids, nitrite reduction was dependent on a supply of glucose-6-phosphate (G6P) and did not require ATP. The estimated K_m value for glucose 6-phosphate was 1.25 mM. Glucose and fructose-1,6-diphosphate were ineffective substrates for nitrate reduction. Anaerobic conditions and treatment with DNP, which would result in a cessation of ATP production by the mitochondria and a stimulation of glycolysis via the Pasteur effect, were shown to decrease the G6P content of excised roots of wheat and pea. A negative correlation was observed between the level of G6P and nitrite accumulation on root tissues. It is proposed that an interruption in the supply of G6P to the root plastid under these conditions would result in an inhibition of nitrite reduction leading to nitrite accumulation.Abbreviation G6P glucose-6-phosphate     

Oxidative damage to human red cells induced by copper and iron complexes in the presence of ascorbate

The role of trace metals in the generation of free radical mediated oxidative stress in normal human red cells was studied. Ascorbate and either soluble complexes of Cu(II) or Fe(III) provoked changes in red cell morphology, alteration in the polypeptide pattern of membrane proteins, and significant increases in methemoglobin. Neither ascorbate nor the metal complexes alone caused significant changes to the cells. The rate of methemoglobin formation was a function of ascorbate and metal concentrations, and the chemical nature of the chelate. Cu(II) was about 10-times more effective than Fe(III) in the formation of methemoglobin. Several metals were tested for their ability to compete with Cu(II) and Fe(III). Only zinc caused a significant inhibition of methemoglobin formation by Fe(III)-fructose. These observations suggest that site-specific as well as general free radical damage is induced by redox metals when the metals are either bound to membrane proteins or to macromolecules in the cytoplasm. The Cu(II) and Fe(III) function in two catalytic capacities: (1) oxidation of ascorbate by O2 to yield H2O2, and (2) generation of hydroxyl radicals from H2O2 in a Fenton reaction. These mechanisms are different from the known damage to red cells caused by the binding of Fe(III) or Cu(II) to the thiol groups of glucose-6-phosphate dehydrogenase. Our system may be a useful model for understanding the mechanisms for oxidative damage associated with thalassemia and other congenital hemolytic anemias.     

Evidence for protein phosphorylation as a regulatory mechanism for hepatic microsomal glucose 6 phosphatase

Incubation of microsomal vesicles with ATP and protein kinase results in a fivefold increased glucose-6-phosphatase activity. Evidence is presented that this effect is mediated via a moiety of the outer membrane surface. Evidence is also presented for the presence of an endogenous, peripheral membrane protein also capable of activating glucose-6-phosphatase in an ATP dependent reaction. It is suggested that the glucose-6-phosphate transmembrane carrier system may be the target of phosphorylation.     

Adaptation of rats following sodium-nitrite-induced methemoglobinemia]

Adaptation of rats following sodium nitrite induced methemoglobinemia. The effect of repeated intraperitoneal injections of sodium nitrite on methemoglobin, hemoglobin and blood sugar level, on leucine aminopeptidase activity in plasma and methemoglobin reductase activity in red blood cells was investigated in rats. Repeated methemoglobinemia produced gradual disappearance of hyperglycemia, changes of hemoglobin content in blood and increase of methemoglobin reductase activity in red blood cells.