大鼠急性应激时肝线粒体质子跨膜转动活性的调控

大鼠烫伤早期（烫伤后３０ｍｉｎ）,肝线粒体质子加电子传递速度均加快,线粒体能化态跨膜电位降低（均以琥珀酸为底物）,线粒体膜脂流动性降低。皮下注射去甲肾上腺素后也有上述现象发生。推测急性应激通过儿茶酚胺类作用于肝细胞,导致线粒体内膜有序性增强所致。     

冷暴露对中缅树鼩肝脏、膈肌和心肌线粒体呼吸的影响

在4℃急性冷暴露(1 h,4 h,8 h,24 h)和持续冷暴露 (7 d,14 d,28 d)条件下,测定中缅树鼩膈肌、心肌和肝脏的线粒体状态Ⅲ呼吸、状态Ⅳ呼吸、呼吸控制率(RCR)、线粒体蛋白含量以及肝脏线粒体P/O值的变化.结果表明:肝脏线粒体状态Ⅲ、状态Ⅳ呼吸随着低温处理时间的延长,呼吸速率均极显著增加,在28 d后分别增加了132.9%、124.4%(P<0.01),RCR与对照比较,在8 h和7 d组分别显著增加了35.8%和48.4%(P<0.05),线粒体蛋白含量也极显著增加,在28 d后增加了104.7%(P<0.01),P/O值在整个低温处理过程中呈下降趋势,在28 d后降低了40.2%,达到极显著水平(P<0.01);膈肌线粒体状态Ⅲ呼吸在整个低温处理期间没有显著变化,状态Ⅳ呼吸在28 d达到极显著增加(P<0.01,64.9%),RCR在28 d后显著降低(P<0.05, 42.1%),线粒体蛋白只有4 h组有极显著增加(P<0.01,45.2%);心肌的状态Ⅲ呼吸在8 h组有着极显著的增加(P<0.01, 54.7%),状态Ⅳ呼吸随着低温处理时间的增加而显著增加,28 d后增加了94.7%(P<0.01),RCR在28 d后降低37.8%(P<0.01),线粒体蛋白表现出先下降再上升的趋势,8 h组下降37.8%(P<0.01),28 d增加25.2%(P<0.05).说明中缅树鼩在冷胁迫的条件下肝脏线粒体呼吸能力显著增强,主要表现为状态Ⅳ呼吸即质子漏产热的显著增强,膈肌和心肌的线粒体呼吸也具有一定的适应性变化,补偿了冷胁迫条件下中缅树鼩增加的能量需求,是中缅树鼩在冷胁迫中重要的适应对策.     

烫伤大鼠早期口服谷氨酰胺对血浆氨基酸代谢的影响

研究烫伤早期口服谷氨酰胺 (GLN)后GLN及其相关氨基酸的代谢变化。以Wistar大鼠为烫伤模型 ,烫伤后早期口服GLN ,并以 83 5-50型氨基酸自动分析仪的生理体液法测定血浆游离氨基酸。结果烫伤后饲标准饲料(C)组血浆GLN在烫伤后 2d和 5d降低 ,与GLN代谢相关的丙氨酸和氨无显著性变化 ;GLN饲料 (G)组各时相点GLN均增加 ,1 0h和 8d增加显著 ,与GLN代谢相关的丙氨酸和血氨增加显著 ;GLN +精氨酸 (G +A)组GLN在 2d降低 ,血氨升高显著。与C组比 ,G和G +A组血浆总氨基酸、支琏氨基酸、GLN、丙氨酸、r-氨基丁酸和氨均较C组高。提示 ,烫伤后早期口服GLN能提高血GLN和与之代谢相关的氨基酸浓度。     

CLIC1通过干扰线粒体动力学平衡促进内皮细胞损伤的研究

该文通过研究H2O2诱导人脐静脉内皮细胞(HUVEC)中氯离子通道蛋白1(chloride intracellular channel 1, CLIC1)对线粒体动力学平衡的影响,探讨CLIC1在内皮细胞损伤中的作用及机制。体外培养HUVEC细胞,分别用CLIC1抑制剂IAA94(40μmol/L)、H2O2(0.9 mmol/L)、IAA94(40μmol/L)和H2O2(0.9 mmol/L)联合处理,荧光法检测细胞活性氧(reactive oxygen species,ROS)和丙二醛(malondialdehyde, MDA)的含量; JC-1染色法检测细胞线粒体膜电位的变化;定量PCR技术检测CLIC1、线粒体动力相关蛋白1(dynamin-related protein 1, Drp1)以及线粒体融合蛋白1(mitofusin 1, Mfn1)的mRNA表达;免疫印迹技术检测CLIC1、Drp1蛋白的水平。结果显示:与正常组相比, H2O2处理的内皮细胞中ROS、MDA含量增加(P0.05), CLIC1表达量上调(P0.05),三磷酸腺苷(ATP)含量减少(P0.05),线粒体膜电位降低(P0.001),线粒体融合蛋白Mfn1表达显著降低(P0.05),线粒体分裂蛋白Drp1表达显著升高(P0.05);而IAA94预处理2 h后,内皮细胞中ROS、MDA含量减少(P0.05),线粒体融合蛋白Mfn1表达显著增加(P0.05),线粒体分裂蛋白Drp1表达显著降低(P0.05),线粒体膜电位升高(P0.001)。以上结果表明, CLIC1在H2O2诱导的内皮细胞线粒体损伤中发挥重要作用,其机制可能与CLIC1干扰线粒体动力学平衡有关。     

仙人掌提取物对浅Ⅱ度烫伤小鼠VEGF及FGF-2表达的影响

为探讨野生仙人掌和食用仙人掌提取物对浅Ⅱ度烫伤小鼠内源性血管内皮生长因子(VEGF)及碱性成纤维细胞生长因子(FGF-2)表达的影响,建立小鼠浅Ⅱ度烫伤模型。野生、食用仙人掌提取物组(浓度均为12.5 mg/mL),药物组(京万红),烫伤组(生理盐水),每天2次涂药并观察创面,分别在3 d和7 d各组取5只小鼠处死,取烫伤组织提取蛋白并检测VEGF、FGF-2的表达状况。仙人掌组中VEGF及FGF-2的表达量均高于烫伤组,且两种仙人掌组VEGF及FGF-2的表达量有差异。即仙人掌提取物能提高VEGF及FGF-2的表达量并能促进创面的修复。     

人参皂苷Rb1通过上调PGC-1α缓解糖尿病心肌病

目的:研究人参皂苷Rb1对糖尿病心肌病的治疗作用并阐明其分子机制。方法:采用腹腔注射链脲佐菌素的方法,建立糖尿病心肌病动物模型。将小鼠分为3组:WT组,DM组,DM+Rb1组。超声心动图分析小鼠心功能;Western blot分析PGC-1α、cleaved caspase-3、bcl-2等蛋白表达;MitoSOX染色分析线粒体ROS含量;透射电镜分析线粒体数目。结果:与WT组相比,DM组小鼠心功能显著下降(LVEF,P<0.01),PGC-1α表达下调(P<0.01),线粒体数目减少(P<0.01);而Rb1处理后,显著改善了DM小鼠心功能(LVEF,P<0.01),恢复了PGC-1α表达(P<0.05),增加了线粒体数目(P<0.05)。同时,Rb1处理后,减少了糖尿病小鼠心肌线粒体ROS产生(P<0.01),恢复了bcl-2蛋白表达(P<0.01),降低了cleaved caspase-3蛋白表达(P<0.01),从而减少了高糖引起的细胞凋亡(P<0.05)。而siPGC-1α处理后,阻断了Rb1的上述作用。结论:人参皂苷Rb1通过上调PGC-1α改善糖尿病小鼠心功能,缓解糖尿病心肌病。其机制可能与人参皂苷Rb1降低心肌线粒体ROS产生并减少心肌细胞凋亡有关。     

强啡肽A对烫伤大鼠免疫功能的影响

大鼠烫伤后24h血浆强啡肽A(Dyn A)的含量开始降低,120h仍未恢复到对照水平。烫伤后免疫功能也有明显的变化,表现为淋巴细胞转化功能降低,白细胞介素1,2(IL-1,IL-2)生成量减少。其变化过程与血浆Dyn A的变化基本一致。离体条件下,Dyn A与烫伤大鼠的脾淋巴细胞共同培养,可增强淋巴细胞转化及IL-2的生成。静脉注射Dyn A后,烫伤大鼠的淋巴细胞转化功能、IL-1和IL-2的生成都有不同程度的增加。本实验提示,血浆Dyn A水平的降低可能是烫伤大鼠免疫功能低下的原因之一。     

静脉注射抗β-内啡肽血清对大鼠烫伤休克的影响

本实验在大鼠烫伤后,立即静脉注射不同剂量的抗β-内啡肽血清,观察动物血压、心率、呼吸及存活时间的改变。结果发现:(1)给予抗β-内啡肽血清后,烫伤动物的平均存活时间明显延长(P<0.01),且随抗血清剂量的增加呈明显的剂量依赖关系。(2)静脉注射抗β-内啡肽血清后,烫伤大鼠的血压下降被延缓,烫伤后60至120min时尤为明显。(3)烫伤大鼠的心率减慢在静脉注射抗β-内啡肽血清后也被延缓,这种影响出现早,但持续短。(4)抗β-内啡肽血清可使烫伤动物的呼吸频率保持相对恒定,且这种作用持续时间较长。实验提示:抗β-内啡肽血清对烫伤动物的心血管及呼吸功能有一定的改善作用,延缓烫伤休克的出现,使动物烫伤后存活时间延长,间接提示β-内啡肽参与烫伤休克。     

迷迭香酸对羟自由基所致小鼠肝线粒体损伤的保护作用

探索迷迭香酸对羟自由基致小鼠肝脏线粒体氧化损伤的保护作用。采用羟自由基(.OH),诱导小鼠肝线粒体损伤后,通过测定线粒体肿胀度、膜流动性、丙二醛(MDA)含量及琥珀酸脱氢酶(SDH)活性等指标以确定迷迭香酸对小鼠肝线粒体羟自由基损伤的保护作用。结果迷迭香酸剂量依赖地抑制线粒体肿胀,提高膜流动性,降低MDA的生成,增强SDH活性,差异显著。本实验证明迷迭香酸可以抑制.OH所致的线粒体损伤。     

肝素促进深Ⅱ度烧伤小鼠bFGF及PDGF表达的研究

目的:探讨肝素对深Ⅱ度烧伤小鼠内源性碱性成纤维生长因子(bFGF)和血小板源生长因子(PDGF)表达的影响.方法:制作小鼠深Ⅱ度烫伤模型,肝素组用3000U/mL肝素外敷伤口2min,每日2次,观察创面愈合状况,并在给药后第3天分别从肝素组(烫伤后用肝素处理)、烫伤组(烫伤后自然愈合)及对照组(未进行烫伤处理)取5只小鼠处死,提取烫伤及其周围皮肤组织的蛋白质,用Western-blotting检测bFGF和PDGF的表达状况.结果:肝素组bFGF和PDGF表达均高于烫伤组;而烫伤组的两种生长因子的表达均高于对照组.结论:烫伤后bFGF和PDGF的表达量增高,且肝素能促进深Ⅱ度烧伤内源性生长因子bFGF、PDGF的表达.     

Chromium(VI) interaction with plant and animal mitochondrial bioenergetics: a comparative study

The mechanism of Cr(VI)-induced toxicity in plants and animals has been assessed for mitochondrial bioenergetics and membrane damage in turnip root and rat liver mitochondria. By using succinate as the respiratory substrate, ADP/O and respiratory control ratio (RCR) were depressed as a function of Cr(VI) concentration. State 3 and uncoupled respiration were also depressed by Cr(VI). Rat mitochondria revealed a higher sensitivity to Cr(VI), as compared to turnip mitochondria. Rat mitochondrial state 4 respiration rate triplicated in contrast to negligible stimulation of turnip state 4 respiration. Chromium(VI) inhibited the activity of the NADH-ubiquinone oxidoreductase (complex I) from rat liver mitochondria and succinate-dehydrogenases (complex II) from plant and animal mitochondria. In rat liver mitochondria, complex I was more sensitive to Cr(VI) than complex II. The activity of cytochrome c oxidase (complex IV) was not sensitive to Cr(VI). Unique for plant mitochondria, exogenous NADH uncoupled respiration was unaffected by Cr(VI), indicating that the NADH dehydrogenase of the outer leaflet of the plant inner membrane, in addition to complexes III and IV, were insensitive to Cr(VI). The ATPase activity (complex V) was stimulated in rat liver mitochondria, but inhibited in turnip root mitochondria. In both, turnip and rat mitochondria, Cr(VI) depressed mitochondrial succinate-dependent transmembrane potential (Deltapsi) and phosphorylation efficiency, but it neither affected mitochondrial membrane permeabilization to protons (H+) nor induced membrane lipid peroxidation. However, Cr(VI) induced mitochondrial membrane permeabilization to K+, an effect that was more pronounced in turnip root than in rat liver mitochondria. In conclusion, Cr(VI)-induced perturbations of mitochondrial bioenergetics compromises energy-dependent biochemical processes and, therefore, may contribute to the basal mechanism underlying its toxic effects in plant and animal cells.     

细胞膜毒素对线粒体上钙通道的抑制

本文探讨膜毒素对鼠肝线粒体Ca~(++)传递和Ca~(++)结合亲和力的影响。当膜毒素的浓度为7.14毫微克分子/毫克线粒体蛋白时,处理过的线粒体传递Ca~(++)能力下降至原来一半左右。本实验做Ca~(++)结合膜毒素处理线粒体的Scatchard图呈直线(K_d=48.2μM,结合Ca~(++)数目N=341毫微克分子/毫克线粒体蛋白)。就是说,膜毒素抑制线粒体高亲和力Ca~(++)结合部位,而不影响低亲和力Ca~(++)结合部位。我们认为膜毒素作用位点在于线粒体高亲和力Ca~(++)结合部位。     

Trehalose loading through the mitochondrial permeability transition pore enhances desiccation tolerance in rat liver mitochondria

Trehalose has extensively been used to improve the desiccation tolerance of mammalian cells. To test whether trehalose improves desiccation tolerance of mammalian mitochondria, we introduced trehalose into the matrix of isolated rat liver mitochondria by reversibly permeabilizing the inner membrane using the mitochondrial permeability transition pore (MPTP). Measurement of the trehalose concentration inside mitochondria using high performance liquid chromatography showed that the sugar permeated rapidly into the matrix upon opening the MPTP. The concentration of intra-matrix trehalose reached 0.29 mmol/mg protein (∼190 mM) in 5 min. Mitochondria, with and without trehalose loaded into the matrix, were desiccated in a buffer containing 0.25 M trehalose by diffusive drying. After re-hydration, the inner membrane integrity was assessed by measurement of mitochondrial membrane potential with the fluorescent probe JC-1. The results showed that following drying to similar water contents, the mitochondria loaded with trehalose had significantly higher inner membrane integrity than those without trehalose loading. These findings suggest the presence of trehalose in the mitochondrial matrix affords improved desiccation tolerance to the isolated mitochondria.     

Glibenclamide interferes with mitochondrial bioenergetics by inducing changes on membrane ion permeability

The interference of glibenclamide, an antidiabetic sulfonylurea, with mitochondrial bioenergetics was assessed on mitochondrial ion fluxes (H+, K+, and Cl-) by passive osmotic swelling of rat liver mitochondria in K-acetate, KNO3, and KCl media, by O2 consumption, and by mitochondrial transmembrane potential (Deltapsi). Glibenclamide did not permeabilize the inner mitochondrial membrane to H+, but induced permeabilization to Cl- by opening the inner mitochondrial anion channel (IMAC). Cl- influx induced by glibenclamide facilitates K+ entry into mitochondria, thus promoting a net Cl-/K+ cotransport, Deltapsi dissipation, and stimulation of state 4 respiration rate. It was concluded that glibenclamide interferes with mitochondrial bioenergetics of rat liver by permeabilizing the inner mitochondrial membrane to Cl- and promoting a net Cl-/K+ cotransport inside mitochondria, without significant changes on membrane permeabilization to H+.     

Effect of succinate on mitochondrial lipid peroxidation. 1. Comparative studies on ferrous ion and ADP · Fe/NADPH-induced peroxidation

Lipid peroxidation in isolated rat liver mitochondria, mitoplast, and mitochondrial inner membrane fragments was induced either by ferrous ions, or in an NADPH-dependent process by complexing with adenine nucleotides (ADP or ATP) iron. The Fe²⁺-induced lipid peroxidation is nonenzymic when inner membrane fragments are used, while the differences in the inhibitory effect of Mn²⁺ ions and the stimulatory effect of the ionophore A-23187 in mitochondria and inner membrane fragments suggest an enzymic mechanism for ferrous ion-induced lipid peroxidation in intact mitochondria. Contrary to this the ADP/Fe/NADPH-dependent lipid peroxidation is an enzymic process both in mitochondria and inner membrane preparations. We have shown that cytochrome P₄₅₀ is involved in the ADP/Fe/NADPH-induced lipid peroxidation. Succinate, a known inhibitor of NADPH-dependent lipid peroxidation, inhibited the Fe²⁺-induced process also, and there was no difference in this effect when inner membrane preparations, mitochondria, or mitoplasts were used.     

Regulation of the inner membrane mitochondrial permeability transition by the outer membrane translocator protein (peripheral benzodiazepine receptor)

We studied the properties of the permeability transition pore (PTP) in rat liver mitochondria and in mitoplasts retaining inner membrane ultrastructure and energy-linked functions. Like mitochondria, mitoplasts readily underwent a permeability transition following Ca(2+) uptake in a process that maintained sensitivity to cyclosporin A. On the other hand, major differences between mitochondria and mitoplasts emerged in PTP regulation by ligands of the outer membrane translocator protein of 18 kDa, TSPO, formerly known as the peripheral benzodiazepine receptor. Indeed, (i) in mitoplasts, the PTP could not be activated by photo-oxidation after treatment with dicarboxylic porphyrins endowed with protoporphyrin IX configuration, which bind TSPO in intact mitochondria; and (ii) mitoplasts became resistant to the PTP-inducing effects of N,N-dihexyl-2-(4-fluorophenyl)indole-3-acetamide and of other selective ligands of TSPO. Thus, the permeability transition is an inner membrane event that is regulated by the outer membrane through specific interactions with TSPO.     

Differential protein distributions define two sub-compartments of the mitochondrial inner membrane in yeast

The mitochondrial inner membrane exhibits a complex topology. Its infolds, the cristae membranes, are contiguous with the inner boundary membrane (IBM), which runs parallel to the outer membrane. Using live cells co-expressing functional fluorescent fusion proteins, we report on the distribution of inner membrane proteins in budding yeast. To this end we introduce the enlarged mitochondria of Deltamdm10, Deltamdm31, Deltamdm32, and Deltammm1 cells as a versatile model system to study sub-mitochondrial protein localizations. Proteins of the F(1)F(0) ATP synthase and of the respiratory chain complexes III and IV were visualized in the cristae-containing interior of the mitochondria. In contrast, proteins of the TIM23 complex and of the presequence translocase-associated motor were strongly enriched at the IBM. The different protein distributions shown here demonstrate that the cristae membranes and the IBM are functionally distinct sub-compartments.     

Nuclear-encoded NCX3 and AKAP121: Two novel modulators of mitochondrial calcium efflux in normoxic and hypoxic neurons

Mitochondria are highly dynamic organelles extremely important for cell survival. Their structure resembles that of prokaryotic cells since they are composed with two membranes, the inner (IMM) and the outer mitochondrial membrane (OMM) delimitating the intermembrane space (IMS) and the matrix which contains mitochondrial DNA (mtDNA). This structure is strictly related to mitochondrial function since they produce the most of the cellular ATP through the oxidative phosphorylation which generate the electrochemical gradient at the two sides of the inner mitochondrial membrane an essential requirement for mitochondrial function. Cells of highly metabolic demand like those composing muscle, liver and brain, are particularly dependent on mitochondria for their activities. Mitochondria undergo to continual changes in morphology since, they fuse and divide, branch and fragment, swell and extend. Importantly, they move throughout the cell to deliver ATP and other metabolites where they are mostly required. Along with the capability to control energy metabolism, mitochondria play a critical role in the regulation of many physiological processes such as programmed cell death, autophagy, redox signalling, and stem cells reprogramming. All these phenomena are regulated by Ca²⁺ ions within this organelle. This review will discuss the molecular mechanisms regulating mitochondrial calcium cycling in physiological and pathological conditions with particular regard to their impact on mitochondrial dynamics and function during ischemia. Particular emphasis will be devoted to the role played by NCX3 and AKAP121 as new molecular targets for mitochondrial function and dysfunction.     

泥螺卵黄发生过程中线粒体的变化

利用透射电镜（TEM）技术研究了泥螺卵黄发生过程中线粒体的形态结构的变化特点,结果表明,从卵黄发生早期到晚期,卵母细胞内线粒体经历了从外部形态到内部结构的一系列变化。卵黄合成初期的卵母细胞内,线粒体多,结构典型,仅部分线粒体外膜破裂,嵴 和内膜逐渐消失,卵黄发生中期,线粒体基质空泡化,嵴和内膜消失,腔内充满颗粒状物质,最后演变成卵黄颗粒,随着卵母细胞的发育,卵黄颗粒的数量和直径逐渐增加,卵黄发生后期,卵质中胞器不发达,细胞质中充满卵黄颗粒,在卵黄颗粒之间仅有少量线粒体存在,提供细胞代谢所需的能量,此外,对线粒体在卵黄形成中的功能,去向及行为变化等 进行了讨论。     

Osmotically-induced alterations in volume and ultrastructure of mitochondria isolated from rat liver and bovine heart

Detailed studies correlating changes in mitochondrial optical density, packed volume, and ultrastructure associated with osmotically-induced swelling were performed. Various swelling states were established by incubating mitochondria (isolated in 0.25 M sucrose) at 0°C for 5 min in series of KCl and sucrose solutions ranging in tonicity from 250 to 3 milliosmols. Reversibility of swelling was determined by examining mitochondria exposed to 250 milliosmols media after they had been induced to swell. Swelling induced by lowering the ambient tonicity to approximately 130 (liver mitochondria) and 90 (heart mitochondria) milliosmols involves primarily swelling of the inner compartment within the intact outer membrane. Decreasing the ambient tonicity beyond this level results in rupture of the outer membrane and expansion of the inner compartment through the break. The maximum extent of swelling, corresponding with complete unfolding of the cristae and an increase in over-all mitochondrial volume of approximately 6-fold (liver mitochondria) and 11-fold (heart mitochondria), is reached at approximately 15 (liver mitochondria) and 3 (heart mitochondria) milliosmols. Exposure of liver mitochondria to media of lower tonicity results in irreversibility of inner compartment swelling and escape of matrix material. These changes appear to result from increased inner membrane permeability, possibly due to stretching.