植物甾醇生理功能的线粒体调控机制

植物甾醇是一类在植物中广泛存在的生物活性物质,在食品、医药、化妆品等领域具有广阔应用前景.植物甾醇作为胆固醇类似物可抑制胆固醇肠道吸收进而降低血液中胆固醇水平、降低心血管疾病风险;此外,植物甾醇还具有抑癌、抗炎退热、抗氧化和类激素等多种功能.从亚细胞及分子水平深入探究植物甾醇的生物作用机制有助于充分开发植物甾醇的应用价值.线粒体是细胞能量物质代谢最重要的场所,胆固醇代谢、癌细胞增殖与凋亡、氧化应激和炎症反应等都与线粒体功能密切相关.近年来研究提示植物甾醇可在多种模型中调控线粒体功能,这可能是植物甾醇发挥各种生物学功能的重要潜在机制.本文将首先整理归纳植物甾醇生物学功能,并在此基础上详细讨论其线粒体相关调控机制,以期为领域内基础研究者提供前沿思路和进展报告,并为植物甾醇的应用提供参考依据.     

低分子肝素的抗炎作用及机制

低分子肝素(low molecular weight heparin, LMWH)除作为抗凝血和抗血栓药在临床上广为应用外,近年来其抗炎活性也颇受重视.LMWH抗炎机制涉及炎症细胞、炎症因子和黏附分子等环节.目前对LMWH的抗炎机制研究还处在初级阶段,但是LMWH独特的性质使其有望成为有效且安全的新型抗炎药物.     

吡啶核苷酸转氢酶的结构及功能

吡啶核苷酸转氢酶(pyridine nucleotide transhydrogenases)是能直接催化NADP(H)与NAD(H)之间氢负离子可逆转移的氧化还原酶, 主要调控分解代谢和合成代谢过程中NADH与NADPH之间的动态平衡. 膜结合吡啶核苷酸转氢酶(TH)是ATP依赖性跨膜蛋白, 由2个亚基构成, 每个亚基包含dⅠ、dⅡ和dⅢ三个结构域. 在TH结合可变催化机制中, 氢负离子的转移总是与质子转移相偶联. 可溶性吡啶核苷酸转氢酶(STH)是非能量依赖性的黄素蛋白, 以可溶性多聚体形式存在. 目前认为,很多因活性氧自由基异常增多而引起的线粒体疾病都与TH的活性有关, 包括糖尿病、癌症、神经退行性疾病及心血管疾病等. TH分子机制的研究将有助于揭示这些线粒体疾病的致病机理以及为其诊断和基因治疗提供分子依据. STH作用机理的研究及其在辅酶再生系统中的应用, 将会推动代谢工程和工业生物催化过程的进一步发展.     

线粒体自噬的分子机制

线粒体自噬指细胞选择性清除受损伤或多余线粒体的一种自噬方式,是线粒体应激反应和线粒体稳态调控的重要部分,对其分子机制以及相应调控机制的研究受到广泛关注.本文总结了近年来关于线粒体自噬的分子机制研究进展,同时分析了相关受体介导线粒体自噬的信号调节机制,以期为将来线粒体自噬研究的发展和完善提供借鉴意义.     

线粒体在铁死亡中的形态特征和作用

铁死亡是铁依赖性的脂质过氧化作用驱动的一种独特的细胞死亡方式。与细胞凋亡、自噬性程序性细胞死亡和细胞焦亡等细胞死亡方式不同，铁死亡的主要特征是线粒体形态的改变，包括线粒体膜变得致密并伴随体积变小，以及外膜破裂和线粒体嵴的减少或消失。线粒体作为细胞代谢的核心，是铁代谢、脂质代谢和能量代谢中的重要细胞器。但是，线粒体如何参与铁死亡并在其进程中发挥怎样的作用仍存在争议。本文综述了现有对铁死亡发生和防御机制的认识，并且对线粒体在铁死亡进程中的促进和抑制作用进行了描述和分析，包括线粒体三羧酸循环和糖酵解、线粒体活性氧、线粒体脂质代谢对铁死亡的积极驱动过程，以及通过线粒体铁蛋白、线粒体二氢乳酸脱氢酶等分子对线粒体脂质过氧化物解毒并抑制铁死亡的作用机制。最后补充说明了其他涉及铁死亡的线粒体分子调控机制。本文通过综述线粒体在铁死亡进程中的最新研究进展，旨在对深入了解铁死亡中线粒体的功能及其对铁死亡发生发展的作用机制，为细胞生物学基础研究及临床相关疾病的研究提供理论依据和参考。     

综述: 与神经退行性疾病相关的RNA结合蛋白在线粒体损伤中的作用

线粒体是细胞内制造能量的细胞器,它还负责各种细胞信号的整合,参与协调多种复杂的细胞功能.线粒体是动态变化的,连续不断地进行分裂与融合,这是其功能维持和增殖遗传的关键.在过去20年中,参与线粒体分裂与融合的核心因子陆续被发现,它们在进化上高度保守,但是在形成分裂与融合复合物中的详细分子机制还有待于深入研究.线粒体分裂与融合的动态变化,是线粒体质量控制的重要组成部分,其动态平衡在细胞发育和稳态维持中起重要作用.线粒体动态变化失衡和功能失调,则会导致多种神经退行性疾病的发生.这些研究的发现为探索线粒体生物学及与疾病的关系开拓了令人振奋的新方向.     

与神经退行性疾病相关的RNA结合蛋白在线粒体损伤中的作用

线粒体是细胞内制造能量的细胞器,它还负责各种细胞信号的整合,参与协调多种复杂的细胞功能.线粒体是动态变化的,连续不断地进行分裂与融合,这是其功能维持和增殖遗传的关键.在过去20年中,参与线粒体分裂与融合的核心因子陆续被发现,它们在进化上高度保守,但是在形成分裂与融合复合物中的详细分子机制还有待于深入研究.线粒体分裂与融合的动态变化,是线粒体质量控制的重要组成部分,其动态平衡在细胞发育和稳态维持中起重要作用.线粒体动态变化失衡和功能失调,则会导致多种神经退行性疾病的发生.这些研究的发现为探索线粒体生物学及与疾病的关系开拓了令人振奋的新方向.     

蜜蜂抗狄斯瓦螨机制的研究进展

狄斯瓦螨Varroa destructor已蔓延至世界各地,给养蜂生产带来巨大挑战,被认为是世界养蜂业的主要威胁。因此,抗螨机制的研究和抗螨蜂种的培育显得尤为重要,而掌握蜜蜂的抗螨机制则是成功培育抗螨蜂种的前提条件。本文从行为、生理及分子机制等多个不同角度对国内外蜜蜂抗狄斯瓦螨机制研究的最新进展进行了详细的阐述。尤其是从分子水平研究蜜蜂的抗螨机制对选育抗螨蜂种具有重要意义,将为利用分子遗传辅助标记筛选方法和先进的生物工程技术并结合传统的育种手段成功培育出具有抗螨性能的优良蜜蜂品系奠定基础。     

Bcl—2家族蛋白与细胞凋亡

Bcl 2家族蛋白是在细胞凋亡过程中起关键性作用的一类蛋白质。在线粒体上 ,Bcl 2家族蛋白通过与其他凋亡蛋白的协同作用 ,调控线粒体结构与功能的稳定性 ,发挥着细胞凋亡“主开关”的作用。Bcl 2家族包括两类蛋白质 :一类是抗凋亡蛋白 ,另一类是促凋亡蛋白。在细胞凋亡时 ,Bcl 2家族中的促凋亡蛋白成员发生蛋白质的加工修饰 ,易位到线粒体的外膜上 ,引起细胞色素c、凋亡诱导因子等其他促凋亡因子的释放 ,导致细胞凋亡 ;而平时被隔离在线粒体等细胞器内的该家族的抗凋亡蛋白成员则抑制细胞色素c和凋亡诱导因子等促凋亡因子的释放 ,具有抑制细胞凋亡的功能。但一旦这类抗凋亡蛋白成员与激活的促凋亡蛋白发生相互作用后 ,便丧失了对细胞凋亡的抑制作用 ,造成线粒体等细胞器的功能丧失和细胞器内促凋亡因子的释放 ,导致细胞凋亡。现以Bcl 2家族调控细胞凋亡的最新研究进展为基础 ,对Bcl 2家族成员及其蛋白质结构、分布和调控细胞凋亡的分子机制进行综述。     

Mieap与线粒体的质量控制

线粒体在细胞能量代谢和细胞凋亡中起着至关重要的作用.质量控制是线粒体在细胞中维持正常状态的关键机制.2011年Miyamoto等发现Mieap参与线粒体质量控制的两个新机制.Mieap诱导的溶酶体样细胞器,进入线粒体内,并在线粒体积累,能通过特异性的清除氧化的线粒体蛋白来修复异常线粒体,使得线粒体维持在正常状态.Mieap诱导的通过细胞膜内吞机制形成的囊泡,识别异常线粒体,并对其特异性的清除.Mieap诱导的这两个过程参与了线粒体质量控制,并决定线粒体的命运.     

Propofol is cardioprotective in a clinically relevant model of normothermic blood cardioplegic arrest and cardiopulmonary bypass

The general anesthetic propofol has been shown to be cardioprotective. However, its benefits when used in cardioplegia during cardiac surgery have not been demonstrated. In this study, we investigated the effects of propofol on metabolic stress, cardiac function, and injury in a clinically relevant model of normothermic cardioplegic arrest and cardiopulmonary bypass. Twenty anesthetized pigs, randomized to propofol treatment (n = 8) and control (n = 12) groups, were surgically prepared for cardiopulmonary bypass (CPB) and cardioplegic arrest. Doses of warm blood cardioplegia were delivered at 15-min intervals during a 60-min aortic cross-clamped period. Propofol was continuously infused for the duration of CPB and was therefore present in blood cardioplegia. Myocardial biopsies were collected before, at the end of cardioplegic arrest, and 20 mins after the release of the aortic cross-clamp. Hemodynamic parameters were monitored and blood samples collected for cardiac troponin I measurements. Propofol infusion during CPB and before ischemia did not alter cardiac function or myocardial metabolism. Propofol treatment attenuated the changes in myocardial tissue levels of adenine nucleotides, lactate, and amino acids during ischemia and reduced cardiac troponin I release on reperfusion. Propofol treatment reduced measurable hemodynamic dysfunction after cardioplegic arrest when compared to untreated controls. In conclusion, propofol protects the heart from ischemia-reperfusion injury in a clinically relevant experimental model. Propofol may therefore be a useful adjunct to cardioplegic solutions as well as being an appropriate anesthetic for cardiac surgery.     

富氢水和富氢生理盐水生物医学研究进展——动物实验

自2007年发现吸氢可有效保护脑缺血再灌注损伤以来,氢气的生物学作用被陆续发现。富氢水或富氢生理盐水作为主要的氢气干预方式已广泛应用于基础医学和临床研究中,并且已被证实对多种疾病有很好的预防和治疗作用。以往关于富氢水或富氢生理盐水的研究多是针对其医学效应的介绍,通过介绍富氢水或富氢生理盐水干预后体内氢浓度的变化情况、对正常生理功能的影响、对疾病的保护作用以及对肠道菌群的影响,并对不同动物实验中富氢水或富氢生理盐水的氢气浓度、干预介入时间点、干预时长以及每次干预剂量进行阐述,以期为氢分子基础研究提供一定的理论依据。     

Controversial significance of early S100B levels after cardiac surgery

Background  

The brain-derived protein S100B has been shown to be a useful marker of brain injury of different etiologies. Cognitive dysfunction after cardiac surgery using cardiopulmonary bypass has been reported to occur in up to 70% of patients. In this study we tried to evaluate S100B as a marker for cognitive dysfunction after coronary bypass surgery with cardiopulmonary bypass in a model where the inflow of S100B from shed mediastinal blood was corrected for.     

Inflammatory cytokines and soluble receptors after coronary artery bypass grafting

Much interest has been focused on the overexpression of proinflammatory cytokines, but studies on their soluble receptors are rare. For a comprehensive picture of cytokine activation in cardiac surgery, a combination of cytokines and the corresponding soluble receptor concentration should be determined. Blood samples were collected from the radial artery and coronary sinus perioperatively in ten patients undergoing coronary artery bypass grafting with cardiopulmonary bypass. TNF-alpha, IL-6, sTNFRI, sTNFRII, and sIL-6R levels in the plasma were determined. Systemic TNFRI, TNFRII and IL-6 increased significantly after reperfusion to the myocardium, while perioperative systemic sIL-6r levels were similar. Arterial and sinus levels of TNFRI, TNFRII and sIL-6r were similar before cardiopulmonary bypass. Five minutes after reperfusion to the myocardium, higher sinus TNFRI and TNFRII and lower sinus sIL-6R levels were observed as compared to the arterial levels. The myocardium release of sTNFRI (r=0.57, P=0.089) and sTNFRII (r=0.64, P=0.047) positively correlated with the change of cardiac index after cardiopulmonary bypass. Myocardium releases sTNFRI and sTNFRII after ischaemic-reperfusion injury, and this may be of benefit to cardiac performance. sIL-6R is constantly being produced in areas other than the myocardium, while sIL-6R levels are reduced by consumption in the myocardium after ischaemic-reperfusion injury.     

Metabolic cardioprotection by pyruvate: recent progress

Pyruvate, a natural metabolic fuel and antioxidant in myocardium and other tissues, exerts a variety of cardioprotective actions when provided at supraphysiological concentrations. Pyruvate increases cardiac contractile performance and myocardial energy state, bolsters endogenous antioxidant systems, and protects myocardium from ischemia-reperfusion injury and oxidant stress. This article reviews and discusses basic and clinically oriented research conducted over the last several years that has yielded fundamental information on pyruvate's inotropic and cardioprotective mechanisms. Particular attention is placed on pyruvate's enhancement of sarcoplasmic reticular Ca2+ transport, its antioxidant properties, and its ability to mitigate reversible and irreversible myocardial injury. These research efforts are establishing the essential foundation for clinical application of pyruvate therapy in numerous settings including cardiopulmonary bypass surgery, cardiopulmonary resuscitation, myocardial stunning, and cardiac failure.     

Effect of 1-(chloromethyl)silatrane on the alteration of the blood elements during extracorporeal circulation

The damaging effect of cardiopulmonary bypass on blood elements and the possibility of its correction with 1-(chloromethyl) silatrane have been investigated. Cardiopulmonary bypass is a powerful damaging factor producing a wide range of effects including the activation of lipid peroxidation, reduction of erythrocyte membrane resistance to ultra-sound, destruction of blood elements and appearance of hemoglobin in the plasma (hemolysis). A possible mechanism of cardiopulmonary bypass damaging effect on blood elements is suggested. The use of 1-(chloromethyl)silatrane drastically increases the resistance of blood element membranes to injury, which seems promising for the drug application during cardiopulmonary bypass.     

The protective role of neocuproine against cardiac damage in isolated perfused rat hearts

The effect of neocuproine on cardiac injury was studied using retrogradely perfused isolated rat hearts in two experimental systems. In the first system, where hydrogen peroxide-induced damage was studied, neocuproine at the range of 40-175 microM provided protection at the level of 70-85%, as demonstrated by the reduced loss in the peak systolic pressure (P), in +dP/dt and in -dP/dt. In the second system, where ischemia/reperfusion-induced arrhythmias were studied, neocuproine (42 microM) provided a marked protection against cardiac injury as demonstrated by the lowering of the incidence in irreversible ventricular fibrillation, by decreasing the duration of ventricular fibrillation and by the concomitant increase of the duration of normal sinus rhythm, and by improving the post-ischemic recovery of P, +dP/dt and -dP/dt. Free radicals have already been implicated as causative agents in cardiac injury resulting from either hydrogen peroxide or ischemia followed by reperfusion. Additionally, iron and copper have already been shown to drastically exacerbate the injurious effects of free radicals. Thus, the results reported here with neocuproine, a highly effective chelator for both iron and copper, as well as with adventitious copper and with the combination of neocuproine and copper, are in accord with the mediatory role of transition metals in enhancing the deleterious effects induced by free radicals.     

心肺复苏后脑缺血再灌注损伤治疗理念及相关动物模型研究进展

心肺复苏后脑缺血再灌注损伤是一个复杂的病理生理变化过程,由多种损伤机制共同参与。自心肺复苏后系统性综合治疗和亚低温治疗在临床上广泛应用后,目前已有多种治疗理念在不同的动物实验和动物模型基础上被提出,包括缺血预处理、药物预处理、缺血后处理、和药物后处理,而后吸入麻醉药对心肺复苏后脑缺血再灌注损伤的保护作用受到了人们的重视,而七氟烷后处理已经成为目前研究的热点之一。为了指导临床上的心肺复苏,人们一直在利用不同动物模型,探究不同保护方法,寻找有效的脑保护药物。而各种治疗理念的提出均是建立在动物实验和动物模型的基础上,窒息性心肺复苏模型模拟围术期气道梗阻,能较贴切的复制临床上由窒息引起的心肺复苏后脑损伤,对将来指导临床复苏具有重大意义。     

Angiotensin IV protects against angiotensin II-induced cardiac injury via AT4 receptor

Angiotensin II (Ang II) is an important regulator of cardiac function and injury in hypertension. The novel Ang IV peptide/AT4 receptor system has been implicated in several physiological functions and has some effects opposite to those of Ang II. However, little is known about the role of this system in Ang II-induced cardiac injury. Here we studied the effect of Ang IV on Ang II-induced cardiac dysfunction and injury using isolated rat hearts, neonatal cardiomyocytes and cardiac fibroblasts. We found that Ang IV significantly improved Ang II-induced cardiac dysfunction and injury in the isolated heart in response to ischemia/reperfusion (I/R). Moreover, Ang IV inhibited Ang II-induced cardiac cell apoptosis, cardiomyocyte hypertrophy, and proliferation and collagen synthesis of cardiac fibroblasts; these effects were mediated through the AT4 receptor as confirmed by siRNA knockdown. These findings suggest that Ang IV may have a protective effect on Ang II-induced cardiac injury and dysfunction and may be a novel therapeutic target for hypertensive heart disease.