ATP-sensitive potassium channels:novel potential roles in Parkinson's disease

The ATP-sensitive potassium（KATP）channels which extensively distribute in diverse tissues（e.g.vascular smooth muscle,cardiac cells,and pancreas）are well-established for characteristics like vasodilatation,myocardial protection against ischemia,and insulin secretion.The aim of this review is to get insight into the novel roles of KATPchannels in Parkinson＇s disease（PD）,with consideration of the specificities KATPchannels in the central nervous system（CNS）, such as the control of neuronal excitability,action potential,mitochondrial function and neurotransmitter release.

Effect of G_(αq/11) Protein and ATP-sensitive Potassium Channels on Ischemic Preconditioning in Rat Hearts

Objectives To investigate the effect of Gαq/11 signaling pathway and ATP-sensitive potassium channel ( KATP channel ) on ischemic preconditioning (IPC) protection in rat hearts. Methods Two series of experiments were performed in Wistar rat hearts. In the first series of experiment, ischemic preconditioning was induced by left anterior descending occlusion (three, 5 min episodes separated by 5 min of reperfusion), ischemia-reperfusion injury was induced by 30 min coronary artery occlusion followed by 90 min reperfusion. Hemodynamics, infarct size and scores of ventricular arrhythmias were measured. The expression of Gαq/11 protein in the heart was measured by Western blot analysis in the second series. Results Ischemic preconditioning rats showed decreased infarct size and scores of ventricular arrhythmia vs non-IP control rats. The effect of IPC was significantly attenuated by glibenclamide (1 mg/kg, ip), a nonselective KATP channel inhibitor. IPC caused a significant increase in the expression of Gαq/11 protein. Conclusions Activations of Gαq/11 signal pathway and KATP channel played significant roles in the classical cardioprotection of ischemic precon-ditioning rat heart and might be an important mechanism of signal transduction pathway during the ischemic preconditioning.

Regulation of adenosine triphosphate-sensitive potassium channels suppresses the toxic effects of amyloid-beta peptide(25-35)

In this study, we treated PC12 cells with 0-20 μM amyloid-β peptide （25-35） for 24 hours to induce cytotoxicity, and found that 5-20 μM amyloid-β peptide （25-35） decreased PC12 cell viability, but adenosine triphosphate-sensitive potassium channel activator diazoxide suppressed the decrease in PC12 cell viability induced by amyloid-β peptide （25-35）. Diazoxide protected PC12 cells against amyloid-β peptide （25-35）-induced increases in mitochondrial membrane potential and intracellular reactive oxygen species levels. These protective effects were reversed by the selective mitochondrial adenosine triphosphate-sensitive potassium channel blocker 5-hydroxydecanoate. An inducible nitric oxide synthase inhibitor, Nw-nitro-L-arginine, also protected PC12 cells from amyloid-β peptide （25-35）-induced increases in both mitochondrial membrane potential and intracellular reactive oxygen species levels. However, the H202-degrading enzyme catalase could not reverse the amyloid-β peptide （25-35）-induced increase in intracellular reactive oxygen species. A 24-hour exposure to amyloid-13 peptide （25-35） did not result in apoptosis or necrosis, suggesting that the increases in both mitochondrial membrane potential and reactive oxygen species levels preceded cell death. The data suggest that amyloid-β peptide （25-35） cytotoxicity is associated with adenosine triphosphate-sensitive potassium channels and nitric oxide. Regulation of adenosine triphosphate-sensitive potassium channels suppresses PC12 cell cytotoxicity induced by amyloid-β peptide （25-35）.

Adenosine triphosphate-sensitive potassium channel opener protects PC12 cells against hypoxia-induced apoptosis through PI3K/Akt and Bcl-2 signaling pathways

Although previous studies have shown the neuroprotective effects of the adenosine triphosphate （ATP）-sensitive potassium （KATP） channel opener against ischemic neuronal damage, little is known about the mechanisms involved. Phosphatidylinositol-3 kinase （PI3K）/v-akt murine thy-moma viral oncogene homolog （Akt） and Bcl-2 are thought to be important factors that mediate neuroprotection. The present study investigated the effects of KATP openers on hypoxia-induced PC12 cell apoptosis, as well as mRNA and protein expression of Akt and Bcl-2. Results demon-strated that pretreatment of PC12 cells with pinacidil, a KATP opener, resulted in decreased PC12 cell apoptosis following hypoxia, as detected by Annexin-V fluorescein isothiocyanate/ propidium iodide double staining flow cytometry. In addition, mRNA and protein expression of phosphorylated Akt （p-Akt） and Bcl-2 increased, as detected by immunofluorescence, Western blot analysis, and reverse-transcription polymerase chain reaction. The protective effect of this preconditioning was attenuated by glipizide, a selective KATP blocker. These results demonstrate for the first time that the protective mechanisms of KATP openers on PC12 cell apoptosis following hypoxia could result from activation of the PI3K/Akt signaling pathway, which further activates expression of the downstream Bcl-2 gene.

Protective effects of pinacidil hyperpolarizing cardioplegia on myocardial ischemia reperfusion injury by mitochondrial KATP channels

Background Many studies have indicated that hyperpolarizing cardioplegia is responsible for myocardial preservation and researchers have suggested that the adenosine triphosphate-sensitive potassium channels （KATe） were the end effectors of cardio-protection. But whether mitochondrial KATe plays an important role in hyperpolarizing cardioplegia is not apparent. The present study investigated the effect of hyperpolarizing cardioplegia containing pinacidil （a nonselective KATe opener） on ischemia/repeffusion injury in rat hearts, especially the role of mitochondrial KATe in pinacidil hyperpolarizing cardioplegia. Methods Sprague-Dawley rat hearts were Langendorff-perfused for 20 minutes with Krebs-Henseleit buffer at 37℃ before equilibration. Cardiac arrest was then induced in different treatments： there was no arrest and ischemia in the normal group, the control group were arrested by clamping the aorta, depolarizing caidioplegia （St. Thomas solution containing 16 mmol/L KCI） and hyperpolarizing cardioplegia groups used St. Thomas solution containing 0.05 mmol/L pinacidil and 5 mmol/L KCI to induce cardiac arrest in group hyperkalemic and group pinacidil, in group hyperkalemic ＋ 5-hydroxydecanote （5HD） and Pinacidil ＋ 5HD, 5HD （0.1 retool/L） was added to the above two solutions to block mitochondria KATe channels. Global ischemia was then administrated for 40 minutes at 37℃, followed by 30 minutes of reperfusion. At the end of equilibration and reperfusion, hemodynamics, ultrastructure, and mitochondrial function were measured. Results In the control group, ischemia/reperfusion decreased the left ventricular developed pressure, heart rate, coronary flow, mitochondrial membrane potential, impaired mitochondrial respiratory function, increased reactive oxygen species and left ventricular end diastolic pressure. Damage to myocardial ultrastructure was also evident. Both depolarized arrest and especially hyperpolarized cardioplegia significantly reduced these lesions. 5HD partially blocked the beneficial effects of pinacidil cardioplegia but showing no effects on hyperkalemic arrest. Conclusions Pinacidil cardioplegia provides better cardioprotection with preservation of hemodynamics, ultrastructure, and mitochondrial function than traditional cardioplegia. The mitochondria KATe channels may play an important role in the protection mechanism.

Beneficial effects of adenosine triphosphate-sensitive K^+ channel opener on liver ischemia/reperfusion injury

AIM: To investigate the effect of diazoxide administration on liver ischemia/reperfusion injury.

Regulatory role of mitochondria in oxidative stress and atherosclerosis

Mitochondrial physiology and biogenesis play a crucial role in the initiation and progression of cardiovascular disease following oxidative stress-induced damage such as atherosclerosis(AST).Dysfunctional mitochondria caused by an increase in mitochondrial reactive oxygen species(ROS)production,accumulation of mitochondrial DNA damage,and respiratory chain deficiency induces death of endothelial/smooth muscle cells and favors plaque formation/rupture via the regulation of mitochondrial biogenesis-related genes such as peroxisome proliferator-activated receptorγcoactivator(PGC-1),although more detailed mechanisms still need further study.Based on the effect of healthy mitochondria produced by mitochondrial biogenesis on decreasing ROS-mediated cell death and the recent finding that the regulation of PGC-1 involves mitochon- drial fusion-related protein(mitofusin),we thus infer the regulatory role of mitochondrial fusion/fission balance in AST pathophysiology.In this review,the first section discusses the possible association between AST-inducing factors and the molecular regulatory mechanisms of mitochondrial biogenesis and dynamics,and explains the role of mitochondria-dependent regulation in cell apoptosis during AST development. Furthermore,nitric oxide has the Janus-faced effect by protecting vascular damage caused by AST while being a reactive nitrogen species(RNS)which act together with ROS to damage cells.Therefore,in the second section we discuss mitochondrial ATP-sensitive K+ channels,which regulate mitochondrial ion transport to maintain mitochondrial physiology,involved in the regulation of ROS/RNS production and their influence on AST/cardiovascular diseases(CVD).Through this review,we can further appreciate the multi-regulatory functions of the mitochondria involved in AST development.The understanding of these related mechanisms will benefit drug development in treating AST/CVD through targeted biofunctions of mitochondria.

Iptakalim,an ATP-sensitive potassium channel opener,confers neuroprotection against cerebral ischemia/reperfusion injury in rats by protecting neurovascular unit cells

Objective:To investigate the role of iptakalim,an ATP-sensitive potassium channel opener,in transient cerebral ischemia/reperfusion (I/R) injury and its involved mechanisms.Methods:Intraluminal occlusion of middle cerebral artery (MCAO) in a rat model was used to investigate the effect of iptakalim at different time points.Infarct volume was measured by staining with 2,3,5-triphenyltetrazolium chloride,and immunohistochemistry was used to evaluate the expressions of Bcl-2 and Bax.In vitro,neurovascular unit (NVU) cells,including rat primary cortical neurons,astrocytes,and cerebral microvascular endothelial cells,were cultured and underwent oxygen-glucose deprivation (OGD).The protective effect of iptakalim on NVU cells was investigated by cell viability and injury assessments,which were measured by 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide and release of lactate dehydrogenase.Caspase-3,Bcl-2 and Bax mRNA expressions were evaluated by real-time polymerase chain reaction (PCR).Results:Administration of iptakalim 0 or 1 h after reperfusion significantly reduced infarct volumes,improved neurological scores,and attenuated brain edema after cerebral I/R injury.Iptakalim treatment (0 h after reperfusion) also reduced caspase-3 expression and increased the ratio of Bcl-2 to Bax by immunohistochemistry.Iptakalim inhibited OGD-induced cell death in cultured neurons and astrocytes,and lactate dehydrogenase release from cerebral microvascular endothelial cells.Iptakalim reduced mRNA expression of caspase-3 and increased the ratio of Bcl-2 to Bax in NVU cells.Conclusions:Iptakalim confers neuroprotection against cerebral I/R injury by protecting NVU cells via inhibiting of apoptosis.

Ischemia/reperfusion injury and cardioprotective mechanisms:Role of mitochondria and reactive oxygen species

Reperfusion therapy must be applied as soon as possible to attenuate the ischemic insult of acute myocardial infarction(AMI).However reperfusion is responsible for additional myocardial damage,which likely involves opening of the mitochondrial permeability transition pore(mPTP).In reperfusion injury,mitochondrial damage is a determining factor in causing loss of cardiomyocyte function and viability.Major mechanisms of mitochondrial dysfunction include the long lasting opening of mPTPs and the oxidative stress resulting from formation of reactive oxygen species(ROS).Several signaling cardioprotective pathways are activated by stimuli such as preconditioning and postconditioning,obtained with brief intermittent ischemia or with pharmacological agents.These pathways converge on a common target,the mitochondria,to preserve their function after ischemia/reperfusion.The present review discusses the role of mitochondria in cardioprotection,especially the involvement of adenosine triphosphate-dependent potassium channels,ROS signaling,and the mPTP.Ischemic postconditioning has emerged as a new way to target the mitochondria,and to drastically reduce lethal reperfusion injury.Several clinical studies using ischemic postconditioning during angioplasty now support its protective effects,and an interesting alternative is pharmacological postconditioning.In fact ischemic postconditioning and the mPTP desensitizer,cyclosporine A,have been shown to induce comparable protection in AMI patients.

Structure of an ATP-sensitive potassium channel(K_(ATP))

Subject Code:C05 With the support by the National Natural Science Foundation of China,the collaborative research team led by Prof.Chen Lei(陈雷)at the State Key Laboratory of Membrane Biology,Institute of Molecular Medicine,Peking-Tsinghua Center for Life Sciences,Beijing Key Laboratory of Cardiometabolic

Effect of mitochondrial K_(ATP) channel on voltage gated K^+ channel in 24 hour-hypoxic human pulmonary artery smooth muscle cells

Background Hypoxic pulmonary hypertension (HPH) is initiated by inhibition of O 2 sensitive, voltage gated (Kv) channels in pulmonary arterial smooth muscle cells (PASMCs) The mechanism of hypoxic pulmonary hypertension has not yet been fully elucidated The mitochondrial ATP sensitive K + channel (MitoK ATP ) is extremely sensitive to hypoxia, and is a decisive factor in the control of mitochondrial membrane potential (ΔΨ m) This study investigated the changes of cell membrane potential and Kv channel in cultured human pulmonary artery smooth muscle cell (hPASMC) exposed to 24 hour hypoxia, and explored the role of MitoK ATP and ΔΨ m in this condition Methods Fresh human lung tissues were obtained from the patients undergoing a chest operation hPASMCs were isolated, cultured, and divided into 6 groups: ① control group, cultured under normoxia; ② diazoxide group, cultured in normoxia with diazoxide, an opener of MitoK ATP ; ③ 5 HD group, cultured in normoxia with sodium 5 hydroxydecanoate (5 HD), an antagonist of MitoK ATP ; ④ 24 hour hypoxia group; ⑤ 24 hour hypoxia + diazoxide group; and ⑥ 24 hour hypoxia + 5HD group Whole cell patch clamp technique was used to trace the cell membrane K + currents The expressions of cell membrane Kv1 5 mRNA and protein were determined by RT PCR and Western blot technique, respectively The relative changes in mitochondrial potential were tested with rhodamine fluorescence (R 123) technique Results After exposure to diazoxide for 24 hours, the intensity of R 123 fluorescence in normoxic hPASMCs was significantly increased compared with control group ( P <0 05), but there were no significant changes in these tests after the hPASMCs had been exposed to 5 HD for 24 hours Twenty four hour hypoxia or 24 hour hypoxia + diazoxide could markedly increase the intensity of R 123 fluorescence in hPASMC and the changes were more significant in 24 hour hypoxia +diazoxide group than in 24 hour hypoxia group ( P <0 05) although 5 HD could partly weaken the effect of 24 hour hypoxia on the intensity of R 123 fluorescence After exposure to diazoxide for 24 hours, the cell membrane K + currents and the expression of cell membrane Kv1 5 mRNA and protein in normoxic hPASMCs were significantly decreased compared with control group ( P <0 05), but there were no significant changes in these tests after the hPASMCs had been exposed to 5 HD for 24 hours Also, 24 hour hypoxia or 24 hour hypoxia + diazoxide decreased the cell membrane K + currents and the expression of Kv1 5 mRNA and protein ( P <0 05) but the changes were more significant in 24 hour hypoxia + diazoxide group than in 24 hour hypoxia group ( P <0 05) Again, 5 HD could partly weaken the inhibitory effect of 24 hour hypoxia on the cell membrane K + currents and the expression of Kv1 5 mRNA or protein ( P <0 05) Conclusions The opening of MitoK ATP followed by a depolarization of ΔΨ m in hypoxia might contribute to the alterations in the expression of cell membrane Kv1 5 mRNA and protein leading to change in the cell membrane potential of hypoxic hPASMCs This might be a mechanism of the development of hypoxic pulmonary hypertension

二氮嗪对长时程低温保存大鼠心脏Fas／FasL蛋白表达的影响

本文旨在研究线粒体ATP敏感性钾(mitochondrial ATP-sensitive potassium channel, mitoKATP)通道开放剂二氮嗪(diazoxide,DE)对离体长时程低温保存的大鼠心脏促凋亡蛋白 Fas 和 FasL 表达的影响。利用 Langendorff 离体大鼠心脏灌注法,观察心脏在4 oC 含或不含(对照组) DE 的Celsior 保存液保存8 h 后,复灌期心脏作功量(rate-pressure product, RPP)变化情况,采用原位末端标记(TdT-mediated dUTP nick end labeling, TUNEL)染色法检测心肌细胞凋亡和免疫组织化学方法检测Fas 和FasL蛋白表达情况。结果显示,在Celsior 保存液中加入DE (30 μmol/L),复灌期RPP 的恢复率在多个复灌时间点上优于对照组;同时可降低长时程低温保存心脏心肌细胞凋亡指数,减少 Fas 和FasL 蛋白的表达。DE 的上述作用可被 mitoKATP 通道特异性阻断剂5- 羟基葵酸盐(5-hydroxydecanoate, 5-HD)所取消。以上结果提示,DE 可能通过激活 mitoKATP 通道来减少Fas 和FasL 蛋白表达,从而减轻大鼠心肌缺血 / 再灌注损伤后的心肌细胞凋亡。

七氟醚预处理对大鼠海马脑片缺氧无糖损伤的保护作用:线粒体K_(ATP)通道的作用

利用离体海马脑片缺氧无糖(oxygen-glucose deprivation,OGD)损伤模型,探讨七氟醚预处理对神经细胞的保护作用及陔作用与线粒体内膜ATP敏感钾通道(mitochondrial ATP-sensitive potassium channels,mitoK_(ATP)channels)的关系,随机将脑片用2%、4%、6%七氟醚,以及6%七氟醚复合mitoK_(ATP)通道阻滞剂5-羟基奎酸盐(5-hydroxydecanoic acid,5-HD)预处理30min,观察OGD损伤14min复氧1h期间顺向群峰电位(orthodromic population spike,OPS)的变化,并应用透射电镜观察细胞超微结构的改变。结果表明,与单纯OGD组相比,七氟醚预处理可使海马脑片OPS消失时间明显延长(P＜0．01),使OPS明显恢复,其中4%、6%七氟醚组的恢复率均为71．4%(P＜0．05 vs OGD),相应恢复程度为(61．0±42．3)%和(78．7±21．1)%(P＜0．01),而且6%七氟醚的保护作用可被5-HD取消。OGD组的海马CA1区锥体细胞明显水肿,核膜皱缩、破裂,染色质聚集,线粒体肿胀畸形,嵴断裂或消失,而4%和6%七氟醚组仅见海马CA1区锥体细胞轻度水肿,核膜皱缩不明显,染色质均匀,线粒体轻度肿胀。结果提示,七氟醚预处理对大鼠海马脑片OGD损伤有一定的保护作用,且七氟醚对神经细胞的保护作用与激活mitoK_(ATP)通道有关。

缺氧肺动脉平滑肌细胞中线粒体ATP敏感钾通道开放对细胞色素C的分布及细胞增殖的作用

为了探讨线粒体ATP敏感钾通道(mitochondrial ATP-sensitive K^+channel,mitoK_(ATP))和线粒体膜电位(ΔΨm)在细胞缺氧信号转导中的作用以及对缺氧肺动脉平滑肌细胞中细胞色素C在细胞内的分布及细胞增殖的影响,本实验将人肺动脉平滑肌细胞进行常氧或24h缺氧培养,并将标本分为六组：(1)对照组；(2)mitoK_(ATP)开放剂diazoxide组；(3)mitoK_(ATP)阻断剂5-HD组：(4)24h缺氧组：(5)24h缺氧+diazoxide组；(6)24h缺氧+5．HD组。利用激光共聚焦显微镜成像法检测ΔΨm：线粒体/胞浆成分分离试剂盒(BioVision)分离线粒体和胞浆成分后,Western blot检测两者细胞色素C：Western blot检测细胞中caspase-9的蛋白表达量；MTT法及PI染色后流式细胞仪检测细胞增殖情况。结果显示：(1)diazoxide作用24h后,R-123荧光明显增强,胞浆细胞色素C与线粒体细胞色素C的比值明显降低,caspase-9的蛋白表达显著减少,细胞增殖明显增多、凋亡减少,与正常对照组相比较,均P＜0．05；而5-HD作用24h与正常对照组比较,上述指标无明显变化(P＞0．05)。(2)缺氧24h组,结果与diazoxide组相似,R-123荧光明显增强,胞浆细胞色素C与线粒体细胞色素C的比值明显降低,caspase-9的蛋白表达显著减少,细胞增殖明显增多、凋亡减少,与正常对照组相比较,均P＜0．05：24h缺氧+diazoxide组与缺氧组相比较,R-123荧光明显增强,胞浆细胞色素C与线粒体细胞色素C的比值明显降低,caspase-9的蛋白表达显著减少,细胞增殖明显增多、凋亡减少(P＜0．05)；而24h缺氧+5-HD组与缺氧组比较,R-123荧光明显降低,胞浆细胞色素C与线粒体细胞色素C的比值明显升高,caspase-9的蛋白表达显著增加,细胞增殖明显减少、凋亡增多(P＜0．05)。上述实验结果提示,缺氧可以引起mitoK_(ATP)的开放以及ΔΨm的去极化,并进而抑制细胞色素C从线粒体释放到胞浆,抑制线粒体凋亡途径,从而参与并影响肺动脉高压的发生、发展。

线粒体钾通道参与葛根素抗心肌细胞缺氧/复氧损伤的作用

目的:探讨线粒体ATP敏感性钾通道和线粒体钙激活钾通道在葛根素预处理抗心肌细胞缺氧/复氧损伤中的作用。方法:采用酶解分离大鼠心肌细胞复制心肌细胞缺氧/复氧模型,台盼蓝拒染法测定心肌细胞存活率;四甲基罗丹明乙酯(TMRE)孵育测定线粒体膜电位值;分离线粒体测定线粒体渗透性转换孔开放程度。结果:与缺氧/复氧组相比,葛根素(0.24mmol/L)预处理5min可明显增加心肌细胞的存活率,线粒体ATP敏感性钾通道抑制剂5-羟基癸酸(100μmol/L,预处理20min)或线粒体钙激活钾通道阻断剂paxilline(1μmol/L,预处理5min)均可拮抗葛根素的作用。葛根素预处理可明显减弱缺氧引起的线粒体膜电位的耗损,5-羟基癸酸和paxilline都能明显拮抗其作用。在分离心肌线粒体模型上,葛根素显著减弱CaCl2诱导的线粒体在A520处吸光度降低,其作用与单独应用线粒体渗透性转换孔抑制剂环孢菌素A相似;5-羟基癸酸和paxilline可拮抗葛根素的保护作用。结论:在大鼠分离心肌细胞模型或分离线粒体模型上,葛根素预处理具有抗缺氧/复氧损伤的作用,这种保护作用可能与其促进线粒体ATP敏感性钾通道和线粒体钙激活钾通道的开放,进而稳定线粒体膜电位,抑制线粒体渗透性转换孔开放有关。

ATP敏感性钾通道和线粒体通透转换孔参与白藜芦醇苷的心肌保护作用(英文)

目的探讨白藜芦醇苷(Poly)对大鼠缺血再灌注(I-R)心肌损伤的保护作用及其机制。方法应用Langendorff室技术制备离体大鼠心脏I-R损伤模型。雄性SD大鼠随机分为对照组、模型组、Poly(25, 50和75μmol.L-1)组、格列本脲(Gli) +Poly组、5-羟基癸酸(5-HD) +Poly组和苍术苷(Atr) +Poly组。对照组心脏由K-H液灌流110 min;模型组由K-H液灌流20 min后,停灌30 min,复灌60min;Poly组在I-R处理前用含不同浓度Poly的K-H液灌流10 min;Gli +Poly和5-HD+Poly组在I-R前分别用含Gli (10μmol.L-1)和5-HD(100μmol.L-1)的K-H液灌流5 min,再加入Poly (50μmol.L-1)灌流10 min;Atr +Poly组用含Poly(50μmol.L-1)K-H液灌流10 min及停灌30 min后,先用含Atr(20μmol.L-1)的K-H液灌流15 min,然后改用K-H液灌流。分别记录各组停灌前、停灌30 min和复灌60 min内的左心室舒张末压(LVEDP)、左心室舒张压(LVDP)、左心室等容期压力最大变化速率(±dp/dtmax)和冠脉流量(CF)等心功能指标。心脏复灌60 min后,用氯化三苯基四氮唑染色法测定心肌梗死面积,透射电镜下检测心肌超微结构变化。结果缺血前各组心功能参数无明显变化。与模型组相比,Poly可浓度依赖性地促进大鼠I-R后心功能的恢复,预防I-R损伤。复灌60 min后,Poly组大鼠心脏LVDP,±dp/dtmax和CF明显高于模型组;LVEDP则低于模型组;缺血前给予Poly(50μmol.L-1)10 min可明显减小I-R后心肌梗死面积,并改善心肌超微结构。Gli, 5-HD和Atr可阻断Poly对I-R心脏心功能参数和心肌梗死面积等的保护作用。结论 Poly具有明显的抗心肌I-R损伤作用,其心脏保护作用可能与其增加细胞膜和线粒体膜ATP敏感性钾通道开放和抑制线粒体通透转换孔开放有关。

一氧化氮和线粒体ATP敏感性钾通道介导血管紧张素转换酶抑制剂加强阈下预处理的作用

实验采用离体大鼠心脏Langendorff灌流模型,观察含巯基(卡托普利)和不含巯基(培哚普利拉)的两种血管紧张素转换酶抑制剂(angiotensin-convertingenzymeinhibitors,ACEI)对抗心肌缺血的作用,并探讨一氧化氮(nitricoxide,NO)和线粒体ATP敏感性钾通道(mitochondrialATP-sensitivepotassiumchannel,mitoKATPchannel)是否参与ACEI的心肌保护作用。结果表明:(1)给予大鼠心脏2min全心停灌和10min复灌作为阈下缺血预处理(subthresholdpreconditioning,sPC)、卡托普利或培哚普利拉单独使用,均不能改善长时间缺血复灌(缺血30min+复灌120min)引起的心肌损伤。(2)当两种ACEI分别和sPC联合使用时,与sPC组相比,缺血心脏在长时间缺血后的复灌期间左室舒张末压(leftventricularend-diastolicpressure,LVEDP)明显降低,左室发展压(leftventriculardevelopedpressure,LVDP)和冠脉流量明显增高,乳酸脱氢酶(lactatedehydrogenase,LDH)的释放量和心肌梗死面积明显低于sPC组。(3)利用NOS抑制剂L-NAME和mitoKATP通道的抑制剂5-HD灌流10min后,可明显抑制卡托普利/培哚普利拉和sPC联合使用引起的LVEDP降低,并使LVDP和冠脉流量降低,LDH的释放量和心肌梗死面积明显增高(P<0.05)。(4)sPC、卡托普利或培哚普利拉单独使用,心脏NO的产生增加。ACEI和sPC联合使用,与三者单独使用相比NO的浓度亦明显增高(P<0.05)。结果提示:含与不含巯基的ACEI与阈下缺血预处理联合使用均可使大鼠心脏功能明显改善,其心肌保护作用的机制可能通过NO途径,并和mitoKATP通道的激活有关。

mitoK_(ATP)通道经FOXO1-PGC1α通路调节后负荷过载小鼠心肌线粒体的代谢功能

目的:通过ATP依赖的钾离子通道(KATP)亚基-Kir6.2基因敲除小鼠(Kir6.2KO)模型,研究线粒体ATP敏感钾离子通道mitoKATP对心肌线粒体和代谢酶的调控机制。方法:分别将野生型小鼠(WT平行对照组)和Kir6.2KO小鼠(实验组)分为假手术、主动脉横断缩窄(TAC)2周和4周各3个亚组。检测并比较各组心功能、心肌能量代谢酶基因表达水平、信号转导通路中叉头框O1(FOXO1)和转录因子PGC1α水平、线粒体比面积和嵴间距。结果:与平行WT组相比较,TAC前Kir6.2KO小鼠心肌PGC1α表达水平有所降低、FOXO1略提高,能量代谢酶中链乙酰辅酶A脱氢酶(MCAD)、肉碱软脂酰基转移酶1(CPT1)和细胞色素C氧化酶亚单位III(COXIII)明显负表达,线粒体比面积和线粒体嵴间距有所增加(8.45%和3.11%),表现为有氧代谢能力降低,线粒体代偿增生。TAC后2周时,Kir6.2KO组的心肌线粒体比面积没有变化(8.75%vs0.14%),而嵴间距增加幅度低于WT组(18.27%vs11.65%),线粒体失代偿。TAC后4周时,Kir6.2KO组FOXO1和PGC1α的蛋白或mRNA水平均显著降低,下游能量代谢酶mRNA和蛋白显著负调表达,心肌线粒体比面积降低幅度更大(-8.45%vs-23.6%),嵴间距变化与WT组相同(6.60%vs7.17%),心功能障碍更为明显,有氧代谢功能衰竭。结论:阻断mitoKATP降低了心肌线粒体对负荷增加时的增生和正调能量代谢酶的反应能力,这与FOXO1-PGC1α信号通路的弱化有关。说明mitoKATP通过FOXO1-PGC1α信号通路调节负荷过载小鼠心肌线粒体增殖和能量代谢功能。

线粒体ATP敏感性钾通道不参与异丙酚预处理的心肌保护

目的 观察异丙酚预处理对心肌缺血再灌注损伤的保护机制是否通过开放线粒体ATP敏感性K通道 (KATP)。方法 非循环式Langendorff离体心脏灌注模型 ,灌注 1h ,常温下行全心缺血 2 5min ,恢复再灌注 30min。通过Maclab仪记录左室舒张末压 (LVEDP)、左室发展压 (LVDP)、左室压上升和下降最大速率 (±dp/dtmax)。测恢复再灌注末心肌组织MDA含量。结果 恢复再灌注 30min末 ,对照组(Con)、异丙酚预处理组 (PP)、5 HD +PP和 5 HD组心肌组织的MDA含量分别为 (113 7± 2 0 9)、(89 4± 13 7)、(91 9± 14 4 )和 (114 8± 19 7)nmol·10 0mg-1。PP组和 5 HD+PP组的心肌MDA含量都明显低于Con组和 5 HD组 (P<0 0 5 ) ;PP组和 5 HD +PP组两组间的MDA差异无显著性 (P >0 0 5 )。恢复再灌注 30min末 ,Con组、PP组、5 HD+PP组和 5 HD组的LVEDP值分别为基础值的 5 1、3 2、3 6和 5 3倍。PP组和 5 HD +PP组LVEDP值的上升幅度均明显低于Con组和 5 HD组 (P <0 0 5 ) ,而 5 HD +PP组和PP组之间差异无显著性 (P >0 0 5 )。结论 异丙酚预处理的心肌保护不是通过开放线粒体ATP敏感性K通道 。

线粒体K_(ATP)通道开放对培养成年大鼠心肌细胞PKC epsilon转位激活的影响

目的:探讨MitoKATP通道特异性开放剂二氮嗪(DZ)预处理对PKCε的转位激活作用及其与活性氧生成的关系。方法:采用免疫荧光和Westernblotting等技术检测培养成年大鼠心室肌细胞PKCε的表达。结果:①MitoKATP通道特异性开放剂DZ预处理能引起PKCε向心肌细胞肌丝样结构转位;②活性氧清除剂2-巯基丙酰氨基乙酸(MPG)能抑制DZ预处理引起的PKCε转位;③PKC特性抑制剂氯化白屈菜赤碱(CH)能完全消除DZ预处理引起的PKCε转位。结论:MitoKATP通道开放能够激活PKCε向肌丝样结构转位。MitoKATP通道开放过程中生成的ROS是引起PKCε转位激活的重要原因。