内皮型一氧化氮合酶的激活机制

内皮型一氧化氮合酶（eNOS)通常归为Ca^2 /钙调素（CaM)依赖性酶,它的活性受细胞内[Ca^2 ]及Ca^2 /CaM-eNOS复合物影响,但目前有证据表明切应力,雌激素,胰岛素可通过非Ca^2 依赖方式激活eNOS。除此之外,神经鞘脂（SIP）信号通路以及eNOS与囊泡蛋白-1（caveolin-1)。热休克蛋白90（HSP90）之间的相互作用也可影响eNOS活性,以上提示eNOS激活途径是复杂的。     

内皮型一氧化氮合酶在胚胎小鼠肾脏发育中的表达

目的观察妊娠不同时期胚胎小鼠肾脏发育不同阶段内皮型一氧化氮合酶（eNOS）的表达,探讨eNOS在胚胎小鼠肾脏早期发育中的意义。方法分别取胚龄13d（E13）、14d（E14）、15d（E15）、16d（E16）、18d（E18）组及新生组（P0）小鼠各10只,共6组。分别用免疫组化及免疫印迹方法对小鼠肾脏内eNOS表达进行定性、定量分析。结果（1）免疫组化结果显示：E14、E15组eNOS在生肾区呈阳性表达;E16组生肾区表达减弱,肾近端小管呈强阳性表达,同时远端小管及肾脏小动脉内皮也有阳性表达;E18组、P0组近端小管呈强阳性表达,远端小管呈阳性表达,髓质中的集合管eNOS表达弱阳性,而致密斑呈阴性表达。（2）免疫印迹结果显示：E14组肾脏eNOS含量较少,随后逐渐增多,PD0组eNOS含量最多。结论（1）eNOS在小鼠肾脏第14d开始呈阳性表达,以后含量逐渐升高,出生时含量最高。（2）eNOS表达部位从生肾区开始,以后其表达逐渐减弱甚至消失,而肾近端小管、远端小管的表达晚于生肾区,且呈逐渐增强趋势,至出生时达到最强。这一结果表明eNOS在胚胎小鼠肾脏发育的早期阶段起重要调节作用。     

内含子源性microRNA对内皮型一氧化氮合酶表达及血管内皮细胞增殖的作用

前期工作表明,内皮型一氧化氮合酶(endothelial nitric oxide synthase,eNOS)第4内含子中的27碱基 (nucleotide,nt)重复序列是27-nt microRNA的来源,并对eNOS具有重要的调节作用．为进一步探讨该内含子源性27-nt microRNA参与调节eNOS表达的分子机制及其在内皮细胞增殖中的可能作用,通过构建27-nt microRNA高表达质粒,用脂质体将该质粒转染人脐静脉内皮细胞(human umbilical vein endothelial cells,HUVEC),Western blot和RT-PCR检测该细胞系中eNOS蛋白和mRNA表达情况以及胞核转录因子的表达改变,并观察HUVEC增殖的变化情况．结果发现：27-nt microRNA 高表达能降低eNOSmRNA的水平和蛋白质表达;同时对转录因子Sp1、Ap1的蛋白质表达也产生了不同程度的抑制作用;转染后细胞的生长速度比未转染的细胞明显减慢,尤其转染了27-nt microRNA的双倍长度突变体(pEGP-mut-54nt-mi)质粒的HUVEC,其生长倍增时间比正常对照组明显延长达49.4%．结果表明,27-nt microRNA明显抑制eNOS蛋白及其mRNA表达,同时 HUVEC增殖受到明显抑制,转录因子Sp1 和Ap1 在27-nt microRNA对eNOS的表达调节中起重要作用．实验提示,内含子源性microRNA与转录因子共同参与对内皮细胞增殖及其相关性基因的表达调节,可能是众多真核细胞中某些疾病相关性基因表达自我调节的重要机制之一．     

一氧化氮合酶的作用机制

一氧化氮合酶的作用机制赵慧卿（安徽医科大学化学教研室,合肥２３００３２）关键词一氧化氮一氧化氮合酶８０年代以来,人们发现一氧化氮在许多生理过程中起着十分重要的作用［１］。在血管内皮细胞中,一氧化氮可激活可溶性鸟苷酸环化酶（ｓＧＣ）,通过升高环鸟苷酸水...     

大鼠睾丸内皮型一氧化氮合酶表达的增龄变化

为研究雄性大鼠睾丸在发生、发育和衰老过程中内皮型一氧化氮合酶(eNOS)在生精功能中的作用及其变化规律，本实验采用了免疫组织化学染色及体视学图像分析等方法，对生后1d至生后24月龄大鼠睾丸eNOS表达的变化进行了系统研究，并统计测量了阳性血管内皮细胞及间质细胞面密度的变化。结果表明：生后1d至2周龄eNOS阳性表达极少；3周龄血管内皮细胞、间质细胞及精子细胞均出现了阳性表达；1月龄至18月龄生精小管靠近管腔的精子细胞也呈阳性，阳性血管内皮细胞、间质细胞数目差异显著；24月龄血管内皮细胞、间质细胞eNOS大量表达，部分生精细胞也有表达。本结果提示一氧化氮参与精子的生成及睾酮的分泌过程，衰老时eNOS阳性表达显著增加，这种变化可能会抑制睾酮的分泌，最终会影响睾丸的生精功能[动物学报49(3)：339—345，2003]。     

两种方法检测胚胎小鼠内皮型一氧化氮合酶结果的相关性分析

本实验同时应用免疫印迹法及流式细胞仪法对胚胎小鼠肾脏内皮型一氧化氮合酶（eNOS）的蛋白含量进行检测,旨在探讨两种方法检测结果之间是否有相关性。     

内皮型一氧化氮合酶基因多态性与高血压合并脑 梗塞的关系

目的:探讨内皮型一氧化氮合酶(eNOS)基因894G/T多态性与原发性高血压(EH)合并脑梗塞(CI)的关系。方法:应用聚合酶链反应限制性片段长度多态性方法检测湖北地区汉族74例健康者(NT组)、103例原发性高血压无合并症者(EH组)及70例原发性高血压合并脑梗塞者(EH-CI组)的eNOS基因型;生化技术测定其血脂、一氧化氮代谢物(NOM)水平。结果:EH组及EH-CI组患者的T等位基因频率分别为0.224和0.321,均显著高于NT组(P<0.05);且两者之间的T等位基因频率差异显著性(P<0.05);EH-CI组中,GT+TT基因型者的舒张压显著高于GG基因型者(P<0.05),而NOM显著低于GG基因型者。结论:eNOS基因894位G/T多态性可能与汉族高血压病患者伴脑梗塞有关,该位点多态性可能使T等位基因携带者NOM减少,进而参与EH-CI发病。     

黄芪甲苷Ⅳ通过影响β-actin对内皮型一氧化氮合酶的调节作用

目的：研究黄芪甲苷Ⅳ（AS-Ⅳ）对体外培养脐静脉内皮细胞中内皮型一氧化氮合酶（eNOS）的调节作用及可能的机制。方法：培养人脐静脉内皮细胞系EA-Hy926,用AS-Ⅳ进行干预,同时给予或不给予骨架蛋白β—actin聚合稳定剂phalloidin,用免疫共沉淀方法检测eNOS与单体8-actin结合状态的变化,用L-3H．精氨酸转化为L-SH-瓜氨酸的同位素法测定eNOS活性,I^125环-磷酸鸟苷（cGMP）放射免疫法检测细胞内cGMP水平,Westernblotting方法检测细胞中eNOS和蛋白激酶B（Akt）磷酸化水平,总蛋白水平。结果：（1）AS-IV作用10min后,细胞内单体β—actin与eNOS的结合明显增加（P〈0．05或P〈0．01）,预先给予phalloidin显著抑制了AS．IV引起的两者结合的增加（P〈0．01）。②AS—IV明显增加了eNOS活性（P〈0．05）、cGMP含量（P〈0．01）、eNOSSer-1177磷酸化水平（P〈0．01）、AktSer-473磷酸化水平（P〈0．001）,预先给予phalloidin明显降低了AS—IV引起的eNOS活性（P〈0．05）、cGMP含量（P〈0．01）和磷酸化水平的增加（P〈0．01）,但对Akt的磷酸化没有影响。结论：单体β—actin与eNOS的结合在AS-IV激活eNOS的过程中起着不可或缺作用,其主要是通过促进Akt对eNOSSer—1177的磷酸化来实现的。     

神经型一氧化氮合酶的活性调控

一氧化氮是重要的信使分子,在生物体内参与众多生理及病理过程。生物体内存在着复杂的一氧化氮合酶活性调控机制以精确调控一氧化氮的生成。在神经系统中,一氧化氮主要由神经型一氧化氮合酶催化生成。神经型一氧化氮合酶的活性主要受到翻译后水平上钙离子和钙调蛋白的调控,其调控方式包括二聚化、多位点的磷酸化和去磷酸化,以及主要由PDZ结构域介导的蛋白质-蛋白质相互作用。一氧化氮本身对其合酶的活性具有负反馈调控作用。近年来的研究提示,细胞质膜上的脂筏微区在神经性一氧化氮合酶的活性调控中也起到重要的调节作用。     

新疆4个绵羊品种内皮型一氧化氮合酶基因第8外显子的PCR-SSCP鉴定

目的:对新疆4个绵羊品种内皮型一氧化氮合酶(eNOS)基因第8外显子的多态性进行鉴定。方法:利用PCR-SSCP和测序的方法对76只中国美利奴羊、51只无角陶赛特羊、57只萨福克羊、37只哈萨克羊共4个绵羊品种进行单核苷酸多态性(SNP)检测,并用生物信息学方法对检测出的SNP进行统计分析。结果:在中国美利奴羊、无角陶赛特羊、萨福克羊、哈萨克羊中共检测到AA、AB、BB等3种基因型,AA基因型的频率分别为0.0526、0.0980、0.1754和0.2973,BB基因型的频率分别为0.6316、0.1961、0.5614和0.1892,AB基因型的频率分别为0.3158、0.7059、0.2632和0.5135。通过测序,在eNOS基因第8外显子上发现了一个新的SNP位点(ss974768653),位于绵羊eNOS基因第8外显子142 bp处(A142G)。结论:中国美利奴羊和哈萨克羊的多态性位点(P0.05)处于Hardy-Weinberg平衡状态,萨福克和无角陶赛特羊的多态性位点(P0.05)不处于Hardy-Weinberg平衡状态。     

Flow-dependent regulation of endothelial nitric oxide synthase: role of protein kinases

Vascular endothelial cells are directly and continuously exposed to fluid shear stress generated by blood flow. Shear stress regulates endothelial structure and function by controlling expression of mechanosensitive genes and production of vasoactive factors such as nitric oxide (NO). Though it is well known that shear stress stimulates NO production from endothelial nitric oxide synthase (eNOS), the underlying molecular mechanisms remain unclear and controversial. Shear-induced production of NO involves Ca²⁺/calmodulin-independent mechanisms, including phosphorylation of eNOS at several sites and its interaction with other proteins, including caveolin and heat shock protein-90. There have been conflicting results as to which protein kinases—protein kinase A, protein kinase B (Akt), other Ser/Thr protein kinases, or tyrosine kinases—are responsible for shear-dependent eNOS regulation. The functional significance of each phosphorylation site is still unclear. We have attempted to summarize the current status of understanding in shear-dependent eNOS regulation. shear stress; nitric oxide; endothelial cells; protein kinases     

Conformational states and fluctuations in endothelial nitric oxide synthase under calmodulin regulation

Mechanisms that regulate nitric oxide synthase enzymes (NOS) are of interest in biology and medicine. Although NOS catalysis relies on domain motions and is activated by calmodulin (CaM) binding, the relationships are unclear. We used single-molecule fluorescence resonance energy transfer (FRET) spectroscopy to elucidate the conformational states distribution and associated conformational fluctuation dynamics of the two NOS electron transfer domains in an FRET dye-labeled endothelial NOS reductase domain (eNOSr) and to understand how CaM affects the dynamics to regulate catalysis by shaping the spatial and temporal conformational behaviors of eNOSr. In addition, we developed and applied a new imaging approach capable of recording three-dimensional FRET efficiency versus time images to characterize the impact on dynamic conformal states of the eNOSr enzyme by the binding of CaM, which identifies clearly that CaM binding generates an extra new open state of eNOSr, resolving more detailed NOS conformational states and their fluctuation dynamics. We identified a new output state that has an extra open conformation that is only populated in the CaM-bound eNOSr. This may reveal the critical role of CaM in triggering NOS activity as it gives conformational flexibility for eNOSr to assume the electron transfer output FMN-heme state. Our results provide a dynamic link to recently reported EM static structure analyses and demonstrate a capable approach in probing and simultaneously analyzing all of the conformational states, their fluctuations, and the fluctuation dynamics for understanding the mechanism of NOS electron transfer, involving electron transfer among FAD, FMN, and heme domains, during nitric oxide synthesis.     

Oxidized low density lipoprotein impairs endothelial progenitor cells by regulation of endothelial nitric oxide synthase

Oxidized low density lipoprotein (OxLDL) is one of the most important risk factors of cardiovascular disease. Here, we study the impact of OxLDL on endothelial progenitor cells (EPCs) and determine whether OxLDL affects EPCs by an inhibitory effect on endothelial nitric oxide synthase (eNOS). It was found that OxLDL decreased EPC survival and impaired its adhesive, migratory, and tube-formation capacities in a dose-dependent manner. However, all of the detrimental effects of OxLDL were attenuated by pretreatment of EPCs with lectin-like oxidized low density lipoprotein receptor (LOX-1) monoclonal antibody or l-arginine. Western blot analysis revealed that OxLDL dose-dependently decreased Akt phosphorylation and eNOS protein expression and increased LOX-1 protein expression. Furthermore, OxLDL caused a decrease in eNOS mRNA expression and an increase in LOX-1 mRNA expression. These data indicate that OxLDL inhibits EPC survival and impairs its function, and this action is attributable to an inhibitory effect on eNOS.     

Coordinated regulation of endothelial nitric oxide synthase activity by phosphorylation and subcellular localization

Endothelial nitric oxide synthase (eNOS) is regulated by multiple mechanisms including Ca(2+)/calmodulin binding, protein-protein interactions, phosphorylation, and subcellular locations. Emerging evidence suggests that these seemingly independent mechanisms may be closely correlated. In the present study, the interplay between membrane targeting and phosphorylation of eNOS was investigated by using various mutants designed to target specific subcellular locations or to mimic different phospho states. Phospho-mimicking mutations of wild-type eNOS at S635 and S1179 synergistically activated the enzyme. The targeted eNOS mutants to plasma membrane and Golgi complex exhibited higher NO production activities than that of a myristoylation-deficient cytosolic mutant. Phospho-mimicking mutations at S635 and S1179 rescued the activity of the cytosolic mutant and increased those of the plasma membrane- and Golgi-targeted mutants. In contrast, phospho-deficient mutations at these sites led to inactivation of eNOS. Unlike the other targeted mutants, the cytosolic eNOS mutant was unresponsive to cAMP, indicating that membrane association and phosphorylation are required for eNOS activation. These findings suggest that the coordinated interplay between phosphorylation and subcellular localization of eNOS plays an important role in regulating NO production in endothelial cells.     

Modulation of nitric oxide formation by endothelial nitric oxide synthase gene haplotypes

Nitric oxide (NO) is a major regulator of the cardiovascular system. However, the effects of endothelial nitric oxide synthase (eNOS) gene polymorphisms or haplotypes on the circulating concentrations of nitrite (a sensitive marker of NO formation) and cGMP are unknown. Here we examined the effects of eNOS polymorphisms in the promoter region (T-786C), in exon 7 (Glu298Asp), and in intron 4 (4b/4a) and eNOS haplotypes on the plasma levels of nitrite and cGMP. We hypothesized that eNOS haplotypes could have a major impact on NO formation. We genotyped 142 healthy subjects by PCR-RFLP. To assess NO formation, the plasma concentrations of nitrite and cGMP were determined using an ozone-based chemiluminescence assay and an enzyme immunoassay. Haplotypes were inferred using the PHASE 2.1 program. No significant differences were found in age, body mass index, systolic and diastolic arterial blood pressure, heart rate, total cholesterol, triglycerides, cGMP, or nitrite among the genotype groups for the three polymorphisms studied here (all p>0.05). Interestingly, the C-4b-Glu haplotype was associated with lower plasma nitrite concentrations than those found in the other haplotype groups (p<0.05), but not with different cGMP levels (p>0.05). These findings suggest that eNOS gene variants combined within a specific haplotype modulate NO formation, although individual eNOS polymorphisms probably do not have major effects.