膜上斑点洁显示人红细胞b5还原酶活性

人红细胞NADH-细胞色素b₅还原酶是使高铁血红蛋白还原的主要酶类, 其缺陷将导致遗传性高铁血红蛋白血症. 目前, 主要通过分光光度法测定b₅还原酶活性. 我们将b₅还原酶抗体点于硝酸纤维膜上, 以此捕获并富集红细胞胞浆b₅还原酶. 有b₅还原酶活性的斑点用噻唑蓝染色. 此法简单直观, 可用于b₅还原酶的定性和半定量测定, 为遗传性高铁血红蛋白血症的诊断提供了一种新的实验手段.     

Palmitoyl-CoA Elongation in Brain Microsomes: Dependence on Cytochrome b5 and NADH-Cytochrome b5 Reductase

Experiments were performed to demonstrate the involvement of electron transport system in fatty acid elongation in rat brain microsomes. Mercuric chloride and p-chloromercuriphenylsulfonate, inhibitors on NADH-cytochrome b5 reductase, at 32 microM inhibited NADH-supported palmitoyl-CoA elongation to 30 and 60% of control activity, respectively, whereas NADPH-supported palmitoyl-CoA elongation was unaffected by these mercurials. An antibody to rat liver NADH-cytochrome b5 reductase inhibited brain microsomal NADH-cytochrome b5 reductase activity and NADH-dependent palmitoyl-CoA elongation. Treatment of brain microsomes with trypsin diminished the cytochrome b5 content; NADH- and NADPH-cytochrome c reductase activities were significantly decreased, but the decrease in NADH-cytochrome b5 reductase activity was relatively small. Whereas essentially no incorporation of malonyl-CoA into palmitoyl-CoA was observed with trypsin-treated microsomes, addition of detergent-solubilized cytochrome b5 resulted in a recovery of fatty acid elongation. These results indicate the presence of an electron transport system, NADH-NADH-cytochrome b5 reductase-cytochrome b5-fatty acid elongation, in brain microsomes.     

NADH-细胞色素b5还原酶在大肠杆菌中的表达及其产物的纯化

为了探讨 NADH-细胞色素 b5还原酶基因突变引起遗传性高铁血红蛋白血症的分子病理机制 ,研究突变型 ( b5R)蛋白结构和功能的关系 ,用基因重组技术将野生型和突变型 ( C2 0 3Y) b5Rc DNA克隆于 p GEX- 2 T载体 ,在大肠杆菌 BL2 1中诱导表达 .Western印迹鉴定所表达的蛋白为GST- b5R融合蛋白 .应用谷胱甘肽 - Sepharose 4B亲和层析 ,还原型谷胱甘肽洗脱得到纯化的GST- b5R和 GST- b5RC2 0 3Y融合蛋白 .比较 GST- b5R和 GST- b5RC2 0 3Y酶活性及稳定性 ,发现野生型和突变型的酶活性基本相同 .但与野生型酶相比 ,突变型酶对热的稳定性较差 ,对胰蛋白酶更加敏感 .结果提示 ,C2 0 3Y突变可引起蛋白质二级结构改变而导致酶的稳定性下降 .     

对大肠杆菌中表达蛋白质精氨酸甲基转移酶5的几个缺失突变体的活性研究

蛋白质精氨酸甲基转移酶5(PRMT5)在细胞生长和信号转导方面是一个重要的调节因子,主要参与染色质重塑、RNA剪切、基因转录、细胞分化等过程.因此,对其结构和功能的研究就显得十分重要.通过大肠杆菌表达系统把全长基因PRMT5构建到pGEX-4T-1表达载体上,所得到GST标签的重组蛋白可溶性很低.为此,通过在其N端缺失不同氨基酸序列来增加其表达量,而且其中有一个缺失突变体的活性并没有发生改变.同时,还发现PRMT5 N端的前15个氨基酸对其甲基转移酶的催化活性很重要.     

Effects of Membrane Mimetics on Cytochrome P450-Cytochrome b5 Interactions Characterized by NMR Spectroscopy

Mammalian cytochrome P450 (P450) is a membrane-bound monooxygenase whose catalytic activities require two electrons to be sequentially delivered from its redox partners: cytochrome b₅ (cytb₅) and cytochrome P450 reductase, both of which are membrane proteins. Although P450 functional activities are known to be affected by lipids, experimental evidence to reveal the effect of membrane on P450-cytb₅ interactions is still lacking. Here, we present evidence for the influence of phospholipid bilayers on complex formation between rabbit P450 2B4 (CYP2B4) and rabbit cytb₅ at the atomic level, utilizing NMR techniques. General line broadening and modest chemical shift perturbations of cytb₅ resonances characterize CYP2B4-cytb₅ interactions on the intermediate time scale. More significant intensity attenuation and a more specific protein-protein binding interface are observed in bicelles as compared with lipid-free solution, highlighting the importance of the lipid bilayer in stabilizing stronger and more specific interactions between CYP2B4 and cytb₅, which may lead to a more efficient electron transfer. Similar results observed for the interactions between CYP2B4 lacking the transmembrane domain (tr-CYP2B4) and cytb₅ imply interactions between tr-CYP2B4 and the membrane surface, which might assist in CYP2B4-cytb₅ complex formation by orienting tr-CYP2B4 for efficient contact with cytb₅. Furthermore, the observation of weak and nonspecific interactions between CYP2B4 and cytb₅ in micelles suggests that lipid bilayer structures and low curvature membrane surface are preferable for CYP2B4-cytb₅ complex formation. Results presented in this study provide structural insights into the mechanism behind the important role that the lipid bilayer plays in the interactions between P450s and their redox partners.