基质金属蛋白酶-2 C端片段PEX的原核表达及其对血管发生的抑制作用

为了克隆表达鸡的基质金属蛋白酶-2(MMP-2)的C端片段PEX,并探讨其对血管发生的抑制作用,利用RT-PCR从鸡胚成纤维细胞克隆MMP-2 C端片段PEX,构建原核表达载体pCal-n-PEX;转化大肠杆菌BL21(DE3)-pLys,异丙基β-D硫代半乳糖苷（IPTG）诱导产生PEX融合蛋白,包涵体蛋白用盐酸胍法变性、复性;生长曲线观察PEX融合蛋白对人脐静脉血管内皮细胞增殖的影响;鸡胚绒毛尿囊膜血管发生实验研究其对血管发生的抑制作用.结果表明融合蛋白CBP/PEX具有抑制人脐静脉血管内皮细胞的生长和鸡胚绒毛尿囊膜血管发生的作用.提示PEX是有待进一步开发的潜在抑制血管发生的药物.     

原核表达Arresten蛋白抑制血管生成作用

目的:研究原核表达的Arresten蛋白纯化品对血管内皮细胞及血管生成的抑制作用。方法:MTT法检测Arresten蛋白对人脐静脉内皮细胞(HUVEC)增殖的影响;流式细胞仪分析Arresten蛋白作用下HUVEC凋亡的情况;细胞迁移实验观察Arresten蛋白对HUVEC迁移能力的影响;鸡胚绒毛尿囊膜(CAM)实验观察Arresten蛋白对新生血管的抑制情况。结果:原核表达的Arresten蛋白纯化品能特异性地抑制 HUVEC的增殖、迁移,诱导HUVEC的凋亡,并在一定范围内呈现出剂量—效应关系。Arresten蛋白能有效抑制鸡胚尿囊膜血管的生长(P<0.01)。结论:原核表达的Arresten蛋白纯化品对内皮细胞有特异的抑制作用,能有效抑制血管生成。     

钙网蛋白122～180片段基因克隆、表达和活性分析

钙网蛋白是高等动物细胞中普遍存在的一种钙结合蛋白,近年发现它及其N端1～180位氨基酸能抑制内皮细胞生长和血管生成.为了寻找高效和小分子质量的血管生成抑制因子,用PCR技术扩增出钙网蛋白N端122～180位氨基酸的DNA序列,克隆进原核表达载体pET-3c,转化大肠杆菌BL21(DE3), 经IPTG诱导后,该片段以包涵体形式表达,表达量约占菌体总蛋白的35.4%.包涵体经变性溶解、复性和初步纯化后,纯化产物可以抑制人脐静脉内皮细胞的生长,鸡胚绒毛尿囊膜的血管生成和小鼠原位黑色素瘤的生长.     

人肿瘤抑素(Tumstatin)在E.coli中的克隆、表达及活性分析

从人胚肾2 93细胞中扩增肿瘤抑素(tumstatin)基因,进行原核表达,纯化和生物活性检测.利用原核表达载体pMAL c2在大肠杆菌BL2 1中表达肿瘤抑素,经AmyloseResin亲和层析柱和QSepharoseFastFlow柱纯化,通过体外内皮细胞增殖、内皮细胞凋亡和鸡尿囊绒膜新生血管生成试验检测其抑制活性.MBP tumstatin在BL2 1中表达率约2 0 % ,肿瘤抑素纯度可达95 % .肿瘤抑素可明显抑制内皮细胞增殖(IC50 约为15 μg ml)、诱导内皮细胞凋亡和抑制鸡尿囊绒膜新生血管生成.研究结果表明,肿瘤抑素对内皮细胞具有明显的抑制作用,提示其在肿瘤治疗中有潜在的应用前景.     

人基质金属蛋白酶-2C端片段PEX的高效表达及活性研究

将人的PEX基因克隆到表达载体pET-15b上,构建重组工程菌BL21(DE3)/pETPEX。采用5L发酵罐补料分批培养,当菌体密度增长到OD₆₀₀为35时,用IPTG诱导,PEX蛋白形成包涵体,最终OD₆₀₀达到90,PEX的表达水平达2.2g/L。包涵体蛋白经过纯化、复性后,获得生物活性。PEX能够有效抑制HUVECs的增殖,加药96h后,20nmol/L PEX对HUVECs生长有77.9%的抑制率;PEX能阻断bFGF诱导的鸡胚尿囊膜血管生成,抑制率为85%;小鼠实验表明,当给药剂量为5mg/kg时,PEX对S180肉瘤有31.4%的抑瘤率(P<0.05)。PEX是一个有效的抑制新血管生成和肿瘤生长的蛋白质因子。     

人血管抑素 Kringles 1-3 的表达纯化及生物学活性研究

人血管抑素包含了4个环饼状结构域(Kringle),是一个有效的血管生成抑制因子。采用PCR方法从人胚肝cDNA文库中扩增了人血管抑素Kringles 1-3的基因,重组于pPIC9K载体中,获得重组载体pPIC9K-K1-3,然后转化毕赤酵母细胞GS115,获得重组菌株。K1-3蛋白在5 L发酵罐的表达量达41.2 mg/L,发酵液上清经过浓缩、透析,然后用Lysine Sepharose 4B层析柱纯化,得到的K1-3蛋白纯度大于98%,纯化回收率达到95%以上。K1-3能明显抑制bFGF刺激的人微血管内皮细胞的迁移,达到抑制效果为50%时所需的蛋白浓度(IC₅₀)为1.86 μg/ml。K1-3也能抑制鸡胚绒毛尿囊膜血管的生长,抑制率达95%。为应用人血管抑素Kringles 1-3治疗肿瘤奠定了初步实验基础。     

重组人纤溶酶原Kringle1-3的生物学活性鉴定

目的：检测重组人纤溶酶原Kringle1-3（K1-3）的生物学活性。方法：用含重组人纤溶酶原K1-3基因的表达载体pET21a-Angio（K1-3）转化表达宿主菌大肠杆菌BL21（DE3）后诱导表达,表达产物经溶解、复性和纯化后,进行SDS-PAGE,计算其相对分子质量;用BCA法测蛋白浓度,用细胞抑制实验（MTT法）和鸡胚绒毛膜尿囊膜（CAM）实验鉴定纯化产物对血管内皮细胞增殖和血管生成的抑制效果。结果：表达产物的相对分子质量为38000,与预期值一致;细胞抑制实验和CAM实验结果表明表达产物具有特异抑制血管内皮细胞增殖、血管生成的功能。结论：所纯化的重组人纤溶酶原K1-3具有抑制血管内皮细胞的生物学活性,为该蛋白在病理性血管疾病等方面的应用研究提供了材料。     

重组人色素上皮细胞衍生因子融合蛋白的制备及其抑制新生血管

目的：人色素上皮细胞衍生因子 (pigment epithelium-derived factor, PEDF)是一种有效的新生血管形成抑制因子和神经营养因子。本文通过原核细胞表达人PEDF蛋白,鉴定其抑制新生血管的生物学活性。方法：采用PCR法扩增人PEDFcDNA,将其克隆到pET32a载体中,在大肠杆菌BL21中表达人PEDF蛋白。经SDS-PAGE和Western-blot鉴定后,镍柱亲和层析法变性条件下纯化重组融合蛋白。Bradford法测蛋白浓度,采用鸡胚脲囊膜法测其对新生血管形成的影响。结果：成功构建了pET32a-PEDF表达载体。重组人PEDF蛋白在BL21宿主菌中获得了稳定高效表达,鸡胚脲囊膜实验结果显示在重组蛋白浓度为0.4、0.04 ng/ml时均有对新生血管的显著抑制作用（P<0.01）,而在4 ng/ml时无抑制作用。结论： 成功高效表达及纯化了重组人PEDF蛋白,鉴定其抑制新生血管的生物学活性,并且证实该活性在一定范围内有效,为进一步研究其功能及推广应用奠定了基础。     

人vasostatin的克隆、表达、纯化及活性检测

从成人肝脏cDNA文库中,PCR扩增得到人vasostatin基因编码区序列,将此序列插入原核表达载体pQE30进行表达,SDS-聚丙烯酰胺凝胶电泳(SDS-PAGE)测定表明产物以包涵体形式存在,表达量占菌体总蛋白量的50%以上.包涵体洗涤后溶于8 mol/L尿素溶液,在变性条件下通过镍-氨三乙酸(Ni-NTA)金属螯合亲和层析柱进行纯化后,再经透析进行复性.N端氨基酸序列、分子质量、等电点等理化指标的测定结果与理论值相符.用内皮细胞增殖试验、内皮细胞迁移试验以及鸡胚尿囊膜血管生成试验等方法进行活性检测,证实复性的表达产物具有抑制内皮细胞增殖和迁移、抑制鸡胚尿囊膜血管生成的功能.     

重组人纤溶酶原Kringle1-5的制备及其

为了研究重组人纤溶酶原 Kringle1-5(K1-5)的抗血管生成活性及其对内皮细胞增殖的影响, 通过PCR扩增人纤溶酶原K1-5 cDNA,定向克隆于原核表达载体pET30a(+)中,构建重组表达载体pET-K1-5, 转化E.coli BL21(DE3), IPTG诱导表达,SDS-PAGE 和Western 杂交检测K1-5的表达。鸡胚尿囊膜 (CAM) 实验和MTT实验分别检测重组人纤溶酶原Kringle1-5对鸡胚新生血管生成和内皮细胞的抑制作用。结果表明,IPTG诱导原核表达载体pET-K1-5在E.coli BL21(DE3)中的表达量约占菌体总蛋白量的32%, K1-5主要以包涵体形式存在,包涵体经过洗涤、溶解、Ni-spin 亲合柱层析纯化以及蛋白质复性等步骤后,获得了纯度约为96%的重组K1-5蛋白。CAM实验表明,原核表达的重组人K1-5能有效地按剂量依赖的方式抑制鸡胚新生血管的形成。MTT实验结果显示,重组人K1-5特异地抑制内皮细胞的增殖, 而对非内皮细胞无抑制作用。     

Detecting Protein Aggregates on Untreated Human Tissue Samples by Atomic Force Microscopy Recognition Imaging

We apply topography and recognition (TREC) imaging to the analysis of whole, untreated human tissue for what we believe to be the first time. Pseudoexfoliation syndrome (PEX), a well-known cause of irreversible blindness worldwide, is characterized by abnormal protein aggregation on the anterior lens capsule of the eye. However, the development of effective therapies has been hampered by a lack of detailed knowledge of the protein constituents in these pathological deposits and their distribution. Using both TREC and immunofluorescence, one of the proteins implicated in the PEX pathology—the apolipoprotein clusterin—was detected, and differences in its distribution pattern on the surface of untreated human lens capsule tissue in both PEX and normal control samples were investigated. Our study shows the potential of TREC imaging for the analysis of whole, untreated human tissue samples.     

Human Peroxin PEX3 Is Co‐translationally Integrated into the ER and Exits the ER in Budding Vesicles

The long‐standing paradigm that all peroxisomal proteins are imported post‐translationally into pre‐existing peroxisomes has been challenged by the detection of peroxisomal membrane proteins (PMPs) inside the endoplasmic reticulum (ER). In mammals, the mechanisms of ER entry and exit of PMPs are completely unknown. We show that the human PMP PEX3 inserts co‐translationally into the mammalian ER via the Sec61 translocon. Photocrosslinking and fluorescence spectroscopy studies demonstrate that the N‐terminal transmembrane segment (TMS) of ribosome‐bound PEX3 is recognized by the signal recognition particle (SRP). Binding to SRP is a prerequisite for targeting of the PEX3‐containing ribosome?nascent chain complex (RNC) to the translocon, where an ordered multistep pathway integrates the nascent chain into the membrane adjacent to translocon proteins Sec61α and TRAM. This insertion of PEX3 into the ER is physiologically relevant because PEX3 then exits the ER via budding vesicles in an ATP‐dependent process. This study identifies early steps in human peroxisomal biogenesis by demonstrating sequential stages of PMP passage through the mammalian ER.      

Function of the PEX19-binding site of human adrenoleukodystrophy protein as targeting motif in man and yeast. PMP targeting is evolutionarily conserved

We predicted in human peroxisomal membrane proteins (PMPs) the binding sites for PEX19, a key player in the topogenesis of PMPs, by virtue of an algorithm developed for yeast PMPs. The best scoring PEX19-binding site was found in the adrenoleukodystrophy protein (ALDP). The identified site was indeed bound by human PEX19 and was also recognized by the orthologous yeast PEX19 protein. Likewise, both human and yeast PEX19 bound with comparable affinities to the PEX19-binding site of the yeast PMP Pex13p. Interestingly, the identified PEX19-binding site of ALDP coincided with its previously determined targeting motif. We corroborated the requirement of the ALDP PEX19-binding site for peroxisomal targeting in human fibroblasts and showed that the minimal ALDP fragment targets correctly also in yeast, again in a PEX19-binding site-dependent manner. Furthermore, the human PEX19-binding site of ALDP proved interchangeable with that of yeast Pex13p in an in vivo targeting assay. Finally, we showed in vitro that most of the predicted binding sequences of human PMPs represent true binding sites for human PEX19, indicating that human PMPs harbor common PEX19-binding sites that do resemble those of yeast. Our data clearly revealed a role for PEX19-binding sites as PMP-targeting motifs across species, thereby demonstrating the evolutionary conservation of PMP signal sequences from yeast to man.     

Mutation in PEX16 is causal in the peroxisome-deficient Zellweger syndrome of complementation group D.

Peroxisome-biogenesis disorders (PBDs), including Zellweger syndrome (ZS), are autosomal recessive diseases caused by a deficiency in peroxisome assembly as well as by a malfunction of peroxisomes, among which>10 genotypes have been identified. We have isolated a human PEX16 cDNA (HsPEX16) by performing an expressed-sequence-tag homology search on a human DNA database, by using yeast PEX16 from Yarrowia lipolytica and then screening the human liver cDNA library. This cDNA encodes a peroxisomal protein (a peroxin Pex16p) made up of 336 amino acids. Among 13 peroxisome-deficiency complementation groups (CGs), HsPEX16 expression morphologically and biochemically restored peroxisome biogenesis only in fibroblasts from a CG-D patient with ZS in Japan (the same group as CG-IX in the United States). Pex16p was localized to peroxisomes through expression study of epitope-tagged Pex16p. One patient (PBDD-01) possessed a homozygous, inactivating nonsense mutation, C-->T at position 526 in a codon (CGA) for 176Arg, that resulted in a termination codon (TGA). This implies that the C-terminal half is required for the biological function of Pex16p. PBDD-01-derived PEX16 cDNA was defective in peroxisome-restoring activity when expressed in the patient's fibroblasts. These results demonstrate that mutation in PEX16 is the genetic cause of CG-D PBDs.     

PEX5, the Shuttling Import Receptor for Peroxisomal Matrix Proteins,Is a Redox‐Sensitive Protein

Peroxisome maintenance depends on the import of nuclear‐encoded proteins from the cytosol. The vast majority of these proteins is destined for the peroxisomal lumen and contains a C‐terminal peroxisomal targeting signal, called PTS1. This targeting signal is recognized in the cytosol by the receptor PEX5. After docking at the peroxisomal membrane and release of the cargo into the organelle matrix, PEX5 is recycled to the cytosol through a process requiring monoubiquitination of an N‐terminal, cytosolically exposed cysteine residue (Cys11 in the human protein). At present, the reason why a cysteine, and not a lysine residue, is the target of ubiquitination remains unclear. Here, we provide evidence that PTS1 protein import into human fibroblasts is a redox‐sensitive process. We also demonstrate that Cys11 in human PEX5 functions as a redox switch that regulates PEX5 activity in response to intracellular oxidative stress. Finally, we show that exposure of human PEX5 to oxidized glutathione results in a ubiquitination‐deficient PEX5 molecule, and that substitution of Cys11 by a lysine can counteract this effect. In summary, these findings reveal that the activity of PEX5, and hence PTS1 import, is controlled by the redox state of the cytosol. The potential physiological implications of these findings are discussed.      

Human adrenoleukodystrophy protein and related peroxisomal ABC transporters interact with the peroxisomal assembly protein PEX19p

Four ABC half transporters (ALDP, ALDRP, PMP70, and PMP69) have been identified in the mammalian peroxisomal membrane but no function has been unambiguously assigned to any of them. To date X-linked adrenoleukodystrophy (X-ALD) is the only human disease known to result from a defect of one of these ABC transporters, ALDP. Using the yeast two-hybrid system and in vitro GST pull-down assays, we identified the peroxin PEX19p as a novel interactor of ALDP, ALDRP, and PMP70. The cytosolic farnesylated protein PEX19p was previously shown to be involved in an early step of the peroxisomal biogenesis. The PEX19p interaction occurs in an internal N-terminal region of ALDP which we verified to be important for proper peroxisomal targeting of this protein. Farnesylated wild-type PEX19p and a farnesylation-deficient mutant PEX19p did not differ in their ability to bind to ALDP. Our data provide evidence that PEX19p is a cytosolic acceptor protein for the peroxisomal ABC transporters ALDP, PMP70, and ALDRP and might be involved in the intracellular sorting and trafficking of these proteins to the peroxisomal membrane.     

Pexophagy is responsible for 65% of cases of peroxisome biogenesis disorders

Peroxisome biogenesis disorders (PBDs) is a group of diseases caused by mutations in one of the peroxins, proteins responsible for biogenesis of the peroxisomes. In recent years, it became clear that many peroxins (e.g., PEX3 and PEX14) play additional roles in peroxisome homeostasis (such as promoting autophagic degradation of peroxisomes or pexophagy), which are often opposite to their originally established functions in peroxisome formation and maintenance. Even more interesting, the peroxins that make up the peroxisomal AAA ATPase complex (AAA-complex) in yeast (Pex1, Pex6 and Pex15) or mammals (PEX1, PEX6, PEX26) are responsible for the downregulation of pexophagy. Moreover, this might be even their primary role in human: to prevent pexophagy by removing from the peroxisomal membrane the ubiquitinated peroxisomal matrix protein import receptor, Ub-PEX5, which is also a signal for the Ub-binding pexophagy receptor, NBR1. Remarkably, the peroxisomes rescued from pexophagy by autophagic inhibitors in PEX1^G843D (the most common PBD mutation) cells are able to import matrix proteins and improve their biochemical function suggesting that the AAA-complex per se is not essential for the protein import function in human. This paradigm-shifting discovery published in the current issue of Autophagy has raised hope for up to 65% of all PBD patients with various deficiencies in the AAA-complex. Recognizing PEX1, PEX6 and PEX26 as pexophagy suppressors will allow treating these patients with a new range of tools designed to target mammalian pexophagy.