Ad-Ang1-IRES-VEGF165腺病毒载体的构建及其促血管形成作用

目的:构建人血管生成素1(Ang1)和血管内皮生长因子VEGF165 (VEGF165)的共表达腺病毒载体Ad-Ang1-IRES-VEGF165(简称Ad-AV),为研究Ad-AV转基因细胞表达产物血管诱生活性提供实验依据。方法:采用IRES介导的Ang1和VEGF165双基因腺病毒共表达模式,通过常规的基因克隆和重组技术,构建Ad-AV双基因共表达腺病毒载体,经感染人胚肾QBI-293A细胞(293A)进行扩增和效价测定后,再感染WI-38人胚肺成纤维细胞,均用ELISA法检测VEGF、Ang1目的基因的表达,并采用鸡胚尿囊膜血管形成实验(CAM)法分析其对血管形成的影响。结果: 扩增的Ad-AV腺病毒效价可达4×10¹⁰pfu/ml;Ad-AV不仅能在293A细胞中成功表达目的基因Ang1、VEGF,而且在WI-38成纤维细胞也能成功表达,其表达产物具有显著的促进CAM上血管生成的活性。结论:成功构建并获得了Ad-Ang1-IRES-VEGF165重组病毒子, 目的基因均能在人胚肾和人胚肺成纤维细胞中表达,其表达产物具有诱导血管形成的功能。     

PEG-PEI共聚物介导VEGF165基因转染及对内皮细胞生长的影响

为了考察PEG-PEI共聚物作为基因载体介导VEGF165基因的能力,合成不同接枝量的PEG-PEI共聚物,考察共聚物的细胞毒性,同时采用PCR技术获得上下游含有HindⅢ和BamHⅠ酶切位点的目的基因VEGF165,与pEGFP-C1构建重组质粒pEGFP-VEGF165,将PEG-PEI作为基因载体,与pEGFP-VEGF165通过自组装成DNA复合物,使其转染脐静脉内皮细胞(HUVEc),测定发荧光细胞百分数获得转染率,利用ELISA、RT-PCR检测VEGF的表达,用MTT法考察VEGF165转染HUVEc后对内皮细胞生长的影响.结果显示,形成PEG-PEI共聚物后可显著降低PEI的细胞毒性.作为基因载体介导pEGFP-VEGF165转染HUVEc后,在荧光显微镜下可见强绿色荧光蛋白表达,转染率与接枝PEG的量及N/P有关,PEG-PEI(5-25-1)在N/P=30时转染率达到最大值,比PEI显著提高.转染后血管内皮生长因子(VEGF)蛋白表达及mRNA水平均有显著提高,且可有效地刺激内皮细胞增殖.研究表明,PEG-PEI共聚物可做为基因载体,有效地介导pEGFP-VEGF165基因的传递.     

VEGF重组质粒pcDNA/V的构建及其在大鼠急性心肌缺血模型中的表达

构建人血管内皮细胞生长因子(VEGF165)真核表达载体,并研究其在细胞水平和大鼠急性心肌梗死动物模型中的表达。利用RT-PCR方法,从人扁桃体组织中扩增人VEGF165基因,构建真核表达载体pcDNA/V。应用脂质体介导的基因转移技术,将pcDNA/V转染至人胚肾细胞(293细胞)中,经G418筛选获得稳定表达的重组质粒细胞克隆。ELISA、Westernblot检测证实重组质粒pcDNA/V能在293细胞中高效表达外源VEGF基因,鸡胚绒毛尿囊膜血管生成实验证实表达产物具有促血管生成的活性。进一步的体内表达研究,建立大鼠急性心肌梗死模型,将重组质粒pcDNA/V、空质粒pcDNA3.1( )分三点注射于梗死交界处心肌内,四周后取材。经免疫组化染色检测,pcDNA/V组在梗死交界区有VEGF阳性表达;电镜观察显示,pcDNA/V组在梗死交界处心肌细胞间有大量毛细血管内皮细胞增生。实验结果表明成功克隆了人VEGF165基因,构建了其真核表达载体。体内、外表达研究证实重组质粒的表达产物具有促血管生成的生物学活性,为VEGF基因治疗缺血性心肌病的研究提供实验基础。     

腺病毒载体介导PDX-1在骨髓间充质干细胞中的表达

为研究PDX-1基因在骨髓间充质干细胞中的表达情况及生物学功能的发挥,构建了含PDX-1基因的重组腺病毒载体.酶切PDX-1基因并连入穿梭质粒pAdTrack-CMV.用电穿孔法使穿梭质粒pAdTrack-CMV-PDX-1与病毒骨架质粒pAdEasy-1在大肠杆菌BJ5183中同源重组.利用脂质体介导重组腺病毒载体转染293细胞,包装出完整的腺病毒.分离、培养、扩增骨髓间充质干细胞.用重组腺病毒感染间充质干细胞.用荧光显微镜、RT-PCR、免疫荧光染色等方法检测PDX-1、胰岛素基因及蛋白质的表达,用放射免疫分析法检测转基因细胞分泌胰岛素情况.结果表明:通过测序、PCR、酶切等鉴定PDX-1基因已正确插入穿梭质粒中,并与病毒骨架质粒重组.重组腺病毒滴度为6.3×107PFU/ml.通过荧光显微镜观察证实重组腺病毒可高效感染骨髓间充质干细胞,经RT-PCR、免疫荧光染色证实转染pAd-PDX-1后培养7天的细胞中有PDX-1及胰岛素基因的表达.这些转基因的细胞向胞外分泌的胰岛素量为(15.21±3.50)mIU/L.     

小鼠SOCS1基因重组腺病毒载体的构建及其在树突状细胞中的表达

目的:构建含小鼠细胞因子信号抑制因子-1基因(SOCS1)的重组腺病毒载体(Ad5F35-SOCS1),探讨其介导SOCS1基因在小鼠树突状细胞中的表达。方法:设计含AgeI和NheI酶切位点的SOCS1基因上下游引物,以质粒pEF-FLAG-1/mSOCS1为模版,通过PCR扩增获得SOCS1全部序列,片段回收后经AgeI和NheI酶切,再定向插入到经AgeI和NheI酶切的质粒pDc316-LacZa中,获得重组穿梭质粒pDC316-SOCS1,经AgeI和NheI酶切、PCR及测序等鉴定后,用脂质体将穿梭质粒pDC316-SOCS1与腺病毒骨架质粒pBHGF35共转染293细胞,经位点特异性重组获得重组腺病毒Ad5F35-SOCS1,行PCR鉴定,经293细胞扩增、纯化制备高滴度病毒液,TCID50法测定病毒滴度。用获得的重组腺病毒感染小鼠树突状细胞,以免疫组化检测SOVD1的表达。结果:成功构建了含小鼠SOCS1基因的重组腺病毒载体,病毒感染滴度为1.4×10~9IU/ml,该载体能有效介导SOCS1基因在小鼠树突状细胞中的表达。结论:重组腺病毒载体能将SOCS1基因转入小鼠树突状细胞并有效表达,为基因转染制备耐受性树突状细胞奠定了基础。     

人Semaphorin 4D慢病毒载体的构建及鉴定

目的:构建并制备能够有效表达Semaphorin 4D的重组慢病毒。方法:从人急性T细胞白血病Jurkat细胞DNA 扩增人Semaphorin 4D基因,克隆至pWPI GW慢病毒载体上,与pVSVG及pSPAX质粒共转染人胚肾293T细胞,包装出重组慢病毒,将纯化后的重组病毒直接感染293T和HUVEC细胞,通过免疫印迹、免疫荧光染色和血管内皮细胞迁移分析等方法检测Semaphorin 4D的表达和诱导血管内皮细胞迁移的作用。结果: 重组慢病毒介导Semaphorin 4D在293T和HUVEC内获得表达,能介导血管内皮细胞迁移。结论:成功构建了表达Semaphorin 4D的重组慢病毒载体。     

Microdystrophin基因重组腺病毒的构建及转染mdx骨髓间充质干细胞的表达

构建含有人microdystrophin基因的重组腺病毒,来感染dystrophin基因敲除小鼠mdx的骨髓间充质干细胞(MSC)进行基因修饰,为同种异体基因修饰的干细胞移植治疗DMD疾病奠定基础。用NotⅠ酶切含microdystrophin基因的pBSK-MICRO质粒,获得microdystrophin基因。片段回收后定向插入腺病毒穿梭质粒pShuttle-CMV,获得重组质粒pShuttle-CMV-MICRO。PmeⅠ线性化重组质粒pShuttle-CMV-MICRO,去磷酸化后回收后与腺病毒骨架质粒pAdeasy-1共电转化BJ5183感受态细胞。同源重组后用选择性培养基筛选阳性克隆,提取质粒,用脂质体介导转染293细胞,通过观察293细胞病变及PCR扩增目的基因等方法鉴定重组的腺病毒。然后将病毒上清转染DMD模型鼠mdx小鼠的骨髓间充质干细胞,通过RT-PCR以及间接免疫荧光检测microdystrophin的转录及蛋白表达。成功构建了含有microdystrophin基因的重组腺病毒,病毒滴度为5·58×1012vp/mL。间接免疫荧光检测可见microdystrophin蛋白在mdx小鼠MSCs中高效表达。该重组腺病毒载体的构建及成功转染到mdxMSCs内表达为下一步用microdystrophin基因修饰的mdxMSCs进行同种异体移植治疗DMD疾病奠定了基础。     

pcDNA3.1(+)-VEGF165载体的构建及表达蛋白特性分析

构建含人VEGF165基因的重组真核表达质粒,并对其表达蛋白特性进行初步分析。将合成的VEGF165基因序列克隆至pCR2.1-TOPO载体,测序鉴定证实基因碱基序列无误后,再克隆至真核表达载体pcDNA3.1(+),构建成pcD-NA3.1(+)-VEGF165重组质粒。利用DNAstar软件分析基因序列并翻译成氨基酸序列,再用ExPASy protscale和Protean软件分析其疏水特性、蛋白二级结构。经基因测序、酶切鉴定和PCR鉴定证实pcDNA3.1(+)-VEGF165重组质粒构建成功。Ex-PASy protscale和Protean软件分析表明VEGF165蛋白具有较好的水溶性。本研究为VEGF165的基因治疗应用和VEGF165蛋白直接治疗勃起功能障碍奠定了基础。     

裂解型腺病毒Ad-E1A对人脐静脉内皮细胞的影响

以QBI-293A细胞基因组DNA为模板,PCR扩增E1A基因,酶切连接到pAdTrack-CMV转移质粒上,pAdTrack-CMV-E1A经PmeI线性化后,与pAdEasy-1共转化大肠杆菌BJ5183,筛选重组腺病毒质粒pAdEasy-1-pAdTrack-CMV-E1A,经PacI线性化,脂质体转染QBI-293A细胞,获得裂解型腺病毒Ad-E1A。裂解型腺病毒Ad-E1A在ECV304细胞内复制裂解,抑制细胞的生长,并可以降低VEGF的表达,探讨了Ad-E1A可能通过抑制ECV304细胞NF-κB的激活而引起细胞生长抑制的机制,说明Ad-E1A具有抑制肿瘤转移的功能。     

血管内皮生长因子对猪心肌侧枝血管生成的作用

为检测血管内皮生长因子165（VEGF165)能否促进冠状动脉侧枝血管形成,实验在成功制作小型猪慢性心肌缺血模型后,将以复制缺陷复组腺病毒为载体的人VEGF165互补脱氧核糖核酸[(cDNA)Ad-VEGF165]直接注入左回旋支（LCX）分布的缺血心肌内,以心电图门控单光子发射计算机断层摄影和离体太动脉造影检测冠状动脉侧枝形成,心肌灌注和功能变化,结果显示,与对照组和自身给预Ad-VEGF165前比较,给予Ad-VEGF165四周后心肌缺血面积（P＜0．01）和最大缺血程度（P＜0．01）明显减小,左心室射血分数（P＜0．01）TCX区局部心室壁运动（P＜0．05）明显改善,治疗组侧枝血管生成明显多于对照组（P＜0．05）,表明Ad-VEGF165能诱导心肌侧肢血管形成并改善心肌灌注与运动功能。     

Gene therapy by adenovirus-mediated vascular endothelial growth factor and angiopoietin-1 promotes perfusion of muscle flaps

An experimental study was conducted to investigate the potential use of intravascular gene therapy with adenovirus-mediated (Ad) vascular endothelial growth factor (VEGF) or angiopoietin-1 (Ang-1) for the enhancement of muscle flap perfusion and to evaluate the effect of therapy on microcirculatory hemodynamics and microvascular permeability in vivo by using a cremaster muscle flap model in the rat. The cremaster tube flap was left intact after isolation of the pudo-epigastric pedicle. A total of 90 male Sprague-Dawley rats were divided into five groups of 18 each, according to the type of intraarterial treatment. Control flaps received phosphate-buffered saline. Group 2 (the control gene encoding green fluorescent protein, Ad-GFP) served as the adenovirus control. In Groups 3, 4, and 5, flaps were pretreated with Ad-VEGF, Ad-Ang-1, and Ad-Ang-1 + Ad-VEGF, respectively. Flaps were preserved in a subcutaneous pocket in the hindlimb for evaluation of functional capillary density and microvascular permeability indices at 3, 7, and 14 days by intravital microscopy system. At day 7 and 14, Ad-VEGF, Ad-Ang-1, and combined treatment groups showed significantly higher numbers of capillary densities when compared with control and Ad-GFP groups (p < 0.05). At day 14, Ad-VEGF was the superior treatment group compared with Ad-Ang-1 and Ad-VEGF + Ad-Ang-1 (p < 0.05). Overall, there was a linear increase in the number of functional capillaries in all treatment groups (p < 0.05). At day 3 after Ad-Ang-1 therapy, a significantly lower permeability index was found when compared with Ad-VEGF + Ad-Ang-1 and Ad-VEGF alone treatment (p < 0.05). At day 7, the Ad-VEGF group had the highest score of permeability index compared with control, combined, and Ad-Ang-1 groups (p < 0.05). Histologic evaluation of muscle flaps demonstrated mild focal inflammation. There was evidence of mild vasculitis in all flaps except control muscles. Intravascular angiogenic therapy with Ad-VEGF or Ad-Ang-1 was technically feasible, as demonstrated by expression of the control gene, GFP, along the vascular tree. All treatment groups increased perfusion of the muscle flap over a period of 14 days, indicating a long-lasting effect of gene therapy. Ang-1 alone or in combination with VEGF was as effective as VEGF alone in augmenting muscle perfusion with more stable vessels 1 week after gene therapy.     

VEGF(165), but not VEGF(189), stimulates vasculogenesis and bone marrow cell migration into Ewing's sarcoma tumors in vivo

We previously showed that bone marrow stem cells participate in the tumor vessel expansion that supports the growth of Ewing's sarcoma tumors in vivo. The purpose of this study was to determine the relative importance of two isoforms of vascular endothelial growth factor (VEGF) in tumor vessel expansion and recruitment of bone marrow-derived cells during tumor growth. We injected VEGF(165)-siRNA-transfected cells (TCsi/7-1), control siRNA-transfected cells (TC/si-control), or TC71 parental Ewing's sarcoma cells into nude mice. The TCsi/7-1 tumors were then treated with adenoviral vectors expressing VEGF(165) (Ad-VEGF(165)), VEGF(189) (Ad-VEGF(189)), or beta-galactosidase (Ad-beta-gal). Bone marrow cells labeled with fluorescent tracker dye were injected into the mice 3 weeks later. The TCsi/7-1 tumors were significantly smaller (P < 0.05), had decreased vessel density, and showed significantly lower bone marrow cell migration than did TC71 parental and TC/si-control tumors. Treatment with Ad-VEGF(165), but not Ad-VEGF(189) or Ad-beta-gal, resulted in a significant increase in bone marrow cell infiltration, tumor vessel density, and tumor growth. Immunohistochemical staining revealed that the injected bone marrow cells migrated to and incorporated into the expanding CD31(+) tumor vessel network. Taken together, these data show that VEGF(165) is a chemoattractant that recruits bone marrow cells into the tumor area. These data provide a mechanism by which Ewing's sarcoma cells induce vasculogenesis.     

Dyskerin depletion increases VEGF mRNA internal ribosome entry site-mediated translation

Dyskerin is a nucleolar protein encoded by the DKC1 gene that (i) stabilizes the RNA component of the telomerase complex, and (ii) drives the site-specific pseudouridilation of rRNA. It is known that the partial lack of dyskerin function causes a defect in the translation of a subgroup of mRNAs containing internal ribosome entry site (IRES) elements such as those encoding for the tumor suppressors p27 and p53. In this study, we aimed to analyze what is the effect of the lack of dyskerin on the IRES-mediated translation of mRNAs encoding for vascular endothelial growth factor (VEGF). We transiently reduced dyskerin expression and measured the levels of the IRES-mediated translation of the mRNA encoding for VEGF in vitro in transformed and primary cells. We demonstrated a significant increase in the VEGF IRES-mediated translation after dyskerin knock-down. This translational modulation induces an increase in VEGF production in the absence of a significant upregulation in VEGF mRNA levels. The analysis of a list of viral and cellular IRESs indicated that dyskerin depletion can differentially affect IRES-mediated translation. These results indicate for the first time that dyskerin inhibition can upregulate the IRES translation initiation of specific mRNAs.     

Enhancement of bone formation by genetically-engineered bone marrow stromal cells expressing BMP-2, VEGF and angiopoietin-1

To explore the potential of combined delivery of osteogenic and angiogenic factors to bone marrow stromal cells (BMSCs) for repair of critical-size bone defects, we followed the formation of bone and vessels in tissue-engineered constructs in nude mice and rabbit bone defects upon introducing different combinations of BMP-2, vascular endothelial growth factor (VEGF) and angiopoietin-1 (Ang-1) to BMSCs with adenoviral vectors. Better osteogenesis and angiogenesis were found in co-delivery group of BMP-2, VEGF and angiopoietin-1 than any other combination of these factors in both animal models, indicating combined gene delivery of angiopoietin-1 and VEGF165 into a tissue-engineered construct produces an additive effect on BMP-2-induced osteogenesis.     

Adenoviral delivery of soluble VEGF receptor 1 (sFlt-1) inhibits experimental autoimmune encephalomyelitis in dark Agouti (DA) rats

Previous studies have shown that vascular endothelial growth factor (VEGF) expression is up-regulated in both multiple sclerosis (MS) and experimental autoimmune encephalomyelitis (EAE), a model for MS, and may exacerbate the disease. However, it remains unknown whether anti-VEGF modalities could serve as a potential treatment for such central nervous system (CNS) autoimmune diseases. We constructed a recombinant adenoviral vector carrying FLAG-tagged sFlt-1(1-3) (the first three extracellular domains of Flt-1, the hVEGF receptor-1). Intramuscular transfection of the recombinant adenoviral vector suppressed VEGF-induced inflammatory cell infiltration in matrigel plugs. When given intracerebrally to EAE rats, recombinant sFlt-1(1-3) adenoviral vector significantly reduced disease severity compared to untreated rats. sFlt-1(1-3) gene transfer blocked VEGF and greatly reduced the number of cells that express VEGF and ED1-positive cells in CNS in EAE rats. This study demonstrates that sFlt-1(1-3) gene transfer into the brain ameliorates the severity of EAE by inhibiting monocyte recruitment in the CNS of dark Agouti rats.     

Directing endothelial differentiation of human embryonic stem cells via transduction with an adenoviral vector expressing the VEGF(165) gene

Endothelial progenitors derived from human embryonic stem cells (hESCs) hold much promise in clinical therapy. Conventionally, lineage-specific differentiation of hESCs is achieved through supplementation of various cytokines and chemical factors within the culture milieu. Nevertheless, this is a highly inefficient approach that is often limited by poor replicability. An alternative is through genetic modulation with recombinant DNA. Hence, this study investigated whether transduction of hESCs with an adenoviral vector expressing the human VEGF(165) gene (Ad-hVEGF(165)) can enhance endothelial-lineage differentiation. The hESCs were induced to form embryoid bodies (EBs) by culturing them within low-attachment plates for 7 days, and were subsequently trypsinized into single cells, prior to transduction with Ad-hVEGF(165). Optimal transduction efficiency with high cell viability was achieved by 4-h exposure of the differentiating hESCs to viral particles at a ratio of 1 : 500 for three consecutive days. ELISA results showed that Ad-hVEGF(165)-transduced cells secreted human vascular endothelial growth factor (hVEGF) for more than 30 days post-transduction, peaking on day 8, and the conditioned medium from the transduced cells stimulated extensive proliferation of HUVEC. Real-time PCR analysis showed positive upregulation of VEGF, Ang-1, Flt-1, Tie-2, CD34, CD31, CD133 and Flk-1 gene expression in Ad-hVEGF(165)-transduced cells. Additionally, flow cytometric analysis of CD133 cell surface marker revealed an approximately 5-fold increase in CD133 marker expression in Ad-hVEGF(165)-transduced cells compared to the non-transduced control. Hence, this study demonstrated that transduction of differentiating hESCs with Ad-hVEGF(165) facilitated expression of the VEGF transgene, which in turn significantly enhanced endothelial differentiation of hESCs.     

Construction of a bicistronic proangiogenic expression vector and its application in experimental angiogenesis in vivo

Manipulation of angiogenesis in vivo is an example of successful gene therapy strategies. Overexpression of angiogenic genes like VEGF, FGF or PDGF causes new vessel formation and improves the clinical state of patients. Gene therapy is a very promising procedure but requires large amounts of pharmaceutical-grade plasmid DNA. In this regard we have constructed a bicistronic plasmid DNA vector encoding two proangiogenic factors, VEGF165 and FGF-2. The construct (pVIF) contains the internal ribosome entry site (IRES) of the encephalomyocarditis virus (ECMV) which permits both genes to be translated from a single bicistronic mRNA. The IRES sequence allows for a high efficiency of gene expression in vivo. The pVIF vector was characterized in vitro and in vivo. In vivo angiogenesis studies showed that the bicistronic vector encoding two proangiogenic factors induces the formation of new vessels significantly more than pVEGF165 or pFGF-2 alone. In our opinion the combined proangiogenic approach with VEGF165 and FGF-2 is more powerful and efficient than single gene therapy. We also postulate that IRES sequence can serve as a useful device improving efficiency of gene therapy.     

利用慢病毒载体构建稳定过表达人VEGF_(165)的小鼠巨噬细胞系

目的:通过构建人血管内皮生长因子165(humanVEGF_(165),hVEGF_(165)的慢病毒载体,感染小鼠单核巨噬细胞RAW264.7,建立稳定高表达人VEGF165的小鼠巨噬细胞系。方法:将聚合酶链反应(PCR)扩增得到的hVEGF_(165)和慢病毒载体pLVX-IRES-ZsGreen1双酶切后连接,构建慢病毒表达载体pLVX-hVEGF_(165)-IRES-ZsGreen1。再经双酶切和测序鉴定后,进行病毒包装及浓缩。将该慢病毒载体感染RAW264.7细胞,利用绿色荧光蛋白ZsGreen1进行2次流式分选。用Realtime-PCR、WesternBlot分别检测各组细胞中hVEGF165的mRNA和蛋白表达;ELISA分别检测细胞上清中人VEGF和小鼠VEGF的含量。结果:酶切及测序结果示慢病毒表达载体pLVX-hVEGF165-IRES-ZsGreen1构建正确;流式分选后得到高纯度的ZsGreen1-hVEGF_(165)-RAW264.7细胞。Realtime-PCR、WesternBlot显示该细胞特异高表达hVEGF_(165)基因和蛋白(P均0.01)。ELISA显示该细胞分泌人和小鼠VEGF均显著增加(P均0.01)。结论:成功构建hVEGF_(165)慢病毒表达载体,并建立稳定高表达hVEGF_(165)的小鼠巨噬细胞系。为深入研究该细胞的功能、机制及应用提供充足稳定的细胞来源。