核定位信号分析示踪载体——pGST-EGFP的构建及功能鉴定

目的 构建谷胱甘肽转硫酶（GST）与EGFP相融合的新型蛋白质示踪载体--pGST-EGFP,以用于蛋白质细胞亚定位信号序列的深入分析.方法 以质粒pEGFP-N1为骨架,融合从pGEX-2TK载体中扩增的GST编码序列,构建成pGST-EGFP融合表达质粒;再插入人工合成的已知核定位蛋白SV40的核定位序列（NLS）,构建成pGST-EGFP-SV40 NLS作为阳性对照;另外,构建小分子量蛋白TNNI2在pGST-EGFP的融合表达质粒.将对照pEGFP-N1和各重组质粒分别用脂质体介导,瞬时转染HeLa细胞,荧光显微镜下观察蛋白的核定位情况.结果 单独表达的EGFP呈全细胞分布,而GST-EGFP融合蛋白只存在于细胞浆;SV40 NLS能将GST-EGFP融合蛋白带进细胞核.虽然TNNI2-EGFP融合蛋白的细胞亚定位呈现核内丰度更高的特点,但TNNI2-GST-EGFP融合蛋白仅限定于胞浆分布,提示TNNI2不能主动定位到细胞核中.结论 成功构建了蛋白质细胞亚定位示踪载体--pGST-EGFP.作为核定位信号分析系统,其对小分子蛋白细胞亚定位的示踪效果优于传统的pEGFP载体,更适用于科研工作中小分子量蛋白质核定位信号序列的研究.     

真核表达载体pcDNA3.1(-)+KG的构建及在HeLa细胞中的表达

为了将绿色荧光蛋白(green fluorescent protein,GFP)引入细胞核内,采用两轮PCR方法从原先克隆在pcD-NA3.1(-)+GFP载体中将GFP编码序列扩增出来并引入Kozak序列和核定位信号,使用常规酶切和连接方法将其重组至pUCm-T克隆载体中,再将目的片段重组至pcDNA3.1(-)中,对阳性克隆进行酶切、PCR和测序鉴定后,构建了带有Kozak序列和核定位信号的绿色荧光蛋白(GFP)真核表达载体pcDNA3.1(-)+KG。真核表达载体pcDNA3.1(-)+KG被转染试剂Su-perfect转染至HeLa细胞中,绿色荧光蛋白基因在HeLa细胞中得到表达而且在细胞核中观察到绿色荧光。该研究以绿色荧光蛋白为标记初步建立了活体观察真核细胞核动态变化的研究体系。     

HPV16L1核浆运输的动力学过程

利用增强型绿色荧光蛋白(Enhancegreenflurenscentprotein,EGFP)标记不同的截短型HPV16L1蛋白(Humanpapillomavirustype16L1protein,HPV16L1),分析HPV16L1蛋白核定位信号(Nucleuslocationsignal,NLS)的作用。构建重组pFB-EGFP、pFB-EGFP-HPV16L1、pFB-EGFP-HPV16L1△NLS和pFB-EGFP-NLSHPV16L1p转移载体;在DH10Bac宿主菌内经Tn7转座子介导的同源重组后转染Sf-9细胞,获得重组Ac-EGFP、Ac-EGFP-HPV16L1、Ac-EGFP-HPV16L1△NLS和Ac-EGFP-NLSHPV16L1杆状病毒,感染Sf-9昆虫细胞表达相应截短型HPV16L1融合蛋白;利用荧光显微镜和激光共聚焦显微镜观察不同融合蛋白的荧光特性和核浆转运动力学过程。结果发现Ac-EGFP杆状病毒感染的Sf-9细胞内明亮的绿色荧光均匀分布;重组Ac-EGFP-HPV16L1和Ac-EGFP-NLSHPV16L1杆状病毒感染的Sf-9细胞,明亮的绿色荧光主要位于细胞核内;重组Ac-EGFP-HPV16L1△NLS杆状病毒感染的Sf-9细胞,绿色荧光局限于细胞浆内,细胞核内无绿色荧光。说明HPV16L1蛋白羧基端的23个氨基酸(GKRKATPTTSSTSTTAKRKKRKL)具有完全核定位作用,能引导HPV16L1蛋白和EGFP突破核膜屏障进入Sf-9细胞核内。     

Red系统三种蛋白在哺乳动物细胞核中定位表达的设计和构建

目的：构建在哺乳动物细胞核中同时定位表达Red系统三种蛋白的载体。方法：通过给red基因（gam、bet和exo）的3,端分别加入由7个氨基（pro—lys—lys—lys—Arg-Lys—Val）组成的核定位信号序列（nuclearlocalizationsignal,NLS）和4个甘氨酸构成的linker序列,再从入噬菌体基因组中,通过PCR技术分别扩增到C端均都带有NLS的gam、bet和exo的DNA全长序列,将三种PCR产物依次克隆入真核表达载体plRES2-EGFP中,得到含3个目的基因（gam—NLS、bet—NLs和exo—NLS）的三顺反子表达载体pCMV—gNIbNIxN,转染培养的哺乳类细胞后,用作者制备并纯化的抗Red3种蛋白的抗体进行间接免疫荧光检测,观察蛋白的定位情况。结果：不带有NLS的Red3种蛋白在细胞中表达主要集中在细胞质很少进入细胞核;而带有NLS的Red3种蛋白于不同时间转染人和鼠的两种细胞后,均表达定位于细胞核中。结论：三顺反子表达载体pCMV—gNIbNIxN的成功构建为进一步探索将λ噬菌体的red系统用于哺乳动物细胞的基因替代打下基础。     

人APOBEC-3F和-3G的克隆表达、亚细胞定位及其抑制HBV的研究

载脂蛋白B mRNA编辑酶催化多肽(apolipoprotein B mRNA-editing enzyme catalytic-polypeptide,APOBEC)家族成员,是近年来发现的具有抗病毒作用的天然免疫分子,对HIV和HBV等多种病毒具有抑制作用,为研究APOBEC的抗病毒作用,对APOBEC-3F和-3G进行克隆、表达及亚细胞定位分析．HBV主要的生物合成发生于细胞核中,利用核定位信号(NLS)及二联核定位信号(B-NLS)与APOBEC-3F和-3G融合表达,以进一步了解APOBEC-3F和-3G的亚细胞定位及功能．利用RT-PCR从植物凝集素(PHA)刺激的人外周血淋巴细胞RNA中,对APOBEC-3F和-3G进行克隆,利用HindⅢ和KpnⅠ双酶切插入到pcFlag载体中,脂质体转染MDCK细胞后利用免疫荧光检测APOBEC重组蛋白的亚细胞定位．电泳结果表明,RT-PCR扩增得到APOBEC-3F和-3G基因,双酶切鉴定结果表明,APOBEC真核表达载体构建成功,基因序列经DNA测序证实．免疫荧光结果表明,转染表达后的APOBEC-3F和-3G均定位于细胞胞浆中．APOBEC-3F和-3G可以在HepG2.2.15细胞中显著抑制HBV的复制．可以有效转运绿色荧光蛋白(GFP)入核的NLS及B-NLS,不能将APOBEC-3F和-3G有效地转运至核中．成功地对APOBEC家族中的两个重要成员APOBEC-3F和-3G进行了克隆、表达及亚细胞定位研究,为进一步利用APOBEC家族蛋白开发抗HIV及HBV药物提供基础．     

核定位信号筛选系统的构建

建立了一酵母克隆系统用于克隆含核定位信号 (NLS)的蛋白质的基因 .用表达转录因子GAL4 DNA结合域 - p53(GAL4- DBD- p53)融合蛋白的质粒转化酵母 HF7c,使 GAL4- DBD- p53可结合于报告基因的启动子但因无转录激活域而不能激活转录 .构建一酵母穿梭载体 ,可表达无NLS的 GAL4转录激活域 -大 T抗原 (GAL4- AD- LT)融合蛋白 .融合蛋白基因的下游插入一多克隆位点 .将 c DNA文库插入多克隆位点后 ,如果 c DNA片段可编码 NLS,则 GAL4- AD- LT分子可进入细胞核 ,并通过 LT与 p53的相互作用而使 GAL4- AD结合于启动子和激活报告基因的转录 .构建了这一克隆系统的各质粒 ,并用绿色荧光蛋白 (GFP)验证了其对核内蛋白和胞浆蛋白的甄别能力 .这一系统将有助于从 c DNA文库中筛选编码带有 NLS的蛋白质的基因     

大鼠大麻素Ⅰ型受体绿色荧光融合蛋白真核表达载体的构建与鉴定

目的:构建大鼠大麻素型Ⅰ受体绿色荧光融合蛋白真核表达载体并观察其在细胞中的表达。方法:大鼠CB1基因序列设计引物,以大鼠脑组织为模板扩增CB1基因编码区片段,克隆至增强型绿色荧光蛋白表达载体pEGFP-N3中,构建重组融合蛋白表达载体pCB1-EGFP。将pCB1-EGFP质粒转染HeLa细胞,通过观察EGFP报告基因的表达以及免疫荧光,Western Blot方法鉴定CB1可在真核细胞中过表达情况。结果:构建重组融合蛋白表达载体pCB1-EGFP,单双酶切和测序验证正确。将pCB1-EGFP质粒转染HeLa细胞,荧光显微镜下观察到融合表达的绿色荧光蛋白,且呈胞膜表达。免疫荧光试验也证明重组载体转染后,CB1基因和GFP共同定位于胞膜部分。Western Blot实验证明表达CB1蛋白。结论:成功构建了高表达的CB1-EGFP融合蛋白真核表达载体。     

植物细胞质介导GFP-NLS蛋白入核转运的HeLa细胞系统的建立

细胞核作为细胞中重要的遗传物质存储、复制和转录的结构,牵涉着大量信息和物质的传输活动,尤其是蛋白质的入核转运一直以来都是研究的热点问题之一。本文利用病毒SV40抗原蛋白中的核定位信号（nuclear localization signal,NLS）标记GFP蛋白,通过拟南芥细胞质的介导,利用HeLa细胞核建立起了研究蛋白质入核转运的半细胞体系。结果显示,植物细胞质结合NLS片段能改变GFP在HeLa细胞核内外的分布,实现对目标蛋白入核过程的介导,使GFP-NLS最后定位于细胞核内。这也意味着通过HeLa细胞建立起的半细胞体系能为蛋白入核转运研究提供一个有效的研究体系。     

过氧化物酶蛋白1 真核表达载体构建及在Hela 细胞的表达与定位

目的:构建过氧化物酶蛋白1(PRDX 1)的真核表达载体,观察其在Hela细胞内表达及定位。方法:提取BALB/c小鼠肝脏组织总RNA,通过RT-PCR方法扩增得到小鼠PRDX 1编码序列,酶切后克隆至pcDNA3-myc载体。重组质粒通过PCR、酶切、测序证明构建正确后经脂质体转染Hela细胞,然后利用Western blot和荧光显微镜技术观察该融合蛋白在细胞内表达及定位。结果:经鉴定证明重组质粒构建正确;Western blot实验显示,该质粒能够在Hela细胞中特异表达;免疫荧光试验显示,蛋白产物分布在胞浆和胞核,证明该蛋白在细胞内高表达。结论:成功构建带有myc标签的PRDX 1真核表达载体,该质粒能够在哺乳细胞中特异表达并且外源性PRDX 1蛋白分布在Hela细胞胞浆胞核内,为深入研究PRDX 1蛋白在细胞内相关生物学研究奠定了基础。     

鸭源新城疫病毒M蛋白核定位信号突变影响病毒的毒力和复制能力

【目的】研究鸭源新城疫病毒(Newcastle disease virus,NDV)M蛋白核定位信号(nuclear localization signal,NLS)突变对其毒力和复制能力的影响。【方法】利用鸭源NDV SS1株P基因和F基因上的AgeⅠ和Bstz17Ⅰ酶切位点,将overlapPCR方法获得的M蛋白NLS突变的片段替换到p NDV/SS1GFP中获得全长质粒pNDV/SS1GFP-M/NLSm。通过反向遗传学技术拯救M蛋白NLS突变体病毒,并对拯救的病毒进行血凝(hemagglutination,HA)试验、荧光试验和M基因测序鉴定。另外,对突变体病毒进行M蛋白的亚细胞定位观察,以及病毒的生物学特性、空斑形成能力和体外增殖能力测定。【结果】成功构建M蛋白NLS突变的全长质粒pNDV/SS1GFP-M/NLSm。细胞转染物接种鸡胚后的第1代尿囊液无HA效价,盲传3代才能检测到拯救病毒的HA效价。进一步的荧光试验和M基因测序确定拯救的病毒是突变体病毒r SS1GFP-M/NLSm。与亲本病毒rSS1GFP相比,突变体病毒M蛋白由细胞核定位变为细胞质定位。此外,突变体病毒的毒力、在鸡胚上的复制能力以及在细胞中的空斑形成能力显著降低,并且感染细胞后产生的细胞病变轻微,M蛋白和绿色荧光蛋白的表达量均降低,说明M蛋白NLS突变使病毒的体外增殖能力受到抑制。【结论】NLS突变导致的M蛋白细胞核定位功能丧失可明显降低鸭源NDV的毒力和复制能力。     

Identification of amino acid sequence in the hinge region of human vitamin D receptor that transfers a cytosolic protein to the nucleus

The localization of human vitamin D receptor (VDR) in the absence of its ligand 1,25-dihydroxyvitamin D(3) was investigated using chimera proteins fused to green fluorescent protein (GFP) at either the N or C terminus, and the nuclear localization signal (NLS) was identified. Plasmids carrying the fusion proteins were transiently or stably introduced into COS7 cells, and the subcellular distribution of the fusion proteins was examined. GFP-tagged wild-type VDRs were located predominantly in nuclei but with a significant cytoplasmic presence, while GFP alone was equally distributed throughout the cells. 10(-8) M 1,25-dihydroxyvitamin D(3) promoted the nuclear import of VDR in a few hours. To identify the NLS, we constructed several mutated VDRs fused to GFP. Mutant VDRs that did not bind to DNA were also localized predominantly in nuclei, while the deletion of the hinge region resulted in the loss of preference for nucleus. A short segment of 20 amino acids in the hinge region enabled cytoplasmic GFP-tagged alkaline phosphatase to translocate to nuclei. These results indicate that 1) VDR is located predominantly in nuclei with a significant presence in cytoplasm without the ligand and 2) an NLS consisting of 20 amino acids in the hinge region facilitates the transfer of VDR to the nucleus.     

The N-terminus of porcine circovirus type 2 replication protein is required for nuclear localization and ori binding activities

Porcine circovirus type 2 possesses a circular, single-stranded DNA genome that requires the replication protein (Rep) for virus replication. To characterize the DNA binding potential and the significant region that confers the nuclear localization of the Rep protein, the defined coding regions of rep gene were cloned and expressed. All of the recombinant proteins except for the N-terminal 110 residues deletion mutant could bind to the double-stranded minimal binding site of replication origin (ori). In addition, the N-terminal deletion mutant lacking 110 residues exhibited mainly cytoplasmic staining in the transfected cells in contrast to the others, which localized dominantly in the nucleus, suggesting that this N-terminal domain is essential for nuclear localization. Furthermore, a series of green fluorescence proteins (GFP) containing potential nuclear localization signal (NLS) sequences were tested for their cellular distribution. The ability of the utmost 20 residues of the N-terminal region to target the GFP to the nucleus confirmed its role as a functional NLS.     

BRD7核定位信号的结构分析和功能鉴定

目的:对BRD7的核定位信号进行预测、结构分析和功能鉴定,并考察其对BRD7亚细胞定位的影响。方法:通过生物信息学对BRD7的核定位信号进行预测和结构分析,然后利用绿色荧光蛋白(GFP)介导的直接荧光和间接免疫荧光定位方法分别对核定位信号的功能进行鉴定,并考察其对BRD7亚细胞定位的影响。结果:BRD7的65～96位氨基酸残基具有潜在核定位信号(NLS)的结构特征,该核定位信号包含3簇碱性氨基酸残基,可视为由2个紧密相邻、部分重叠的双向核靶序列NLS1和NLS2组成;并发现NLS及其构成上的NLS1和NLS2均具有介导异源蛋白GFP胞核定位的功能,从而证实BRD7的65～96位残基为BRD7功能性核定位信号所在区域,且单簇碱性氨基酸残基的缺失不足以破坏其核定位信号的功能;同时发现野生型BRD7呈胞核分布,而核定位信号缺失型BRD7主要呈胞浆分布。结论:BRD7的65～96位氨基酸残基为BRD7功能性核定位信号所在区域,在BRD7胞核分布模式中发挥了十分重要的作用。     

Characterization of the nuclear localization and nuclear export signals of bovine herpesvirus 1 VP22

The bovine herpesvirus 1 (BHV-1) tegument protein VP22 is predominantly localized in the nucleus after viral infection. To analyze subcellular localization in the absence of other viral proteins, a plasmid expressing BHV-1 VP22 fused to enhanced yellow fluorescent protein (EYFP) was constructed. The transient expression of VP22 fused to EYFP in COS-7 cells confirmed the predominant nuclear localization of VP22. Analysis of the amino acid sequence of VP22 revealed that it does not have a classical nuclear localization signal (NLS). However, by constructing a series of deletion derivatives, we mapped the nuclear targeting domain of BHV-1 VP22 to amino acids (aa) 121 to 139. Furthermore, a 4-aa motif, 130PRPR133, was able to direct EYFP and an EYFP dimer (dEYFP) or trimer (tEYFP) predominantly into the nucleus, whereas a deletion or mutation of this arginine-rich motif abrogated the nuclear localization property of VP22. Thus, 130PRPR133 is a functional nonclassical NLS. Since we observed that the C-terminal 68 aa of VP22 mediated the cytoplasmic localization of EYFP, an analysis was performed on these C-terminal amino acid sequences, and a leucine-rich motif, 204LDRMLKSAAIRIL216, was detected. Replacement of the leucines in this putative nuclear export signal (NES) with neutral amino acids resulted in an exclusive nuclear localization of VP22. Furthermore, this motif was able to localize EYFP and dEYFP in the cytoplasm, and the nuclear export function of this NES could be blocked by leptomycin B. This demonstrates that this leucine-rich motif is a functional NES. These data represent the first identification of a functional NLS and NES in a herpesvirus VP22 homologue.     

Nuclear localization of enzymatically active green fluorescent protein-CTP:phosphocholine cytidylyltransferase alpha fusion protein is independent of cell cycle conditions and cell types

To address the recent controversy about the subcellular localization of CTP:phosphocholine cytidylyltransferase alpha (CTalpha), this study was designed to visualize green fluorescent protein (GFP). CTalpha fusion proteins directly and continuously under different conditions of cell cycling and in various cell lines. The GFP. CTalpha fusion proteins were enzymatically active and capable of rescuing mutant cells with a temperature-sensitive CT. The expressed GFP.CTalpha fusion protein was localized to the nucleus in all cell lines and required the N-terminal nuclear targeting sequence. Serum depletion/replenishment did not cause shuttling of CTalpha between the nucleus and cytoplasm. Moreover, the subcellular localization of CTalpha was examined continuously through all stages of the cell cycle in synchronized cells. No shuttling of CTalpha between the nucleus and cytoplasm was observed at any stage of the cell cycle. Stimulation of cells with oleate had no effect on the localization of CTalpha. The GFP.CTalpha lacking the nuclear targeting sequence stayed exclusively in the cytoplasm. Regardless of their localization, the GFP.CTalpha fusion proteins were equally active for phosphatidylcholine synthesis and mutant rescue. We conclude that the nuclear localization of CTalpha is a biological event independent of cell cycle in most mammalian cells and is unrelated to activation of phosphatidylcholine synthesis.     

Two putative alpha-helical domains of human immunodeficiency virus type 1 Vpr mediate nuclear localization by at least two mechanisms

To identify the domains of Vpr that are involved nuclear localization, we transfected HeLa cells with a panel of expression vectors that encode mutant Vpr protein with deletions or substitutions within putative domains. Immunofluorescence staining of transfected cells revealed that wild-type Vpr was localized predominantly in the nucleus and the nuclear envelope and certainly in the cytoplasm. Introduction of substitutions or deletions within alphaH1 or alphaH2 resulted, by contrast, in diffuse expression over the entire cell. In addition, double mutations within both of these alpha-helical domains led to the complete absence of Vpr from nuclei. Next, we prepared HeLa cells that express chimeric proteins which consist of the alphaH1 and alphaH2 domains fused individually with green fluorescent protein (GFP) and a Flag tag and extracted them with digitonin and Triton X-100 prior to fixation. Flag-alphaH1-GFP was detected in the nucleus but not in the cytoplasm, while Flag-alphaH2-GFP was retained predominantly in the nucleus and in a small amount in the cytoplasm. The immunostaining patterns were almost eliminated by substitutions in each chimeric protein. Thus, it appeared that the two alpha-helical domains might be involved in nuclear import by binding to certain cellular factors. Taken together, our data suggest that the two putative alpha-helical domains mediate the nuclear localization of Vpr by at least two mechanisms.     

Identification of a nuclear localization signal in mouse polycomb protein, M33

The mouse Polycomb group (PcG) protein M33 forms nuclear complexes with the products of other PcG members and maintains repressed states of developmentally important genes, including homeotic genes. In this context, nuclear localization is a prerequisite for M33 to exert its function. However, we previously found that M33 in mouse liver shuttles dynamically between the nucleus and the cytoplasm, depending on the proliferative states of cells, coupled with phosphorylation and dephosphorylation of M33 protein. To understand the mechanism and significance of this phenomenon, we identified the functional nuclear localization signal (NLS) of M33 protein. Deletion mutants that lack a particular one of three putative NLS motifs failed to localize in the nucleus. Green fluorescent protein (GFP) fused to this motif specifically localized in the nucleus. We conclude that this amino-acid stretch in M33 acts as the functional NLS for this protein.