大麦黄矮病毒运动蛋白是RNA沉默抑制因子

大麦黄矮病毒(barley yellow dwarf virus,BYDV)属黄症病毒科家族,其基因组包含6个开放阅读框(open reading frames,ORFs).将BYDV的6个基因分别克隆到pWEIMING101载体上,得到重组基因.电击转化农杆菌后,利用农杆菌瞬时表达方法渗透注射转GFP基因的本氏烟草16c植株的叶片,在长波长紫外灯下观察GFP的表达,并通过Northern blot证明所得现象.研究结果表明,BYDV的PAV株系ORF4编码的运动蛋白(movement protein,MP)是RNA沉默抑制因子,其表达可以抑制局部和系统RNA沉默.BYDV-MP与GFP的双链RNA(dsGFP)共表达后仍能抑制RNA沉默,荧光强度与叶片中GFP的mRNA和其沉默降解形成的siRNA的量有对应关系,其N端核定位序列对抑制局部基因沉默起主要作用,第5、6位氨基酸是抑制基因沉默的关键氨基酸.BYDV-MP单独渗透注射的部位均产生细胞死亡.     

病毒诱导的PVX cp转基因沉默及其DNA甲基化

利用PCR方法获得了马铃薯X病毒(PVX)外壳蛋白(CP)基因(cp),并将其构建到植物表达载体中,利用农杆菌介导的叶盘法转化烟草(Nicotiana tabacum L.).Northern杂交及Run on实验表明有3株转基因烟草发生了转录后基因沉默.发生沉默的cp基因的甲基化分析结果表明,发生转录后基因沉默的cp基因发生了不同程度的甲基化,说明DNA甲基化并没有完全抑制cp基因的转录.利用PVX病毒对外壳蛋白正常表达的转基因烟草进行接毒,Northern杂交检测结果表明,病毒诱导cp发生了基因沉默.进一步的Run on结果表明,转基因烟草中cp基因在沉默前后转录速率并没有发生变化,说明病毒诱导的沉默是一种转录后沉默.对cp基因沉默前后的甲基化分析表明,病毒的侵染导致了cp基因甲基化程度的增加.     

病毒诱导的PVX cp转基因沉默及其DNA甲基化

利用PCR方法获得了马铃薯X病毒(PVX)外壳蛋白(CP)基因(cp),并将其构建到植物表达载体中,利用农杆菌介导的叶盘法转化烟草(Nicotiana tabacum L.)。Northern杂交及Run on实验表明有3株转基因烟草发生了转录后基因沉默。发生沉默的cp基因的甲基化分析结果表明,发生转录后基因沉默的cp基因发生了不同程度的甲基化,说明DNA甲基化并没有完全抑制cp基因的转录。利用PVX病毒对外壳蛋白正常表达的转基因烟草进行接毒,Northern杂交检测结果表明,病毒诱导cp发生了基因沉默。进一步的Run on结果表明,转基因烟草中cp基因在沉默前后转录速率并没有发生变化,说明病毒诱导的沉默是一种转录后沉默。对cp基因沉默前后的甲基化分析表明,病毒的侵染导致了cp基因甲基化程度的增加。     

马铃薯卷叶病毒P0蛋白抑制RNA沉默及其与AGO蛋白的相互作用

马铃薯卷叶病毒(Potato leafroll virus,PLRV)P0是由开放阅读框1(ORF1)所编码,利用农杆菌介导的瞬时表达技术渗透注射转绿色荧光蛋白(GFP)基因的16c烟草叶片发现PLRV-P0能够抑制由GFP mRNA引起的基因沉默,结果表明PLRV-P0是马铃薯卷叶病毒编码的一个基因沉默抑制因子。通过序列分析发现PLRV-P0基因序列中含有两个重复的WG基序,我们将PLRV-P0基因序列中第87位和第140位的色氨酸(W)点突变为丙氨酸(A)(命名为P0WA),构建植物表达载体pCAMBIA1300-CE-P0,pCAMBIA1300-CE-P0WA,农杆菌渗透注射本氏(Nicotiana benthamiana)烟草叶片,通过荧光显微镜观察发现PLRV-P0和AGO共同注射后有绿色荧光出现而PLRV-P0WA和AGO共同注射后则没有绿色荧光出现。研究结果初步表明,PLRV-P0能够和AGO蛋白发生相互作用,重复的WG基序是其与AGO蛋白相互作用的关键氨基酸。     

重组马铃薯X病毒载体介导的烟草γ-微管蛋白基因沉默

用重组马铃薯X病毒(potato virus X,PVX)载体将γ-微管蛋白反义基因导入烟草(Nicotiana tabacum var.Samsun NN),得到了γ-微管蛋白基因沉默的烟草植株。它与侵染PVX空载体的正对照相比有明显的差异:不同形态的叶片分层交替生长;到生殖期所有的花苞都提前脱落;小孢子不能发育到四分体阶段。沉默的形态反应主要起始于顶端幼嫩组织。在沉默过程中除存在基因沉默及恢复现象外还出现靶基因水平的陡然升高,甚至有时会明显反超过正常对照水平。     

利用病毒载体在烟草中瞬时表达融合HBsAg基因

利用马铃薯PVX病毒载体构建了外源人工融合乙肝表面抗原HBsAg基因的表达载体,在烟草中利用农杆菌介导进行瞬时表达,以快速鉴定外源基因瞬时表达的状况以及重组蛋白的免疫活性。利用PCR技术从含有人工融合HBsAg基因的表达载体中分别扩增出LP PreS1 PreS2 S、PreS1 PreS2 S、PreS2 S序列,将其分别与PVX病毒载体pgR106连接,构建成PVX-LP、PVX-S1和PVX-S2等3个转化载体,并将此载体导入农杆菌菌株GV3101中用于侵染烟草植株叶片。感染植株经RT-PCR、RNA Dot blotting和HBsAg蛋白的ELISA检测显示,3个人工融合的HBsAg基因均可在植物体内得到转录,翻译成具有活性的蛋白。结果表明,外源融合HB-sAg基因经过植物病毒载体瞬时表达系统可以在植物系统中正常转录和翻译。     

马铃薯X病毒载体介导的乙肝病毒表面抗原在烟草中的表达

目的:利用马铃薯X病毒(PVX)表达载体,在本生烟草中表达乙肝病毒表面抗原(HBsAg),为生产植物疫苗提供一条快速高效的新途径.方法:将HBsAg基因克隆进PVX表达载体,电转化农杆菌,侵染本生烟的叶片、茎和根.结果与结论:采用ELISA检测重组HBsAg的表达水平,SDS-PAGE确认其大小,Western印迹分析表明重组蛋白可与鼠抗HBsAg单克隆抗体发生特异性反应.HBsAg蛋白表达量在幼小叶片中远高于已伸展的叶片,在叶片中的表达量远高于茎根;表达量会随侵染后时间发生一定的变化,但因植株而异;重组蛋白在可溶性蛋白中的含量最高可达796.81 ng/mg.     

复制酶与运动蛋白编码基因的突变对烟草花叶病毒的弱化效应

番茄花叶病毒弱毒疫苗K(ToMV-K)的复制酶基因和运动蛋白基因分别具有乳石和赭石突变的特征. 为了对这一致弱特征进行扩展研究, 用PCR介导的定点突变技术, 对烟草花叶病毒普通株中国分离物(TMV-Cv)复制酶基因和运动蛋白基因分别进行乳石突变(UGA)和赭石突变(UAA), 构建了复制酶单突变体——TMV-Cv^rase, 运动蛋白单突变体——TMV-Cv^mp和复制酶与运动蛋白双突变体——TMV-Cv^rase-mp. 烟草侵染试验发现, TMV-Cv^mp和TMV-Cv^rase-mp能侵染枯斑(Xanthi NC)和系统(K326)寄主, 后者侵染普通烟K326仅出现少量轻微的花叶症状; 子代病毒的电子显微镜观察、重复接种试验及其核酸的RNA斑点杂交、RT-PCR扩增与测序结果表明, TMV-Cv^mp和TMV-Cv^rase-mp子代病毒与TMV-Cv的大小和形态基本一致, 具有完整和稳定的侵染、复制和繁殖能力, 且其基因组仍保持着突变, 而复制酶单突变体TMV-Cv^rase不能侵染烟草. 以上结果表明, 复制酶与运动蛋白的乳石突变与赭石突变协同致弱TMV-Cv对烟草的侵染症状, 从而暗示ToMV-K基因组的这种突变模式也可以用于其他植物病毒的致弱研究.     

人细小病毒B19 VP1u多克隆抗体的制备及其保守区外N端氨基酸对sPLA2活性影响的初步研究

【目的】制备人细小病毒B19-VP1u的多克隆抗体,探究VP1u多克隆抗体及其保守区外N端氨基酸对病毒磷脂酶A2活性的影响。【方法】首先通过分子克隆方法构建相应原核表达载体;利用原核表达系统纯化含MBP标签的VP1u全长及N端系列截短突变融合蛋白;接着免疫新西兰大白兔制备全长VP1u蛋白的多克隆抗体;最后利用磷脂酶A2活性检测试剂盒检测了纯化蛋白的磷脂酶A2活性。【结果】Western blot及免疫荧光实验证实制备的多克隆抗体具有较高的特异性;磷脂酶A2活性检测发现全长VP1u-MBP融合蛋白具有一定的活性,该活性可以被VP1u的抗体抑制;N端保守区外截短系列蛋白的酶活检测发现,N端截掉12个氨基酸时酶活降低53%,截掉67个氨基酸时酶活性几乎完全丧失。【结论】首次发现VP1u保守区外N端氨基酸,尤其是第12个氨基酸前的区域以及第22-67个氨基酸之间的区域,对sPLA2活性的保持具有重要意义,推测该区域可能对维持正常的蛋白构象起重要的作用;而其特异性多克隆抗体的制备也为进一步研究B19病毒VP1u在病毒复制周期的作用奠定基础。     

外壳蛋白羧端序列缺失对烟草花叶病毒侵染性的影响

对野生型烟草花叶病毒(TMV-U1)的外壳蛋白羧端序列进行系列缺失突变,观察到TMV-U1株系的外壳蛋白羧端序列缺失6个氨基酸(保留152个氨基酸),仍能较强系统侵染烟草并高水平表达外壳蛋白,且能在新生叶里复制大量完整的病毒粒子。该研究结果表明：外壳蛋白羧端6个氨基酸序列并非烟草花叶病毒感染和复制所必需,并对利用外壳蛋白羧端缺失型病毒载体表达外源多肽具有一定的启示性。     

Hijacking of the nucleolar protein fibrillarin by TGB1 is required for cell‐to‐cell movement of Barley stripe mosaic virus

Barley stripe mosaic virus (BSMV) Triple Gene Block1 (TGB1) is a multifunctional movement protein with RNA‐binding, ATPase and helicase activities which mainly localizes to the plasmodesmata (PD) in infected cells. Here, we show that TGB1 localizes to the nucleus and the nucleolus, as well as the cytoplasm, and that TGB1 nuclear‐cytoplasmic trafficking is required for BSMV cell‐to‐cell movement. Prediction analyses and laser scanning confocal microscopy (LSCM) experiments verified that TGB1 possesses a nucleolar localization signal (NoLS) (amino acids 95–104) and a nuclear localization signal (NLS) (amino acids 227–238). NoLS mutations reduced BSMV cell‐to‐cell movement significantly, whereas NLS mutations almost completely abolished movement. Furthermore, neither the NoLS nor NLS mutant viruses could infect Nicotiana benthamiana systemically, although the NoLS mutant virus was able to establish systemic infections of barley. Protein interaction experiments demonstrated that TGB1 interacts directly with the glycine–arginine‐rich (GAR) domain of the nucleolar protein fibrillarin (Fib2). Moreover, in BSMV‐infected cells, Fib2 accumulation increased by about 60%–70% and co‐localized with TGB1 in the plasmodesmata. In addition, BSMV cell‐to‐cell movement in fib2 knockdown transgenic plants was reduced to less than one‐third of that of non‐transgenic plants. Fib2 also co‐localized with both TGB1 and BSMV RNA, which are the main components of the ribonucleoprotein (RNP) movement complex. Collectively, these results show that TGB1–Fib2 interactions play a direct role in cell‐to‐cell movement, and we propose that Fib2 is hijacked by BSMV TGB1 to form a BSMV RNP which functions in cell‐to‐cell movement.     

Interaction between cucumber green mottle mosaic virus MP and CP promotes virus systemic infection

The movement protein (MP) and coat protein (CP) of tobamoviruses play critical roles in viral cell-to-cell and long-distance movement, respectively. Cucumber green mottle mosaic virus (CGMMV) is a member of the genus Tobamovirus. The functions of CGMMV MP and CP during viral infection remain largely unclear. Here, we show that CGMMV MP can interact with CP in vivo, and the amino acids at positions 79–128 in MP are vital for the MP–CP interaction. To confirm this finding, we mutated five conserved residues within the residue 79–128 region and six other conserved residues flanking this region, followed by in vivo interaction assays. The results showed that the conserved threonine residue at the position 107 in MP (MP^T107) is important for the MP–CP interaction. Substitution of T107 with alanine (MP^T107A) delayed CGMMV systemic infection in Nicotiana benthamiana plants, but increased CGMMV local accumulation. Substitutions of another 10 conserved residues, not responsible for the MP–CP interaction, with alanine inhibited or abolished CGMMV systemic infection, suggesting that these 10 conserved residues are possibly required for the MP movement function through a CP-independent manner. Moreover, two movement function-associated point mutants (MP^F17A and MP^D97A) failed to cause systemic infection in plants without impacting on the MP–CP interaction. Furthermore, we have found that co-expression of CGMMV MP and CP increased CP accumulation independent of the interaction. MP and CP interaction inhibits the salicylic acid-associated defence response at an early infection stage. Taken together, we propose that the suppression of host antiviral defence through the MP–CP interaction facilitates virus systemic infection.     

Retention and mobility of the mammalian lamin B receptor in the plant nuclear envelope

Background information. In a previous study, we showed that GFP (green fluorescent protein) fused to the N‐terminal 238 amino acids of the mammalian LBR (lamin B receptor) localized to the NE (nuclear envelope) when expressed in the plant Nicotiana tabacum. The protein was located in the NE during interphase and migrated with nuclear membranes during cell division. Targeting and retention of inner NE proteins requires several mechanisms: signals that direct movement through the nuclear pore complex, presence of a transmembrane domain or domains and retention by interaction with nuclear or nuclear‐membrane constituents. Results. Binding mutants of LBR—GFP were produced to investigate the mechanisms for the retention of LBR in the NE. FRAP (fluorescence recovery after photobleaching) analysis of mutant and wild‐type constructs was employed to examine the retention of LBR—GFP in the plant NE. wtLBR—GFP (wild‐type LBR—GFP) was shown to have significantly lower mobility in the NE than the lamin‐binding domain deletion mutant, which showed increased mobility in the NE and was also localized to the endoplasmic reticulum and punctate structures in some cells. Modification of the chromatin‐binding domain resulted in the localization of the protein in nuclear inclusions, in which it was immobile. Conclusions. As expression of truncated LBR—GFP in plant cells results in altered targeting and retention compared with wtLBR—GFP, we conclude that plant cells can recognize the INE (inner NE)‐targeting motif of LBR. The altered mobility of the truncated protein suggests that not only do plant cells recognize this signal, but also have nuclear proteins that interact weakly with LBR.     

Function of two discrete regions is required for nuclear localization of polymerase basic protein 1 of A/WSN/33 influenza virus (H1 N1).

Polymerase basic protein 1 (PB1) of influenza virus (A/WSN/33), when expressed from cloned cDNA in the absence of other viral proteins, accumulates in the nucleus. We have examined the location and nature of the nuclear localization signal of PB1 by using deletion mutants and chimeric constructions with chicken muscle pyruvate kinase, a cytoplasmic protein. Our studies showed some novel features of the nuclear localization signal of PB1. The signal was present internally within residues 180 to 252 of PB1. Moreover, unlike most nuclear localization signals, it was not a single stretch of contiguous amino acids. Instead, it possessed two discontinuous regions separated by an intervening sequence which could be deleted without affecting its nuclear localization property. On the other hand, deletion of either of the two signal regions rendered the protein cytoplasmic, indicating that the function of both regions is required for nuclear localization and that one region alone is not sufficient. Both of these signal regions contained short stretches of basic residues. Possible ways by which this novel bipartite signal can function in nuclear localization are discussed.     

The cis-expression of the coat protein of turnip mosaic virus is essential for viral intercellular movement in plants

To establish infection, plant viruses are evolutionarily empowered with the ability to spread intercellularly. Potyviruses represent the largest group of known plant-infecting RNA viruses, including many agriculturally important viruses. To better understand intercellular movement of potyviruses, we used turnip mosaic virus (TuMV) as a model and constructed a double-fluorescent (green and mCherry) protein-tagged TuMV infectious clone, which allows distinct observation of primary and secondary infected cells. We conducted a series of deletion and mutation analyses to characterize the role of TuMV coat protein (CP) in viral intercellular movement. TuMV CP has 288 amino acids and is composed of three domains: the N-terminus (amino acids 1–97), the core (amino acids 98–245), and the C-terminus (amino acids 246–288). We found that deletion of CP or its segments amino acids 51–199, amino acids 200–283, or amino acids 265–274 abolished the ability of TuMV to spread intercellularly but did not affect virus replication. Interestingly, deletion of amino acids 6–50 in the N-terminus domain resulted in the formation of aberrant virions but did not significantly compromise TuMV cell-to-cell and systemic movement. We identified the charged residues R178 and D222 within the core domain that are essential for virion formation and TuMV local and systemic transport in plants. Moreover, we found that trans-expression of the wild-type CP either by TuMV or through genetic transformation-based stable expression could not rescue the movement defect of CP mutants. Taken together these results suggest that TuMV CP is not essential for viral genome replication but is indispensable for viral intercellular transport where only the cis-expressed CP is functional.     

Identification and characterization of nuclear localization signals within the nucleocapsid protein VP15 of white spot syndrome virus

The nucleocapsid protein VP15 of white spot syndrome virus (WSSV) is a basic DNA-binding protein. Three canonical bipartite nuclear localization signals (NLSs), called NLS1 (aa 11-27), NLS2 (aa 33-49) and NLS3 (44-60), have been detected in this protein, using the ScanProsite computer program. To determine the nuclear localization sequence of VP15, the full-length open reading frame, or the sequence of one of the three NLSs, was fused to the green fluorescent protein (GFP) gene, and transiently expressed in insect Sf9 cells. Transfection with full-length VP15 resulted in GFP fluorescence being distributed exclusively in the nucleus. NLS 1 alone could also direct GFP to the nucleus, but less efficiently. Neither of the other two NLSs (NLS2 and 3) was functional when expressed alone, but exhibited similar activity to NLS1 when they were expressed as a fusion peptide. Furthermore, a mutated VP15, in which the two basic amino acids (11RR12) of NLSI were changed to two alanines (11AA12), caused GFP to be localized only in the cytoplasm of Sf9 cells. These results demonstrated that VP15, as a nuclear localization protein, needs cooperation between its three NLSs, and that the two residues (11RR12) of NLS1 play a key role in transporting the protein to the nucleus.     

Transient expression of <Emphasis Type="Italic">Human papillomavirus</Emphasis> type 16 L2 epitope fused to N- and C-terminus of coat protein of <Emphasis Type="Italic">Potato virus X</Emphasis> in plants

Transient expression of foreign genes based on plant viral vectors is a suitable system for the production of relevant immunogens that can be used for the development of a new generation of vaccines against a variety of infectious diseases. In the present study the epitope derived from HPV-16 L2 minor capsid protein (amino acids 108–120) was expressed from Potato virus X (PVX)-based vector pGR106 as N- or C-terminal fusion with the PVX coat protein (PVX CP) in transgenic Nicotiana benthamiana plants. The fusion protein L2_108-120-PVX CP was successfully expressed in plants at a level of 170 mg/kg of fresh leaf tissue. The C-terminal fusion protein PVX CP- L2_108-120 was expressed using mutated vector sequence to avoid homologous recombination at a level of 8 mg/kg of fresh leaf tissue. Immunogenicity of L2_108-120-PVX CP virus-like particles was tested after immunization of mice by subcutaneous injection or tattoo administration. In animal sera the antibodies against the PVX CP and the L2_108-120 epitope were found after both methods of vaccine delivery.     

猪瘟病毒Core蛋白核仁定位序列鉴定

黄病毒科病毒核衣壳蛋白的核仁定位在病毒颗粒包装与病毒复制中发挥重要作用。为鉴定黄病毒科的猪瘟病毒Core蛋白核仁定位序列,本研究构建了将Core蛋白、截短突变体和氨基酸位点突变体分别与增强型绿色荧光蛋白(enhanced green fluorescent protein, EGFP )融合的真核表达质粒,转染至PK15细胞后进行表达和定位分析,结果显示 Core蛋白核仁定位序列为PESRKKL,其关键氨基酸为R76K77,对理解猪瘟病毒Core蛋白结构与功能和为后续研究Core蛋白在病毒复制及颗粒包装中的作用有重要意义。     

Human cytomegalovirus UL84 localizes to the cell nucleus via a nuclear localization signal and is a component of viral replication compartments

The UL84 open reading frame encodes a protein that is required for origin-dependent DNA replication and interacts with the immediate-early protein IE2 in lytically infected cells. Transfection of UL84 expression constructs showed that UL84 localized to the nucleus of transfected cells in the absence of any other viral proteins and displayed a punctate speckled fluorescent staining pattern. Cotransfection of all the human cytomegalovirus replication proteins and oriLyt, along with pUL84-EGFP, showed that UL84 colocalized with UL44 (polymerase accessory protein) in replication compartments. Experiments using infected human fibroblasts demonstrated that UL84 also colocalized with UL44 and IE2 in viral replication compartments in infected cells. A nuclear localization signal was identified using plasmid constructs expressing truncation mutants of the UL84 protein in transient transfection assays. Transfection assays showed that UL84 failed to localize to the nucleus when 200 amino acids of the N terminus were deleted. Inspection of the UL84 amino acid sequence revealed a consensus putative nuclear localization signal between amino acids 160 and 171 (PEKKKEKQEKK) of the UL84 protein.