马铃薯Y病毒HC-Pro中心区域在病毒协生作用中的主导地位

利用PCR方法获得了马铃薯病毒中国株系（PVY－C）HC－Pro基因的5个缺失突变体,构建了相应的植物表达载体。通过土壤农杆菌(Agrobacterium tumefaciens)介导法转化了烟草品种K326(Nicotina tabacum cv.k326)。PCR和Southern blot分析证明了HC－Pro基因及其缺失突变体已整合到烟草基因组中,Western blot表明它们在转基因烟草中得到了表达。侵染性试验发现HC－Pro中心区域介导转基因烟草中PVC－C和黄瓜花叶病毒（CMV）、PVY－C和马铃薯X病毒（PVX）之间的协生作用,从而明确了PVY－C HC－Pro中心区域为病毒协生作用的功能区域。     

马铃薯Y病毒HC-Pro中心区域在病毒协生作用中的主导地位

利用PCR方法获得了马铃薯病毒中国株系(PVY-C)HC-Pro基因的5个缺失突变体,构建了相应的植物表达载体。通过土壤农杆菌(Agrobacterium tumefaciens)介导法转化了烟草品种K₃₂₆(Nicotina tabacum cv.K₃₂₆)。PCR和Southern blot分析证明了HCPro基因及其缺失突变体已整合到烟草基因组中,Western blot表明它们在转基因烟草中得到了表达。侵染性试验发现HCPro中心区域介导转基因烟草中PVY-C和黄瓜花叶病毒(CMV)、PVYC和马铃薯X病毒(PVX)之间的协生作用,从而明确了PVY-C HC-Pro中心区域为病毒协生作用的功能区域。     

马铃薯Y病毒蚜传辅助因子促进马铃薯X病毒长距离运输

采用PCR和定点突变法,对马铃薯Y病毒中国株系（Chyinese strain of potato Ypotyvirus,PVY-C)蚜传辅助成分（helper component proteinase,HC-Pro)基因中心区域的CCCT基序和PTK基序进行定点改造,获得了4种突变体。然后将突变体砍降到植物表达载体pBin438中,所得到的重组体通过根癌土壤杆菌（Agrobacterium tumefaciens(Smith et Townsend)Conn）介导法转了烟草（Nicotiana tabacum L.cv.K326).Southern blotting和Western blotting分析表明4种突变体已经成功整合到烟草的基因组中,并在蛋白水平上得到了表达。马铃薯X病毒（potato X potexvirus,PVX)对转基因烟草的攻毒实验表明,4种突变体均使PVY－C HYC－Prog严重丧失了促进PVX病毒粒子在寄主体内积累和提高PVX致病性的功能,说明CCCT、PTK基序为PVY－C HYC－Pro介导PVX／PVY协生作用所必需。同时证明了HC-Pro具有增强PVX在寄主体内长距离运输的功能。     

TMV 54K基因的3个突变体介导抗病性的研究

利用PCR方法分别构建了烟草花叶病毒（TMV）中一个推测为复制酶的54－kD蛋白基因（54K）缺失N端、C端和仅余基因中部261bp的3个缺失突变体,与野生型54K一起克隆入植物中间载体p208,并通过根癌土壤杆菌（Agrobacterium tumefaciens (SDmith et Townsend)Conn）介导的方法转化烟草（Nicotiana tabacum L.）。用TMV侵染转基因植物的R0代和R1代,结果显示这3个缺失突变体均能介导对TMV的抗病性。     

马铃薯X病毒外壳蛋白的表达水平与变偶密码子使用频率的相关性

把经密码子修饰的马铃薯X病毒（Potato Virus X, PVX）外壳蛋白（Coat Protein, CP）基因和未修饰的野生型外壳蛋白基因与CaMV 35S启动子融合后,构建成相应的植物表达载体,利用农杆菌介导转化烟草。分别对修饰CP和野生CP的转基因烟草进行Western blot和ELISA分析,结果表明经密码子修饰的PVX外壳蛋白的表达量是野生型蛋白表达量的1/3～1/5。Northern blot结果表明修饰和未修饰的外壳蛋白在转录水平上是一致的。以上结果暗示外源基因中稀有密码子的数量可能是限制外源基因表达的一个因素。改变基因中稀有密码子的数量有可能成为控制基因表达的一种有效途径。     

百合查尔酮合成酶基因克隆及其转化烟草的花色表达分析

以‘西伯利亚’百合为试材,利用PCR技术克隆了查尔酮合成酶基因(CHS),构建了CHS基因的正义和反义植物表达载体,采用农杆菌介导法转化烟草叶盘,获得了转正义CHS基因的本明烟草18株,转反义CHS基因的普通烟草21株,总转化率为26.0%。高效液相色谱法(HPLC)检测结果显示,正义CHS转基因的本明烟草类黄酮含量升高14.0%～59.7%,反义CHS转基因的普通烟草类黄酮含量降低44.5%～76.4%。花色观察结果显示,正义转基因烟草的花瓣颜色未见变化,反义转基因烟草部分植株的花瓣颜色变浅。研究表明,CHS基因遗传转化是进行花色调控的有效手段之一。     

烟草黄矮双生病毒基因组突变体间的持久性互补和功能研究

应用基因突变技术,在烟草黄矮双生病毒（Ｔｏｂａｃｏｙｅｌｏｗｄｗａｒｆｇｅｍｉｎｉｖｉｒｕｓ,简称ＴｏｂＹＤＶ）基因组的正义和反义链引入或缺失碱基,从而构建成一系列移码突变体。这些突变体在个别感染的情况下,全部丧失了系统侵染三生烟植株的能力,但是,成对地进行接种,能发生持久的互补作用,重新获得系统侵染的能力。突变体的互补作用发生在重组之前。在个别感染的叶块组织中,各种反义链突变体丧失了复制能力,然而,突变体Ｖ１－、Ｖ２－和Ｖ１－Ｖ２－能高度复制,表明反义链读码框编码产物为复制所必需,Ｖ１和Ｖ２读码框编码产物与复制无关,而为病毒的转移所必需。从Ｖ１－和Ｖ２－转化叶块中再生转基因植株,发现Ｖ１－和Ｖ２－都能在植株中维持复制,但是,只有Ｖ１－引起典型的病症,表明Ｖ１编码产物与病症出现无关。这些结果将为发展ＴｏｂＹＤＶ为载体,在寄主植物中高度复制和表达外源基因提供依据。     

烟草黄矮双生病毒基因组突变体内的持久性互补和功能研究

应用基因突变技术,在烟草黄矮双生病毒（ＴｏｂＹＤＶ）基因组的正义和反义链引入或缺失碱基,从而构建成一系列移码突变体。这些突变体在个别感染的情况下,全部丧失了系统侵染三生烟植株的能力,但是,成对地进行接种,能发生持久的互补作用,重新获得系统侵染的能力。突变体的互补作用发生在重组之前。在个别感染的叶块组织中,各种反义链突变体丧失了复制能力,然而,突变体Ｖ１＾－、Ｖ２＾－和Ｖ１＾－Ｖ２＾－能高度复制,表     

改造的马铃薯Y病毒复制酶基因介导高度抗病性

提取马铃薯Y病毒中国分离株(PVY—c)的mRNA作为模板,随机六聚脱氧核苷酸和寡聚dT为引物合成了单链cDNA。通过聚合酶链式反应(PcR)获得了PVY—C的核内含体b(Nib)全长cDNA克隆。在对其进行全序列分析的基础上,构建了PVY—CNIb基因全长．5’端缺失381个碱基和Nib反义RNA三种不同形式高等植物表达载体。在土壤农杆菌LBA4404的介导下,转化烟草生产品种NC89,获得了所有三种表达载体的转基因植株。通过分子生物学检测和抗性分析发现不同形式的Nib基因序列的转基因植株对马铃薯Y病毒表现不同程度的抗性。其中,以5’端缺失的Nlb的基因转化植株表现最好,从总共20个这类转化株系中筛选到4个株系至少在100μg／m1 PVY—C接种浓度下,表现完全的抗病效果。从总共39个全长Nib基因转化株系中,仅有一个株系,在100μg／ml PVY—c的攻毒接种下具有完全的抗病性。所有33个Nib基因反义RNA的转化植株中,无一株系表现完全的抗病效果,但是有部分株系能不同程度地延缓或减轻发病程度,并有部分植株在发病后50d左右有恢复健康的趋势。虽然能够在上述3种形式的Nib基因序列的转基因植物中检测到相应的RNA的转录产物,但是均未能检测到其相应的蛋白表达产物。     

金属硫蛋白突变体的植物高效表达载体的构建及其在烟草中的表达

金属硫蛋白有α、β两个结构域（ｄｏｍ ａｉｎ）,其中α结构域优先结合Ｃｄ２＋ 和Ｈｇ２＋ ．小鼠αα突变体在大肠杆菌中已经构建并得到表达,其转基因植株已得到,可在Ｃｄ３００（３００ μｍ ｏｌ／Ｌ）中生长．为了进一步提高外源基因在烟草中的表达量,首先用ＰＣＲ 的方法设计引物,在基因翻译起始密码子ＡＴＧ 附近加入植物偏爱的碱基组合ＡＡＣＡＡＴＧ．另外,将该突变体基因插入具有双３５ Ｓ（ＣａＭＶ３５Ｓ）强启动子的植物双元表达载体ｐＧＰＴＶｄ３５Ｓ－ＢＡＲ中,获得了带有αα突变体的植物双元表达载体．通过农杆菌介导的叶盘转化法转化烟草ＮＣ８９,获得了抗除草剂的转基因植株．经ＰＣＲ－Ｓｏｕｔｈｅｒｎ 和蛋白Ｄｏｔ－ｂｌｏｔｔｉｎｇ 检测,证明了αα突变体在烟草中的嵌合与表达．抗重金属实验证明转基因烟草可以在Ｃｄ４００（４００ μｍ ｏｌ／Ｌ）中生长．     

Effect of cDNA fragments in different length derived from Potato Virus Y coat protein gene on the induction of RNA-mediated virus resistance

Potato virus Y (PVY) is a main viral pathogen infecting economic crops such as potato and tobacco plants. Genetic engineering has been so far the most effective method to produce viral resistant plants. Be-cause of the shortage of viral resistant genes in plants, cDNAs derived from viral genes were often used for induction of resistance in transgenic plants (the so- called pathogen-derived resistance)[1]. Among the genes used in the pathogen-derived resistance strategy, the coat protein gen…     

Expression of Potato Virus Y Coat Protein Gene in Transgenic Potato

Potato virus Y (PVY) N coat protein (CP) coding sequence was cloned into a plant expression vector pMON316 under the CaMV 35S promoter. Leaf discs of potato (Solanum tuberosum) were used to Agrobacterium-mediated gene transfer. A large number of regenerated putative transgenic plants were obtained based on kanamycin resistance. Using total DNA purified from transgenic plants as templates and two oligonucleotides synthesized from 5' and 3' of the PVY coat protein gene as primers, the authors carried out polymerase chain reaction (PCR) to check the presence of this gene and obtained a 0. 8 kb specific DNA fragment after 35 cycles of amplification. Southern blot indicated that the PCR product was indeed PVY CP gene which had been integrated into the potato genome. Enzyme-linked immunosorbent assay (ELISA) of our transgenic plants showed that CP gene was expressed in at least some transgenic potato plants.     

Nutritional properties of tubers of conventionally bred and transgenic lines of potato resistant to necrotic strain of Potato virus Y (PVYN)

The potential effect of genetic modification on nutritional properties of potatoes transformed to improve resistance to a necrotic strain of Potato virus Y was determined in a rat experiment. Autoclaved tubers from four transgenic lines were included to a diet in the amount of 40% and compared with the conventional cv. Irga. The experiment lasted 3 weeks and special attention was paid to nutritional properties of diets, caecal metabolism and serum indices. Genetic modification of potato had no negative effect on the chemical composition and nutritional properties of tubers, ecosystem of the caecum, activity of serum enzymes and non-specific defence mechanism of the rats. Obtained results indicate that transgenic potato with improved resistance to PVY(N): line R1F (truncated gene coding for PVY(N) polymerase in sense orientation), R2P (truncated gene coding for PVY(N) polymerase in antisense orientation), and NTR1.16 (non-translated regions of PVY(N) genome in sense orientation) are substantial and nutritional equivalence to the non-transgenic cultivar. Tubers of transgenic line NTR2.27 (non-translated regions of PVY(N) genome in antisense orientation) increased the bulk of caecal digesta and the production of SCFA as compared to tubers of the conventional cultivar and the other transgenic clones. Taking into account some deviations, it seems reasonable to undertake a long-term feeding study to confirm the nutritional properties of tubers of transgenic lines.     

Helper component‐proteinase enhances the activity of 1‐deoxy‐D‐xylulose‐5‐phosphate synthase and promotes the biosynthesis of plastidic isoprenoids in Potato virus Y‐infected tobacco

Virus‐infected plants show strong morphological and physiological alterations. Many physiological processes in chloroplast are affected, including the plastidic isoprenoid biosynthetic pathway [the 2C‐methyl‐D‐erythritol‐4‐phosphate (MEP) pathway]; indeed, isoprenoid contents have been demonstrated to be altered in virus‐infected plants. In this study, we found that the levels of photosynthetic pigments and abscisic acid (ABA) were altered in Potato virus Y (PVY)‐infected tobacco. Using yeast two‐hybrid assays, we demonstrated an interaction between virus protein PVY helper component‐proteinase (HC‐Pro) and tobacco chloroplast protein 1‐deoxy‐D‐xylulose‐5‐phosphate synthase (NtDXS). This interaction was confirmed using bimolecular fluorescence complementation (BiFC) assays and pull‐down assays. The Transket_pyr domain (residues 394–561) of NtDXS was required for interaction with HC‐Pro, while the N‐terminal region of HC‐Pro (residues 1–97) was necessary for interaction with NtDXS. Using in vitro enzyme activity assays, PVY HC‐Pro was found to promote the synthase activity of NtDXS. We observed increases in photosynthetic pigment contents and ABA levels in transgenic plants with HC‐Pro accumulating in the chloroplasts. During virus infection, the enhancement of plastidic isoprenoid biosynthesis was attributed to the enhancement of DXS activity by HC‐Pro. Our study reveals a new role of HC‐Pro in the host plant metabolic system and will contribute to the study of host–virus relationships.     

Transgenic Potato with PVY Coat Protein Gene and Its Small-Scale Field Test

Potato virus Y (PVY) infection may cause a severe yield depression up to 80%. To develop the potato (Solanum tuberosum L. ) cultivars that resist PVY infection is very crucial in potato production. The authors have been cloned the coat protein gene of PVY from its Chinese isolate. A chimaeric gene containing the cauliflower mosaic virus 35S promoter and PVY coat protein coding region was introduced into the potato cultivars “Favorita”, “Tiger head” and “K4” via Agrobacterium tumefaciens. Results from PCR and Southern blot analysis confirmed that the foreign gene has integrated into the potato chromosomes. These transgenic potato plants were mechanically inoculated with PVY virus (20 mg/L). The presence of the virus in the potato plants was determined by ELISA and method of back inoculation into tobacco. The authors observed a drastic reduction in the accumulation of virus in some transgenic potato lines. Furthermore, some transgenic potato lines produced more tubers per plant than the untransformed potato did, and the average weight of these transgenic plant tubers was also increased. In the field test, the morphology and development of these transgenic potato plants were normal, 3 transgenic lines of “Favorita” exhibited a higher yield than the untrasformed virus-free potato with an increase ranged from 20% to 30%. From these transgenic lines, it will be very hopeful to develop a potato cultivar which not only has a significant resistance to PVY infection, but also a good harvest in potato production.     

一种基于过敏性反应机制的抗植物病毒侵染策略

基于植物的过敏性反应机制,构建了PVY Nib基因和来自于细菌Bacillus amy—loliquefaciens的一类Rnase基因Barnase基因的融合基因的植物表达载体。在此表达载体内两基因的拼接处,保留了原来PVY蛋白酶识别PVYNIb和CP蛋白剪切位点的七肽保守序列。通过农杆菌介导获得此融台基因的转基因烟草植株。病毒侵染试验表明,转基因植物在病毒侵染后,发病症状被改变。少部分转融合基因的植株对病毒侵染表现局部抗性。