Volatiles from potato plants infected with potato leafroll virus attract and arrest the virus vector, Myzus persicae (Homoptera: Aphididae)

The influence of viral disease symptoms on the behaviour of virus vectors has implications for disease epidemiology. Here we show that previously reported preferential colonization of potatoes infected by potato leafroll virus (genus Polerovirus) (luteovirus) (PLRV) by alatae of Myzus persicae, the principal aphid vector of PLRV, is influenced by volatile emissions from PLRV-infected plants. First, in our bioassays both differential immigration and emigration were involved in preferential colonization by aphids of PLRV-infected plants. Second, M. persicae apterae aggregated preferentially, on screening above leaflets of PLRV-infected potatoes as compared with leaflets from uninfected plants, or from plants infected with potato virus X (PVX) or potato virus Y (PVY). Third, the aphids aggregated preferentially on screening over leaflet models treated with volatiles collected from PLRV-infected plants as compared with those collected from uninfected plants. The specific cues eliciting the aphid responses were not determined, but differences between headspace volatiles of infected and uninfected plants suggest possible ones.     

Effect of an alternate weed host, hairy nightshade, Solanum sarrachoides, on the biology of the two most important potato leafroll virus (Luteoviridae: Polerovirus) vectors, Myzus persicae and Macrosiphum euphorbiae (Aphididae: Homoptera)

Hairy nightshade, Solanum sarrachoides (Sendtner), is a ubiquitous weed in potato agro-ecosystems and nonagricultural lands of southeastern Idaho and the Pacific Northwest. This weed increases the complexity of the Potato leafroll virus (PLRV) (Luteoviridae: Polervirus)-potato pathosystem by serving as aphid and virus reservoir. Previous field studies showed higher densities of green peach aphid, Myzus persicae (Sulzer), and potato aphid, Macrosiphum euphorbiae (Thomas), the two most important vectors of PLRV, on S. sarrachoides compared with potato plants in the same fields. Some of the S. sarrachoides plants sampled in these surveys tested positive for PLRV. Viral infections can alter the physiology of plant hosts and aphid performance on such plants. To understand better the potential effects of S. sarrachoides on the PLRV-potato-aphid pathosystem, the life histories of M. persicae and M. euphorbiae were compared on virus-free and PLRV-infected S. sarrachoides and potato. Individual nymphs of each aphid species were held in clip cages on plants from each treatment to monitor their development, survival, and reproductive output. Nymphal survival for both aphids across plant species was higher on S. sarrachoides than on potato, and, within plant species, it was higher on PLRV-infected plants than on noninfected plants. With a few exceptions, similar patterns occurred for fecundity, reproductive periods, adult longevity, and intrinsic rate of increase. The enhanced performance of aphids on S. sarrachoides and on PLRV-infected plants could alter the vector population dynamics and thus the PLRV-disease epidemiology in fields infested with this weed.     

FACTORS AFFECTING THE SPREAD OF APHID-BORNE VIRUSES IN POTATO IN EASTERN SCOTLAND: I. OVERWINTERING OF POTATO APHIDS, PARTICULARLY MYZUS PERSICAE (SULZER)

Three species of potato aphids, Myzus persicae (Sulzer), Macrosiphum euphorbiae (Thomas) and Aulacorthum solani (Kltb.), overwinter in eastern Scotland, primarily as apterae on perennial, glasshouse, frame and brassica crops. Brassica crops are the commonest hosts of overwintering Myzus persicae , the principal vector of potato leaf roll and Y viruses, and these crops are concentrated in the market-gardening areas of the Lothians and Moray. Although crops of savoy cabbage and brussels sprout often carried numerous M.persicae during the winter, spring cabbage, cabbage for seed and broccoli seem the most important overwintering hosts because they usually persist until mid-May, long enough to allow the development and dispersal of alatae to spring-planted crops. Many alatae dispersed during July and August from crops colonized in spring. Although M. persicae overwintered as eggs on peach and viviparously on plants in glasshouses, the influence of such sites, which are generally distributed throughout the main seed-potato growing areas of Angus, Perth and Fife, was local and unless numerous M. persicae survive the winter on weeds, the market-garden area of the Lothians is probably the most important source from which this aphid disperses in spring and early summer to colonize potato crops in eastern Scotland.     

Infection of potato plants with potato leafroll virus changes attraction and feeding behaviour of Myzus persicae

Potato leafroll virus (PLRV; genus Polerovirus, family Luteoviridae) is a persistently transmitted circulative virus that depends on aphids for spreading. The primary vector of PLRV is the aphid Myzus persicae (Sulzer) (Homoptera: Aphididae). Solanum tuberosum L. potato cv. Kardal (Solanaceae) has a certain degree of resistance to M. persicae: young leaves seem to be resistant, whereas senescent leaves are susceptible. In this study, we investigated whether PLRV‐infection of potato plants affected aphid behaviour. We found that M. persicae's ability to differentiate headspace volatiles emitted from PLRV‐infected and non‐infected potato plants depends on the age of the leaf. In young apical leaves, no difference in aphid attraction was found between PLRV‐infected and non‐infected leaves. In fact, hardly any aphids were attracted. On the contrary, in mature leaves, headspace volatiles from virus infected leaves attracted the aphids. We also studied the effect of PLRV‐infection on probing and feeding behaviour (plant penetration) of M. persicae using the electrical penetration graph technique (DC system). Several differences were observed between plant penetration in PLRV‐infected and non‐infected plants, but only after infected plants showed visual symptoms of PLRV infection. The effects of PLRV‐infection in plants on the behaviour of M. persicae, the vector of the virus, and the implications of these effects on the transmission of the virus are thoroughly discussed.     

Characterization of the expression and inheritance of potato leafroll virus (PLRV) and potato virus Y (PVY) resistance in three generations of germplasm derived from Solanum etuberosum

Potato virus Y (PVY) and potato leafroll virus (PLRV) are two of the most important viral pathogens of potato. Infection of potato by these viruses results in losses of yield and quality in commercial production and in the rejection of seed in certification programs. Host plant resistance to these two viruses was identified in the backcross progeny of a Solanum etuberosum Lindl. somatic hybrid. Multiple years of field evaluations with high-virus inoculum and aphid populations have shown the PVY and PLRV resistances of S. etuberosum to be stably expressed in two generations of progeny. However, while PLRV resistance was transmitted and expressed in the third generation of backcrossing to cultivated potato (Solanum tuberosum L. subsp. tuberosum), PVY resistance was lost. PLRV resistance appears to be monogenic based on the inheritance of resistance in a BC₃ population. Data from a previous evaluation of the BC₂ progeny used in this study provides evidence that PLRV resistance was partly conferred by reduced PLRV accumulation in foliage. The field and grafting data presented in this study suggests that resistance to the systemic spread of PLRV from infected foliage to tubers also contributes to the observed resistance from S. etuberosum. The PLRV resistance contributed by S. etuberosum is stably transmitted and expressed through sexual generations and therefore would be useful to potato breeders for the development of PLRV resistant potato cultivars.     

Evaluation of hairy nightshade as an inoculum source for aphid-mediated transmission of potato leafroll virus

Potato leafroll virus (PLRV) causes one of the most serious aphid-transmitted diseases affecting yield and quality of potatoes, Solanum tuberosum (L.), grown in the United States. The green peach aphid, Myzus persicae (Sulzer), is considered to be by far the most efficient vector of this virus. Even the most strict aphid control strategy may not prevent the spread of PLRV unless measures also are taken to keep virus source plants within and outside the crop at a minimum. Hairy nightshade, Solanum sarrachoides (Sendtner), is one of the preferred weed hosts for green peach aphid. The potential of this weed as an aphid reservoir and virus source and its spread or perpetuation were investigated. With the use of double antibody sandwich enzyme-linked immunosorbent assay, it was confirmed that green peach aphid can transmit PLRV to hairy nightshade and that aphids can become viruliferous after feeding on infected hairy nightshade plants. Transmission from hairy nightshade to potato is 4 times the rate of potato to potato or potato to hairy nightshade. The green peach aphid preferred hairy nightshade over potato plants and reproduced at a higher rate on hairy nightshade than on potato. Therefore, a low level of PLRV-hairy nightshade infection could enhance the disease spread in the field.     

Potato leafroll virus (PLRV) and Potato virus Y (PVY) influence vegetative growth, physiological metabolism, and microtuber production of in vitro-grown shoots of potato (Solanum tuberosum L.)

Effects of Potato leafroll virus (PLRV) and Potato virus Y (PVY) on vegetative growth, physiological metabolism and microtuber production were investigated using in vitro shoot cultures. The results showed that parameters of shoot growth including bud break percentage, shoot length, and node number and length were markedly reduced in the diseased shoots. These negative effects were much more pronounced in shoots co-infected with PLRV and PVY than in those singly infected with either PLRV or PVY. The inhibitive effects on root developments measured by root number and length were observed only in shoots co-infected with PLRV and PVY. Significantly lower contents of chl-a, chl-b and total chl were found in virus infected shoots than in healthy ones. There were striking differences in contents of total soluble protein observed between healthy shoots and PLVR and PVY co-infected ones. The content of total soluble sugar was highest in shoots co-infected with PLRV and PVY, and lowest in healthy shoots. Furthermore, there were no significant differences found in the level of endogenous indole-acetic acid among healthy shoots verses virus infected shoots. However, the level of zeatin-ribosome was much higher in healthy shoots than in virus infected ones. Yet, both healthy and single PLRV infected shoots produced similar levels of gibberillic acid 3, which were much higher than those of PVY single-infected shoots and PLRV and PVY co-infected shoots. Also, there were no significant differences in the number of microtubers among healthy shoots, PLVR single or PVY single infected shoots, but shoots co-infected with PLRV and PVY produced the lowest number of microtubers. Overall, the healthy shoots produced the largest size of microtubers and the highest percentage of microtubers ≥5 mm in diameter.     

Green peach aphid (Homoptera: Aphididae) action thresholds for controlling the spread of potato leafroll virus in Idaho.

Arbitrary green peach aphid, Myzus persicae (Sulzer), action thresholds (0, 5, 10, 20, and 40 aphids per 100 leaves) were tested in 3 yr of field experimentation to determine if they could be maintained and if they would significantly impact aphid densities and limit the incidence of potato leafroll virus (PLRV). In 1997 and 1998, significant linear relationships between thresholds and final percentage of PLRV (expressed as the percentage of tubers infected with PLRV) were observed: there was a trend toward lower PLRV incidence with decreasing action threshold in 1999. There were significant relationships between thresholds and mean number of apterous aphids in 1998 and 1999, indicating that reduction of PLRV resulted from reduced within-field spread by apterae. In almost all cases, aphid densities exceeded threshold levels from one week to the next, clearly showing that the thresholds could not be maintained. Over all experiments, four to nine seasonal applications of methamidophos were warranted by the magnitude of the threshold. Imidacloprid applied at planting to the zero aphid threshold reduced the number of methamidophos applications from nine in the insecticide-at-detection treatment to five. A revised within-field green peach aphid management plan is recommended that includes systemic insecticide applied at planting, aphid sampling every 3-4 d, and foliar insecticide application following aphid detection.     

PVY侵染后烟草营养成分的变化及其对介体烟蚜生长发育的影响

【目的】明确马铃薯Y病毒(potato virus Y,PVY)侵染后诱导的烟草营养成分的变化及其对烟蚜Myzus persicae生命特性的影响,旨在进一步解析PVY-烟草-烟蚜三者间的互作机制。【方法】通过蒽酮比色法和氨基酸自动分析仪测定了PVY不同侵染时期烟株体内的可溶性糖和游离氨基酸含量的变化;测定和比较了感病与健康烟草植株上烟蚜种群生长发育、成虫寿命、繁殖力和有翅蚜产生量的差异性。【结果】PVY侵染前、中、后期(分别为侵染后5,12和20 d)的烟草叶片中游离氨基酸的总量均显著高于健康烟草叶片。相较于健康烟草叶片,在PVY侵染前期的烟草叶片中,谷氨酸、脯氨酸、天冬氨酸、色氨酸、缬氨酸、赖氨酸和组氨酸的含量显著增加;PVY侵染中期,感病叶片中丝氨酸含量显著下降,谷氨酸、天冬氨酸、色氨酸、缬氨酸、亮氨酸、苯丙氨酸、精氨酸和组氨酸含量显著提高;PVY侵染后期,感病叶片中甘氨酸含量显著下降,谷氨酸、脯氨酸、天冬氨酸、苏氨酸、缬氨酸、亮氨酸、丙氨酸、苯丙氨酸、组氨酸、酪氨酸和精氨酸含量显著提高。在PVY侵染的前期和中期,感病叶片中的可溶性糖含量显著高于健康烟叶,而在侵染后期感病叶片中可溶性糖含量显著低于健康烟草叶片的。PVY侵染前期和中期的烟草叶片中总糖和总游离氨基酸的含量比值显著高于健康烟草叶片中的。在PVY侵染的烟草植株和健康烟草植株上取食的烟蚜其发育历期、若蚜历期、成蚜繁殖期、繁殖后期、寿命、烟蚜种群的内禀增长率、周限增长率和平均世代周期均无显著差异,但在感病烟草植株上取食的烟蚜成蚜繁殖前期显著缩短,其繁殖力和净生殖率显著提高。相较于健康烟草植株,在PVY侵染烟草植株上定殖的烟蚜种群有翅蚜发生的高峰期提前。【结论】PVY侵染前期和中期提高了寄主烟草的营养品质,从而提高了烟蚜的繁殖力。侵染后期烟草营养品质的下降,促使烟蚜种群有翅蚜的产生和扩散,从而有利于PVY自身的传播。     

Quantitative studies on the uptake and retention of potato leafroll virus by aphids in laboratory and field conditions

Enzyme-linked immunosorbent assay (ELISA) was adapted for the efficient detection and assay of potato leafroll virus (PLRV) in aphids. Best results were obtained when aphids were extracted in 0.05 M phosphate buffer, pH 7.0, and the extracts incubated at 37 °C for 1 h before starting the assay. Using batches of 20 green peach aphids (Myzus persicae), about 0.01 ng PLRV/aphid could be detected. The virus could also be detected in single aphids allowed a 1-day acquisition access period on infected potato leaves. The PLRV content of aphids depended on the age of potato source-plants and the position of source leaves on them. It increased with increase in acquisition access period up to 7 days but differed considerably between individual aphids. A maximum of 7 ng PLRV/aphid was recorded but aphids more usually accumulated about 0.2 ng PLRV per day. When aphids were allowed acquisition access periods of 1–3 days, and then caged singly on Physalis floridana seedlings for 3 days, the PLRV content of each aphid, measured subsequently, was not strongly correlated with the infection of P. floridana. The concentration of PLRV in leaf extracts differed only slightly when potato plants were kept at 15, 20, 25 or 30 °C for 1 or 2 wk, but the virus content of aphids kept on leaves at the different temperatures decreased with increase of temperature. PLRV was transmitted readily to P. floridana at all temperatures, but by a slightly smaller proportion of aphids, and after a longer latent period, at 15 °C than at 30 °C. The PLRV content of M. persicae fed on infected potato leaves decreased with increasing time after transfer to turnip (immune to PLRV). The decrease occurred in two phases, the first rapid and the second very slow. In the first phase the decrease was faster, briefer and greater at 25 and 30 °C than at 15 and 20 °C. No evidence was obtained that PLRV multiplies in M. persicae. These results are compatible with a model in which much of the PLRV in aphids during the second phase is in the haemocoele, and transmission is mainly limited by the rate of passage of virus particles from haemolymph to saliva. The potato aphid, Macrosiphum euphorbiae, transmitted PLRV much less efficiently than M. persicae. Its inefficiency as a vector could not be ascribed to failure to acquire or retain PLRV, or to the degradation of virus particles in the aphid. Probably only few PLRV particles pass from the haemolymph to saliva in this species. The virus content of M. euphorbiae collected from PLRV-infected potato plants in the field increased from early June to early July, and then decreased. PLRV was detected both in spring migrants collected from the plants and in summer migrants caught in yellow water-traps. PLRV was also detected in M. persicae collected from infected plants in July and August, and in trapped summer migrants, but their PLRV content was less than that of M. euphorbiae, and in some instances was too small for unequivocal detection.     

Accumulation of potato virus Y is enhanced in Solatium brevidens also infected with tobacco mosaic virus or potato spindle tuber viroid

The accumulation of potato virus Y?(PVY?) and potato leaf roll virus (PLRV) was studied in plants of Solanum brevidens co-infected with each of six viruses or a viroid. Virus could not be detected by ELISA in plants of S. brevidens infected solely with PVY. However, accumulation of PVY was increased c. 1000-fold in plants doubly infected with tobacco mosaic virus or potato spindle tuber viroid (PSTVd). PVY titres in doubly infected plants of S. brevidens were between 1% and 0.1% of those found in the PVY-susceptible interspecific Solanum hybrid DTO-33. Double infections of 5. brevidens by PVY and alfalfa mosaic virus or potato viruses M, S, T or X did not significantly enhance PVY accumulation. Accumulation of PLRV was not enhanced in plants co-infected with any of the six viruses or PSTVd.     

温度对桃蚜和马铃薯长管蚜实验种群生命表参数的影响

【目的】桃蚜Myzus persicae (Sulzer)和马铃薯长管蚜Macrosiphum euphorbiae (Thomas)是2种主要的马铃薯害虫。本研究旨在明确温度对这两种马铃薯蚜虫生长发育、存活、繁殖及种群增长的影响。【方法】在室内测定了5个温度（10, 15, 20, 25和30℃）下桃蚜和马铃薯长管蚜的生长发育、存活和繁殖指标,并组建了4个恒温条件下（10,15,20和25℃）的实验种群生命表。【结果】在10~25℃范围内,2种蚜虫的若蚜期、世代历期、成蚜寿命和产蚜期等均随温度的升高而缩短,而30℃高温抑制了其发育、存活和繁殖。2种蚜虫的平均世代历期（T）随温度的升高而缩短,桃蚜和马铃薯长管蚜分别从10℃的30.08 d和35.35 d缩短至25℃的14.28 d和12.95 d。桃蚜的净增殖率（R₀）在15℃时最高（86.00）,其次为20℃（73.75）,再次为25℃（62.49）,最低为10℃（51.00）;马铃薯长管蚜的R0在15℃最高（58.97）,其次为10℃（51.98）,再次为20℃（48.94）,最低为25℃（12.36）。桃蚜的内禀增长率（r_m）随温度的升高而增大,从最小10℃的0.1307增大到25℃的0.2896;马铃薯长管蚜的r_m在20℃时最大（0.2182）,其次为25℃（0.1942）,再次为15℃（0.1485）,最小为10℃（0.1118）。在相同的温度下,桃蚜的发育速率、净增殖率和内禀增长率均高于马铃薯长管蚜。【结论】温度对2种马铃薯蚜虫的生长发育、存活、繁殖及种群增长有显著的影响,桃蚜在马铃薯上的种群增长能力强于马铃薯长管蚜。这一结果为马铃薯蚜虫预测模型的建立奠定了必要的基础,并解释了桃蚜在马铃薯上发生数量多于马铃薯长管蚜的原因。     

Behavior of bird cherry-oat aphid and green peach aphid in relation to potato virus Y transmission

Potato virus Y is transmitted to potato in a nonpersistent manner by many aphid species, some of which do not colonize this crop. The behavior of bird cherry-oat aphid, Rhopalosiphum padi (L.) on potato, Solanum tuberosum L., a plant species that is not colonized by this aphid, was described and compared with that of the potato-colonizing green peach aphid, Myzuspersicae (Sulzer). A higher proportion of winged morph of R. padi than M. persicae left the plant, but aphids that stayed in contact with the plant took the same mean time to initiate the first probe and it lasted the same mean time compared with M. persicae. Electronic penetration graph technique was used to study the probing behavior of the aphids during Potato virus Y (family Potyviridae, genus Potyvirus, PVY) transmission tests. Transmission rate decreased from 29 to 8% when the acquisition time increased from 5 min of continuous probing to 1 h with M. persicae, but it remained low (2 and 1%) with R. padi. Most of the difference in transmission rate between acquisition time with M. persicae and between aphid species was related to the change in the time and behavior taking place between the last cell puncture of the acquisition phase to the first cell puncture of the inoculation phase. Results presented here clearly demonstrated the importance of host plant selection and probing behavior in the transmission of nonpersistent plant viruses. They also stress the need to consider the behavior of the aphid in the design of laboratory tests of virus vector efficacy.     

Dynamics of Myzus persicae arrestment by volatiles from Potato leafroll virus‐infected potato plants during disease progression

Green peach aphid, Myzus persicae (Sulzer) (Hemiptera: Aphididae), an important pest of potato (Solanum tuberosum L.) (Solanaceae), preferentially settles on Potato leafroll virus (PLRV)‐infected potato plants as compared with non‐infected ones, primarily in response to volatile organic compounds (VOCs) released by the plants. In this study, we examined the dynamics of these effects, measuring arrestment of apterous M. persicae in response to VOC from upper, middle, and lower leaflets of PLRV‐infected potato plants at the same stage in disease progression (4 weeks after inoculation), but inoculated at 1, 3, or 5 weeks after transplanting (WAT). Sham‐inoculated plants were used as controls and VOC were collected and quantified. Aphid arrestment was greater on PLRV‐infected plants inoculated at 1 and 3 WAT as compared with sham‐inoculated plants, but this preference was reversed in plants inoculated at 5 WAT. Relative arrestment of M. persicae by infected plants and VOC release was greater for lower and middle leaflets than for upper leaflets at 1 and 3 WAT compared to sham‐inoculated plants. The reverse was observed in plants inoculated at 5 WAT. Findings indicate that aphid preference is influenced by VOC release from PLRV‐ or sham‐inoculated potato plants and that VOC emissions and aphid preference depend upon the age at inoculation and leaf position within the potato plants. The implications of these dynamics in vector behavior for spread of PLRV in the field in natural and managed systems are discussed.     

Construction of Plant Expression Vectors and Identification of Transgenic Potato Plants

Potato virus X (PVX), potato virus Y (PVY) and potato leaf roll virus (PLRV) infection in potato may result in the loss of centrification of seed potatoes and affect the quality and yield of potatoes in agricultural production. The authors cloned coat protein (cp) genes of PVX, PVY and PLRV and constructed two kinds of plant expression vector which contain PVX and PVY or PVY and PLRV cp genes. Three major commercial cultivars of potato and one cultivar of tobacco were transformed via Agrobacterium tumefaciens mediated procedure. Transgenic plants were confirmed by PCR analysis. Transgenic tobacco plants containing both PVX and PVY cp genes were significantly resistant to PVX and PVY infection via mechanical inoculation.     

Comparison of transmission efficiency of various isolates of Potato virus Y among three aphid vectors

Potato virus Y (PVY) strains are transmitted by different aphid species in a non‐persistent, non‐circulative manner. Green peach aphid (GPA), Myzus persicae Sulzer, is the most efficient vector in laboratory studies, but potato aphid (PA), Macrosiphum euphorbiae Thomas (both Hemiptera: Aphididae, Macrosiphini), and bird cherry‐oat aphid (BCOA), Rhopalosiphum padi L. (Hemiptera: Aphididae, Aphidini), also contribute to PVY transmission. Studies were conducted with GPA, PA, and BCOA to assess PVY transmission efficiency for various isolates of the same strain. Treatments included three PVY strains (PVY^O, PVY^N:O, PVY^NTN) and two isolates of each strain (Oz and NY090031 for PVY^O; Alt and NY090004 for PVY^N:O; N4 and NY090029 for PVY^NTN), using each of three aphid species as well as a sham inoculation. Virus‐free tissue‐cultured plantlets of potato cv. Russet Burbank were used as virus source and recipient plants. Five weeks post inoculation, recipient plants were tested with quantitative DAS‐ELISA to assess infection percentage and virus titer. ELISA‐positive recipient plants were assayed with RT‐PCR to confirm presence of the expected strains. Transmission efficiency (percentage infection of plants) was highest for GPA, intermediate for BCOA, and lowest for PA. For all aphid species, transmission efficiency did not differ significantly between isolates within each strain. No correlations were found among source plant titer, infection percentage, and recipient plant titer. For both GPA and BCOA, isolates of PVY^NTN were transmitted with greatest efficiency followed by isolates of PVY^O and PVY^N:O, which might help explain the increasing prevalence of necrotic strains in potato‐growing regions. Bird cherry‐oat aphid transmitted PVY with higher efficiency than previously reported, suggesting that this species is more important to PVY epidemiology than has been considered.     

双价外壳蛋白基因植物表达载体的构建及马铃薯转基因植株的鉴定

在克隆了马铃薯Ｘ病毒（ＰＶＸ）、马铃薯Ｙ 病毒（ＰＶＹ）和马铃薯卷叶病毒（ＰＬＲＶ）的外壳蛋白基因的基础上,构建同时包含ＰＶＸ和ＰＶＹ 与ＰＶＹ 和ＰＬＲＶ 两个外壳蛋白基因植物表达框架的表达载体,通过农杆菌（Ａｇｒｏｂａｃｔｅｒｉｕｍ ｔｕｍｅｆａｃｉｅｎｓ）介导转化烟草（Ｎｉｃｏｔｉａｎａｔａｂａｃｕｍ ）和生产上常用的几个马铃薯（Ｓｏｌａｎｕｍ ｔｕｂｅｒｏｓｕｍ ）优良品种：“Ｆａｖｏｒｉｔａ”、“虎头”、“克４”。经ＰＣＲ检测证明外源基因已整合到植物的染色体上,得到批量转基因植株。在转ＰＶＸ＋ＰＶＹ 外壳蛋白基因的烟草上接种ＰＶＸ （５ μｇ／ｍ Ｌ）、ＰＶＹ（２０ μｇ／ｍ Ｌ）病毒,得到有一定抗性的植株     

表达PVY和PLRV双价外壳蛋白基因马铃薯的抗病性研究

表达马铃薯Y病毒(PVY)和马铃薯卷叶病毒(PLRV)双价外壳蛋白基因的马铃薯(Solanum tubero-sum L.)栽培品种“Favorita”和“虎头”,经摩擦接种PVY和用桃蚜接种PLRV后,观察症状并用ELISA测定病毒滴度。结果表明,两个品种转双价CP基因的各株系,接种病毒后表现无症状或症状轻微,其中PVY和PLRV平均滴度均较不转基因对照植株低。不同品种对PVY和PLRV的抗性比较表明,转双价CP基因的“Favorita”对PVY抗性较明显,而转双价CP基因的“虎头”则对PLRV抗性较对PVY抗性明显。不同转基因株系抗病毒水平不同。“Favorita”9个转双价CP基因株系中有6个株系PVY滴度较未转基因对照降低52.5％～90.0％,而“虎头”7个转双价CP基因株系中有4个株系PLRV含量较对照降低53.0％～98.0％。在抗性株系中还出现一些抗1种病毒或抗2种病毒的抗性较强的单株。