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.     

Strong resistance to potato tuber necrotic ringspot disease in potato induced by transformation with coat protein gene sequences from an NTN isolate of Potato virus Y

The potato cv. Igor is susceptible to infection with Potato virus Y (PVY) and in Slovenia it has been so severely affected with NTN isolates of PVY causing potato tuber necrotic ringspot disease (PTNRD) that its cultivation has ceased. Plants of cv. Igor were transformed with two transgenes that contained coat protein gene sequence of PVY^NTN. Both transgenes used PVY sequence in a sense (+) orientation, one in native translational context (N‐CP), and one with a frame‐shift mutation (FS‐CP). Although most transgenic lines were susceptible to infection with PVY^NTN and PVY^O, several lines showed resistance that could be classified into two types. Following manual or graft inoculation, plants of partially resistant lines developed some symptoms in foliage and tubers, and virus titre in the foliage, estimated by ELISA, was low or undetectable. In highly resistant (R) lines, symptoms did not develop in foliage and on tubers, and virus could not be detected in foliage by ELISA or infectivity assay. Four lines from 34 tested (two N‐CP and two FS‐CP) were R to PVY^NTN and PVY^O and one additional line was R to PVY^O. When cv. Spey was transformed with the same constructs, they did not confer strong resistance to PVY^O.     

Determination of aphid transmission efficiencies for N, NTN and Wilga strains of Potato virus Y

Potato virus Y (PVY, genus Potyvirus, family Potyviridae) causes high economic losses worldwide, especially in the production of seed potatoes (Solanum tuberosum). PVY control systems rely on measuring virus pressure and vector pressure in the field. Calculation of the vector pressure is based on the relative efficiency factors (REFs) of aphid species. These REFs express the transmission efficiency of aphid species in relation to the transmission efficiency of Myzus persicae, the most efficient vector of PVY. In this paper, we report on the determination of aphids' relative transmission efficiency factors (REFs) for isolates of the PVY strains PVY^N, PVY^NTN and PVY^N-Wi. Biotype Mp2 of M. persicae was tested for its transmission efficiency for six PVY isolates (one PVY^N, three PVY^NTN and two PVY^N-Wi isolates) and showed comparable average transmission efficiencies for all isolates. The transmission rate of this biotype for the six PVY isolates was set to 1 and Mp2 was used as an internal control in transmission experiments to determine the REFs of three other biotypes of M. persicae and 16 other aphid species (three biotypes per species when available) for the six PVY isolates. Comparing the calculated REFs for PVY^N with the REFs reported in the previous century for PVY^N, we observe overall comparable REFs, except for Aphis fabae, Aphis spp., Hyperomyzus lactucae, Macrosiphum euphorbiae and Rhopalosiphum padi, which have a lower REF in our experiments, and Aphis frangulae and Phorodon humuli, which have now a higher REF. Comparing the new REFs found for the PVY^NTN strains with the new REFs for PVY^N, we observe that they are overall comparable, except for A. frangulae (0.17 compared with 0.53) and Schizaphis graminum (0.05 compared with 0.00). Comparing the REFs calculated for PVY^N-Wi with those calculated for PVY^N, we can observe six aphid species with higher REFs (Acyrthosiphon pisum, A. fabae, Aphis nasturtii, Aphis spp., P. humuli and R. padi). Only the species A. frangulae shows a lower REF for PVY^N-Wi compared with the transmission efficiency of PVY^N. Three aphid species (Aulacorthum solani, Myzus ascalonicus and S. graminum) for which no REF was determined earlier were found to be capable to transmit PVY and their REFs were determined.     

Primary Metabolism,Phenylpropanoids and Antioxidant Pathways Are Regulated in Potato as a Response to Potato virus Y Infection

Potato production is one of the most important agricultural sectors, and it is challenged by various detrimental factors, including virus infections. To control losses in potato production, knowledge about the virus—plant interactions is crucial. Here, we investigated the molecular processes in potato plants as a result of Potato virus Y (PVY) infection, the most economically important potato viral pathogen. We performed an integrative study that links changes in the metabolome and gene expression in potato leaves inoculated with the mild PVY^N and aggressive PVY^NTN isolates, for different times through disease development. At the beginning of infection (1 day post-inoculation), virus-infected plants showed an initial decrease in the concentrations of metabolites connected to sugar and amino-acid metabolism, the TCA cycle, the GABA shunt, ROS scavangers, and phenylpropanoids, relative to the control plants. A pronounced increase in those metabolites was detected at the start of the strong viral multiplication in infected leaves. The alterations in these metabolic pathways were also seen at the gene expression level, as analysed by quantitative PCR. In addition, the systemic response in the metabolome to PVY infection was analysed. Systemic leaves showed a less-pronounced response with fewer metabolites altered, while phenylpropanoid-associated metabolites were strongly accumulated. There was a more rapid onset of accumulation of ROS scavengers in leaves inoculated with PVY^N than those inoculated with PVY^NTN. This appears to be related to the lower damage observed for leaves of potato infected with the milder PVY^N strain, and at least partially explains the differences between the phenotypes observed.     

Production of monoclonal antibodies for the detection of potato virus Y

Monoclonal antibodies (McAb) were obtained to potato virus Y (PVY) after immunisation of BALB/c mice with purified PVY, tobacco necrotic strain (PVY_n). Spleen cells from a mouse showing a high serum titre were used for fusion with X63NS1 myeloma cells. Hybridomas were selected in medium containing HAT. Culture supernatants were screened for antibody production against PVY, ordinary strain (PVY₀) and PVY_n using indirect ELISA. Clones of interest were further cross-reacted with 12 isolates each of PVY₀ and PVY_n and two isolates of potato virus A (PVA) and healthy sap. For further trials, two clones which reacted specifically with PVY_n isolates and one which detected all PVY isolates except two of potato virus C (PVC) were selected.     

Capacity assessment of <Emphasis Type="Italic">Myzus persicae,Aphis gossypii</Emphasis> and <Emphasis Type="Italic">Aphis spiraecola</Emphasis> (Hemiptera: Aphididae) to acquire and retain PVY<Superscript>NTN</Superscript> in Tunisia

The study was carried out to investigate the ability of three aphids, Myzus persicae, Aphis gossypii and Aphis spiraecola, to acquire and retain the Potato Virus Y (PVY) isolate, PVY^NTN. Tobacco plants, Nicotiana tabacum var. Xanthi, were used as test plant for the virus inoculation and aphid acquisition. The serological test double-antibody sandwich enzyme-linked immunosorbent assay was applied for virus detection on the test plants and aphids. Furthermore, virus retention by aphids was also assessed using a monoclonal anti-PVY^N. Although a duration of 2 min was enough for the virus acquisition, the three tested aphids showed different capacities to retain PVY^NTN. The retention of PVY^NTN was 3 h for M. persicae and A. spiraecola, and 2 h for A. gossypii. This study provides basic information of the virus retention by potato-colonizing aphid species, which may increase our understanding of PVY epidemiology in Tunisia.     

黑龙江马铃薯Y病毒P1基因的特点北大核心CSCD

【目的】本研究通过对不同PVY分离物基因的测序及分析,从而了解PVY株系的多样性,进而对PVY病毒的分子检测及防治提供重要的资料和参考。【方法】本研究针对黑龙江15个马铃薯Y病毒样品的P1基因进行克隆测序和进化树分析。【结果】经比对分析,样品被分成两组,有10个样品的基因类型高度同源,且相对保守,是本地区的优势群组,无论是与国内其它地区样品比较还是与国外样品比较,其亲缘关系都有一定距离;而另一组中的5个样品的P1基因与本地优势组群有较大差异,且这5个样品间也有一定的差异,并与国内其它地区和国外一些样品的P1基因序列比较接近。通过比对Gen Bank中已上传的序列提供的PVY株系的信息,得知本次试验的P1基因与PVY^(NTN-NW)株系是相似的,且这15个样品与国内其他样品一样都是由PVY^N株系演变而来。【结论】由P1基因分析表明,PVY受环境影响较大,黑龙江10个样品的PVY在长期的进化中产生了具有地方特点的变化,而后来的5个样品说明中国大部分PVY有可能是跟随国外品种资源的引进进入,同时PVY也随国内不同区域间资源交流和种薯调运而传播。     

Generation of transgenic potato plants highly resistant to potato virus Y (PVY) through RNA silencing

In this study we applied RNA silencing to engineer potato plants that are resistant to potato virus Y (PVY). We expressed double-stranded (ds) RNA derived from the 3 terminal part of the coat protein gene of PVY, which is highly conserved in sequence amongst different PVY isolates, in transgenic potatoes of the commercial variety Spunta. Transgenic plants were analyzed for generation of transgene-derived short interfering RNAs (siRNAs) prior to virus inoculation. Twelve of fifteen transgenic lines produced siRNAs and were highly resistant to three strains of PVY, each belonging to three different subtypes of the virus (PVY^N, PVY^O and PVY^NTN). Infection of transgenic plants with Potato virus X (PVX) simultaneously or prior to the challenge with PVY did not interfere with PVY-resistance.Anastasia Missiou: M.A. and K.K. have contributed equally to this workKriton Kalantidis: M.A. and K.K. have contributed equally to this work     

The participation of plant cell organelles in compatible and incompatible potato virus Y-tobacco and -potato plant interaction

Potyviruses replicate and express their genomes in the cytoplasm in closely related membranous structures such as the endoplasmic reticulum or in the vicinity of the ER. The present research demonstrates the participation of plant cell organelles based on ultrastructural examination of compatible and incompatible interactions in tobacco- and potato-potato virus Y (PVY) necrotic strains. In two interaction types, PVY^N Wi and PVY^NTN particles were documented inside cell nuclei. Virus cytoplasmic inclusions and particles were associated with nuclear envelope pore complexes. Moreover, the PVY capsid protein was immunolocalised in the cell nucleus and nucleolus. Our results for the first time show PVY particles and capsid proteins inside the mitochondrion in compatible interactions, whereas in hypersensitive responses these interactions were identified inside chloroplasts. The PVY particles attached to mitochondria caused association groups of these organelles. The ultrastructural analysis clearly demonstrated both the dynamics of the endoplasmatic reticulum in two types of PVY interactions and connections between PVY cytoplasmic inclusions and particles with its membranous structures. Moreover, we demonstrated strongly localised immunodetection of the PVY capsid protein on the surface and in the vicinity of ER in cases of hypersensitive response as well as in compatible interaction.     

Ultrastructural events during hypersensitive response of potato cv. Rywal infected with necrotic strains of potato virus Y

Potato plants cv. Rywal with hypersensitivity gene Ny-1 infected with PVY^N or PVY^NTN reacted in local necroses 3 days after infection. Potato virus Y (PVY) particles were found in epidermis, mesophyll, phloem and xylem cells in inoculated leaves. Noncapsidated virus particles (without capsid protein) were observed already 10 h after infection by using electron microscopy in situ. Capsid protein on one terminus of noncapsidated virus particles was located 5 days after inoculation with the use of immunogold labeling method. Whereas cytoplasmic inclusions were observed for the first time 24 days after infection during hypersensitive response. Ultrastructural studies showed that ER may take part in PVY RNA replication and capsidation of Potyvirus particles. Observed cytopathological changes and virus particles indicate that cell nucleus and mitochondrion might participate in PVY life cycle. During hypersensitive response PVY particles were found in plasmodesmata as well as in phloem and xylem.     

Optimum Conditions for the Storage of Potato Virus YNTN Strain

The effect of storage conditions on the serological activity of two isolates of potato virus Y^NTN strain (PVY^NTN) was studied by ELISA. Purified virus, intact and homogenized infected leaves stored freeze-dried and frozen at various temperatures were tested. Purified virus was the most stable at +4 °C and non-purified virus was best preserved as a freeze-dried leaf homogenate at –20 °C. Their serological activity did not change after three months of storage.     

The novel gene Ny-1 on potato chromosome IX confers hypersensitive resistance to Potato virus Y and is an alternative to Ry genes in potato breeding for PVY resistance

Hypersensitive resistance (HR) is an efficient defense strategy in plants that restricts pathogen growth and can be activated during host as well as non-host interactions. HR involves programmed cell death and manifests itself in tissue collapse at the site of pathogen attack. A novel hypersensitivity gene, Ny-1, for resistance to Potato virus Y (PVY) was revealed in potato cultivar Rywal. This is the first gene that confers HR in potato plants both to common and necrotic strains of PVY. The locus Ny-1 mapped on the short arm of potato chromosome IX, where various resistance genes are clustered in Solanaceous genomes. Expression of HR was temperature-dependent in cv. Rywal. Strains PVY^O and PVY^N, including subgroups PVY^NW and PVY^NTN, were effectively localized when plants were grown at 20°C. At 28°C, plants were systemically infected but no symptoms were observed. In field trials, PVY was restricted to the inoculated leaves and PVY-free tubers were produced. Therefore, the gene Ny-1 can be useful for potato breeding as an alternative donor of PVY resistance, because it is efficacious in practice-like resistance conferred by Ry genes.     

Molecular and Biological Characterization of Potato virus Y Isolates from Vietnam

Eight isolates from different potato growing regions in Vietnam were characterized. All were highly pathogenic in some potato cultivars, but did not overcome the extreme resistance of Solanum stoloniferum and Solanum demissum. RT‐PCR analysis revealed that all of these isolates are recombinants. Sequence data for 4 isolates were obtained, and their reaction in potato cultivars harbouring specific N genes was determined. Different phylogenetic analyses of viral sequences confirmed previous results that the recombinant isolates evolved from different parental sequences. One of the Vietnamese isolates investigated had a specific structure. The need for a clear classification of PVY^NWi isolates is discussed.     

Phylogeography of Asparagopsis taxiformis revisited: Combined mtDNA data provide novel insights into population structure in Japan

Six intraspecific lineages (Lineages 1–6) of Asparagopsis taxiformis have been previously established based on mitochondrial cox2‐cox3 intergenic spacer and a partial cox1 sequences. ‘Lineage 2’ (L2) was suggested to be a recent introduction to the Mediterranean Sea, but its source population has not yet been identified. In order to clarify the nature of northwestern Pacific populations, we performed extensive sampling in Japan (60 individuals from 16 locations) and molecular phylogenetic analyses based on mitochondrial sequences. Sixteen additional individuals, collected from eight locations in the Indo‐Pacific, Caribbean, and Mediterranean regions, were also analyzed. Combined sequence analyses revealed that the Japanese populations only consisted of L2. Out of 19 combined haplotypes identified within L2, two are shared between Japan and the Mediterranean Sea and the Hawaiian Islands, and 12 were identified as endemic to Japan. Genetic analyses of population differentiation suggested that Japanese populations are genetically isolated from the Mediterranean and the Hawaiian populations. A genetic disjunction appears to separate two subpopulations within Japan: one between Toi and Kagoshima and the other between Ojikajima Island and Kagoshima in the Kyushu area.     

Comparison of resistance to potyviruses within Solanaceae: infection of potatoes with tobacco etch potyvirus and peppers with potato A and Y potyviruses

The reaction of several cultivated potato varieties (Solarium tuberosum L.) to three strains of tobacco etch potyvirus (TEV-F, TEV-Mex21 and TEV-ATCC) and the reaction of several pepper lines (Capsicum annuum L. and C. chinense L.) to two strains of potato Y potyvirus (PVY^O and PVY^N) and one strain of potato A potyvirus (PVA-M) was tested. The potato varieties included in this study carried resistance genes against PVY, PVA and potato V potyvirus, but all were susceptible to TEV and developed mottle and mosaic symptoms. TEV was readily transmitted by mechanical inoculation from tobacco and potato to potato, whereas transmission from pepper to potato occurred infrequently. TEV was transmitted through potato tubers, and from pepper to potato plants by aphids. Lack of detectable systemic infection following graft-inoculation indicated extreme resistance to PVY^O and PVA in several pepper lines. No pepper line was systemically infected with PVY^N following mechanical inoculation (graft-inoculation was not carried out with PVY^N). The development of necrotic lesions following mechanical and graft-inoculation indicated hypersensitive response to PVY^O in several pepper lines which resembled the resistance responses to these potyvirus strains in potato. Results of this study together with previous work indicate that C. annuum cv. Avelar is resistant to four potyviruses [PVY, PVA, pepper mottle potyvirus (PepMoV) and some isolates of TEV]; C. annuum cv. Criollo de Morelos and C. chinense PI 152225 and PI 159236 are resistant to three potyviruses (PVY, PepMoV and PVA; and PVY, PepMoV and TEV, respectively); C. annuum 9093–1 and 92016–1 are resistant to PVY and PepMoV; and C. annuum cv. Jupiter and C. annuum cv. RNaky are resistant to PVY^N and PVA.     

Linking belowground and aboveground phenology in two boreal forests in Northeast China

Plants are frequently attacked by both pathogens and insects, and an attack from one can induce plant responses that affect resistance to the other. However, we currently lack a predictive framework for understanding how pathogens, their vectors, and other herbivores interact. To address this gap, we have investigated the effects of a viral infection in the host plant on both its aphid vector and non-vector herbivores. We tested whether the infection by three different strains of Potato virus Y (PVY^NTN, PVY^NO and PVY^O) on tomato plants affected: (1) the induced plant defense pathways; (2) the abundance and fecundity of the aphid vector (Macrosiphum euphorbiae); and (3) the performance of two non-vector species: a caterpillar (Trichoplusia ni) and a beetle (Leptinotarsa decemlineata). While infection by all three strains of PVY induced the salicylate pathway, PVY^NTN induced a stronger and longer response. Fecundity and density of aphids increased on all PVY-infected plants, suggesting that the aphid response is not negatively associated with salicylate induction. In contrast, the performance of non-vector herbivores positively correlated with the strength of salicylate induction. PVY^NTN infection decreased plant resistance to both non-vector herbivores, increasing their growth rates. We also demonstrated that the impact of host plant viral infection on the caterpillar results from host plant responses and not the effects of aphid vector feeding. We propose that pathogens chemically mediate insect–plant interactions by activating the salicylate pathway and decreasing plant resistance to chewing insects, which has implications for both disease transmission and insect community structure.     

全基因组序列的系统发育与重组分析鉴定我国马铃薯Y病毒株系

为明确我国马铃薯Y病毒(Potato virus Y,PVY)株系组成及其在不同寄主上的分布特征,文章对31条PVY中国分离物的基因组编码区进行了系统发育及重组分析。系统发育分析结果显示,最大似然法(maximum likelihood,ML)和邻接法(neighbor-joining,NJ)重建的系统发育拓扑结构基本一致,GF_YL20、FZ10、DF、SD1、1116和9703-3等6个分离物均未与已知株系相聚,其他株系来源相同的分离物以较高的自展值相聚成簇,显示出较强的株系特异性。重组分析显示,31个PVY分离物中,共有28个PVY分离物均检测到具有显著的重组信号,这些分离物主要包括PVY~(N-Wi)、PVY~(NTN)和PVY~(NTN-NW)三种株系。进一步分析显示,分离物1104、DF、SD1、1116和9703-3为未报道过的PVY新重组分离物。株系统计结果显示PVY重组株系已上升为优势株系,生产上需要密切注意这些株系,尤其新重组分离物的发展动态。以上结果表明,综合应用PVY全基因组序列的系统发育和重组分析,可以实现PVY株系的准确鉴定。